RU2179283C2 - Process and gear to use energy of medium containing combustible substances even in low concentration - Google Patents

Abstract

FIELD: utilization of energy released in process of medium cleaning by burning of combustible substances. SUBSTANCE: process of regeneration of energy of medium containing combustible materials and based on burning of these materials includes passing of flow of medium through regenerative combustion chamber and its bleed-off after burning through outlet pipe linked to combustion chamber. In this case controlled direct bleed-off of part of flow of heated medium from combustion zone of regenerative chamber is executed after burning for utilization of heated medium for required purposes. Formula of invention describes gear meant for implementation of process. EFFECT: utilization of excessive thermal energy released during burning of combustibles in combustion chamber, control over temperature during burning of combustible substances from cleaned gas in combustion chamber. 11 cl, 2 dwg

Description

 The invention generally relates to a method and apparatus for using energy from a medium containing combustible substances even at low concentrations and, in particular, to using energy in connection with cleaning the medium by burning combustible substances.

 A known technology for the purification of exhaust gases generated, for example, in the manufacture of dyeing and printing work and containing combustible substances, such as solvents, by heating the gases to the combustion temperature of combustible substances. However, this is an expensive process due to the need to heat the entire flow of the spent medium. Thanks to the “combustion heat exchanger”, one embodiment of which is described, for example, in connection with the absorption technology in Sweden patent 8903556-2, the costs associated with heating the exhaust gases can be reduced. In the aforementioned patent, a combustion heat exchanger is defined as a device containing a heat accumulating layer that can be heated to a spontaneous ignition temperature of combustible substances and in which a layer of combustible substances by reversing the flow direction contributes to maintaining a spontaneous ignition temperature inside the layer. A device of this type is also described, for example, in US Pat. No. 4,741,690. When certain quantities of combustible substances are present in the medium, heating of the medium inside the combustion heat exchanger can take place due to the energy released from spontaneous ignition of the substances inside the layer. Thus, additional heating becomes necessary only for heating the layer to a temperature of spontaneous ignition at the start of the installation or when the amount of combustible substances is very small and insufficient to independently maintain the temperature of spontaneous ignition inside the layer.

 However, due to the high efficiency of the combustion heat exchanger, it is relatively rare that the amount of combustible substances in the medium is insufficient, as in the latter case. Thus, the amount of combustible substances usually exceeds the amount required to maintain the temperature of spontaneous ignition inside the layer. This leads to an increase in heat in the layer, which, in turn, leads to increased requirements for cooling the layer to prevent its destruction and the surrounding area. In addition, the fact that the thermal energy released during the combustion process is not used is a problem per se, given the high cost of energy and the environment.

 Therefore, the object of the invention is to develop a method and device that allows the use of excess thermal energy released during combustion in a regenerative combustion chamber, that is, a combustion device with reversing the flow direction, in which combustion takes place in a heated zone, which is preferably a combustion heat exchanger.

 Another objective of the proposed method and device is to ensure not only the use of energy, but with it the temperature control in the regenerative combustion chamber.

 The next objective of the proposed method and device is the elimination of toxic or threatening the climate or malodorous substances by burning them.

 Another objective of the invention is the use of a regenerative combustion chamber of thermal energy of such quality that it can be used primarily for the transfer of heat of high temperature, for example, in the production of electricity.

 The tasks are solved in that in the method of energy recovery from a medium containing combustible materials even at low concentrations, based on the burning of combustible materials, including passing a stream of a medium containing combustible materials through a regenerative combustion chamber and its selection after combustion through an combustion chamber connected to the combustion chamber the exhaust pipe, while burning is carried out in the heated zone of the regenerative combustion chamber when the combustion temperature is reached, at which almost all the chemical energy of the combustible erialov converted into thermal energy in accordance with the invention, further selection adjustment produce partial flow of the heated medium directly from the post-combustion zone regenerative combustion chamber for use in a heated environment required purposes, including for converting thermal energy of the medium in a different type of energy. Gas can be used as the medium, and it is advisable to use the diverted medium in a steam boiler, followed by a turbine and generator, to produce electric energy.

 The method according to the invention can be used for mine operations, where the medium is mine gas, or in a plant with an autoclave, where the medium is cooking gas, or in a production installation where the medium is exhaust gas.

 The tasks are also solved by the fact that the device for implementing the method of energy recovery from a medium containing combustible materials, including a regenerative combustion chamber, in the combustion zone of which there is a heating device for spontaneous ignition of combustible materials in the combustion zone, while the regenerative combustion chamber is connected to the input the pipe for supplying the medium and the output pipe for draining from it the outgoing heated medium, purified from combustible materials, according to the invention, is located the outlet means in the combustion zone of the regenerative chamber, with which a part of the heated medium stream is taken after combustion, for use for necessary purposes, including for converting the thermal energy of the medium to another type of energy, and the outlet means contains at least one perforated pipe that is connected to a power generating plant.

 The device according to the invention can be used for mine operations, where the medium is mine gas, or in a plant with an autoclave, where the medium is cooking gas, or in a production installation where the medium is exhaust gas.

One example embodiment of the invention will be described in more detail below with reference to the accompanying drawings, in which:
FIG. 1 schematically depicts a top view of the proposed device for cleaning exhaust or exhaust air from a coal mine;
FIG. 2 is a schematic side view of the proposed combustion heat exchanger.

 The device shown in FIG. 1, is used to clean the medium, in this case exhaust or exhaust air from a coal mine. This type of exhaust air usually contains flammable substances and, among other things, flammable gas methane. Exhaust air is discharged from the shaft 1 through the fan 2 and valve 3 to the outlet pipe 4 or through the fan 5 to the outlet pipe 6, when the proposed device is not used, generally indicated at 7.

According to the shown embodiment, the proposed device 7 contains four combustion heat exchangers, which are generally indicated by 8, 8 ^I , 8 ^II , 8 ^III , 8 ^IV , but it, of course, could include more or fewer combustion heat exchangers depending on the area use. Through a processing fan that is common to all combustion heat exchangers and a valve 10, one for each combustion heat exchanger, each combustion heat exchanger 8 is connected to a plurality of inlet pipes 11 and a plurality of outlet pipes 12. In the illustrated embodiment, there are nine inlet pipes and nine outlet pipes, but their number may vary. Each inlet pipe 11 and each outlet pipe 12 is equipped with a damping device, generally indicated by 13 and 14, respectively. By means of a valve 15, one for each combustion heat exchanger 8, the output pipes 12 communicate with the exhaust pipe 6. A single fan 9 can also be replaced, for example, by four fans, one for each combustion heat exchanger.

 In FIG. 2 shows a schematic cross-section of a combustion heat exchanger 8. The damping devices 13 and 14 are provided with sliders 18 and 19, respectively, which are movable in the vertical direction between two sealing positions in which each slide is firmly pressed against its channels 16 and 17, respectively. Two gates 18 and 19 never seal the same channel and in the position illustrated by continuous lines, the gate 18 hermetically seals the entrance 20 to the channel 17, while the gate 19 hermetically seals the outlet 21 from the channel 16. Therefore, the medium containing combustible substance is transferred through the inlet pipe 11 through the inlet 22 of the channel 16 into the layer 23 of the combustion heat exchanger, in which the substances are burned in a manner known per se, after which the stream continues to exit through the channel 17 and through its exit 24 to the output pipe 12. This flow illustrates is illustrated schematically by continuous arrows 25 in FIG. 2. In a manner known per se, the direction of flow through the combustion heat exchanger layer 23 should be reversed from time to time to prevent the heat front of the layer 23 from moving too close to one of the channels 16, 17. With this change in direction, the gates 18 and 19 are moved to the position shown in FIG. 2 by dashed lines, and the flow associated with these gate positions is shown schematically by arrows with dashed lines 26.

 Obviously, the valves 10, 15 can be used to stop the flow to and from the combustion heat exchanger, for example, during maintenance, for repair work and the like. It is further understood that the valve 3 could be a valve, which, depending on the flow through the fan 9, opens or closes the flow to the outlet pipe 4 to ensure that the barrel 1 is always vented regardless of the flow through the device 7.

 In the central region of the layer 23, known as the combustion zone, there is a heating device 27, which could be an electric heater, with which the layer could be heated to a spontaneous ignition temperature of combustible substances, for example, when the combustion heat exchanger should be put into operation.

 In the area of the combustion zone there is also a drainage or drainage means 28, which is used to divert a partial flow of the heated medium after combustion. In this embodiment of the invention, the outlet means 28 is a perforated pipe extending along the combustion zone layer 23, but could also be configured in another way, for example, as a means for suctioning the medium directly through the wall 29 of the layer 23. In the illustrated embodiment, the outlet the means 28, in turn, is connected to the steam boiler 30, schematically shown in FIG. 1. The medium diverted by the drainage means 28 is transferred through the steam boiler 30 to the outlet pipe 6 through the fan 31, which compensates for the pressure drop inside the boiler.

Since the spontaneous ignition temperature in the combustion heat exchanger is approximately 1000 ^° C. in accordance with the described embodiment, according to which the combustible substance preferably consists of methane gas from a coal mine, the medium discharged directly from the combustion zone can be effectively used in a steam boiler 30 to generate electricity by using a steam turbine and generator. This electricity could be used in accordance with the embodiment described above, for example, to drive one or more fans 2, 5, 9 and 31. Since it is absolutely necessary when developing mineral deposits that the drifts are always ventilated to prevent the danger of an explosion, significant It is that at least one of the fans 2, 5 is constantly functioning, that is, also in the event of a failure of the electrical network. Otherwise, the mine must be evacuated, which is difficult, consuming a significant amount of time and expensive operation. Thanks to the invention, such fans can be operated in an economical manner without the shaft relying on electric power from an external distribution network. In addition, surplus electricity generated by a steam boiler, turbine, and generator could be sold. Thus, the proposed device and method makes it economically feasible and technically possible to protect the environment by burning inside layer 23 and at the same time generating electricity.

 In coal mines, the concentration of methane gas in the treated air is usually a maximum of 20% of the low Explosion Limit (LEL). It turned out to be possible to design the combustion heat exchanger in such a way that allows to achieve thermal efficiency. 98% This means that the combustion heat exchanger is self-sufficient with respect to maintaining the temperature of spontaneous ignition inside the combustion zone when the concentration of methane gas in the medium exceeds 0.1 / 2% LEL /.

Thus, the application of the invention makes it possible to use electricity also from an environment having a low concentration of combustible substances, which until now has been practically not possible. In addition, the amount of medium discharged by the diverting means 28 could be used to control the temperature inside the layer 23 in order to avoid the combustion zone becoming too wide and, for example, coming into contact with the housing surrounding the layer, which in itself could would lead to the danger of burns and also unnecessary loss of energy. Using the proposed device, it is also easy to control the energy released by changing the exhaust flow to compensate for any changes in the amount of combustible substance in the medium passing through layer 23. The combustion process is also very clean, since the flame does not produce immediate and / or thermal NO _x .

 It is clear that it is quite possible to slightly modify the described embodiment example. For example, the number of combustion heat exchangers 8 could be changed, as well as the number of exhaust means 28 in each layer 23. Obviously, the damping devices 13, 14 could have a different configuration of parts compared to the parts shown, while they cause a change in the direction of flow inside the layer 23. In addition, the channels 16, 17 could have a different shape and could, for example, consist of perforated pipes located inside the layer 23, while the combustion zone was installed between them, for example, as described in Swedish patent 9103534-3. It is also understood that instead of a combustion heat exchanger, any regenerative combustion chamber could be used.

 Of course, the heating medium could also be used to produce other forms of energy other than electricity, and in this case, the by-pass means 28 could be connected to other types of energy-generating plants than the steam boiler 30. For example, the heated medium could be used to heat another medium, such as water, in this case the thermal energy in the second medium would be energy instead of that used, for example, in a district heating system. In addition, the thermal energy of the heated medium could be used in this case by means of an exhaust system in the form of at least one pipe, which would allow the corresponding flow of the second medium and which would be located inside the combustion zone of the regenerative combustion chamber, preferably the layer / 23 / of the heat exchanger burning.

 The proposed device and method are not limited to use in mining operations, but can also be used, for example, in ventilation plants in the manufacture of paints, in printing works, coating and laminating processes, in the production of chemicals and pharmaceutical products, livestock plants, cooking plants , in waste deposits and in the production of plastics and tires, in other words, in connection with such plants and processes in which some type of carbohydrate native compounds such as solvents, styrene, fumes from plastics, fumes from fuel tanks, fumes from fish processing plants, soot from a diesel engine or natural gas or combustible inorganic substances, i.e. carbon monoxide, for example, from steelmaking in an electric furnace or hydrogen for example, from chemical plants are present in an environment that must be transported through a regenerative combustion chamber, which is preferably a combustion heat exchanger. All types of combustible substances, that is, also fetid or poisonous emanations from various processes or from degassification or gas leaks, can be effectively removed from the medium while generating energy. It is also easy to understand that the invention does not have to be used in combination with outlet pipes 4, 6, fans 2, 5 or valve 3, as shown in FIG. 1, but that instead it could be used in any installation in which the environment meets the above requirements.

 All such changes and modifications that embody the basic idea of the invention, however, could be considered as not going beyond the scope of protection reflected in the attached claims.

Claims (11)

 1. A method of energy recovery from a medium containing combustible materials even at low concentrations, based on the combustion of combustible materials, comprising passing a stream of a medium containing combustible materials through a regenerative combustion chamber and its selection, after burning, through an outlet pipe connected to the combustion chamber, the combustion is carried out in the heated zone of the regenerative combustion chamber when the combustion temperature is reached, at which almost all the chemical energy of the combustible materials is converted into heat Gia, characterized in that the further adjustment selection produce partial flow of the heated medium directly from the post-combustion zone of a regenerative combustion chamber for use in a heated environment required purposes, including for converting thermal energy of the medium in a different type of energy.  2. The method according to p. 1, characterized in that the medium used is gas.  3. The method according to p. 1 or 2, characterized in that the allocated medium is used in a steam boiler, followed by a turbine and generator, to produce electrical energy.  4. The method according to any one of paragraphs. 1-3, characterized in that it is used for mine operations, where the environment is mine gas.  5. The method according to any one of paragraphs. 1-3, characterized in that it is used in an installation with an autoclave, where the medium is cooking gas.  6. The method according to any one of paragraphs. 1-3, characterized in that it is used in a production installation, where the medium is exhaust gas.  7. A device for implementing a method of energy recovery from a medium containing combustible materials, including a regenerative combustion chamber, in the combustion zone of which there is a heating device for spontaneous ignition of combustible materials in the combustion zone, while the regenerative combustion chamber is connected to the inlet pipe for supplying the medium and the output a pipe for discharging from it the outgoing heated medium, purified from combustible materials, characterized in that it has a regenerative chamber located in the combustion zone a diversion means, with the help of which a part of the flow of the heated medium is selected after combustion, for use for necessary purposes, including for converting the thermal energy of the medium into another type of energy.  8. The device according to p. 7, characterized in that the outlet means contains at least one perforated pipe, which is connected to a plant that produces energy.  9. The device according to p. 7 or 8, characterized in that it is used for mine operations, where the medium is mine gas.  10. The device according to p. 7 or 8, characterized in that it is used in an installation with an autoclave, where the medium is cooking gas.  11. The device according to p. 7 or 8, characterized in that it is used in a production installation where the medium is exhaust gas.

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