C01B 3/34 - Production d'hydrogène ou de mélanges gazeux contenant de l'hydrogène par réaction de composés organiques gazeux ou liquides avec des agents gazéifiants, p. ex. de l'eau, du gaz carbonique, de l'air par réaction d'hydrocarbures avec des agents gazéifiants
C01B 3/50 - Séparation de l'hydrogène ou des gaz contenant de l'hydrogène à partir de mélanges gazeux, p. ex. purification
C08F 10/00 - Homopolymères ou copolymères d'hydrocarbures aliphatiques non saturés contenant une seule liaison double carbone-carbone
2.
PROCESS FOR PREPARING SYNGAS FROM A LIQUID FEEDSTOCK
C01B 3/36 - Production d'hydrogène ou de mélanges gazeux contenant de l'hydrogène par réaction de composés organiques gazeux ou liquides avec des agents gazéifiants, p. ex. de l'eau, du gaz carbonique, de l'air par réaction d'hydrocarbures avec des agents gazéifiants avec l'oxygène ou des mélanges contenant de l'oxygène comme agents gazéifiants
C01B 3/50 - Séparation de l'hydrogène ou des gaz contenant de l'hydrogène à partir de mélanges gazeux, p. ex. purification
C10J 3/00 - Production de gaz contenant de l'oxyde de carbone et de l'hydrogène, p. ex. du gaz de synthèse ou du gaz de ville, à partir de matières carbonées solides par des procédés d'oxydation partielle faisant intervenir de l'oxygène ou de la vapeur
C10J 3/46 - Gazéification des combustibles granuleux ou pulvérulents en suspension
3.
Method for producing pressed products and assembly for producing pressed products
A method of manufacturing compacts and an arrangement for manufacturing compacts, in which the disadvantages of the state of the art are overcome and an efficient method and at the same time a simple construction and a simple implementation are achieved. This involves a method for manufacturing compacts, wherein after feeding the feedstock, pre-pressing into a pre-agglomerate using at least one pre-pressing punch or at least one stuffing screw and subsequently main pressing of the pre-agglomerate into a compact in at least one pressing die using at least one main pressing punch and subsequently ejection of the compact from the at least one pressing die are performed, pre-pressing, main pressing and ejection being performed in a mutually parallel working direction. This also involves an arrangement for manufacturing compacts, wherein at least one pressing die is provided in die tool receptacle with a feed for feedstock.
B30B 11/02 - Presses spécialement adaptées à la fabrication d'objets à partir d'un matériau en grains ou à l'état plastique, p. ex. presses à briquettes ou presses à tablettes utilisant un pilon exerçant une pression sur le matériau dans une cavité de moulage
B30B 11/00 - Presses spécialement adaptées à la fabrication d'objets à partir d'un matériau en grains ou à l'état plastique, p. ex. presses à briquettes ou presses à tablettes
B30B 11/10 - Presses spécialement adaptées à la fabrication d'objets à partir d'un matériau en grains ou à l'état plastique, p. ex. presses à briquettes ou presses à tablettes utilisant un pilon exerçant une pression sur le matériau dans une cavité de moulage coopérant avec des moules portés par une table tournante à mouvement intermittent
4.
JOINT SELANT FOR HIGH-TEMPERATURE APPLICATIONS AND USE OF THE JOINT SEALANT PREFERABLY FOR USE ON SILICA MATERIALS
The object of the invention is to create a joint sealant for sealing joints in the high-temperature range, which overcomes the disadvantages in the state of the art, which is self-sealing and resistant to high temperatures, and which adapts to the thermal expansion behaviour of the joint. A joint sealant (3) for high-temperature applications comprises a foamable mixture of glass flour or a glass substitute and an additive for increasing viscosity or for temperature adjustment, blowing agent and binding agent. Also provided is a method for sealing joints (2) in industrial furnaces for high-temperature applications, wherein a joint sealant (3) is introduced into the joint (2) as a foamable mixture of glass flour or a glass substitute and quartz flour, blowing agent and binding agent, at least sections of which are foamed with the effect of the heat of the high-temperature applications. Also provided is a use of a foamable mixture comprising glass flour or a glass substitute and quartz flour, blowing agent and binding agent as a joint sealant for high-temperature applications in expansion joints or other unintentional furnace chamber openings in an industrial furnace or a glass-melting system.
C04B 28/24 - Compositions pour mortiers, béton ou pierre artificielle, contenant des liants inorganiques ou contenant le produit de réaction d'un liant inorganique et d'un liant organique, p. ex. contenant des ciments de polycarboxylates contenant des silicates d'alkylammonium ou des silicates de métaux alcalinsCompositions pour mortiers, béton ou pierre artificielle, contenant des liants inorganiques ou contenant le produit de réaction d'un liant inorganique et d'un liant organique, p. ex. contenant des ciments de polycarboxylates contenant des sols de silice
The invention relates to a method for producing pressed products and to an assembly for producing pressed products, in which the disadvantages of the prior art are overcome and an efficient method is achieved together with simple construction and simple implementation. Method for producing pressed products, in which, after feedstock has been supplied, the volume of the feedstock (11) is reduced and the feedstock subsequently undergoes a main compression process to form a pressed product and the pressed product is ejected, characterised in that, after the feedstock (11) is supplied, a preliminary compression process takes place to form a preliminary agglomerate (12) using at least one preliminary compression ram (1) or using at least one compacting screw (17) and the preliminary agglomerate (12) then undergoes the main compression process to form a pressed product in at least one compression mould (3) using at least one main compression ram (21) and the pressed product is then ejected from the at least one compression mould (3), the preliminary compression process, the main compression process and the ejection each taking place in a mutually parallel working direction. Assembly for producing pressed products, wherein, in at least one mould receiver (2), there is at least one compression mould (3) having a supply means (10) for feedstock (11), wherein the at least one compression mould (3) can be brought into alignment with at least one preliminary compression ram (1) or at least one compacting screw (17) and with at least one main compression ram (21), wherein the working directions of the at least one preliminary compression ram (1) or the at least one compacting screw (17) and the at least one main compression ram (21) are mutually parallel, wherein there is a counter pressing plate (4) on the side of the respective compression mould (3) or mould receiver (2) which is nearest or furthest away from the at least one preliminary compression ram (1), and there is a counter pressing plate (4) and/or a moulding channel (30) with a narrowed region (31), on the side of the respective compression mould (3) which is furthest from the at least one main compression ram (21), wherein the at least one compression mould (3) is continuous in the working direction.
B30B 11/02 - Presses spécialement adaptées à la fabrication d'objets à partir d'un matériau en grains ou à l'état plastique, p. ex. presses à briquettes ou presses à tablettes utilisant un pilon exerçant une pression sur le matériau dans une cavité de moulage
B30B 11/10 - Presses spécialement adaptées à la fabrication d'objets à partir d'un matériau en grains ou à l'état plastique, p. ex. presses à briquettes ou presses à tablettes utilisant un pilon exerçant une pression sur le matériau dans une cavité de moulage coopérant avec des moules portés par une table tournante à mouvement intermittent
6.
METHOD FOR PRODUCING FUNCTIONAL LAMINATED GLASS UNITS, METHOD FOR ARRANGING GLASS ELEMENTS FOR FUNCTIONAL LAMINATED GLASS UNITS AND ARRANGEMENT OF GLASS ELEMENTS FOR FUNCTIONAL LAMINATED GLASS UNITS
The object of the invention is to provide a method for producing functional laminated glass units, a method for arranging glass elements for functional laminated glass units and an arrangement of glass elements for functional laminated glass units with which an area-specifically individual or inhomogeneous thermal treatment is made possible, so that even thermally sensitive functional elements in particular can be laminated into the laminated glass for a functional laminated glass unit. It is also intended to achieve an arrangement and combination of the components suitable for this. A method for producing functional laminated glass units from an arrangement of glass elements (12), wherein at least one lower laminating layer (2) is placed on a lower glass element (1) as a base glass element (1), in that at least one functional element (3) is arranged on the lower laminating layer (2) at a distance from the edge of the pane (7), in that at least one upper laminated layer (4) is placed onto the at least one functional element (3) and subsequently an upper glass element (5) is placed on as a top glass element (5), and in that subsequently a vacuum lamination of the arrangement of glass elements (12) is performed, wherein in the vacuum lamination an inhomogeneous temperature zone is produced, wherein, at least in the region of the at least one functional element (3, 13), the arrangement of glass elements (12) is brought to at least a first laminating temperature and in that, at least at the edge of the pane (7) or in the region (11) away from the at least one functional element (3), the arrangement of glass elements (12) is brought to at least a second laminating temperature, wherein the first laminating temperature is lower than the second laminating temperature.
B32B 17/10 - Produits stratifiés composés essentiellement d'une feuille de verre ou de fibres de verre, de scorie ou d'une substance similaire comprenant du verre comme seul composant ou comme composant principal d'une couche adjacente à une autre couche d'une substance spécifique de résine synthétique
B32B 37/00 - Procédés ou dispositifs pour la stratification, p. ex. par polymérisation ou par liaison à l'aide d'ultrasons
B32B 37/10 - Procédés ou dispositifs pour la stratification, p. ex. par polymérisation ou par liaison à l'aide d'ultrasons caractérisés par la technique de pressage, p. ex. faisant usage de l'action directe du vide ou d'un fluide sous pression
7.
DEVICES AND METHODS FOR IMPACT LOAD TRANSMISSION ONTO DISK-SHAPED DRILL BITS OF ROCK PROCESSING MACHINES
The aim of the invention is to reduce the loading of the bearing of disk-shaped drill bits and roller bits caused by impact and vibratory stress produced, e.g. by pneumatic and hydraulic hammers of rock breaking machines or similar machines and to thereby increase the reliability and service life of the bearing. The disk-shaped drill bit (2) is mounted on a rotation axis (10) via bearings (11) by means of a fork (7), said fork (7) being pivotably mounted on a frame (4) that is rigidly fastened to the device. A compression spring (8) is arranged between the fork (7) and the frame (4) and an intermediate percussion element (3) the lower end of which is U-shaped and thus encloses the disk-shaped drill bit (2) on both sides, touching the main body (26) of the disk-shaped drill bit, and the upper end of which extends up to a ram (13) which is a constituent part of a percussion device (1) and to the right-hand side and to the left-hand side of the intermediate percussion element (3), at the top, coupling elements (5), and at the bottom, coupling rods (6) are mounted on pins (31) of the intermediate percussion element (3), the coupling elements (5) and the other ends of the coupling rods (6) being mounted on the frame (4). The coupling elements (5), the coupling rods (6) and the fork (7) run in parallel and, at the center of the coupling elements (5), respective spring-mounted coupling elements (9) are mounted and the other ends thereof are mounted centrally on the fork (7), each spring-mounted coupling element (9) having a spring (15), a sprung element (17) and a threaded bush (16).
E21C 25/16 - Machines pratiquant des saignées uniquement par l'action d'un ou plusieurs disques, scies ou roues, coupants, tournant sur eux-mêmes
E21D 9/10 - Exécution en utilisant des machines à forer ou à inciser
E21D 9/11 - Exécution en utilisant des machines à forer ou à inciser avec une tête de forage de type rotatif coupant simultanément toute la section transversale, c.-à-d. tunneliers pleine-face
E21B 10/12 - Trépans à organes coupants roulants, p. ex. à molettes à organes coupants en forme de disque
E21B 10/20 - Trépans à organes coupants roulants, p. ex. à molettes caractérisés par des parties amovibles ou réglables, p. ex. des bras ou des arbres
E21B 10/22 - Trépans à organes coupants roulants, p. ex. à molettes caractérisés par des détails de paliers, de lubrification ou d'étanchement
E21B 10/10 - Trépans à organes coupants roulants, p. ex. à molettes l'axe de l'organe roulant étant supporté à ses deux extrémités
The invention relates to a thermal solar flat collector, consisting of a heat transfer medium conduction system which is sealed in a water-proof manner at the edges and provided with an inlet and an outlet and which has at least two glass panes, which face the sun and are arranged spaced apart from each other, comprising a heat insulation layer facing away from the sun and a collector bottom, wherein the collector bottom forms the lower wall of the heat transfer medium conduction system and the innermost of the glass panes facing the sun forms the upper wall of the heat transfer medium conduction system, wherein the collector bottom is designed in the form of black glass and the heat insulation layer facing away from the sun is designed in the form of foam glass having closed porosity, having thermal expansion coefficients that are adapted to each other.
The invention relates to a glass production method for producing glass from glass raw materials and broken glass, comprising the following steps: making glass raw materials available in the form of a mixture (10, 11); comminuting the broken glass to give finely broken glass (21); combining the mixture and the finely broken glass (21) to give a standard mixture (30); and agglomerating (31) the standard mixture (30).
The invention relates to the use of an aluminosilicate glass as the substrate glass for photovoltaics, said glass having a glass composition which is boron-free or low in boron and which – based on the oxide base of the glass composition in mole percent - has an Al2O3 content that is higher than the alkali content R2O.
C03C 1/00 - Ingrédients généralement utilisés pour la fabrication des verres, glaçures ou émaux vitreux
C03C 3/062 - Compositions pour la fabrication du verre contenant de la silice avec moins de 40% en poids de silice
C03C 3/087 - Compositions pour la fabrication du verre contenant de la silice avec 40 à 90% en poids de silice contenant de l'oxyde d'aluminium ou un composé du fer contenant un oxyde d'un métal divalent contenant de l'oxyde de calcium, p. ex. verre à vitre ordinaire ou verre pour récipients creux
H01L 31/00 - Dispositifs à semi-conducteurs sensibles aux rayons infrarouges, à la lumière, au rayonnement électromagnétique d'ondes plus courtes, ou au rayonnement corpusculaire, et spécialement adaptés, soit comme convertisseurs de l'énergie dudit rayonnement e; Procédés ou appareils spécialement adaptés à la fabrication ou au traitement de ces dispositifs ou de leurs parties constitutives; Leurs détails
The present invention relates to a method for producing thermally tempered glasses. This type of surface finishing is used in particular when mechanical properties, in particular strength, are required, such as in the automobile sector, in architecture and in the exploitation of solar energy. The technical object of the invention is to develop a method for producing thermally tempered glasses with thicknesses of less than 2.8 mm. The method can be adapted in an advantageous manner such that thermally tempered glasses can be produced with a lower amount of energy usage while utilizing controlled rapid cooling.
C03B 27/012 - Trempe des articles de verre par traitement thermique, p. ex. pour la cristallisationTraitement thermique d'articles en verre avant la trempe par refroidissement
C03B 27/02 - Trempe des articles de verre en utilisant un liquide
12.
PRESSURE SLIP CASTING APPARATUS AND METHOD FOR CASTING A MOLDED ARTICLE
The invention relates to a pressure slip casting apparatus and a method for casting a molded article. Said apparatus is designed and said method is devised to produce a slip-cast molded article that is bimodally composed of granular and fire-resistant material comprising fine fractions (K1) having first grain sizes (k1) ranging from 0.01 μm to 100 μm and coarse fractions (K2) having second grain sizes (k2) ranging from 100 μm to 10 mm. A fire-resistant molded article can thus be prepared in a simple manner after sintering the molded article. In the apparatus according to the invention, a slip (S) prepared in a pressure vessel (5) is discharged from the pressure vessel (5) into the casting chamber (8) through the discharge pipe (7) by means of a pressurized medium (G). Preferably, the size of the discharge pipe (7) is such and the pressure is selected at such a high level that the slip (S) is discharged through the discharge pipe in such a way that no more than negligible shearing forces act on the slip (S).
B28B 1/26 - Fabrication d'objets façonnés à partir du matériau par coulée en moule poreux ou absorbant, c.-à-d. en coulant une suspension ou une dispersion du matériau dans un absorbeur de liquide ou un moule poreux, le liquide pouvant imbiber les parois du moule ou passer à travers celles-ci, p. ex. coulage de barbotineMoules à cet effet
B28B 13/02 - Alimentation en matériau non façonné des moules ou des appareillages destinés à la fabrication d'objets façonnés
C04B 35/626 - Préparation ou traitement des poudres individuellement ou par fournées
13.
POROUS FIREPROOF MATERIAL SUITABLE FOR GLASS PRODUCTION, METHOD FOR THE PRODUCTION THEREOF, AND USES
The present invention relates to a method for producing a porous fireproof material suitable for glass production, a porous fireproof material that can be produced using a method according to the invention, and the use thereof in glass production or for reducing production disadvantages in glass production, and use of one or more reducing substances for adjusting an oxygen sink in the pore volume of a fireproof material suitable for glass production, according to the independent claims.