A salt-containing water desalination treatment device for concentrating and crystallizing high-salt wastewater by means of a heat pump, comprising a heat pump unit, a concentrated brine evaporation chamber and a water vapor condensation chamber, and consisting of a hot air evaporation concentrated brine crystallization salt-containing device. A high-temperature and high-pressure refrigerant heat source is provided by means of a compressor (20) of the heat pump unit. A water-cooled condenser is used as a concentrated brine heater. An air-cooled condenser is used as an air heater. A throttling device (21) inputs a refrigerant into an evaporator to evaporate and absorb heat as a cold source for the condensation of evaporated water vapor. The refrigerant vapor that has evaporated and absorbed heat is inputted into the compressor (20) to form a cycle. A heat pump condensation device has at least two stages. the first stage is to heat concentrated brine, and the second stage is to heat air, which constitutes the condensation of a heat pump refrigerant. The condensed heat pump refrigerant enters a heat pump evaporation device by means of the throttling device (21) to absorb heat and evaporate. The heat pump evaporation device is at least one stage, and condenses the vapor evaporated by means of negative pressure. The heat pump evaporation device absorbs the heat of the water vapor to provide the heat pump with the evaporation heat of the refrigerant, so that the heat pump has a highly efficient heat cycle.
A water treatment device for concentrating, crystallizing and desalting high-salinity wastewater by means of a lithium bromide unit, the device comprising a lithium bromide unit, a strong brine evaporation chamber and a water vapor condensation chamber, and being composed of a crystallization salt-containing device for evaporating strong brine by means of hot air. Hot circulating water heated by an absorber (23) and a condenser (21) of the lithium bromide unit is used as a heat source for heating strong brine and air to cool the hot circulating water of the lithium bromide unit and is used as a heat source for evaporating, concentrating and crystallizing the strong brine. The cooled circulating water is heated by the absorber (23) and the condenser (21) to form a cycle. Refrigerant circulating water evaporated and cooled by the lithium bromide unit is used as a condensation cold source for spraying and evaporating water vapor. The refrigerant circulating water heated by absorbing heat enters an evaporator (37) of the lithium bromide unit to release heat and cool, and is then input into the water vapor condensation chamber to condense negative-pressure vapor in the water vapor condensation chamber. An induced fan (4) induces air to heat air by means of an air heater, and the hot air evaporates the strong brine lifted by spraying and water lifting devices (1) to finally generate crystallized salt.
F25B 15/06 - Machines, installations ou systèmes à sorption, à marche continue, p. ex. à absorption sans gaz inerte le frigorigène étant de la vapeur d'eau évaporée d'une solution salée, p. ex. bromure de lithium
C02F 1/04 - Traitement de l'eau, des eaux résiduaires ou des eaux d'égout par chauffage par distillation ou évaporation
3.
DEVICE FOR PREPARING PURE CONDENSATE WATER FROM THERMAL POWER PLANT TURBINE CONDENSER CONDENSATE WATER
A device for preparing pure condensate water from thermal power plant turbine condenser condensate water, comprising a turbine condenser device, a condensate water purification treatment device, and a pure condensate water canning device. The condensate water passes through a condensate water pump (12) and is pumped into a condensate water filter module (11); condensate water filtered by the condensate water filter module (11) is input into a pure condensate water reverse osmosis treatment device by means of a condensate water reverse osmosis high-pressure water pump (10); the concentrated condensate water containing ammonia ions is discharged by the pure condensate water reverse osmosis treatment device, and the concentrated condensate water is supplemented into a boiler water supplementing device by means of a pipeline; the pure condensate water treated by the pure condensate water reverse osmosis treatment device is input into a pure condensate water tank (23), and the pure condensate water in the pure condensate water tank (23) is pumped into a pure condensate water main pipe (24) by means of the pure condensate water pump (25) or supplied in multiple ways. According to the device, condensate water of a power plant is fully utilized, chemicals are not needed, the requirements of people for pure drinking water are met, materials can be obtained nearby, and the problem that drained water produced during drinking water production pollutes the environment is solved.
Disclosed is a device for preparing pure condensate water and comprehensively utilizing chemical water treatment resources in a thermal power plant. The device comprises a steam turbine condenser device, a condensate water purification treatment device, a pure condensate water tanking device and a chemical water treatment device. Disclosed is a device for preparing pure condensate water and comprehensively utilizing chemical water treatment resources in a thermal power plant. The device comprises a turbine condenser device, a condensate water purification treatment device, a pure condensate water tanking device and a chemical water treatment device. The concentrated condensate water containing ammonia ions is discharged by means of the pure condensate water reverse osmosis treatment device and is supplemented into a boiler water supplementing device by means of a pipeline. Softened water generated by a chemical water treatment device is recycled, and acidic and basic wastewater generated by the chemical water treatment device reacts with raw water and is recycled. The pure condensate water treated by the pure condensate water reverse osmosis treatment device is divided into multiple streams for water supply. Condensate water of a power plant is fully utilized without a chemical being needed, such that people's requirements for pure drinking water are met, nearby materials can be used, and the problem of the environment being polluted by the water discharged during drinking water production is solved.
A raw water heating and hard water removal treatment device, comprising coarse filtration and activated carbon filtration, wherein raw water is pressurized and pumped out by means of a water pump, and passes through an injector to mixed with a gravel abrasive, or the raw water is mixed with the gravel abrasive and then passes through the water pump so as to set the flow rate, and is thereafter inputted into a heating side and final-stage heater of a multi-stage vertical or horizontal heat exchanger (1), and the raw water is heated to a set temperature from an initial room temperature. The foregoing process causes temporary and permanently hard components in the raw water to undergo a decomposition reaction under heat, and produce calcium carbonate precipitates and magnesium carbonate precipitates. A gravel abrasive is added to the raw water, so that the gravel abrasive in the water rubs against limescale on pipe walls of the vertical heat exchanger (1), thereby rubbing off the limescale and keeping the pipe walls clean. According to the apparatus, a cooling side of the multi-stage vertical or horizontal heat exchanger (1) reduces the water temperature to a set temperature, and boiled water the temporary and permanently hard components of which are removed is obtained by means of filtration; the utilization rate of raw water is high, there is no need for the use of drugs, energy is conserved, discharge is reduced, and the problems of scaling on the heat exchange surface of the heat exchanger, low thermal efficiency, high power consumption, and environment pollution are resolved.
A device for producing pure plain boiled drinking water by heating and removing hard substances from raw water and without wastewater discharge. A production process comprises: rough filtration and activated carbon filtration, after pressurization by using a water pump, pumping raw water out, mixing same with sand abrasives, then feeding same into a heating side of a multi-stage vertical or horizontal heat exchanger and a final-stage heater, and heating the raw water to a set temperature. Temporarily hard and perpetually hard substances in the raw water are reacted and decomposed by heating to generate calcium carbonate precipitates and magnesium carbonate precipitates. The sand abrasives are added into the raw water, such that the sand abrasives in the water and scale on a tube wall of the vertical heat exchanger are rubbed to keep the tube wall clean. The water temperature is lowered to an appropriate set temperature by means of a cooling side of the multi-stage vertical or horizontal heat exchanger of the device, and plain boiled water from which the temporarily hard and perpetually hard substances are removed is obtained by means of filtration. Plain boiled water meeting different indicator requirements can be obtained by means of exhausting, multi-stage filtration and reverse osmosis. The device has a high utilization rate of raw water, drugs are not needed to be used in same, same is energy saving and has reduced emissions, and the problems of scaling on the heat exchange surface of the heat exchanger, a low thermal efficiency, large energy consumption, and environmental pollution are solved.
A dual-interface display smart phone provided with a double-sided touch display screen and a back input keyboard, provided with a front touch display screen (1) and a back touch display screen (12). The front touch display screen (1) is a full touch display screen, and at least the inner side of one side frame of the back touch display screen (12) is provided with camera assemblies which are arranged in a line. The dual-interface display smart phone can realize that the two screens simultaneously display the same interface, or the two screens simultaneously display different interfaces, or a single screen displays the same interface, or a single screen displays different interfaces, or single-screen display is manually controlled, or single-screen display is controlled in an automatic sensing mode. When the two touch display screens are arranged on the back, the function of setting a standard keyboard or a self-setting function keyboard can be realized by means of an input keyboard on the back touch display screen (12) and an input keyboard on the front touch display screen (1). The powerful function of a rear-facing camera is fully exerted, the utilization rate of the rear-facing camera is improved, and interface exchange can be realized by means of the double-screen back input keyboard and the double-screen dual-interface display.
A photovoltaic concrete precast panel having built-in energy storage devices (4) and a thermal and acoustic insulation material core layer, and a construction method therefor. The photovoltaic concrete precast panel comprises a reinforcing grid (3) provided with a reinforcing frame (5) on the periphery, energy storage devices (4), a mesh rack, and a thermal and acoustic insulation material core layer; the reinforcing grid (3) is bound by a rope (10) or fixedly connected by a connecting piece (12); the energy storage devices (4) are provided on one side in the outer wall reinforcing grid (3); the thermal and acoustic insulation material core layer is provided in the mesh rack; the mesh rack is placed in a precasting mold and concrete is poured for precasting, and after demolding and drying, a photovoltaic cell module (8) is pasted by a waterproof adhesive to the outer surface of the concrete precast panel having built-in energy storage devices (4) and a thermal and acoustic insulation material core layer, to prepare a photovoltaic concrete precast panel having built-in energy storage devices (4) and a thermal and acoustic insulation material core layer. The concrete precast panel can control smog by means of an energy storage function, and has good thermal and acoustic insulation performance.
E04C 2/30 - Éléments de construction de relativement faible épaisseur pour la construction de parties de bâtiments, p. ex. matériaux en feuilles, dalles ou panneaux caractérisés par la forme ou la structure
9.
CONCRETE PREFABRICATED FLOOR SLAB WITH BUILT-IN ENERGY STORAGE TANK
Disclosed is a concrete prefabricated floor slab with a built-in energy storage tank, the concrete prefabricated floor slab comprising concrete, reinforcing steel bars and connecting members. The reinforcing steel bars, and a reinforcement mesh frame integrated with an energy storage tank are placed in a prefabricated formwork, and then the concrete is poured for prefabricated forming. The two opposite ends of the concrete prefabricated floor slab with a built-in energy storage tank are provided with reinforcement heads, which are used for connection with other reinforcing steel bars, for connection with other structures. Concrete pouring is used for improving the strength. The energy storage tank is a tubular tank body with both ends being sealed and filled with an energy storage liquid, and the tubular tank body is provided with a pipe port for filling the energy storage liquid and gas. The energy storage tank is internally provided with an expansion space for thermal expansion and cold contraction of the energy storage liquid, and the energy storage tank is filled with gas higher than the atmospheric pressure, such that the energy storage tank forms a rigid body. A filling pipe opening of the energy storage tank is provided with a pressure relief safety valve, with an opening of the pressure relief safety valve facing downwards and being sealed with cement grout. When there is a fire, the energy storage liquid in the energy storage tank is vaporized at a high temperature to generate high vapor pressure, such that the pressure relief safety valve is opened to perform spray fire-extinguishing for an indoor fire.
A prefabricated concrete slab having built-in energy accumulators (4) and a core layer made of a thermal insulation and sound insulation material, comprising reinforced grids (3) with a reinforced frame (5) provided on the periphery, energy accumulators (4), and a core layer made of a thermal insulation and sound insulation material. The reinforced grids (3) are tied by ropes (6) or fixedly connected by connecting pieces (8) to form a grid framework having a reinforced frame (5) on the periphery, reinforced grids (3) on two sides, energy accumulators (4) provided on at least one side of the external wall reinforced grids (3), and a core layer made of a thermal insulation and sound insulation material inside. The grid framework is placed in a prefabricating mold, and concrete (2) is then poured to form a prefabricated product. The wall can control the haze by means of the energy accumulation function, achieve good heat preservation performance and sound insulation performance, save the concrete and steel, improve the overall strength of a building, make full use of the wastes, and protect the natural environment.
E04C 2/30 - Éléments de construction de relativement faible épaisseur pour la construction de parties de bâtiments, p. ex. matériaux en feuilles, dalles ou panneaux caractérisés par la forme ou la structure
11.
CONCRETE PRECAST PLANTING SLAB PROVIDED WITH ENERGY STORAGE PIPE AND HEAT AND SOUND INSULATION MATERIAL SANDWICH LAYER
A concrete precast planting slab internally provided with energy storage tanks (4) and a heat and sound insulation material sandwich layer, the slab comprising: the heat and sound insulation material sandwich layer, the energy storage tanks (4), reinforcing grids (3), a reinforced frame (5), connecting members (11), and concrete (2). At least one group of parallel horizontally distributed reinforcing grids (3) the outer perimeters of which are provided with the reinforced frame (5) are connected to partition grids (3) to form slotted reinforcing grids (3). The slotted reinforcing grids (3) pass through and connect to the reinforcing grids (3) the perimeters of which are provided with the reinforced frame (5), as well as to the energy storage tanks (4) and the heat and sound insulation material sandwich layer. The reinforcing grids (3) the perimeters of which are provided with the reinforced frame (5) are bound by using a rope (9) or are boltedly fixed by the connecting members (11) for connection. Thus, a grid frame is produced in which the reinforced frame (5) is provided at the periphery, the reinforcing grids (3) are provided on both sides, the energy storage tanks (4) are disposed on at least one side of an outer wall within the reinforcing grids (3), and the heat and sound insulation material sandwich layer is provided at the interior. The grid frame is placed within a prefabricated mold and is prefabricated by pouring concrete (2). By means of a wall energy storage function, haze is processed, heat insulation performance and sound insulation performance are good, and concrete and steel are saved; moreover, the overall strength of a building can be improved, the application value of waste can be fully mined, and the natural environment can be protected.
E04C 2/30 - Éléments de construction de relativement faible épaisseur pour la construction de parties de bâtiments, p. ex. matériaux en feuilles, dalles ou panneaux caractérisés par la forme ou la structure
12.
FLOOR-HEATING PIPE HAVING ELECTRICAL WIRE ELECTRODES COMPOUNDED ON INNER WALL OF PLASTIC PIPE
A floor-heating pipe having electrical wire electrodes (2) compounded on the inner wall of a plastic pipe (1), comprising the plastic pipe (1), and the electrical wire electrodes (2) on the pipe wall, wherein two electrical wire electrodes (2) are mutually electrically insulated and symmetrically arranged on the diameter of the inner wall of the plastic pipe (1) in parallel straight lines or in a parallel winding mode. Water formed between the two electrical wire electrodes (2) at the inner wall of the pipe is electrically connected in parallel to the two electrical wire electrodes (2) to constitute an electrical circuit in which the electrical wire electrodes (2) generate heat by means of water resistance. Safe electric heating of the electrically heated floor-heating pipe is achieved by directly powering the two electrical wire electrodes (2) compounded on the inner wall of the plastic pipe, and utilizing the inherent resistance of water between the two electrical wire electrodes (2) inside the plastic pipe (1) to generate heat. Further disclosed is a fabrication method for the floor-heating pipe having the electrical wire electrodes (2) compounded on the inner wall of the plastic pipe (1).
Provided is an electric heating-hot water radiant floor heating tube having a corrugated stainless steel tube (1) combined with electrical wire electrodes (2), comprising the corrugated stainless steel tube (1) and the electrical wire electrodes (2), wherein the two electrical wire electrodes (2) that are in good electrical connection with an outer wall of the corrugated stainless steel tube (1) are symmetrically arranged on the diameter of the outer wall of the corrugated stainless steel tube (1). The corrugated stainless steel tube (1) with the outer wall combined with the electrical wire electrodes (2) conducts electricity and emits heat by means of walls of the corrugated stainless steel tube (1) between the two electrical wire electrodes (2), and forms, together with hot water in the corrugated stainless steel tube (1), a hot water and electric heating double-heat-source corrugated stainless steel radiant floor heating tube. Further provided is a manufacturing method for the electric heating-hot water radiant floor heating tube.
A corrugated stainless steel pipe composite electric wire electrode electric-heating and hot water dual-form heat source floor heating device, a floor heating pipe (6) and a fabrication method therefor. The floor heating device comprises a corrugated stainless steel pipe, electric wire electrodes (21), a bearing positioning groove plate (9), a floor (12), a water distribution device, a water pump (15), a hot water source, and a smart temperature control power supply (19). The device is respectively electrically connected to a live wire (4) and a neutral wire (7) of a power line by means of the two electric wire electrodes (21), such that water in the wall of the corrugated stainless steel pipe and water in the pipe channel form an electric water-heating circuit with the wall of the corrugated stainless steel pipe by means of the two electric wire electrodes (21). Pipe openings at the two ends of the corrugated stainless steel pipe are connected to the water distribution device by means of electrically insulated connection pipe fittings.
F24D 13/04 - Systèmes de chauffage électrique utilisant le chauffage électrique d'un fluide échangeur de chaleur dans des éléments du système séparés
F24D 19/10 - Aménagements ou montage des dispositifs de commande ou de sécurité
F16L 53/34 - Chauffage des tuyaux ou des systèmes de tuyaux en utilisant des champs électriques, magnétiques ou électromagnétiques, p. ex. chauffage par induction, diélectrique ou par micro-ondes
15.
ELECTRIC HOT WATER DOUBLE-FORM HEAT SOURCE FLOOR HEATING DEVICE HAVING PLASTIC TUBE INNER WALL COMPOSITE WIRE ELECTRODE TUBE
Disclosed are an electric hot water double-form heat source floor heating device having a plastic tube inner wall composite wire electrode tube, and a manufacturing method therefor. The floor heating device comprises a plastic tube inner wall composite electric wire electrode floor heating tube (6), a floor heating tube electric connection export electrode electric insulation tube fitting, a bearing positioning groove plate (9), a floor board (12), a water distribution device, a water pump (15), a hot water source, and an intelligent temperature control power source (19), wherein two electric wire electrodes (21) are distributed on an inner tube wall of a plastic tube in a mutual electric insulation composite manner; and tube openings at two ends of the plastic tube inner wall composite wire electrode floor heating tube (6) are connected, by means of the electric insulation tube fitting, to a water distribution device (16) for heating the hot water source.
F24D 13/04 - Systèmes de chauffage électrique utilisant le chauffage électrique d'un fluide échangeur de chaleur dans des éléments du système séparés
F24D 19/10 - Aménagements ou montage des dispositifs de commande ou de sécurité
F16L 53/34 - Chauffage des tuyaux ou des systèmes de tuyaux en utilisant des champs électriques, magnétiques ou électromagnétiques, p. ex. chauffage par induction, diélectrique ou par micro-ondes
16.
ADJUSTABLE VACUUM HEAT INSULATION GLASS PLATE PROVIDED WITH METAL BRAZED SANDWICH ROLLING SUPPORTED BY PROTECTIVE FRAME
An adjustable vacuum heat insulation glass plate provided with a metal brazed sandwich rolling supported by a protective frame, comprising flat glass (3, 5), gap isolating supports (6, 9, 10), an aluminum or aluminum alloy brazed frame (2), and a stainless steel frame (1), wherein a flat glass frame is supported on the engagement position of a sealing surface with a gap therebetween, and wraps a closed-loop aluminum or aluminum alloy braze frame (2) with the cross section in the shape of a Chinese character "山" and at least provided with an engagement position; the outer side of the closed-loop aluminum or aluminum alloy frame with the cross section in the shape of the Chinese character "山" is wrapped with a closed-loop corrugated stainless steel frame (1) with a U-shaped cross section.
C03C 27/08 - Liaison verre-verre par des procédés autres que la fusion au moyen d'un métal interposé
E06B 3/66 - Blocs comprenant plusieurs panneaux de verre ou analogues qui sont espacés et fixés les uns aux autres de façon permanente, p. ex. le long des bords
17.
GLASS AND STAINLESS BRACED FRAME AND TENSILE BRACED FRAME MADE BY METAL-TO-GLASS VACUUM JACKETED BRAZING
A glass and stainless braced frame and tensile braced frame made by metal-to-glass vacuum jacketed brazing, comprising flat glass (3, 5), a gap isolation support, an aluminum or aluminum alloy brazing braced frame (6), and stainless braced frames (1, 15). The edges of the two glass panels are provided with a tensile braced frame (2) for sealing the glass panels in an annular manner, the edges of the two flat glass panels are covered and embedded with the closed-loop aluminum or aluminum alloy braced frame (6) which has a "山"-shaped cross section and is provided with at least one joint, and the closed-loop corrugated stainless braced frames (1, 15) with a "U" or "L"-shaped cross section are covered on the outside of the closed-loop aluminum or aluminum alloy braced frame with a "山"-shaped cross section.
C03C 27/08 - Liaison verre-verre par des procédés autres que la fusion au moyen d'un métal interposé
E06B 3/66 - Blocs comprenant plusieurs panneaux de verre ou analogues qui sont espacés et fixés les uns aux autres de façon permanente, p. ex. le long des bords
18.
GLASS-PLATE FRAME SUPPORT COMPLEMENTARY SNAP-FIT METAL BRAZING STAINLESS STEEL FRAME HOLLOW GLASS PLATE
Provided is a glass-plate frame support complementary snap-fit metal brazing stainless steel frame hollow glass plate, comprising glass plates (3, 5), an aluminum or aluminum-alloy brazing profiled material (2), and stainless steel frames (1, 7); the edge of the glass plate is provided with a ring-shaped closed glass-plate adjacent-edge bending support frame (6); by means of the T-shaped aluminum or aluminum alloy frame (2) arranged on the ring-shaped closed glass-plate parallel bending support frame, the two glass plates fit with each other and cover to close a closure tab.
C03C 27/08 - Liaison verre-verre par des procédés autres que la fusion au moyen d'un métal interposé
E06B 3/66 - Blocs comprenant plusieurs panneaux de verre ou analogues qui sont espacés et fixés les uns aux autres de façon permanente, p. ex. le long des bords
19.
THERMAL-INSULATION GLASS PLATE HAVING VACUUMIZED INTERLAYER BY PERFORMNG METAL BRAZING AND ISOLATING GLASS AND STAINLESS STEEL FRAME
A thermal-insulation glass plate having a vacuumized interlayer by performng metal brazing and isolating glass and a stainless steel frame, comprising plate glass (3, 5), a gap-isolation support (6, 8, 9, 10), an aluminum or aluminum alloy brazing frame (2, 13), and a stainless steel frame (1), wherein the gap-isolation support may comprise multiple shapes and manufacturing methods; the aluminum or aluminum alloy brazing frame may be E-shaped or in a specific shape; and a long-acting getter is provided in an interlayer cavity (4) between two glass plates.
C03C 27/08 - Liaison verre-verre par des procédés autres que la fusion au moyen d'un métal interposé
E06B 3/66 - Blocs comprenant plusieurs panneaux de verre ou analogues qui sont espacés et fixés les uns aux autres de façon permanente, p. ex. le long des bords
20.
VACUUM REGULATION GLASS WITH METAL BRAZED TO GLASS TENSION SUPPORT FRAME AND STAINLESS STEEL FRAME
Support lattices of a glass frame are organically combined by means of using the different conductive properties of metals and the combined action of metal brazing technology and a stainless steel frame, and vacuumization is performed by way of heating in a vacuum brazing furnace to realize vacuumization between glass panes. Thereafter, edges of the vacuum glass panes are closed by way of brazing, and the vacuum glass panes are made by means of the de-encapsulation of a getter. The vacuum glass pane is provided with a communication sealing pipe in communication with two sides, and an air-discharge one-way valve is provided at an opening of the communication sealing pipe. The glass avoids the technique where existing vacuum glass is formed by welding brittle low-temperature glass, and a metal having Kovar characteristics is used to realize the vacuum brazing of metal into stainless steel and glass.
E06B 3/66 - Blocs comprenant plusieurs panneaux de verre ou analogues qui sont espacés et fixés les uns aux autres de façon permanente, p. ex. le long des bords
C03C 27/10 - Liaison verre-verre par des procédés autres que la fusion au moyen d'un adhésif spécialement adapté à ce but
21.
HOLLOW GLASS HAVING GLASS STRETCHING FRAME SUPPORTING LAMINATE WITH DOUBLE-ADHESIVE BONDING AND SEALING OF STAINLESS STEEL FRAME
A hollow glass having a glass stretching frame supporting laminate with double-adhesive bonding and sealing of a stainless steel frame, comprising glass sheets (3, 5), an adhesive sealant, and the stainless steel frame (1). At least one of the edges of the glass is provided with an annular glass stretching closed supporting frame; an airtight sealant (6) is coated on an adhesive sealing surface, and low thermal conduction gas comprising argon, carbon dioxide and the like is filled, so that a glass hollow interlayer (4) is filled with the low thermal conduction gas; then, a laminate is bonded, and a stainless steel frame (1) is wrapped on the outer side of the periphery of the glass sheet bodies.
E06B 3/66 - Blocs comprenant plusieurs panneaux de verre ou analogues qui sont espacés et fixés les uns aux autres de façon permanente, p. ex. le long des bords
C03C 27/10 - Liaison verre-verre par des procédés autres que la fusion au moyen d'un adhésif spécialement adapté à ce but
22.
GLASS COMPOSITE BRACED FRAME AND STAINLESS BRACED FRAME OBTAINED BY METAL-TO-GLASS VACUUM BRAZING
By means of different metallic conductivities and under the combined effect of a metal brazing process and a stainless braced frame, supporting lattices of a glass braced frame are combined organically, and by means of heating and vacuumizing in a vacuum brazing furnace, vacuumization between glass panels is achieved. Thereafter, the edges of the vacuum glass panels are sealed by means of brazing, and the vacuum glass panels are formed by de-encapsulation of a getter. The vacuum glass panels are provided with a communication sealing pipe for communicating two sides, and a discharge check valve is provided on a pipe port of the communication sealing pipe. Said glass overcomes the disadvantages of the existing manner in which the vacuum glass is formed by brittle low-temperature glass welding, and metal having the kovar characteristic enables the metal-to-stainless steel and metal-to-glass vacuum brazing. The problem existing in the current vacuum glass is solved, and a large-area vacuum glass is manufactured without losing tempering. The present invention has a simple process, a good effect of brazing sealing, a long service life, and is a tempered safety glass, which is a development direction of the current vacuum glass.
Disclosed is a vacuum thermal insulation glass plate regulated by cavities at intervals of double-adhesive sealed glass. The vacuum thermal insulation glass plate comprises glass plates (3, 5), an adhesive sealant and a stainless steel frame (1), wherein lattice protruding points (9) are uniformly distributed on the glass plates; an annular closed glass plate extension supporting frame (2) is provided, and the glass plate (3, 5) and the extension supporting frame (2) are closed and combined together; an air-tight sealing adhesive (7) is connected to a metal thin belt (19) with great plasticity as an air-tight sealing ring of an isolation sealing layer; the periphery of hollow interlayer glass plate bodies are covered by the corrugated stainless steel frame (1) with a cross section of inverted U-shaped closed loops; and a groove of the corrugated stainless steel frame is filled with a structure sealing adhesive (6) that does not chemically react with the air-tight sealing adhesive (7).
E06B 3/66 - Blocs comprenant plusieurs panneaux de verre ou analogues qui sont espacés et fixés les uns aux autres de façon permanente, p. ex. le long des bords
C03C 27/10 - Liaison verre-verre par des procédés autres que la fusion au moyen d'un adhésif spécialement adapté à ce but
24.
THERMALLY INSULATED GLASS PLATE HAVING ROLLER-SUPPORTED INSULATING CAVITY FORMED BY SEALING GLASS SHEETS WITH TWO SEALANTS
A thermally insulated glass plate having a roller-supported insulating cavity formed by sealing glass sheets with two sealants employs a protective outer frame and sealing with two sealants. Argon or carbon dioxide gas is introduced into a vacuum oven, then a high-humidity gas is introduced therein, and an air exhaust process is performed on an insulated interlayer (4), such that glass sheets sealed with two sealants can be cured quickly, so as to achieve fast sealing and curing of an edge of insulated glass, and to produce high-quality insulated glass while improving production efficiency. The insulated glass solves the problem in which the corners of glass are fragile due to lack of protection, can improve the quality of welding of glass and metal, and has the advantages of tempering maintenance, high strength, low production costs, good air tightness and thermal insulation properties, low energy consumption, and high transparency, while also achieving protective effects for the insulated glass. The stainless frame prevents damages caused by the corners thereof being struck during transport.
The present invention uses the different conductivity of metals; by means of the combined action of metal brazing processing and a stainless steel frame, organically combining a glass frame supporting lattice and evacuating a vacuum by means of heating in a vacuum brazing furnace to achieve vacuum evacuation between two glass sheets. Thereafter, sealing the edges of the vacuum glass sheets by means of brazing and unsealing the suction agent to manufacture a vacuum glass sheet. The vacuum glass sheet is provided with a communicating sealed pipe fitting in communication on both sides, an exhaust check valve being arranged on the pipe opening of the communicating sealed pipe fitting. The present glass overcomes the method of manufacturing existing vacuum glass by means of brittle low-temperature glass welding, and uses metal with Kovar properties to achieve vacuum brazing of metal to stainless steel and glass. The problems of current vacuum glass are solved, and large volume vacuum glass can be manufactured without losing toughness; the present invention has simple processing, good brazing sealing effects, and long service life, and is a toughened safety glass, which is the current direction of development for vacuum glass.
A vacuum heating insulating and light-transmitting tempered glass plate having a sandwich sweat-soldered along the periphery of tempered glass, comprising tempered glass plates, a gap isolation support, and a closed glass support. Two tempered glass plates which correspond to each other in contour shape and size are spaced apart to define a hollow isolation gap therebetween by means of the gap isolation support and the closed glass support, with which the gap is filled, between the two tempered glass plates, thereby forming a double-layer tempered glass plate having a gap sandwich cavity. By means of glass resistance sweat soldering, the difficulty of loss of tempering of vacuum glass is solved, so that the safety problem of vacuum glass is solved. Compared with existing vacuum glass, the vacuum glass manufactured using the present process method further has better heat insulation and sound insulation effects and has top-level light transmission. The materials can be widely applied in tempered glass, the manufacturing costs are greatly reduced, the structural forms are diversified, the glass is high in strength, safe, long in service life, large in size, low in costs, and high in yield, and the heat insulation and sound insulation performance is good.
C03B 23/24 - Fabrication des feuilles ou briques creuses en verre
E06B 3/66 - Blocs comprenant plusieurs panneaux de verre ou analogues qui sont espacés et fixés les uns aux autres de façon permanente, p. ex. le long des bords
27.
ONLINE PRODUCED AND PRINTED DOT-MATRIX SUPPORT GLASS PLATE FOR USE IN MANUFACTURING VACUUM GLASS
An online produced and printed dot-matrix support glass plate for use in manufacturing a vacuum glass and a manufacturing method therefor. The dot-matrix support glass plate is printed by a glass printing apparatus in a glass hardening critical temperature region of a tin bath, wherein the glass printing apparatus is disposed in a top housing on top of the tin bath in a float glass production line and located after an edge roller and before a transition roller platform. A printing mold head of the glass printing apparatus is a pin-like printing mold (11) having conical pits or crater-shaped pits or the head thereof is convex.
A method for manufacturing glass tensile frame supporting joining piece metal brazing stainless steel frame hollow insulating glass, the method using an outer protective frame and a metal brazing process, argon or carbon dioxide gas being introduced into a vacuum brazing furnace to perform gas extraction of a hollow interlayer, rapid fusion seal brazing on the hollow glass edge being implemented by means of the different resistances of the brazing metal and the stainless steel frame in order to produce high quality hollow glass. The present method overcomes the problem of glass corners being unprotected and fragile, and can improve the quality of the glass and the metal brazing, such that the manufactured hollow glass has the characteristics of enduring toughness, high strength, low manufacturing costs, good air tightness, good thermal insulation, low energy consumption, and good transparency; the stainless steel frame ensures that the strength is high, preventing damage caused by the edges and corners being knocked during transportation.
E06B 3/677 - Vidage ou remplissage de l'espace entre les vitresPrévention de la condensation dans l'espace entre les vitresNettoyage de l'espace entre les vitres
29.
VACUUM-REGULATED THERMAL INSULATION GLASS PLATE PROVIDED WITH ROLLER-PRESS SUPPORT DOUBLE-ADHESIVE SEALED GLASS SPACER CAVITY
Provided is a vacuum-regulated thermal insulation glass plate provided with a roller-press support double-adhesive sealed glass spacer cavity, containing two glass plates which constitute an interlayer cavity; at least one of them has a point array protruding support point and a frame support band; one of the glass plates is provided with a communicated sealed pipe fitting; after applying airtight sealant to the protruding frame support band, the convex frame support bands of the two glass plates are complementarily closed and adhesively bonded and closed; a peripheral groove of the hollow laminated glass plate body is filled with a structural sealant which does not have a chemical reaction with the airtight sealant, forming an adhesively bonded protruding frame support band groove bottom, and a closed structure sealing rubber ring of the glass groove walls of both sides.
E06B 3/66 - Blocs comprenant plusieurs panneaux de verre ou analogues qui sont espacés et fixés les uns aux autres de façon permanente, p. ex. le long des bords
Disclosed is a kind of hollow glass in a stainless steel frame brazed with a compound glass frame supporting composite sheet, comprising: sheet glasses (3, 5), an aluminum or aluminum alloy brazed frame (2), a stainless steel frame (1) with an aluminum or aluminum alloy frame support as shown in formula (I); and a hollow interlayer (4) being filled with low-heat-conducting gases including argon and carbon dioxide and being brazed by means of electric heating. The aluminum or aluminum alloy brazing materials include Al and those containing Al, such as AI-Si, Al-Cu-Si and Zn-AI.
C03C 27/08 - Liaison verre-verre par des procédés autres que la fusion au moyen d'un métal interposé
E06B 3/66 - Blocs comprenant plusieurs panneaux de verre ou analogues qui sont espacés et fixés les uns aux autres de façon permanente, p. ex. le long des bords
31.
DOUBLE EPOXY RESIN-BASED GROOVED VACUUM INSULATED SANDWICH GLASS PANEL HAVING SUPPORT FASTENING
Vacuum glass panels use an outer braced frame and double epoxy resin sealing, high humidity air is introduced into a vacuum furnace, and then a hollow interlayer is exhausted, so that a double epoxy resin-based glass can be rapidly cured, and the edge of the vacuum glass can be quickly sealed and cured. The vacuum glass panels are provided with a communication sealing pipe for communicating two sides, and a discharge check valve is provided on a pipe port of the communication sealing pipe. The vacuum glass panels have a good quality of glass-to-metal bonding, and the problem of the vacuum glass losing tempering and the vacuum glass safety problem are solved. As a result, the functional vacuum glass has a simple manufacturing process, and widely uses ordinary tempered glass in the material, and greatly reduces the manufacturing cost, greatly improves the safety and yield, and has a variety of structure forms. The glass panels are thin and lightweight, and have high intensity, safety, a long lifetime, a large size, a high yield, strong functionality, low energy consumption, high efficiency of light transmission, a low cost, and condensation resistance, and facilitate mass production and the like.
A vacuum glass plate having a glass plate frame support buckled with a metal brazing stainless steel frame in a complementary manner. Said vacuum glass plate uses the difference of a metal conduction property to organically combine glass frame support dot matrixes by means of the combined action of a metal brazing process and a stainless steel frame (1), and to implement vacuum between the glass plates by heating and vacuumizing in a vacuum furnace. Then, an edge of the vacuum glass plate is closed by brazing, and the vacuum glass plate is made by unsealing a getter. The glass overcomes a mode that the existing vacuum glass is soldered by means of brittle low-temperature glass, and the vacuum brazing of stainless steel and glass is implemented by using a metal having a kovar characteristic. Therefore, the vacuum glass is prepared into large area of vacuum glass without loss of steel, and has a simple process, a good brazing sealing effect and a long service life, and is tempering safety glass, thereby solving the existing problem of vacuum glass.
Adjustable vacuum heat insulating glass having a protective frame, a rolled support frame and a metal brazed sandwich, comprising flat glass (3, 5), a vacuum sandwich (4), metal brazed layers (2), and a stainless steel frame (13), wherein a linking and sealing tube (9) which links the two sides and implements linking and sealing by means of a connection fastener and an airtight bonding agent on one of the two glass plates or a closed sealing frame support; an exhaust check valve (10) is provided at the opening of the linking and sealing tube.
Insulating glass panels regulated by a vacuum in a cavity between spaced glass and sealed by two sealants, comprising glass panels (3, 5), adhesive sealants (2, 8), and stainless steel frames (15, 16). An annular sealing frame support (11), an airtight sealant (2), and a structural sealant (8) that does not react with the airtight sealant are provided between edges of the two glass panels.
C03C 27/10 - Liaison verre-verre par des procédés autres que la fusion au moyen d'un adhésif spécialement adapté à ce but
E06B 3/66 - Blocs comprenant plusieurs panneaux de verre ou analogues qui sont espacés et fixés les uns aux autres de façon permanente, p. ex. le long des bords
35.
HOLLOW INSULATING GLASS PLATE PROVIDED WITH PROTECTIVE FRAME ROLLING SUPPORT METAL BRAZING INTERLAYER
A hollow insulating glass plate provided with protective frame rolling support metal brazing interlayer is prepared by using an outer protective frame and a metal brazing process, introducing argon gas or carbon dioxide gas into the vacuum furnace to pump down the hollow interlayer (4), and achieving rapid fusion sealing brazing of the edge of the hollow glass by using the difference in resistance between the brazing metal and the stainless steel frame to produce a high-quality hollow glass. It overcomes the problem that the glass corners are fragile due to lack of protection, and the quality of glass and metal brazing can be improved. This hollow glass has the features of not losing tempering, high strength, low cost, good air tightness, good thermal insulation performance, low energy consumption and good perspective effect, has protective effect on hollow glass and represents the development direction of hollow glass.
Disclosed is insulated glass with a glass frame supporting, complementary to, snap-fitted to and double-adhesive adhesion sealing a stainless steel frame, the insulated glass comprising glass panes, an adhesion sealant and a stainless steel frame, characterized in that annular sealed glass pane parallel bending support frames, the contour shapes and sizes of which correspond to each other, are arranged on the two glass panes forming an interval sandwiched cavity. With the outer protective frame, the strength of the insulated glass is high, and the damage caused by collisions at the corners during the transportation process is avoided. Through the double-adhesive sealing, the double-adhesive sealed glass can be solidified quickly, thereby realizing quick sealing and solidification of rims of the insulated glass, and improving the production efficiency thereof.
E06B 3/66 - Blocs comprenant plusieurs panneaux de verre ou analogues qui sont espacés et fixés les uns aux autres de façon permanente, p. ex. le long des bords
C03C 27/10 - Liaison verre-verre par des procédés autres que la fusion au moyen d'un adhésif spécialement adapté à ce but
37.
INSULATING GLASS HAVING GLASS SHEETS SUPPORTED BY COMPOSITE GLASS FRAME DOUBLY ADHERED TO SEALED STAINLESS STEEL FRAME
Insulating glass having glass sheets supported by a composite glass frame doubly adhered to a sealed stainless steel frame. The insulating glass comprises glass plates, an adhesive sealant, a stainless steel frame, and an annular sealed glass-plate frame support corresponding to profile shapes of the glass plates. Two glass-plate cover sheets supported by the glass-plate frame support are adhered together to seal two layers of the glass plates. A layer of thin metal strips having good plasticity is further adhered to the periphery of the glass plates by means of an air-tight sealant, and serves as an air-tight sealing ring of an insulation sealing layer. The steel frame is sealed, annular, corrugated, has an inverted U-shaped cross-section, and is wrapped around the periphery of an outer side of the layered insulating glass plates.
E06B 3/66 - Blocs comprenant plusieurs panneaux de verre ou analogues qui sont espacés et fixés les uns aux autres de façon permanente, p. ex. le long des bords
38.
THERMAL-INSULATION LIGHT-TRANSMITTING TEMPERED GLASS PLATE WITH INTERLAYER FORMED BY ELECTROTHERMAL FUSION WELDING AT TEMPERED GLASS EDGES AND WITH ADJUSTABLE VACUUM
Disclosed is a thermal-insulation light-transmitting tempered glass plate with interlayer formed by electricothermal fusion welding at tempered glass edges and with adjustable vacuum, the thermal-insulation light-transmitting tempered glass plate comprising tempered glass plates, spaced isolation supports, and closed-loop glass supports. Two tempered glass plates corresponding to each other in terms of contour and size are provided, and by means of the spaced isolation supports between the two tempered glass plates and the closed-loop glass supports, which fill up gaps, hollow isolation gaps are formed between the two tempered glass plates, thereby forming a double-layer tempered glass plate with an interval interlayer cavity. By means of glass electric-resistance thermal fusion welding, the problem of loss of tempering of vacuum glass is solved, thereby solving the problem of the safety of the vacuum glass. Compared with existing vacuum glass, the vacuum glass manufactured by means of this technological process has better thermal insulation and soundproofing effects, and also has top-level light transmission. Tempered glass can be widely used as the material, manufacturing costs are greatly reduced, and structural forms are diversified, and the glass is strong and safe, has a long service life and large size, and is low cost, has high yield and has good thermal insulation and soundproofing effects.
C03B 23/24 - Fabrication des feuilles ou briques creuses en verre
E06B 3/66 - Blocs comprenant plusieurs panneaux de verre ou analogues qui sont espacés et fixés les uns aux autres de façon permanente, p. ex. le long des bords
Disclosed is a threaded screwable telescopic sealing pipe fitting, comprising a recessed tooth tip end cover threaded pipe composed of a recessed tooth tip end cover (2) arranged at one end thereof and an external threaded pipe (3) connected to the end cover. The recessed tooth tip end cover threaded pipe and a tooth-tip base threaded pipe (7) are sleeved on each other by means of relative screwing, and the length of an external thread of the recessed tooth tip end cover threaded pipe corresponds to the length of an internal thread of the tooth-tip base threaded pipe (7); and a corrugated telescopic pipe (1) is arranged in the recessed tooth tip end cover threaded pipe and the tooth-tip base threaded pipe (7). A clamping ring (11) is arranged on a pipe head at one end of the corrugated telescopic pipe (1) or on each of pipe heads at two ends thereof. The effective telescopic lengths of the tooth-tip base threaded pipe (7) and the recessed tooth tip end cover threaded pipe match the effective telescopic length of the corrugated telescopic pipe (1). The thread screwing telescopic sealing pipe fitting enables the telescopic displacement between the recessed tooth tip end cover threaded pipe and the tooth-tip base threaded pipe (7) by screwing. The sealing pipe fitting is simple and firm in structure, has a large range of a permissible mounting tolerance and is easy to dismount and mount. The threaded screwable telescopic sealing pipe fitting can tightly abut against and seal a vacuum heat collecting pipe with water inlet and outlet pipe heads arranged at two ends thereof.
F16L 15/00 - Raccords avec filetageFormes des filetages pour ces raccords
F16L 15/02 - Raccords avec filetageFormes des filetages pour ces raccords permettant un réglage sensiblement longitudinal par emploi d'une partie à long filetage
Disclosed are a horizontally transverse bending stacking heat collection core pipe head same-side vacuum heat collection pipe module and a process for producing same. The module comprises a heat-preservation heat collection dual-layer header, horizontally transverse bending stacking heat collection core pipe head same-side vacuum heat collection pipes, a mounting and supporting frame, and a tightly ejecting tail seat arranged on parallel opposite side frames of the mounting and supporting frame and the heat-preservation heat collection dual-layer header. Horizontally transverse bending stacking heat collection core pipe head same-side vacuum heat collection pipe mounting pipe holes in the heat-preservation heat collection dual-layer header are connected to the horizontally transverse bending stacking heat collection core pipe head same-side vacuum heat collection pipes via inner inserting or outer inserting pipe heads, and by the tightly ejecting tail seat arranged on the parallel opposite side frames of the mounting and supporting frame and the heat-preservation heat collection dual-layer header, the horizontally transverse bending stacking heat collection core pipe head same-side vacuum heat collection pipes are arranged between the heat-preservation heat collection dual-layer header and the mounting and supporting frame in a tightly ejecting seal manner.
F24S 10/40 - Collecteurs de chaleur solaire utilisant des fluides vecteurs dans des éléments absorbeurs entourés d'une enveloppe transparente, p. ex. collecteurs de chaleur solaire sous vide
F24S 10/70 - Collecteurs de chaleur solaire utilisant des fluides vecteurs le fluide vecteur circulant à travers des tubes absorbeurs
F24S 25/00 - Agencement de montages ou de supports fixes pour des modules de collecteurs de chaleur solaire
F24S 80/00 - Détails, accessoires ou parties constitutives des collecteurs de chaleur solaire non prévus dans les groupes
41.
HORIZONTAL TRANSVERSELY DISPOSED BENT AND STACKED HEAT PIPE HEAT COLLECTION CORE EVACUATED TUBE MODULE
A horizontal transversely disposed bent and stacked heat pipe heat collection core evacuated tube module and a production process for a horizontal transversely disposed bent and stacked heat pipe heat collection core evacuated tube, the module consisting of a connection between horizontal transversely disposed bent and stacked heat pipe heat collection core evacuated tubes, a thermal insulation heat collection manifold, a heat collection tube mounting support frame and a top-tightened tailstock. The horizontal transversely disposed bent and stacked heat pipe heat collection core evacuated tubes comprise a cover glass tube (1), a horizontal transversely disposed bent and stacked heat pipe heat collection core, media inlet and outlet head glass sealing end caps and clamping positioning support getter elastic clamps. The thermal insulation heat collection manifold is arranged horizontally, arranged at an incline, or arranged vertically. A phase change heat transfer medium is transported and distributed under capillary action; the phase change heat transfer medium absorbs heat and vaporizes, and then condenses into a liquid by means of a phase change medium condensation heat release end. The heat collection system achieves thermosiphon convection self-circulation or forced circulation by a heating medium by means the difference in density between cold water within the thermal insulation heat collection manifold and hot water within the thermal insulation heat collection manifold, as well as the pressure generated by the height difference between a thermal insulation water storage tank and the heat collection tube module.
F24S 10/95 - Collecteurs de chaleur solaire utilisant des fluides vecteurs utilisant une circulation thermosiphonique interne comprenant des parties évaporateur et des parties condenseur, p. ex. des tubes de chaleur
F24S 70/10 - Détails des éléments absorbeurs caractérisés par le matériau absorbant
42.
LONGITUDINAL TRANSVERSELY DISPOSED BENT AND STACKED HEAT COLLECTING CORE TUBE HEAD IPSILATERAL EVACUATED TUBE MODULE
A longitudinal transversely disposed bent and stacked heat collecting core tube head ipsilateral evacuated tube module, which is connected to longitudinal transversely disposed bent and stacked heat collecting core tube head ipsilateral evacuated tubes (6) consisting of an outer cover glass tube (5), a longitudinal transversely disposed bent and stacked heat collecting core, a medium inlet and outlet tube head glass sealing end cover, a U-shaped longitudinal clamping positioning support elastic clamp, and a horizontal clamping positioning support getter elastic clamp; by means of a top-tightened tailstock, the module is top-tightened and sealingly installed between a thermal insulation heat collecting double-layered manifold (12) and a heat collecting tube mounting support frame. The thermal insulation heat collecting double-layered manifold (12) is horizontally installed such that the longitudinal transversely disposed bent and stacked heat collecting core is close to vertical to the irradiation angle of sunlight. The system generates medium thermosiphon convection self-circulation power by means of the difference in density between cold water within a cold water pipeline and hot water within a hot water pipeline, as well as the difference in pressure caused by the height difference between the thermal insulation heat collecting double-layered manifold (12) and the longitudinal transversely disposed bent and stacked heat collecting core tube head ipsilateral evacuated tube module; or forced circulation may be achieved for the system by installing a water pump on the system.
F24S 10/40 - Collecteurs de chaleur solaire utilisant des fluides vecteurs dans des éléments absorbeurs entourés d'une enveloppe transparente, p. ex. collecteurs de chaleur solaire sous vide
F24S 10/70 - Collecteurs de chaleur solaire utilisant des fluides vecteurs le fluide vecteur circulant à travers des tubes absorbeurs
F24S 80/00 - Détails, accessoires ou parties constitutives des collecteurs de chaleur solaire non prévus dans les groupes
43.
VACUUM HEAT COLLECTION AND HEAT TRANSFER TUBE MODULE WITH LONGITUDINAL TRANSVERSE BENT LAMINATED HEAT COLLECTION CORE
A vacuum heat collection and heat transfer tube module with a longitudinal transverse bent laminated heat collection core. The module is formed by connecting a heat preservation and heat collection header, a vacuum heat collection and heat transfer tube row with the longitudinal transverse bent laminated heat collection core, a heat collection tube mounting and supporting frame, and a pressing tail seat which is provided at the frame edge, which is parallel with and opposite to the heat preservation and heat collection header, of the heat collection tube mounting and supporting frame; the heat preservation and heat collection header is horizontally installed and provided; and a vacuum heat collection and heat transfer tube with the longitudinal transverse bent laminated heat collection core is composed of an outer cover glass tube, the longitudinal transverse-arranged bent laminated heat collection core, a medium inlet and outlet tube head glass sealing end cover, a heat dissipation glass tube head, a longitudinal clamping positioning and supporting elastic clamp, and a transverse clamping positioning and supporting getter elastic clamp assembly. According to the system, according to a density difference between cold water in the heat preservation and heat collection header and hot water in the heat preservation and heat collection header, and a height difference between the heat accumulation and heat collection header and the vacuum heat collection and heat transfer tube with the longitudinal transverse bent laminated heat collection core, thermal siphon convection self-circulation of a heated medium is realized; or a water pump is installed on the system so that forced circulation of the system can be realized.
F24S 10/40 - Collecteurs de chaleur solaire utilisant des fluides vecteurs dans des éléments absorbeurs entourés d'une enveloppe transparente, p. ex. collecteurs de chaleur solaire sous vide
F24S 80/30 - Agencements pour connecter les circuits de fluides des collecteurs de chaleur solaire entre eux ou avec d’autres composantes, p. ex. connections de conduitsMoyens pour la répartition du fluide p. ex. boîtes de distribution
44.
VACUUM HEAT COLLECTING AND TRANSFERRING PIPE MODULE WITH HORIZONTAL TRANSVERSE BENT STACKED HEAT COLLECTING CORES
Provided is a vacuum heat collecting and transferring pipe module with horizontal transverse bent stacked heat collecting cores, comprising a heat-preservation heat collecting header (16), a heat collecting pipe mounting supporting frame, and a propping tailstock arranged on a frame edge of the heat collecting pipe mounting supporting frame parallel and opposite to the heat-preservation heat collecting header, and comprising vacuum heat collecting and transferring pipes with horizontal transverse bent stacked heat collecting cores formed by glass outer cover pipes (1), horizontal transverse bent stacked heat collecting cores, medium inlet and outlet pipe head glass sealing end covers, heat-dissipation glass pipe heads, and clamping, locating and supporting getter elastic clamps. The horizontal transverse bent stacked heat collecting cores are horizontal transverse bent stacked heat collecting core pipe racks that are sequentially bent back, tightly arranged between upper and lower layers, and distributed on the same plane. The heat-preservation heat collecting header (16) is a dual-fluid channel heat collecting header provided with a fluid director and comprising an upper header and a lower header; the fluid director is provided between the upper and lower headers, and is connected to a header diaphragm and the perforated header wall. The periphery of the heat-preservation heat collecting header (16) is coated with a heat preservation layer and a housing (15); the header is arranged horizontally, vertically, or obliquely, so as to achieve thermosyphon convection self-circulation by means of a density difference between cold and hot water.
F24S 10/40 - Collecteurs de chaleur solaire utilisant des fluides vecteurs dans des éléments absorbeurs entourés d'une enveloppe transparente, p. ex. collecteurs de chaleur solaire sous vide
A horizontal transverse bent stacked pipe opening diagonal arrangement heat collection core vacuum heat collection pipe module, comprising a mounting frame, parallel heat preservation and collection headers, and sealing mounting pipe fittings; horizontal transverse bent stacked pipe opening diagonal arrangement heat collection core vacuum heat collection pipes are hermetically positioned between the parallel heat preservation and collection headers distributed on two sides of the mounting frame, so as to form a module in an abutting connection mode; the periphery of each heat collection header provided with sealing mounting elastic pipe fittings (12) or telescopic rotary jacking sealing pipe fittings is wrapped by a heat preservation box upper cover and a heat preservation box lower cover; the heat preservation and collection headers are horizontally, obliquely, or vertically mounted and arranged. Gas in the vacuum heat collection pipes can be naturally exhausted; a system generates medium thermosyphon convection self-circulation power by means of the density difference between cold water in a cold water pipeline and hot water in a hot water pipeline as well as the pressure difference generated by the height difference between a heat preservation water storage box and the opening diagonal arrangement heat collection core vacuum heat collection pipe module; or a water pump is mounted on the system, so that forced circulation of the system is achieved.
F24S 10/40 - Collecteurs de chaleur solaire utilisant des fluides vecteurs dans des éléments absorbeurs entourés d'une enveloppe transparente, p. ex. collecteurs de chaleur solaire sous vide
F24S 10/70 - Collecteurs de chaleur solaire utilisant des fluides vecteurs le fluide vecteur circulant à travers des tubes absorbeurs
F24S 25/00 - Agencement de montages ou de supports fixes pour des modules de collecteurs de chaleur solaire
F24S 80/00 - Détails, accessoires ou parties constitutives des collecteurs de chaleur solaire non prévus dans les groupes
Disclosed is a same-plane pipe arrangement glass heat pipe heat collection core vacuum heat collection pipe module, composed of a heat-preservation heat collection header, same-plane pipe arrangement glass heat pipe heat collection core vacuum heat collection pipes, a heat collection pipe installing and supporting frame, and a tightly ejecting tail seat arranged on parallel opposite side frames of the heat collection pipe installing and supporting frame and the heat-preservation heat collection header. The phase-change heat transfer medium is condensed into liquid to form a condensation and evaporation heat transfer circulation of the phase-change medium under the action of gravity or capillary membranes arranged on heat collection capillary pipes along inner walls of same-plane pipe arrangement glass heat pipe heat collection cores; a thermal siphon convection self-circulation of the heated medium is realized in the heat collection system by the density difference between cold water in the heat-preservation heat collection header and hot water in the heat-preservation heat collection header, and pressure caused by the height difference between a heat-preservation water-storage tank and the same-plane pipe arrangement glass heat pipe heat collection core vacuum heat collection pipe module; or a water pump is installed in the system to realize a forced circulation of the system.
F24S 10/95 - Collecteurs de chaleur solaire utilisant des fluides vecteurs utilisant une circulation thermosiphonique interne comprenant des parties évaporateur et des parties condenseur, p. ex. des tubes de chaleur
47.
VACUUM HEAT COLLECTING PIPE MODULE WITH HEAT COLLECTING CORES COAXIAL WITH LONGITUDINAL TRANSVERSE BENT STACKED PIPE ORIFICES
A vacuum heat collecting pipe module with heat collecting cores coaxial with longitudinal transverse bent stacked pipe orifices, comprising vacuum heat collecting pipes, sealing connection pipe fittings, a heat-preservation heat collecting header, and a heat collecting pipe mounting supporting frame. The module is formed by tightly arranging, propping, and connecting multiple vacuum heat colleting pipes with heat collecting cores coaxial with longitudinal transverse bent stacked pipe orifices. The heat-preservation heat collecting header is horizontally mounted and arranged, so that the heat collecting cores coaxial with longitudinal transverse bent stacked pipe orifices of the vacuum heat collecting pipes with heat collecting cores coaxial with longitudinal transverse bent stacked pipe orifices are approximately perpendicular to sunlight beams. According to the module, a density difference between cold water in a cold water pipeline and hot water in a hot water pipeline and a pressure difference caused by a height difference between a water storage tank and the vacuum heat collecting pipes with heat collecting cores coaxial with longitudinal transverse bent stacked pipe orifices serve as medium thermosyphon convection self-circulation power.
F24S 10/50 - Collecteurs de chaleur solaire utilisant des fluides vecteurs le fluide vecteur circulant entre des plaques
F24S 10/70 - Collecteurs de chaleur solaire utilisant des fluides vecteurs le fluide vecteur circulant à travers des tubes absorbeurs
F24S 80/30 - Agencements pour connecter les circuits de fluides des collecteurs de chaleur solaire entre eux ou avec d’autres composantes, p. ex. connections de conduitsMoyens pour la répartition du fluide p. ex. boîtes de distribution
48.
VACUUM HEAT-COLLECTION PIPE MODULE FOR LONGITUDINAL TRANSVERSE BEND LAMINATED HEAT-PIPE HEAT COLLECTION CORE
Provided is a vacuum heat-collection pipe module for a longitudinal transverse bend laminated heat-pipe heat collection core, consisting of a thermal-insulation heat collection header (13), a vacuum heat-collection pipe (6) for a longitudinal transverse bend laminated heat-pipe heat collection core, a heat-collection pipe mounting support frame, and a top tight tailstock arranged on the heat-collection pipe mounting support frame and parallel to the thermal insulation header (13) opposite edge, all of which being connected. The thermal-insulation heat collection header (13) is horizontally mounted and arranged; under the action of gravity or a capillary film disposed on the inner wall, the longitudinal transverse bend laminated heat-pipe heat collection core completes the transmission distribution of a phase-change heat transfer medium; the phase-change heat transfer medium in liquid form absorbs heat and vaporizes, constituting a condensation evaporation heat transfer cycle of the phase change medium. By means of the cold water in the thermal-insulation heat collection header (13), the difference in density between the hot water in the thermal-insulation heat collection header (13), and the difference in height between the thermal-insulation heat collection header (13) and the vacuum heat collection pipe for the longitudinal transverse bend laminated heat-pipe heat collection core, the system achieves thermal siphon convection self-circulation of the heated medium; or a pump is installed in the system to achieve a forced loop in the system.
An air conditioner with enhanced outdoor condenser coolant gas evaporation, humidification, and cooling, comprising: an outdoor condenser coolant gas evaporation, humidification, and cooling system module, and an outdoor condenser coolant gas evaporation, humidification, and cooling water input system module. High speed air generated by a fan (13) accelerates an evaporation of a condensate. The evaporation of the condensate significantly cools a coolant gas of the air conditioner while disposing of the condensate at the same time.
F24F 1/06 - Éléments extérieurs séparés, p. ex. élément extérieur à relier à un élément intérieur séparé comprenant un compresseur et un échangeur de chaleur
F24F 1/42 - Éléments extérieurs séparés, p. ex. élément extérieur à relier à un élément intérieur séparé comprenant un compresseur et un échangeur de chaleur caractérisés par l'emploi d'un condensat, p. ex. pour un refroidissement amélioré
F24F 13/22 - Moyens pour éviter la condensation ou pour évacuer le condensat
50.
OPENING AND CLOSING SWITCHABLE AIR-COOLED COOL WATER-TYPE MACHINE COOLING TOWER FOR AIR-COOLED RADIATOR AND OPERATING MODE OF SAME
An opening and closing switchable air-cooled cool water-type machine cooling tower for an air-cooled radiator and operation mode of the same. By combining the advantages of a cooling tower, a closed cooling tower and an air cooling tower, and making full use of characteristics that heat exchange between water and the air, as the water flows through the cooling tower, it increases air humidity and the endothermic capacity, improves heat-absorption capability and decreases air dry-bulb temperature, and the cooling tower cools the air-cooled radiator. The air-cooled radiator can automatically adjust its operation status according to environmental climatic conditions and inlet and outlet temperatures of a fluid to be cooled. When the external ambient temperature and the humidity or the temperatures of the inlet and outlet of the fluid to be cooled change, an automatic control system controls water flow amount and supply air amount of an atomization nozzle and of a shower head respectively, and automatically adjusts the operation mode of the air cooled radiator, thereby maintaining the air-cooled radiator always in an economic operation mode.
F28C 1/14 - Réfrigérants à ruissellement à contact direct, p. ex. tours de réfrigération comprenant également un échange de chaleur sans contact direct
51.
OUTDOOR UNIT CONDENSER COOLING AIR EVAPORATION HUMIDIFICATION COOLING SYNERGISTIC AIR CONDITIONER
Disclosed is an outdoor unit condenser (14) cooling air evaporation humidification cooling synergistic air conditioner. The air conditioner comprises an outdoor unit condenser (14) cooling air evaporation humidification cooling system module, and an outdoor unit condenser cooling air evaporation humidification cooling water supply system module. High-speed air generated by a fan (13) accelerates evaporation of condensed water; and the evaporation of the condensed water not only can largely cool the cooling air of the air conditioner, but also can effectively treat the condensed water to guarantee no water dripping of the air conditioner. The effect of reducing the temperature of the cooling air by the condensed water is exerted to the greatest extent; the refrigeration efficiency of the air conditioner is improved to the greatest extent; the problem of incapability of normally operating the air conditioner due to thermal protection of the air conditioner caused by excessive temperature of the cooling air of the air conditioner is prevented; and the service life of the air conditioner is prolonged. In order to exert the working performance of a ventilation evaporation humidification cooling device to the greatest extent, when the condensed water of the air conditioner is insufficient, additional water can be supplied to the ventilation evaporation humidification cooling device.
F24F 1/06 - Éléments extérieurs séparés, p. ex. élément extérieur à relier à un élément intérieur séparé comprenant un compresseur et un échangeur de chaleur
F24F 13/22 - Moyens pour éviter la condensation ou pour évacuer le condensat
52.
SPECIAL COFFIN FOR SEA BURIAL OF BODY OF DECEASED PERSON
A special coffin for sea burial of the body of a deceased person, which is composed in two parts: an inner coffin and an outer sleeving coffin (1). Further provided is a method for using the special coffin for sea burial of the body of a deceased person; the method turns the coffin into an artificial reef which is permanently preserved, and which is beneficial to growth and reproduction of marine life; the method avoids environmental pollution caused by inhumation or cremation, conserves a large amount of cemetery land, and fulfills people's desire for the remains of the deceased to last forever. The present method is a burial method that saves energy, protects the environment, and benefits the country and people.
Provided is an air-cooled heat-sink open/close switchable hybrid air-cooled/cold-water cooling tower and a manner of operation thereof; according to environmental climate conditions and the temperature of an inlet/outlet for a to-be-cooled fluid, the state of operation of an air-cooled heat sink is automatically adjusted; when the temperature and humidity of the external environment or the temperature of the inlet/outlet for the to-be-cooled fluid changes, a system is automatically controlled to control the water-flow rate and air-intake rate of a vaporization nozzle (41) or spray head, respectively, and automatically adjust the mode of operation of the air-cooled heat sink, so that the air-cooled heat sink is in an economical mode of operation at all times.
F28C 1/14 - Réfrigérants à ruissellement à contact direct, p. ex. tours de réfrigération comprenant également un échange de chaleur sans contact direct
54.
COMPOSITE HIGH-TEMPERATURE RESISTANT, SELECTIVE-ABSORPTION FUNCTIONAL MEMBRANE AND MANUFACTURING METHOD THEREFOR
Provided are a composite high-temperature resistant, selective-absorption functional membrane and a manufacturing method therefor. The composite high-temperature resistant, selective-absorption functional membrane comprises a metal or non-metal substrate (1), a reflective metal film layer (4) and a heat-absorption film layer. The heat-absorption film layer is a carbon film surface layer with distributed dense micropores and formed from a nano ceramic material film (2) and an organic adhesive after a thermal decomposition treatment, and can form a black body having a low reflectivity, a high absorptivity, stable physicochemical properties and a high temperature resistance.
F24J 2/48 - caractérisés par le matériau absorbant
C23C 14/06 - Revêtement par évaporation sous vide, pulvérisation cathodique ou implantation d'ions du matériau composant le revêtement caractérisé par le matériau de revêtement
55.
THERMALLY INSULATED CORROSION-RESISTANT NON-METALLIC COMPOSITE PIPE WITH TENSION-RESISTANT SHELL INTERNALLY PROVIDED WITH PRESTRESSED EXPANSIVE CEMENT
Disclosed is a thermally insulated corrosion-resistant non-metallic composite pipe with a tension-resistant shell internally provided with prestressed expansive cement, comprising a corrosion-resistant and pressure-bearing rigid non-metallic liner pipe, a tension-resistant shell pipe and expansive cement. The corrosion-resistant and pressure-bearing rigid non-metallic liner pipe provided with at least two openings is placed inside a tension-resistant shell pipe shaped and sized correspondingly and comprising a pipe wall provided with an injection nozzle for the injection of expansive cement slurry and a corresponding injection nozzle plug. The corrosion-resistant and pressure-bearing rigid non-metallic liner pipe is wrapped in the tension-resistant shell pipe with clearance. The pipe orifice of the corrosion-resistant and pressure-bearing rigid non-metallic liner pipe and the pipe orifice of the tension-resistant shell pipe, as well as a pipe wall of the corrosion-resistant and pressure-bearing rigid non-metallic liner pipe and a pipe wall of the tension-resistant shell pipe, are supported and positioned with respect to each other with symmetrical clearance, and a gap between the two pipe orifices is sealed. The expansive cement slurry is injected into a gap between the tension-resistant shell pipe and the corrosion-resistant and pressure-bearing rigid non-metallic liner pipe, and is shaken to be compact; and the injection nozzle is sealed with the injection nozzle plug thereof. The thermally insulated corrosion-resistant and pressure-bearing rigid non-metallic liner pipe is easy to machine, resistant to corrosion, has a long service life, and is environmentally friendly, sanitary, healthy and low in costs.
F16L 9/153 - Tubes en matériaux composites, c.-à-d. faits de matériaux non complètement couverts dans un seul des groupes précédents comportant uniquement des couches en métal et en béton avec ou sans renforcement
56.
CORROSION-RESISTANT NON-METALLIC COMPOSITE PIPE WITH TENSION-RESISTANT SHELL INTERNALLY PROVIDED WITH PRESTRESSED EXPANSIVE CEMENT
Disclosed is a thermally insulated corrosion-resistant non-metallic composite pipe with a tension-resistant shell internally provided with prestressed expansive cement. The pipe is provided with a corrosion-resistant and pressure-bearing rigid non-metallic liner pipe (7) with at least two openings. The liner pipe is placed inside a tension-resistant shell pipe (4) shaped and sized correspondingly and comprising a pipe wall provided with an injection nozzle (6) for the injection of expansive cement slurry (2) and an injection nozzle plug (5) corresponding to the nozzle. The corrosion-resistant and pressure-bearing rigid non-metallic liner pipe is wrapped in the tension-resistant shell pipe with clearance. By means of a positioning and connecting device provided at a pipe orifice (8) of the corrosion-resistant and pressure-bearing rigid non-metallic liner pipe and a pipe orifice of the tension-resistant shell pipe, the pipe orifice and a pipe wall of the corrosion-resistant and pressure-bearing rigid non-metallic liner pipe and the pipe orifice and a pipe wall of the tension-resistant shell pipe are supported and positioned with respect to each other with symmetrical clearance, and a gap between the two pipe orifices is sealed. The expansive cement slurry is injected into a gap between the tension-resistant shell pipe and the corrosion-resistant and pressure-bearing rigid non-metallic liner pipe, and is shaken to be compact; and the injection nozzle is sealed with the injection nozzle plug. The thermally insulated corrosion-resistant non-metallic composite pipe with a tension-resistant shell internally provided with prestressed expansive cement is easy to machine, resistant to corrosion, low in costs and has a long service life.
F16L 9/14 - Tubes en matériaux composites, c.-à-d. faits de matériaux non complètement couverts dans un seul des groupes précédents
F16L 58/06 - Revêtements caractérisés par les matériaux utilisés de ciment, béton ou similaire
F16L 57/02 - Protection des tuyaux ou d'objets de forme similaire contre les dommages ou les usures internes ou externes contre la fissuration ou le flambement
57.
THERMALLY INSULATED CORROSION-RESISTANT NON-METALLIC COMPOSITE LINER WITH TENSION-RESISTANT SHELL INTERNALLY PROVIDED WITH PRESTRESSED EXPANSIVE CEMENT
Disclosed is a thermally insulated corrosion-resistant non-metallic composite liner with a tension-resistant shell internally provided with prestressed expansive cement, comprising a corrosion-resistant and pressure-bearing rigid non-metallic liner (7), a tension-resistant shell (4) and expansive cement (2). The shape and pipe orifice of the corrosion-resistant and pressure-bearing rigid non-metallic liner (7) provided with at least one opening match, in one-one correspondence, the shape and pipe orifice of the tension-resistant shell (4). The corrosion-resistant and pressure-bearing rigid non-metallic liner (7) is wrapped in the tension-resistant shell (4) with clearance. By means of a positioning and connecting device provided at a pipe orifice (8) of the corrosion-resistant and pressure-bearing rigid non-metallic liner and an orifice of the tension-resistant shell, the pipe orifice (8) of the corrosion-resistant and pressure-bearing rigid non-metallic liner and the orifice of the tension-resistant shell, as well as a wall of the corrosion-resistant and pressure-bearing rigid non-metallic liner and a wall of the tension-resistant shell, are positioned with respect to each other with symmetrical clearance, and a gap between the pipe orifices is sealed. The expansive cement slurry is injected into the tension-resistant shell (4) and is sealed inside with an injection nozzle plug (5) thereof, so that the expansive cement slurry expands in the process of solidification, thus exerting a pressing force on the corrosion-resistant and pressure-bearing rigid non-metallic liner (7) and an expanding force on the tension-resistant shell (4); and an injection nozzle (6) is sealed with the injection nozzle plug (5) thereof. The corrosion-resistant non-metallic composite liner with a tension-resistant shell internally provided with prestressed expansive cement is supported and connected to the corresponding shell with a gap by means of thermally insulated supports, and the interlayer between the two is supported, connected and sealed with a thermally insulating foamed material to form a thermally insulated water tank.
F16L 57/02 - Protection des tuyaux ou d'objets de forme similaire contre les dommages ou les usures internes ou externes contre la fissuration ou le flambement
F16L 59/02 - Forme ou configuration de matériaux isolants, avec ou sans revêtement formant un tout avec les matériaux isolants
F16L 59/04 - Dispositions utilisant des charges sèches, p. ex. de la ouate minérale
F16L 51/00 - Compensation de la dilatation dans les canalisations
E04B 1/98 - Protection contre d'autres agents indésirables ou dangers contre les vibrations ou les chocsProtection contre d'autres agents indésirables ou dangers contre les destructions mécaniques, p. ex. par les raids aériens
58.
CORROSION-RESISTANT NON-METALLIC COMPOSITE LINER WITH TENSION-RESISTANT SHELL INTERNALLY PROVIDED WITH PRESTRESSED EXPANSIVE CEMENT
Disclosed is a corrosion-resistant non-metallic composite liner with a tension-resistant shell internally provided with prestressed expansive cement, comprising a corrosion-resistant and pressure-bearing rigid non-metallic liner (7), a tension-resistant shell (4) and expansive cement (2). The shape and pipe orifice of the corrosion-resistant and pressure-bearing rigid non-metallic liner (7) provided with at least one opening match, in one-one correspondence, the shape and pipe orifice of the tension-resistant shell (4). The corrosion-resistant and pressure-bearing rigid non-metallic liner (7) is wrapped in the tension-resistant shell (4) with clearance. By means of a positioning and connecting device provided at a pipe orifice (8) of the corrosion-resistant and pressure-bearing rigid non-metallic liner and an orifice of the tension-resistant shell, the pipe orifice (8) of the corrosion-resistant and pressure-bearing rigid non-metallic liner and the orifice of the tension-resistant shell, as well as a wall of the corrosion-resistant and pressure-bearing rigid non-metallic liner and a wall of the tension-resistant shell, are positioned with respect to each other with symmetrical clearance, and a gap between the pipe orifices is sealed. The expansive cement slurry is injected into the tension-resistant shell (4) and is sealed inside with an injection nozzle plug (5) thereof, so that the expansive cement slurry expands in the process of solidification, thus exerting a pressing force on the corrosion-resistant and pressure-bearing rigid non-metallic liner (7) and an expanding force on the tension-resistant shell (4); and an injection nozzle (6) is sealed with the injection nozzle plug (5) thereof. The corrosion-resistant non-metallic composite liner with a tension-resistant shell internally provided with prestressed expansive cement is easy to machine, resistant to corrosion, has a long service life, and is environmentally friendly, sanitary, healthy and low in costs.
F16L 57/02 - Protection des tuyaux ou d'objets de forme similaire contre les dommages ou les usures internes ou externes contre la fissuration ou le flambement
F16L 59/02 - Forme ou configuration de matériaux isolants, avec ou sans revêtement formant un tout avec les matériaux isolants
F16L 58/04 - Revêtements caractérisés par les matériaux utilisés
F16L 51/00 - Compensation de la dilatation dans les canalisations
An air purification electric fan, comprising a casing (1), a fan (6), a fan motor (9), a fan guard and a plasma high voltage generator (13). When the fan (6) is turned on, the fan (6) starts to rotate, air passes through the fan guard and a plasma generation electrode having a high voltage negative charge, the plasma generation electrode discharges the air, the air is ionised, the ionised air is drawn in by the plasma collection electrode fan (6) having a high voltage positive charge, pollutants having negative ions are attracted onto the fan (6), and the air is purified. The fan not only has an air purification function, but also has a blowing function.
F24F 3/16 - Systèmes de conditionnement d'air dans lesquels l'air conditionné primaire est fourni par une ou plusieurs stations centrales aux blocs de distribution situés dans les pièces ou enceintes, blocs dans lesquels il peut subir un traitement secondaireAppareillage spécialement conçu pour de tels systèmes caractérisés par le traitement de l'air autrement que par chauffage et refroidissement par purification, p. ex. par filtrageSystèmes de conditionnement d'air dans lesquels l'air conditionné primaire est fourni par une ou plusieurs stations centrales aux blocs de distribution situés dans les pièces ou enceintes, blocs dans lesquels il peut subir un traitement secondaireAppareillage spécialement conçu pour de tels systèmes caractérisés par le traitement de l'air autrement que par chauffage et refroidissement par stérilisationSystèmes de conditionnement d'air dans lesquels l'air conditionné primaire est fourni par une ou plusieurs stations centrales aux blocs de distribution situés dans les pièces ou enceintes, blocs dans lesquels il peut subir un traitement secondaireAppareillage spécialement conçu pour de tels systèmes caractérisés par le traitement de l'air autrement que par chauffage et refroidissement par ozonisation
60.
AIR-PURIFICATION ELECTRIC FAN WITH DUAL-LAYER BLADES
An air-purification electric fan with dual-layer blades, comprising a shell, a fan set, a fan motor, a fan shroud (4), and a plasma high-voltage generator. The fan set consists of an active fan and a passive fan. When the active fan is turned on and starts rotating, air passes through the active fan shroud (4) and then through a plasma generation pole with high-voltage negative charges; the plasma generation pole discharges to the air to ionize the air, so that the air is filled with anions and is sucked to the plasma collector electrode active fan with high-voltage positive charges, so as to be preliminarily purified; then the air enters the passive fan, wherein due to negative charges generated by induction on the surface of the passive fan adjacent to the active fan, different pollutants with positive charges are further adsorbed, and due to positive charges generated by induction on the surface of the passive fan opposite to the active fan, different pollutants with negative charges are further adsorbed, so that second air purification is implemented; and the purified air is discharged by means of the shroud. The plasma is fully used by means of multiple forced reactions, and thus there are few residual free radicals of ozone at an air outlet of the purifier, so that the air-purification electric fan can not only efficiently remove solid and gaseous pollutants in air, but also accelerate air circulation, thereby achieving high security and a high price-performance ratio.
F04D 25/08 - Ensembles comprenant des pompes et leurs moyens d'entraînement le fluide énergétique étant l'air, p. ex. pour la ventilation
F04D 29/70 - Grilles d'aspirationFiltresSéparateurs de poussièreNettoyage
B03C 3/10 - Installations alimentées en électricité de l'extérieur du type par voie sèche caractérisées par la présence d'électrodes se déplaçant pendant l'opération de séparation
61.
MULTI-EFFECT PLASMA AIR PURIFICATION BLADELESS ELECTRIC FAN
A multi-effect plasma air purification bladeless electric fan, comprising a fan base (14), a casing (1), a fan motor (9), a blowing ring (3), a plasma high voltage generator (13), a plasma generation electrode (7) and a collecting electrode fan set. The plasma generation electrode is arranged within a fan guard air inlet, the collecting electrode fan set is mounted within the casing (1), a conductive active fan (6) is connected to the fan motor (9) to provide wind power, and a fan passively rotated by the wind power is a conductive passive fan (17). The bladeless electric fan purifies air and also has a fan function, discharges via multiple forced reactions, makes full use of plasma, and has a high purification efficiency.
F04D 29/70 - Grilles d'aspirationFiltresSéparateurs de poussièreNettoyage
B03C 3/10 - Installations alimentées en électricité de l'extérieur du type par voie sèche caractérisées par la présence d'électrodes se déplaçant pendant l'opération de séparation
A thermal conduction convection ventilation electrostatic induction dust suction multi-functional composite glass curtain wall, comprising a window frame (32), a glass curtain wall, and a ventilation opening, the glass curtain wall comprising indoor side glass (10), a composite thermal conductive electrostatic induction glass (11) sandwiching a conductive adhesive film layer (25), and an outdoor side glass (26), a sandwich layer having a dual-layer ventilation duct separated in parallel being enveloped by means of separate supporting heads arranged at both ends, and the top and bottom ends of the glass curtain wall being provided with an air ventilation window. The present glass curtain wall has the functions of dust suction, air purification, and lighting and ventilation.
F24F 7/013 - Ventilation à écoulement forcé par l'emploi de ventilateurs dans les parois ou les fenêtres, par déplacement d'air à travers la paroi ou la fenêtre
F24F 1/00 - Climatiseurs individuels pour le conditionnement de l'air, p. ex. éléments séparés ou monoblocs ou éléments recevant l'air primaire d'une station centrale
A plasma air-purification bladeless electric fan, comprising a fan base, a shell (1), a blower motor, a collector electrode conductive fan (6), a blowing ring (3), an oscillating means, and a plasma high-voltage generator (13). A plasma generation pole (7) is provided within the air inlet of a fan shroud; when the collector electrode conductive fan (6) is turned on and starts rotating, air passes through the fan shroud and then through the plasma generation pole (7) with high-voltage negative charges, so that the air is ionized and filled with anions; the air passes through the collector electrode conductive fan (6) with high-voltage positive charges, so as to be preliminarily purified; then, the air flows upwards to the inner cavity of the blowing ring (3), and the air with anions induces the inner cavity wall of the blowing ring (3) to form a surface having a film with positive charges, thereby implementing second air purification. The plasma is fully used by means of multiple forced reactions, and thus there are few residual free radicals of ozone that would cause damage to a human body; therefore, the bladeless fan is safe. Moreover, high air circulation rate and dust removal efficiency are implemented, and the air purification effect is improved.
F04F 5/16 - Pompes à jet, p. ex. dispositifs dans lesquels le flux est produit par la chute de pression causée par la vitesse d'un autre fluide le fluide inducteur étant un fluide compressible déplaçant des fluides compressibles
B03C 3/38 - Postes de chargement ou d'ionisation des particules, p. ex. utilisant des décharges électriques, des radiations radioactives ou des flammes
64.
ENERGY-STORING, TEMPERATURE-REGULATING, WATER-CONDENSING AND SAND-FIXING APPARATUS BASED ON PLANT STRAW PROFILE TUBES
An energy-storing, temperature-regulating, water-condensing and sand-fixing apparatus based on plant straw profile tubes, comprising: plant straw profile tubes (5), ropes (7), fixing anchor piles (1), and energy storage medium containers (4). Each plant straw profile tube (5) is provided with at least one tube hole (9); a rope (7) passes through the tube hole (9); an energy storage medium container (4) using water or a water solution as an sufficient energy storage medium (6) is placed in the plant straw profile tube (5); an expansion space (8) for the energy storage medium (6) needs to be reserved in the energy storage medium container (4). The plant straw profile tubes (5) are semi-buried in sandy soil (10) and the ropes (7) are fixed using the fixing anchor piles (1), so as to form a sand-fixing grid by means of latticed or triangular arrangement.
A metal conductor electric heating dual heat source heating plastic pipe, comprising an electrically insulated pipe (1), a metal conductor material (3), electrically connected lead electrodes (2), and an electrically insulating material sleeve pipe (4). The metal conductor material (3) is either tightly wound or wrapped around the outer wall of the electrically insulated pipe (1). Provided on the metal conductor material (3) are electrically connected electrically-conductive ferrules (5) for leading out electrode connectors. The electrically insulating material sleeve pipe (4) is an extruded plastic pipe.
A composite electric heating wire dual heat source heating plastic pipe. Provided on the outer wall of an electrically insulated pipe (1) are at least two lead electrodes (2) symmetrically distributed, wound, and fixed on the outer pipe wall of the electrically insulated pipe (1), electric heating wires (3) are evenly distributed, wound, wrapped around, and fixed on the at least two lead electrodes (2), thus forming a pipe-shaped layer wound by the electric heating wires (3) in which the electric heating wires (3) have great electrical connection with the lead electrodes (2), constituting a heating circuit in which the electric heating wires (3) are connected in parallel by means of winding the at least two lead electrodes (2) with the electric heating wires (3). By controlling a power supply and increasing the length to regulate power, water in the pipe is kept at a certain temperature, thus implementing the function of complementary heating of multiple heat sources. Because an electro-thermal material is compounded in the heating pipe, the mechanical strength is greatly increased, production process is mature and simple, and because of the presence of water in the pipe, the phenomenon of overheating from electric heating does not occur easily, thus being safe and reliable. By adjusting the voltage, controllable power is implemented, thus fully utilizing off-peak electricity for heating with a single heat source or multiple heat sources.
F16L 11/12 - Manches, c.-à-d. tuyaux flexibles en caoutchouc ou en matériaux plastiques flexibles avec agencements pour usages particuliers, p. ex. spécialement profilés, avec couche protectrice, chauffés, conducteurs d'électricité
F16L 53/00 - Chauffage des tuyaux ou des systèmes de tuyauxRefroidissement des tuyaux ou des systèmes de tuyaux
F24D 12/02 - Autres systèmes de chauffage central avec plus d'une source de chaleur
67.
COMPOSITE ELECTROTHERMAL FILM HEAT-TRACING INSULATING PLASTIC PIPE
A composite electrothermal film heat-tracing insulating plastic pipe , comprising an electric insulating pipe (1), an electrothermal film (3), electrically connected lead electrodes (2), a bonding adhesive, and a plastic pipe. The electrothermal film is tightly wrapped on the outer wall of the electric insulating pipe to form at least one layer of the tubular electrothermal film; and at least two lead electrodes are symmetrically distributed and fixedly wound around the electrothermal film on the outer pipe wall of the electrical insulation pipe to achieve a good electrical connection with the electrothermal film. An annular parallel electrothermal film heating circuit formed by the lead electrodes and the electrothermal film can safely, quickly and uniformly melt ice on the inner wall of a pipeline along the electrothermal film using less electric energy, constituting a liquid pathway, allowing the hot water in the pipeline to flow downwardly along the whole pipeline to melt ice quickly. A control element can control the power of a low voltage power supply, so that heat is generated in the leads to keep the insulating pipeline from being frozen. By means of controlling the power supply to keep the water in the pipeline at a certain temperature, the function of providing hot water once a water nozzle is turned on is achieved. Since the presence of water in the pipeline makes the electric heating less prone to overheating, the strength of the pipeline is improved.
F16L 53/00 - Chauffage des tuyaux ou des systèmes de tuyauxRefroidissement des tuyaux ou des systèmes de tuyaux
F16L 9/14 - Tubes en matériaux composites, c.-à-d. faits de matériaux non complètement couverts dans un seul des groupes précédents
F16L 11/12 - Manches, c.-à-d. tuyaux flexibles en caoutchouc ou en matériaux plastiques flexibles avec agencements pour usages particuliers, p. ex. spécialement profilés, avec couche protectrice, chauffés, conducteurs d'électricité
68.
DUAL-HEAT SOURCE SELF-CONTROLLED TEMPERATURE HEATING PLASTIC PIPE OF COMPOSITE PTC ELECTRICALLY-CONDUCTIVE POLYMER MATERIAL FILM
A dual-heat source self-controlled temperature heating plastic pipe of a composite PTC electrically-conductive polymer material film comprising an electrically insulating pipe (1), a PTC electrically-conductive polymer material film (3), electrically connected wire electrodes (2) and a plastic pipe (4), wherein the wire electrodes (2) are fixed in a winding manner to the outer wall of the electrical insulating pipe (1), the PTC electrically-conductive polymer material film (3) is evenly distributed, extruded, coated and fixed to the wire electrodes (2) to form a tubular layer coated with the PTC electrically-conductive polymer material film (3) having a good electric connection between the PTC electrically-conductive polymer material film (3) and the wire electrodes (2), and the tubular layer coated with the PTC electrically-conductive polymer material film (3) and the wire electrodes (2), are at least compounded with the electrically insulating plastic pipe (4) manufactured by an extrusion process. When an electric current passes, the PTC electrically-conductive polymer material works as a heating body to transfer electric energy into heat due to Joule heat.
A composite electric heating wire trace heated and thermally insulated plastic pipe, capable of using minimum electric power to electrically heat safely and rapidly the inner wall of the pipe for rapid and even deicing, thus constituting a liquid flow channel, and allowing hot water in the pipe to flow downstream through the entire pipe for rapid deicing. The power of a low-voltage power supply can be controlled by a control element, the heat generated by a lead can keep the thermally insulated pipe from freezing, and water in the pipe can be kept at a certain temperature by means of controlling the power supply, thus implementing the function of instant hot water supply upon opening a faucet. This has a mature and simple production process, greatly increases the strength of the pipe, because the phenomenon of overheating from electric heating is largely prevented with the presence of water in the pipe, implements controllable voltage by means of adjusting the voltage, and represents the direction for future developments for thermally insulated pipes.
F16L 11/12 - Manches, c.-à-d. tuyaux flexibles en caoutchouc ou en matériaux plastiques flexibles avec agencements pour usages particuliers, p. ex. spécialement profilés, avec couche protectrice, chauffés, conducteurs d'électricité
F16L 59/06 - Dispositions utilisant une couche d'air ou le vide
F16L 59/14 - Dispositions pour l'isolation des tuyaux ou des tuyauteries
70.
COMPOSITE ELECTRIC HEATING FILM DUAL HEAT SOURCE HEATING PLASTIC PIPE
A composite electric heating film dual heat source heating plastic pipe, comprising an electrically insulated pipe (1), an electric heating film (3), electrically connected lead electrodes (2), an adhesive, and a plastic pipe (4). The electric heating film (3) tightly wraps around the outer wall of the electrically insulating pipe (1). At least two lead electrodes (2) are symmetrically distributed, wound, and fixed on the electric heating film (3) on the outer pipe wall of the electrically insulated pipe (1). An electrically insulated plastic pipe (4) manufactured by means of an extrusion process is at least compounded on the pipe-shaped electric heating film layer (3) and the lead electrodes (2).
A composite PTC electrically-conductive polymer material film self-thermal control and thermally insulated plastic pipe, comprising an electrically insulated pipe (1), a PTC electrically-conductive polymer material film (3), electric connection lead electrodes (2), a thermally insulating pipe-in-pipe (4), and a thermally insulating pipe-on-pipe (6). Provided on the outer wall of the electrically insulated pipe are at least two lead electrodes, symmetrically distributed, wound, and fixed on the outer pipe wall of the electrically insulated pipe, the PTC electrically-conductive polymer material film is evenly distributed, extruded, wrapped around, and fixed on the at least two lead electrodes, thus forming a PTC electrically-conductive polymer material film wrapped pipe-shaped layer in which the PTC electrically-conductive polymer material film has great electrical connection to the lead electrodes. The plastic pipe thermally insulated by an electrically insulating sandwiched air layer thus extruded is the thermally insulating pipe-in-pipe and the thermally insulating pipe-on-pipe sleeved together. Provided between the two pipes are at least two symmetrically and evenly distributed positioning support ribs (5).
F16K 11/12 - Soupapes ou clapets à voies multiples, p. ex. clapets mélangeursRaccords de tuyauteries comportant de tels clapets ou soupapesAménagement d'obturateurs et de voies d'écoulement spécialement conçu pour mélanger les fluides dont plusieurs éléments de fermeture ne se déplacent pas comme un tout dont un boisseau tourne dans un autre
72.
METAL CONDUCTOR ELECTRICALLY HEATED AND THERMALLY INSULATED PLASTIC PIPE
A metal conductor electrically heated and thermally insulated plastic pipe, capable of using minimum electric power to electrically heat safely and rapidly the inner wall of the pipe for rapid and even deicing, thus constituting a liquid flow channel, and allowing hot water in the pipe to flow downstream through the entire pipe for rapid deicing. The power of a low-voltage power supply can be controlled by a control element, the heat generated by a lead can keep the thermally insulated pipe from freezing, and water in the pipe can be kept at a certain temperature by means of controlling the power supply, thus implementing the function of hot water being provided upon opening a faucet.
An underfloor heating glass floor disposed internally to a heating component for collecting dust and purifying air using static electricity comprises a glass panel (1) and a glass substrate panel (2). The glass panel (1) is an electrically isolated panel. An electrically conducting mesh film (3) is disposed between the glass panel (1) and the glass substrate panel (2). A connection slot (5) and a connection link (6) are disposed at edges of the floor. Heating element positioning through holes are provided at a back portion of the glass substrate panel (2) in equal intervals. The floor is simple in structure, conserves energy, and is environmentally friendly, providing a favorable purification effect to collect the dust in the air by collecting the dust using static electricity.
A solar-selective absorbing coating with magnetron sputtering and a single aluminum target. The solar-selective absorbing coating has an aluminum reflective film (2) deposited on a substrate as a bottom layer, aluminum-containing ceramics deposited on the aluminum reflective film (2) as a diffusion barrier layer, an aluminum-containing metal ceramic composite material deposited on the aluminum-containing ceramic diffusion barrier layer as a solar-selective absorbing material layer, and an aluminum-containing ceramic antireflection film deposited on the solar-selective absorbing material layer of the aluminum-containing metal ceramic composite material as a surface layer. For the solar-selective absorbing coating, coating is performed by using a magnetron sputtering vacuum coating machine having a single aluminum target in combination with a reactive gas and a working gas. The layers have high absorptivity and superior thermal stability, and therefore have an excellent heat collection performance while being easy to build. Surface volatilization and gas emission are less than a metal-carbide absorbing material. Therefore, a baking temperature can be adjusted to 400-500 º C when producing heat collector tubes, thereby reducing a manufacturing time period and power consumption.
An underfloor heating glass floor disposed externally to a heating component for collecting dust and purifying air using static electricity comprises an electrically isolated glass panel (1), a glass substrate panel (2), an electrically conducting mesh film (3) disposed therebetween, and a connection slot (5) and a connection link (6) disposed at edges of the floor. The floor is installed above a supporting and locating device that has a heating element laid thereon. The floor is simple in structure, and capable of purifying dust in the air by static electricity.
E04F 15/02 - Revêtements de sol composés d'un certain nombre d'éléments semblables
E04F 15/08 - Revêtements de sol composés d'un certain nombre d'éléments semblables uniquement en pierre ou en matériau analogue, p. ex. bétonRevêtements de sol composés d'un certain nombre d'éléments semblables en verre
F24D 13/02 - Systèmes de chauffage électrique utilisant uniquement le chauffage par résistance, p. ex. chauffage par le sol
76.
UNDERFLOOR HEATING COMPOSITE FLOOR DISPOSED INTERNALLY TO HEATING COMPONENT FOR COLLECTING DUST AND PURIFYING AIR USING STATIC ELECTRICITY
An underfloor heating composite floor disposed internally to a heating component for collecting dust and purifying air using static electricity comprises: a floor panel (1), a floor substrate panel (2). The floor panel (1) is an electrically isolated panel. An electrically conducting mesh film (3) is disposed between the floor panel (1) and the floor substrate panel (2). A connection slot (5) and a connection link (6) are disposed at edges of the floor. A floor heating pipe (15) or heating cables are disposed in the connection slot (5). The floor is simple in structure, conserves energy, and is environmental friendly, providing a favorable purification effect to collect the dust in the air by collecting the dust using static electricity.
Provided is an electrostatic dust-sucking and air-purifying electrothermal film-sandwiched glass floor for underfloor heating. An adhesive electrically-conducting material film layer (3), an electrically-insulating adhesive material film layer (9) and an electrothermal film (10) are successively arranged between a glass panel (1) and a base plate (2), wherein the adhesive electrically-conducting material film layer (3) generates static electricity that has a good adsorption effect on airborne dust, so that the problem that dust caused by underfloor heating circulation convection cannot settle is solved.
An underfloor heating composite floor disposed externally to a heating component for collecting dust and purifying air using static electricity comprises: a panel (1), a substrate panel (2), a connection slot (5), and a connection link (6). The panel (1) is an electrically isolated panel. An adhesive and electrically conductive material film layer (3) is disposed between the panel (1) and the substrate panel (2). The panel (1) and the substrate panel (2) are stacked, pressed, and adhered together by the adhesive and electrically conductive material film layer (3). The composite floor is installed above a supporting and locating device that has a heating element laid thereon, and configured to collect dust in the air by an electrostatic effect produced by the adhesive and electrically conductive material film layer.
E04F 15/02 - Revêtements de sol composés d'un certain nombre d'éléments semblables
F24D 13/02 - Systèmes de chauffage électrique utilisant uniquement le chauffage par résistance, p. ex. chauffage par le sol
B32B 33/00 - Produits stratifiés caractérisés par des propriétés particulières ou des caractéristiques de surface particulières, p. ex. par des revêtements de surface particuliersProduits stratifiés conçus pour des buts particuliers non couverts par une seule autre classe
79.
ELECTROSTATIC-PRECIPITATION AIR-PURIFICATION GROUND-HEATING COMPOSITE FLOOR SANDWICHED WITH ELECTROTHERMAL FILM
An electrostatic-precipitation air-purification ground-heating composite floor sandwiched with an electrothermal film, comprising a floor panel (1) and a floor substrate board (2). The floor panel (1) is an electrical-insulating panel. An electrically-conductive bonding mesh film (3) is disposed between the floor panel (1) and the floor substrate board (2). A connection slot (5) and a connection insertion part (6) are provided on sides of the floor, and a power cable (15) is provided in the connection slot (5). The floor has a simple structure, and is energy-saving and environmentally friendly because electrostatic precipitation has a desirable purification function on dust in the air.
F24D 13/02 - Systèmes de chauffage électrique utilisant uniquement le chauffage par résistance, p. ex. chauffage par le sol
B03C 3/04 - Installations alimentées en électricité de l'extérieur du type par voie sèche
B32B 3/06 - Caractérisés par des caractéristiques de forme en des endroits déterminés, p. ex. au voisinage des bords pour lier les couches ensembleCaractérisés par des caractéristiques de forme en des endroits déterminés, p. ex. au voisinage des bords pour attacher le produit à quelque chose d'autre p. ex. à un support
B32B 5/24 - Produits stratifiés caractérisés par l'hétérogénéité ou la structure physique d'une des couches caractérisés par la présence de plusieurs couches qui comportent des fibres, filaments, grains ou poudre, ou qui sont sous forme de mousse ou essentiellement poreuses une des couches étant fibreuse ou filamenteuse
B32B 33/00 - Produits stratifiés caractérisés par des propriétés particulières ou des caractéristiques de surface particulières, p. ex. par des revêtements de surface particuliersProduits stratifiés conçus pour des buts particuliers non couverts par une seule autre classe
80.
SMART TABLET WITH U-SHAPED LAYOUT TOUCH CONTROL SCREEN HOLDING GESTURE INPUT SELF-SETTING KEYBOARD
A smart tablet (2) with a U-shaped layout touch control screen holding gesture input self-setting keyboard. An input keyboard thereof is arranged on a surface of the smart tablet (2) where ten fingers of two hands naturally touch when in a holding gesture of the two hands, and thumbs of the two hands touch and control a space input key arranged on an edge of a front touch control display screen (1) of the smart tablet (2), and the other functional keys and a mouse; or the space input key touched and controlled by the thumbs of the two hands is arranged on a frame of the smart tablet (2), the other functional keys and the mouse are arranged on an edge of the front touch control display screen (1), and the other fingers of the two hands touch and control a rear touch control screen (4) of the smart tablet (2) with an input key corresponding to a conventional computer keyboard or a specific input keyboard; or the space input key touched and controlled by the thumbs of the two hands is arranged on a frame of the smart tablet (2), the other functional keys and the mouse are arranged on an edge of the front touch control display screen (1), and the other fingers of the two hands touch and control a rear touch control screen (4) of the smart tablet (2) with an input key corresponding to a conventional computer keyboard or a specific input keyboard. A smartphone and the rear surface of the smart tablet (2) are functionalized.
A high-temperature-resistant selective-absorption functional film formed by etching. A heat-absorption film layer is a metallic film layer formed by etching, and is a high-temperature-resistant selective-absorption functional film (2) overlaying micro-pits of a post-etched object surface. The film is a black body having extremely low reflectance, high absorption, stable physicochemical properties, and resistance to high temperatures. A metallic layer (1) has infrared reflection functionality, low transmittance, excellent film-layer heat conductivity, high strength, and high absorption. The film layer is suitable for processing of materials that are both of large size and of various shapes.
A high-temperature-resistant selective absorption functional membrane generated by thermal decomposition comprises a two-layer structure formed by compounding a metal base material (1) and a carbon material absorbing membrane layer (2); the structure of the high-temperature-resistant selective absorption functional membrane sequentially comprises a bottom layer of the metal base material (1) and a carbon membrane layer surface layer (2) that is formed after being treated by thermal decomposition and is provided with dense micropores; the bottom layer of the metal base material (1) is made from a board, or a pipe, or a pipe and a board, or pipes; the high-temperature-resistant selective absorption functional membrane (2) is formed by carrying out thermal decomposition treatment on an organic adhesive; the organic adhesive is made from a single material or more than one composite material; or a membrane layer is formed by mixing an adhesive and a light absorption material, and the carbon membrane layer surface layer (2) provided with the dense micropores on the surface is generated by thermal decomposition sintering.
A notebook computer (1) with a U touch screen holding gesture input self-setting keyboard. When the computer is used at an angle greater than or equal to 180°, a dual-screen plane input keyboard is formed by a notebook computer touch display screen (3) and a notebook computer mainframe input touch screen (6). When the notebook computer (1) is folded by 360° to be used, the notebook computer mainframe input touch screen (6) switches key display from common or specific input keyboard arrangement to holding gesture input keyboard arrangement and switches input key functions, thereby realizing switching from a common or specific input keyboard of the notebook computer (1) to a holding gesture input keyboard consisting of the notebook computer touch display screen (3) and the notebook computer mainframe input touch screen (6). The input keyboard is provided on a surface, of the notebook computer (1), which is touched by ten fingers naturally in a holding gesture of both hands. Thumbs of both hands touch a space input key, other functional keys, and a mouse, which are provided on an edge of the notebook computer touch display screen (3) on the front of the notebook computer (1). Alternatively, the space input key touched by the thumbs of both hands is provided on a notebook computer frame (9), and the other functional keys and the mouse are provided on the edge of the notebook computer touch display screen (3) on the front of the notebook computer.
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