Abstract

An air draft system for preventing odor from escaping during furnace starting and stopping in a garbage incineration power plant, comprising a primary air draft system and a secondary air draft system. Due to the fact that a primary air furnace top air draft pipeline and a secondary air furnace top air draft pipeline are further provided, when the incinerator is in an off state or is in a just-started combustion state, since the hearth temperature is low, pneumatic fire dampers of the primary air draft system and and of the secondary air draft system are closed, and then the primary air furnace top air draft pipeline and the secondary air furnace top air draft pipeline are opened, and the primary air draft system and the secondary air draft system respectively draft air from the top of the furnace. Due to the fact that air above the top of the furnace is clean, the surrounding environment is not affected when flue gas is discharged into the air by means of a chimney. The flue gas discharged into the air by means of the chimney is prevented from containing an obvious odor because the temperature of the furnace is lower, effectively solving the existing technical problem.

IPC Classes  ?

• F23G 5/50 - Control or safety arrangements
• F23L 1/00 - Passages or apertures for delivering primary air for combustion
• F23L 9/00 - Passages or apertures for delivering secondary air for completing combustion of fuel

Abstract

A method for measuring the content of heavy metal elements in household waste incineration power plant fly ash. A potion, i.e., a glacial acetic acid, is prepared at an extraction stage in the measurement process, and a tedious extractant confirmation operation is not needed; at a measurement stage, a calibration curve is drawn only once, the concentration gradient of the curve is set reasonably, and a dilution ratio of a suspected high-concentration sample can be determined before on-machine measurement; the preparation of HJ/ T 300-2007 traditional Chinese medicine can be effectively simplified; an extractant confirmation operation is not needed; and the disadvantages that many types of standard samples are needed, the concentration gradient of the calibration curve is unreasonable, the test time is long, the consumption of high-purity argon is high, the measurement is difficult, and the high-concentration waste liquid pollutes the environment in measuring the content of heavy metal in garbage power plant fly ash and a chelate thereof by HJ 781-2016 can be effectively solved. The present invention has significant advantages in the aspects such as sample testing period, material consumption, labor intensity, pollution control among samples, and measurement difficulty.

IPC Classes  ?

• G01N 1/28 - Preparing specimens for investigation

Abstract

An ammonia water storage system uses a two-ammonia tank structure, and comprises an ammonia water storage tank (1.1), an outer ammonia water storage tank (4), an ammonia gas recovery pipe (6) and a dilution water tank (2.1). The ammonia water storage tank (1.1) is disposed in the outer ammonia water storage tank (4), and a sandwiched space (5) is arranged between the ammonia water storage tank (1.1) and the outer ammonia water storage tank (4), such that ammonia gas escaping from the ammonia water storage tank (1.1) is stored in the sandwiched space (5). An inlet end of the ammonia gas recovery pipe (6) is connected to a top portion of a tank body of the outer ammonia water storage tank (4) and is in communication with the sandwiched space (5). An outlet end of the ammonia gas recovery pipe (6) is connected to the dilution water tank (2.1), and an opening of the outlet end is located below the liquid level of dilution water. The ammonia gas escaping to the sandwiched space (5) flows into the ammonia gas recovery pipe (6) from the inlet end of the ammonia gas recovery pipe (6) and is finally dissolved in the water in the dilution water tank (2.1) to form dilution water. The invention enables recycling of escaped ammonia gas, and ensures the safety of the environment surrounding an ammonia region.

IPC Classes  ?

• B65D 88/00 - Large containers
• B65D 90/24 - Spillage-retaining means, e.g. recovery ponds
• B65D 90/00 - Component parts, details or accessories for large containers
• B01D 53/18 - Absorbing unitsLiquid distributors therefor

Abstract

A strong coupling synergistic treatment method for waste in an urban vein industrial park: on the basis of the concepts of ecological industrial parks and circular economies, a municipal solid waste treatment system is taken as an integrated whole; according to physical and chemical characteristics of different solid wastes such as household garbage, kitchen garbage, municipal sludge and old tires, and process characteristics of combustion, anaerobic fermentation, pyrolysis and other processes, a synergistic coupling method for efficient circulation and cascade utilization of energy, intermediate products, and reclaimed water is established, which achieves the recycling of energy and materials, increases energy efficiency, reduces the consumption of chemical agents and reduces pollution emissions; by means of sharing a portion of treatment facilities, land resources are conserved and investment costs are reduced; at the same time, biogas/combustible gas is reformed to produce hydrogen, which is used for hydrogen energy garbage trucks, thereby successfully creating a green low-carbon closed-loop management model for solid wastes, and fully reflecting the concept of carbon-neutral solid waste energy stations.

IPC Classes  ?

• B09B 3/00 - Destroying solid waste or transforming solid waste into something useful or harmless
• F23G 5/02 - Methods or apparatus, e.g. incinerators, specially adapted for combustion of waste or low-grade fuels including pretreatment

Abstract

Disclosed is a method for the online rapid calculation of a garbage incineration calorific value. The method comprises: collecting real-time temperature and humidity data and garbage fermentation time data of a garbage pool, and collecting real-time temperature data and air chamber pressure difference data of all sections of fire grates in a combustion chamber; and inputting historical data in a database into a data model formula, automatically comparing same with collected real-time data, and rapidly analyzing a garbage calorific value of a certain region by means of big data statistics and the data model formula. Under the support of rapidly analyzing a garbage calorific value, the speed of a fire grate and the opening degree of an air blower can be directly regulated and controlled, such that an optimal combustion working condition is realized, thereby ensuring that the effect of garbage incineration treatment and a pollutant emission index meet the requirements of a related national standard. After a rapid analysis is performed on a garbage calorific value, a regulation link of a garbage incinerator control system is entered in a more targeted manner, thereby improving the garbage incineration efficiency, and meeting the requirements for the decontamination, reduction and resource utilization treatment of solid waste in garbage.

IPC Classes  ?

• G06F 30/20 - Design optimisation, verification or simulation
• G06F 30/28 - Design optimisation, verification or simulation using fluid dynamics, e.g. using Navier-Stokes equations or computational fluid dynamics [CFD]
• F23G 5/50 - Control or safety arrangements
• G06F 113/08 - Fluids
• G06F 119/08 - Thermal analysis or thermal optimisation
• G06F 119/14 - Force analysis or force optimisation, e.g. static or dynamic forces

Abstract

A synergistic treatment method for fly ash washing wastewater and wet-process deacidification wastewater. Chloride salts in fly ash are extracted by means of fly ash washing, then the fly ash is treated by curing using a chelating agent. After fly ash washing, the water content of a filter cake pressed by a plate and frame filter press is 40-50%, and an increase in an amount of water can increase the contact area between the chelating agent and the fly ash and improve the contact efficiency, so that the dosage of the chelating agent can be significantly reduced, and the production cost is reduced; moreover, generated fly ash washing wastewater is pumped into a deacidification wastewater pool by means of a pump and mixed with deacidification wastewater generated by a wet-process deacidification system of a waste incineration power plant, a mixed solution is conveyed to a sewage treatment facility by means of a pump, coagulation-sedimentation and evaporative crystallization processes are jointly performed to separate salts and purify water, the salts obtained by evaporation can be sold in the market, and the purified water is reused as makeup water for a fly ash washing process. Thus, the problem of enrichment of salts and heavy metals in fly ash is solved, and the goals of waste recycling and zero discharge of wastewater are achieved.

IPC Classes  ?

• C02F 9/10 - Thermal treatment
• C02F 103/18 - Nature of the water, waste water, sewage or sludge to be treated from the wet purification of gaseous effluents
• C02F 101/20 - Heavy metals or heavy metal compounds
• C02F 101/30 - Organic compounds

Abstract

A movable medical waste incineration treatment vehicle, comprising a movable unit. A box is provided on the unit, an incineration device and a flue gas treatment device are provided inside the box, a crusher is further provided at an inlet of an incinerator, a liquefied gas combustion-supporting device is further provided, and a combustion-supporting fan is further provided. During operation, medical waste is fed into the crusher for crushing treatment, and then enters into the incinerator to be combusted. In order to ensure smooth combustion, the combustion-supporting fan continuously supplies air into the incinerator. Flue gas generated in the incinerator enters, from a flue, the flue gas treatment device to be treated, and is then discharged from a chimney; ash residues generated after combustion are discharged downwards from an ash residue outlet at the bottom of the incinerator. The flue gas and the dust in the flue gas treatment device sequentially pass through a bag filter, a dust collection chamber, and a dust collector, and are finally discharged from an ash discharge port. Therefore, waste-minimized and environment-friendly incineration treatment for medical waste is achieved in a movable manner.

IPC Classes  ?

• F23G 7/00 - Methods or apparatus, e.g. incinerators, specially adapted for combustion of specific waste or low grade fuels, e.g. chemicals
• F23G 5/033 - Methods or apparatus, e.g. incinerators, specially adapted for combustion of waste or low-grade fuels including pretreatment comminuting or crushing
• F23G 5/12 - Methods or apparatus, e.g. incinerators, specially adapted for combustion of waste or low-grade fuels including supplementary heating using gaseous or liquid fuel
• F23G 5/44 - Methods or apparatus, e.g. incinerators, specially adapted for combustion of waste or low-grade fuels DetailsAccessories
• F23J 1/00 - Removing ash, clinker, or slag from combustion chambers
• F23J 15/02 - Arrangements of devices for treating smoke or fumes of purifiers, e.g. for removing noxious material
• B60P 3/00 - Vehicles adapted to transport, to carry or to comprise special loads or objects
• F27B 7/00 - Rotary-drum furnaces, i.e. horizontal or slightly inclined

Abstract

A water accumulation prevention device for evacuating a power plant condenser comprising an evacuation main pipe and two independent evacuation systems for evacuating the evacuation main pipe. During a normal operation process, one of the evacuation systems is in use while the other is in a standby mode. In each of the two evacuation systems, a communicating water redirection pipe is arranged after an inlet manual diaphragm valve and before an inlet absolute pressure gauge, and a valve is further arranged on the communicating water redirection pipe. Arrangement of the communicating water redirection pipe enables the operating evacuation system to remove water accumulated at an inlet section of the standby evacuation system, such that condensed water continuously generated by a non-condensed gas in a standby pump pipe does not accumulate in a pipe section thereof, thereby solving the problem of water accumulation at the inlet section, and ensuring normal operation of a power plant.

IPC Classes  ?

• F28B 9/10 - Auxiliary systems, arrangements, or devices for extracting, cooling, and removing non-condensable gases

Abstract

A sludge unloading room deodorization system, comprising a sludge unloading room (1.1) in a negative air pressure state and a room deodorization system (1.2), the room deodorization system (1.2) comprising a room airtight door (1.21), a room airtight door air curtain (1.22) and a room deodorization ventilation system air exhaust pipe (1.23). A sludge unloading bin (2.1) which may be closed and which is in a negative air pressure state and a bin deodorization system (2.2) are also provided in the interior of the sludge unloading room (1.1), the bin deodorization system (2.2) comprising a bin airtight door (2.21), a bin airtight door air curtain (2.22) and a bin deodorization ventilation system air exhaust pipe (2.23). Problems such as odor overflow, accumulation and a poor operating environment in a sludge unloading room are effectively solved by configuring two sets of automatic sealing control systems of rapid airtight doors, airtight door air curtains and breather valves and two sets of continuously operating ventilation deodorization systems.

IPC Classes  ?

• B08B 15/00 - Preventing escape of dirt or fumes from the area where they are producedCollecting or removing dirt or fumes from that area
• F24F 7/06 - Ventilation with ducting systems with forced air circulation, e.g. by fan
• E04H 5/02 - Buildings or groups of buildings for industrial purposes, e.g. for power-plants or factories

Abstract

A lime slurry preparation system for a waste incineration plant, the system comprising: a digestion device (1), a dilution device (2) and a lime slurry conveying device (3); and further comprising: a Venturi dust removal device (4), wherein a first lime slurry backflow pipeline (4.2) is further provided, one end of the first lime slurry backflow pipeline (4.2) being connected to a slurry output pipeline (3.2B), and the other end thereof being connected to a first inlet (4.1A1) of a Venturi negative-pressure suction washing device (4.1). A steam collection pipeline (4.3) is further arranged at the top of a digestion tank (1.4), one end of the steam collection pipeline (4.3) being connected to the digestion tank (1.4), and the other end thereof being connected to a second inlet (4.1A2) of the Venturi negative-pressure suction washing device (4.1); and an outlet (4.1B) of the Venturi negative-pressure suction washing device (4.1) is connected to a dilution tank (2.1). By means of adding a lime slurry backflow pipeline, a small portion of an output slurry of the slurry output pipeline (3.2B) in the lime slurry conveying device (3) is conveyed to an atomizer, and the majority of the output slurry flows into the Venturi negative-pressure suction washing device (4.1) via the first inlet (4.1A1), such that in a Venturi pipe, moist hot steam and a backflow slurry are mixed and condensed, and finally flow back to the dilution tank (2.1), thereby eliminating the moist hot steam.

IPC Classes  ?

• B01D 53/80 - Semi-solid phase processes, i.e. by using slurries
• B01D 47/10 - Venturi scrubbers
• B01D 53/40 - Acidic components
• B01D 53/96 - Regeneration, reactivation or recycling of reactants
• C04B 2/08 - Devices therefor

Abstract

In order to solve a problem existing in the prior art, the present invention provides a site location-based system and method for management of engineering quality acceptance: positioning an engineering project inspection site by means of a positioning base station, and solidifying criteria for quality acceptance in a software system; that is, it is convenient for a user to check the acceptance criteria at the time of acceptance; it is also possible to take photos on-site if a quality problem is found, and propose corrective action; during specific operation, the user can make a selection by means of clicking, with no need for the time-consuming input of text; at the same time, the entry of results is standardized, the selection and entry of numbers being the main focus, and the input of text being disabled, significantly increasing convenience for the user; by means of an engineering project information recommendation and selection process, the scope of selection is narrowed, further reducing the time spent by the user to operate the system, improving the operability of the system and effectively solving the problem in the prior art.

IPC Classes  ?

• G06Q 10/10 - Office automationTime management

Abstract

A biogas dual-membrane storage system for a waste incineration power plant. The system comprises an explosion-proof fan (1), a check valve (2), a safety valve (3), a bottom membrane (4), an outer membrane (5), an inner membrane (6), a gas intake pipe (7) and a bottom plate (8), wherein the bottom membrane (4) is attached and fixed to the bottom plate (8), a closed gas storage space (6.1) is formed between the bottom membrane (4) and the inner membrane (6), a pressure regulating chamber (5.1) is formed between the inner membrane (6) and the outer membrane (5), and biogas generated by a biogas digester enters the gas storage space (6.1) by means of the gas intake pipe (7). Since a pressure regulating exhaust device is additionally arranged, when the pressure intensity of gas in the pressure regulating chamber (5.1) experiences overpressure, a pressure regulator (9) of the pressure regulating exhaust device is opened, and gas in the pressure regulating chamber (5.1) sequentially enters an alkali washing tower (10) and a deodorizing spray tower (11) by means of a pipeline for treatment, and then is discharged and is not directly discharged into the atmosphere, such that peculiar smell is prevented from being generated in the surrounding environment, system safety is further ensured, and the problems in the prior art are effectively solved.

IPC Classes  ?

• F17B 1/02 - Gas-holders of variable capacity Details
• F17B 1/12 - Gas admission or discharge arrangements
• F17B 1/14 - Safety devices, e.g. prevention of excess pressure
• F17C 1/00 - Pressure vessels, e.g. gas cylinder, gas tank, replaceable cartridge
• F17C 7/00 - Methods or apparatus for discharging liquefied, solidified, or compressed gases from pressure vessels, not covered by another subclass
• F17C 13/04 - Arrangement or mounting of valves
• B01D 53/75 - Multi-step processes
• B01D 53/78 - Liquid phase processes with gas-liquid contact

Abstract

An abnormality identification and adjustment method in an anaerobic treatment process for a household waste leachate, comprising a first identification step and a subsequent adjustment step. First, a water sample is obtained at a specified sampling point of an anaerobic reactor, and a gas sample is obtained at a discharge valve of a biogas manifold; the volatile organic acid concentration, total alkalinity, chemical oxygen demand, and pH value of the water sample, and the hydrogen sulfide concentration of the gas sample are analyzed; quick identification and diagnosis of working conditions of the anaerobic reactor are performed; on the basis of the identification and diagnosis results, an appropriate adjustment method is selected. The present invention aims at identifying direct causes of abnormalities of leachate anaerobic reactors, and making anticipations and adjustments.

IPC Classes  ?

• C02F 3/28 - Anaerobic digestion processes
• C02F 3/00 - Biological treatment of water, waste water, or sewage
• C02F 103/06 - Contaminated groundwater or leachate

Abstract

A system and method for precisely controlling a production process of a household waste incineration power plant. The system comprises an MVC-based three-layer architecture using a B/S architecture, i.e. a basic service layer, a system performance layer and a business logic layer. The basic service layer comprises a production database module, which is used for storing production statistical data and serves as a system encapsulation basic service layer to implement basic functions, such as data storage and file processing, so as to realize code transparency of underlying data and other basic information for the business logic layer. The system performance layer comprises a mobile phone reporting end, which is used by an operator to report production data and serves as a system performance layer to be responsible for user interaction, so as to call a business logic layer interface to realize various user operations. The business logic layer comprises a management platform, which is used for generating a production and operation indicator from the production data, performing precise production control, and processing all business function logic. Statistical analysis can be effectively performed on the production cost, power consumption and material consumption of household waste incineration power generation, thereby achieving cost control and potentiality exploitation, and providing data support for analysis, decision-making, etc. of a management layer.

IPC Classes  ?

• G06Q 10/06 - Resources, workflows, human or project managementEnterprise or organisation planningEnterprise or organisation modelling
• G06Q 10/10 - Office automationTime management
• G06Q 50/06 - Energy or water supply

Abstract

A compression volume reduction apparatus for a fly ash chelate, comprising a compression box (1), a discharge chute (2), and a mounting seat (3), and further comprising a feeding mechanism (4), a compression mechanism (5), a discharge mechanism (6), and a PLC control system. The feeding mechanism (4) comprises a feeding hopper (4.1) and a screw feeder (4.2). The compression mechanism (5) comprises a first hydraulic piston system (5.1), a guide assembly (5.2), and a compression plate (5.3). The discharge mechanism (6) comprises a second hydraulic piston system (6.1) and a pushing plate (6.2). A fly ash chelate enters the feeding hopper (4.1) from a feeding port on an upper side of the feeding hopper (4.1) and enters the screw feeder (4.2) from a discharge port on a lower side of the feeding hopper (4.1); the screw feeder (4.2) conveys the fly ash chelate to a feeding port at one end of the compression box (1); the fly ash chelate enters the compression box (1), is compressed, and then enters the discharge chute (2) from a discharge port at the other end of the compression box (1); the second hydraulic piston system (6.1) is started up to push the compressed fly ash chelate to a discharge port of the discharge chute (2). The described compression volume reduction apparatus can effectively solve the problem in which land resources are wasted due to the low density, irregular shape, and so on of a fly ash chelate.

IPC Classes  ?

• B30B 9/30 - Presses specially adapted for particular purposes for balingCompression boxes therefor
• B30B 15/30 - Feeding material to presses
• B30B 15/32 - Discharging presses
• B30B 15/26 - Programme control arrangements

Abstract

A garbage pool control cabinet protection system for a garbage incineration power plant. An electric heating unit, an internal circulation fan, a humidity detector and a toxic and harmful gas monitoring apparatus are added and are all connected to a control unit by means of a control line, and parameters such as the temperature, the humidity and the toxic and harmful gas concentration of a control cabinet are transmitted to a garbage hoisting operation control room by means of signals from the control unit passing through a communication line. Effective remote monitoring and safety protection can be performed on a garbage pool control cabinet. Air circulation in the cabinet can be realized, timely elimination of air humidity within the cabinet is be facilitated, and whether a drainage system is blocked can be determined. The concentration of harmful gas in the control cabinet can be monitored in real time, a monitoring basis is provided for personnel in the control room, and a ventilation period for a garbage pool can be adjusted in a timely manner so as to prevent damage to a control system in the control cabinet.

IPC Classes  ?

• H05K 7/20 - Modifications to facilitate cooling, ventilating, or heating
• G01D 21/02 - Measuring two or more variables by means not covered by a single other subclass
• F23G 5/02 - Methods or apparatus, e.g. incinerators, specially adapted for combustion of waste or low-grade fuels including pretreatment

Abstract

An intelligent control method for a waste pool (1) in a waste-to-energy plant. The method mainly comprises the following steps: step one, gridded space locating for the waste pool (1); step two, data acquisition; step three, data systematic analysis; and step four, three-dimensional model displaying. Gridding locating is performed on the waste pool (1) and a three-dimensional scanning system performs regular scanning, and systematic analysis is performed by means of obtained data, so as to construct a real-time three-dimensional digital model regarding stacking of waste (2) in the waste pool (1); a calculation result is output by means of a data output system to an automatic control system of a waste (2) crane, so as to realize the fully automatic operation of the waste (2) crane; and system data can be output to a remote management system to realize far-end situation monitoring, such that the visualized management of the waste pool (1) is finally realized, and continuous efficient management is performed on the waste pool (1).

IPC Classes  ?

• G06Q 10/06 - Resources, workflows, human or project managementEnterprise or organisation planningEnterprise or organisation modelling
• G06Q 50/06 - Energy or water supply
• G06T 17/00 - 3D modelling for computer graphics
• G06F 30/20 - Design optimisation, verification or simulation
• F23G 5/50 - Control or safety arrangements
• B66C 13/48 - Automatic control of crane drives for producing a single or repeated working cycleProgramme control
• B66C 13/46 - Position indicators for suspended loads or for crane elements
• B66C 13/16 - Applications of indicating, registering, or weighing devices

Abstract

A system and method for cooperative treatment of kitchen waste in a waste incineration plant, comprising a kitchen waste system and a domestic garbage treatment system. Waste water generated after the kitchen waste passes through a kitchen waste pretreatment system is divided into two paths for treatment; during the treatment of the first path of kitchen waste water, a coagulation apparatus and an air flotation apparatus are sequentially arranged before a waste leachate treatment system; and during the treatment of the second path of kitchen waste water, a homogeneous emulsification apparatus and a filtering and impurity removal apparatus are provided before a spray-back apparatus. The kitchen waste water is subjected to coagulation, air flotation, homogeneous emulsification, and filtering and impurity removal in advance, thereby solving the problem of high waste water treatment grease in the cooperative treatment process of the kitchen waste; moreover, in consideration of cooperative advantages of using a garbage power plant, the recycling of the kitchen waste is achieved to the greatest extent, the reduction and the harmlessness are achieved to the greatest extent, the treatment cost is reduced, and economic operation is achieved.

IPC Classes  ?

• B09B 3/00 - Destroying solid waste or transforming solid waste into something useful or harmless

Abstract

Disclosed are a system and a method for cooperatively treating kitchen waste in a garbage incineration plant. The system comprises a garbage pool, a three-phase separation device and a garbage incineration and power generation system, and further comprises a garbage leachate treatment system and a back-spraying device which work synergistically. Solid residue resulting from leachate of the garbage pool passing through the three-phase separation device enters the garbage pool; waste water is treated in two paths, waste water in a first path is treated by the garbage leachate treatment system, and waste water in a second path is sprayed back to an incinerator of the garbage incineration power generation system by means of the back-spraying device; and crude grease resulting from kitchen garbage and household garbage passing through the three-phase separation device is further purified or sold. According to a flow direction of the waste water, for the treatment of the waste water in the first path, a coagulation device and an air floatation device are sequentially arranged before the position where the waste water enters the garbage leachate treatment system; and for the treatment of the waste water in the second path, a homogeneous emulsification device and a filtering and impurity removing device are further arranged in front of the back-spraying device. The system can mainly solve the problem of a high amount of grease in waste water treatment during a synergistic treatment process of kitchen waste.

IPC Classes  ?

• F23G 5/02 - Methods or apparatus, e.g. incinerators, specially adapted for combustion of waste or low-grade fuels including pretreatment
• F23G 5/44 - Methods or apparatus, e.g. incinerators, specially adapted for combustion of waste or low-grade fuels DetailsAccessories
• F23G 5/46 - Recuperation of heat
• F01D 15/10 - Adaptations for driving, or combinations with, electric generators
• B09B 3/00 - Destroying solid waste or transforming solid waste into something useful or harmless
• B09B 5/00 - Operations not covered by a single other subclass or by a single other group in this subclass

Abstract

A water-cooled furnace wall of a waste incinerator, comprising a side wall system consisting of a drying section side wall (7), a burning section side wall (8) and a burning-out section side wall (9) which respectively correspond to a drying grate (4), a burning grate (5) and a burning-out grate (6), a front side wall and a rear side wall, and a combustion chamber top wall system consisting of a front arch water-cooled wall (2) and a rear arch water-cooled wall (3). The burning section side wall (8) uses the water-cooled furnace wall, and as such, the flue gas temperature of a portion of a combustion chamber (1) at the side wall is reduced, so that the overall temperature in the combustion chamber (1) is reduced, and the service life of the furnace wall is prolonged; the flue gas distribution in the combustion chamber (1) is more uniform, which is beneficial for performing heat exchange and safe operation of a downstream heating surface; and compared with an air-cooled furnace wall, the water-cooled furnace wall has a simpler structure and a lower cost.

IPC Classes  ?

• F23G 5/44 - Methods or apparatus, e.g. incinerators, specially adapted for combustion of waste or low-grade fuels DetailsAccessories

Abstract

The present invention provides an ash collection device of a waste incineration power plant, sequentially comprising an ash hopper, an ash falling pipe and an ash conveying machine according to the falling direction of ash from top to bottom; an upper port of the ash falling pipe is connected to a discharge port of the ash hopper and a lower port thereof is connected to the ash conveying machine, and the ash falls into the ash conveying machine through the ash falling pipe; a manhole door is further provided on the ash hopper; an ash collection device is further provided, and sequentially comprises a grating plate, a collection hopper, an ash conveying pipe and a gate valve according to the falling direction of the ash from top to bottom; the grating plate is provided on a lower side of the manhole door, an upper port of the ash conveying pipe is connected to the collection hopper and a lower port thereof is connected to the ash conveying machine, and the ash leaked from the manhole door falls through the grating plate and then enters the ash collection device. The present invention can effectively solve the problems in the prior art and ensure the personal safety of operators.

IPC Classes  ?

• B65D 90/10 - ManholesInspection openingsCovers therefor
• B65D 88/64 - Large containers characterised by means facilitating filling or emptying preventing bridge formation
• B65D 90/00 - Component parts, details or accessories for large containers
• B65G 47/18 - Arrangements or applications of hoppers or chutes
• F23J 1/02 - Apparatus for removing ash, clinker or slag from ash-pits, e.g. by employing trucks or conveyors, by employing suction devices

Abstract

In order to overcome the problems existing in the prior art, provided is an electrical cabinet, comprising: a cabinet body, wherein the cabinet body is provided with an accommodating space, and a front side of the accommodating space is opened to form an opening; a cabinet door, wherein the cabinet door is pivotably arranged on the cabinet body to open or close the opening; and a sliding frame and a carrier plate, wherein the sliding frame is arranged in the accommodating space and can slide back and forth between a first position away from the opening and a second position adjacent to the opening, the carrier plate is arranged on the sliding frame and can be pivoted between a third position and a fourth position, when the carrier plate is located at the third position, the carrier plate is accommodated in the accommodating space, when the sliding frame is located at the second position, the carrier plate can be rotated to the fourth position from the third position, and when the carrier plate is located at the fourth position, the carrier plate is located outside the opening. In the electrical cabinet, the problems in the prior art can be effectively solved.

IPC Classes  ?

• H05K 7/14 - Mounting supporting structure in casing or on frame or rack
• H05K 7/18 - Construction of rack or frame
• H05K 7/20 - Modifications to facilitate cooling, ventilating, or heating

Abstract

In order to solve the problem of training new employees in the existing waste-to-energy plants, the present invention provides a manufacture method for computer-simulated training of an operation of a waste-to-energy plant, comprising: establishing a remote login module and a local control station depth simulation operation module, the local control station depth simulation operation module further comprising a fire grate temperature monitoring picture (flame monitoring) module, an environment-protection monitoring data anomaly marking picture display module, and an operation switch 3D model and an operation module thereof. By establishing said modules, a complete operating simulation training method capable of realistically combining waste-to-energy plant grate operating and process flow is established, so as to satisfy the requirements of realistic training of new employees in waste-to-energy plants.

IPC Classes  ?

• G09B 9/00 - Simulators for teaching or training purposes
• G05B 23/02 - Electric testing or monitoring