KR101343558B1 - Cooperative and continuous refilling device of activated charcoal - Google Patents

Abstract

A cooperative and continuous device for regenerating activated charcoal according to the present invention comprises a detachment chamber having a first inlet at one side thereof and a first outlet at the other side thereof; a cooling chamber having a second inlet at one side thereof and a second outlet at the other side thereof; a flowing tool for flowing activated charcoal penetrating the first inlet, the first outlet, the second inlet and the second outlet; a high-temperature inflow line for spraying high-temperature air to the activated charcoal while intercommunicating with the detachment chamber; detachment outflow line for discharging, to a burner, detachment air including volatile organic compounds detached from the cartridge of activated charcoal while intercommunicating with the detachment chamber; a cooling inflow line for spraying cooled air to the cartridge of activated charcoal while intercommunicating with the cooling chamber; and a cooling outflow line for discharging outside the cooled air passed from the cartridge of activated charcoal while intercommunicating with the cooling chamber.

Description

Cooperative and continuous refilling device of activated charcoal}

In the present invention, a plurality of activated carbon cartridges are flowed to sequentially perform desorption and desorption of volatile organic compounds by high temperature air, followed by cooling of the high temperature activated carbon cartridges. In the incinerator, it reuses combustion heat and the like, and in each chamber, it prevents the heat source loss by blocking the inflow and outflow of heat by the thermal barrier during the inflow and outflow of activated carbon cartridges. It is about.

When volatile organic compounds (VOCs) are released into the atmosphere as they are, they react with light to produce photochemical oxides such as ozone, aldehydes, or nitrogen compounds in smog, resulting in environmental pollution such as photochemical smog and global warming in large cities. In addition, most of the volatile organic compounds that make up volatile organic compounds produce irritating and unpleasant odors even at low concentrations. Legal emission regulations are being established for these facilities.

In the treatment of such volatile organic compounds, adsorption methods using activated carbon are generally used. Since activated carbon has a myriad of fine pores and a large surface area, volatile organic compounds having a relatively high molecular weight such as benzene, toluene, and xylene gas are used. Compounds are also allowed to adsorb in a condensed state.

On the other hand, activated carbon having such characteristics is that when volatile organic compounds are continuously adsorbed and the activated carbon is saturated, its inherent adsorption capacity is inevitably lost. Therefore, when the activated carbon of the adsorption apparatus is saturated, it must be replaced with new activated carbon. Since the cost of the activated carbon is relatively high, it is preferable to regenerate the activated carbon by desorbing the volatile organic compound adsorbed on the activated carbon.

As an example of a technology for regenerating activated carbon, Korean Patent Registration No. 0492070 constitutes a circulation line including a space in which activated carbon is disposed, and activates activated carbon at a high temperature while circulating hot air in the circulation line, thereby volatile organic compounds in activated carbon. It is a tropical flow type regeneration device which is designed to extract the gas, and is installed on the exhaust line of the facility that discharges the exhaust gas containing volatile organic compounds, and can be selectively sealed by the inlet side damper and the outlet side damper. A chamber having a constant volume for accommodating multiple stages of activated carbon therein, a circulation line for circulating air in the chamber while passing through one upper portion and the other lower portion of the chamber, and a fan for forced circulation, and installed at one side of the circulation line Supply heat exchanger and heat source for heat exchange of circulating air It presents the structure of the sprinkler, such as the number of lines for injecting a heater and, when activated carbon overheating water.

However, in the case of the above technology, continuous regeneration of activated carbon is impossible, and there is a discontinuous problem of regeneration operation by operating sprinkler during overheating while convection of hot air. On the other hand, most SMEs use activated carbon, but the capacity of activated carbon is so small that it is practically impossible to have a regeneration device like the above technology. Description of the device is required.

Republic of Korea Patent Registration No. 0492070

The present invention has been made in order to solve the above problems, it is possible to co-intensive demand of activated carbon regeneration generated in a certain area, etc., and to make the regeneration work continuously to improve the activated carbon regeneration device To provide.

As a means for solving the above problems, the joint continuous activated carbon regeneration apparatus of the present invention comprises: a desorption chamber having a first inlet on one side and a first outlet on the other side; A cooling chamber having a second inlet on one side and a second outlet on the other side; Flow means for flowing the activated carbon cartridge while passing through the first inlet, the first outlet, the second inlet, and the second outlet; A high temperature inflow line communicating with the desorption chamber and allowing hot air to be injected onto the activated carbon cartridge; A desorption and discharge line which communicates with the desorption chamber and discharges desorption air including a volatile organic compound desorbed from an activated carbon cartridge to a combustor; A cooling inlet line for communicating cooling air to the activated carbon cartridge while communicating with the cooling chamber; And a cooling outflow line which communicates with the cooling chamber and flows out the preheated air to the outside through the activated carbon cartridge.

As one example, the hot inlet line is connected to the first heat exchanger at one side, and the other side of the first heat exchanger may be configured to be connected to the incineration heat inlet line from the incinerator, and as another example, the cooling outlet line and the hot inlet line. The line may be heat exchanged in a second heat exchanger, and the desorption outlet line may be configured to be connected to the combustor via a third heat exchanger.

In addition, the lower portion of the desorption chamber and the lower portion of the cooling chamber is characterized in that the activated carbon discharge line for collecting the activated carbon separated from the activated carbon cartridge to be discharged to the outside.

In addition, the first inlet, the first outlet, the second inlet, and the second outlet are constituted by a thermal barrier, and the first inlet, the first outlet, the second inlet, and the second outlet are opened and closed by an activated carbon cartridge flowing by the flow means. Characterized in that configured to be.

As described above, the co-continuous activated carbon regeneration apparatus of the present invention flows a plurality of activated carbon cartridges concentrated in a specific region, and subsequently sequentially cools and removes the volatile organic compounds by high temperature air and then cools the high temperature activated carbon cartridge. As a result, the regeneration process of the activated carbon cartridge is co-intensive, safe, and continuous.

In addition, the co-continuous activated carbon regeneration apparatus of the present invention has the advantage of saving energy by reusing incineration incineration heat.

In addition, the co-continuous activated carbon regeneration apparatus of the present invention has the advantage of saving energy by preventing heat source loss by blocking the inflow and discharge of heat by the thermal barrier during the inlet and discharge of activated carbon cartridge in each chamber.

1 is a schematic view showing an example of a co-continuous activated carbon regeneration apparatus of the present invention,
2 is a schematic view showing another example of the co-continuous activated carbon regeneration apparatus of the present invention,
Figure 3 is a schematic diagram showing an operation example of the thermal barrier of one configuration of the present invention,
Figure 4 is a side cross-sectional view showing an embodiment of a thermal barrier of one configuration of the present invention.

Hereinafter, the structure and operation of the present invention will be described in more detail with reference to the accompanying drawings. In describing the present invention, the term or word used in the present specification and claims is based on the principle that the inventor can appropriately define the concept of the term in order to best describe the invention of his or her own. It should be interpreted as meanings and concepts corresponding to the technical idea of

In the co-continuous activated carbon regeneration device 10 of the present invention, as shown in FIG. Cooling chamber (12) for cooling (C), flow means (13) for flowing activated carbon cartridge (C) to sequentially pass through the desorption chamber (11) and the cooling chamber (12), the desorption chamber (11) A high temperature inlet line 14 for injecting hot air into the activated carbon cartridge C while communicating with air, and air containing volatile organic compounds desorbed from the activated carbon cartridge C while communicating with the desorption chamber 11. Desorption outflow line (15) flowing to the cooling chamber 12, the cooling inlet line 16 injecting cooling air to the activated carbon cartridge (C) while communicating with the cooling chamber 12, the activated carbon cartridge ( C) preheat the preheated air To be composed of a cooling outlet line 17 for outlet, and so that the desorption and cooling performed while flowing the plurality of the activated carbon cartridge (C) to an apparatus that allows the reproduction of the activated carbon cartridge (C) carried out continuously.

In the co-continuous activated carbon regeneration apparatus 10 of the present invention, "co-" means that the activated carbon cartridge (C) is collected in the apparatus of the present invention from one or more adsorption towers in one factory or adsorption towers of a plurality of factories existing in a specific area. It is used as a means to enable this. That is, it is not easy for a small and medium-sized company to have a device capable of regenerating activated carbon cartridge (C), which means that a "joint" device has a regeneration device for activated carbon cartridge (C).

First, the desorption chamber 11 is formed with a first inlet 111 on one side and a first outlet 112 on the other side, and the flow means 13 moves the desorption chamber 11 to the first inlet 111. It is configured to penetrate from the first outlet 112 from.

In the desorption chamber 11, the activated carbon cartridge C flows from the first inlet 111 to the first outlet 112 by the flow means 13, so that the hot carbon inlet flows into the activated carbon cartridge C. The hot air is injected through the line 14, and the volatile organic compound is desorbed from the activated carbon cartridge C flowing by the hot air. The desorbed volatile organic compounds are sent to the combustor 18 through the desorption and discharge line 15 together with air, and the volatile organic compounds are removed by the combustion of the combustor 18. Here, the air containing the volatile organic compound introduced into the combustor 18 is a high temperature so that the amount of heat applied to the burner 181 when the combustion operation is reduced by that much.

The activated carbon cartridge (C) in which the volatile organic compound is desorbed by the high temperature air has a risk of fire when exposed to the air due to a heat factor. ), And the desorption chamber 11 and the cooling chamber 12 are connected by the cover 26 to prevent the desorbed activated carbon cartridge (C) from being exposed to the atmosphere.

The cooling chamber 12 has a second inlet 121 at one side and a second outlet 122 at the other side, so that the flow means 13 moves the cooling chamber 12 from the second inlet 121. It is configured to penetrate through the second outlet 122.

In the cooling chamber 12, the activated carbon cartridge C desorbed from the second inlet 121 to the second outlet 122 flows by the flow means 13, and thus the desorbed activated carbon cartridge C flows. Blowing (cooling air) through the cooling inlet line 16, the heat factor of the desorbed activated carbon cartridge (C) flowing by the blowing is removed. Through this process, the air by blowing air absorbs heat from the desorbed activated carbon cartridge (C) so that the heat absorbed air is discharged to the outside through the cooling outflow line 17. As will be described below, the air discharged through the cooling outflow line 17 is preheated air, thereby reducing the requirement of the heat source as it is recycled into hot air for desorption. The regenerated activated carbon cartridge (C) passing through the cooling chamber 12 is removed from the heat factor is safe even in the air, it can be used by mounting it directly to the adsorption tower.

The flow means 13 flows in and out of the activated carbon cartridge C placed in the upper portion by the driving force of the motor 131 to the desorption chamber 11, and then to the inlet and outflow of the cooling chamber 12. In one configuration, the mechanical configuration thereof can be presented in various ways, for example, may be a conveyor belt.

In addition, the activated carbon discharge line 19 is formed at the lower portion of the desorption chamber 11 and the lower portion of the cooling chamber 12 to collect activated carbon separated from the activated carbon cartridge C and to discharge the activated carbon to the outside. As air is injected into the cartridge C in each chamber, activated carbon separated from the activated carbon cartridge C is deposited, and the activated carbon discharged from the activated carbon is discharged to the outside through the activated carbon discharge line 19 to be oxidized. By removing the foreign matter and will be recycled.

On the other hand, the present invention proposes two embodiments in reusing the heat of the air flowing in and out of the device.

First, the first embodiment is shown in FIG.

In this embodiment, the high temperature inlet line 14 is connected to the first heat exchanger 20-1 at one side, and the incineration heat inlet line from the incinerator 29 at the other side of the first heat exchanger 20-1. Give an example to connect with 30). That is, the incineration heat of the incinerator 29 is reused through the first heat exchanger 20-1 so that hot air flows into the high temperature inflow line 14 to be introduced into the desorption chamber 11. To this end, the blower 191 is configured in the first heat exchanger 20-1, and the air heat-induced by inflow of heat from the incineration heat inlet line 30 to the first heat exchanger 20-1 is incinerated. It flows into the condenser 32 through the line 31, and is discharged to the water through the water discharge line 33 in the condenser 32.

Based on this configuration, when the activated carbon cartridge C is introduced into the desorption chamber 11 by the initial operation of the present invention, that is, the flow unit 13, the blower 191 is operated to form a flow of air, and the first The air blown by the heat exchanger 20-1 is supplied with a heat source by incineration heat from the incinerator 29 so that high temperature air flows into the desorption chamber 11 through the high temperature inlet line 14. The air containing the volatile organic compound desorbed by the high temperature air is sent to the combustor 18 through the desorption discharge line 15, the burner (18) is the burner (high temperature by the inflow of air) It is possible to burn a volatile organic compound even with a small amount of applied heat of 181).

In addition, when the desorbed activated carbon cartridge (C) is introduced into the cooling chamber 12 is blown (cooling air) to the cooling chamber 12 through the cooling inlet line 16 by the operation of the blower 151. . The cooling air introduced as described above absorbs the heat of the desorbed activated carbon cartridge (C) at high temperature to cool the desorbed activated carbon cartridge (C), and the air preheated in this process is transferred to the first through the cooling discharge line (17). It is delivered to the heat exchanger (20-1), by the heat source supply by the incineration heat from the incinerator 29 is to be introduced into the desorption chamber (11) through the high temperature inlet line (14) again. In this way, by using the incineration heat discarded from the incinerator 29 and the heat generated during the operation of the device, energy is saved by continuously supplying hot air to the desorption process.

Next, a second embodiment is shown in FIG.

In this embodiment, the cooling outlet line 17 and the high temperature inlet line 14 are connected by the second heat exchanger 20-2. When activated carbon cartridge (C) is introduced into the desorption chamber (11), although not shown in the drawing, a separate blower operates to form a flow of air and receives a heat source from the second heat exchanger (20-2). The hot air is introduced into the desorption chamber 11 through the hot inlet line 14. In this case as well, although not shown in the drawing, hot air may be formed using the incineration heat of the incinerator. The air containing the volatile organic compound desorbed by the high temperature air passes through the desorption outflow line 15 through the third heat exchanger 20-3 to the combustor 18 through the combustion gas inlet line 22. The combustion gas is introduced into the third heat exchanger 20-3 again through the combustion gas discharge line 23 in the combustor 18, and the volatile organic matter desorbed in the third heat exchanger 20-3. The heat exchange is performed between the air containing the compound and the combustion gas, thereby supplying a heat source to the air flowing into the combustor 18, thereby further saving energy of the burner 181 that operates the combustor 18. In addition, the combustion gas passing through the third heat exchanger 20-3 flows into the second heat exchanger 20-2 through the second combustion gas discharge line 23, as described in the first embodiment. In the cooling chamber 12 to exchange heat with the preheated air flowing into the second heat exchanger (20-2) through the cooling outflow line (17). That is, the preheated air introduced through the cooling outlet line 17 receives heat from the combustion gas from the first heat exchanger 20-1 to the desorption chamber 11 through the high temperature inlet line 14. It is to be introduced into the hot air. The combustion gas that loses heat in this process is discharged to the outside through the third combustion gas discharge line 25. Through this embodiment, the heat source for desorption and the heat source for combustion can be saved by the second heat exchanger 20-2 and the third heat exchanger 20-3.

Meanwhile, in the present invention, heat shields 27 and 28 are provided at the first inlet 111 and the first outlet 112 of the desorption chamber 11, the second inlet 121 and the second outlet 122 of the cooling chamber 12. ) So that the first inlet 111, the first outlet 112, the second inlet 121, and the second outlet 122 are formed by the activated carbon cartridge C flowing by the flow means 13. It is preferable to be configured to open and close. That is to prevent the heat loss from the desorption chamber 11 and the cooling chamber 12 to the outside by the heat shielding membrane (27, 28). To this end, the thermal barriers 27 and 28 should be made of a material that is both flexible and flame retardant.

The thermal barriers 27 and 28 are upper trains formed at upper ends of each of the first inlet 111 and the first outlet 112, the second inlet 121 and the second outlet 122 of the cooling chamber 12. It is characterized by consisting of a single membrane 27, and a lower heat shielding membrane 28 is formed at the bottom. The upper heat shield membrane 27 is to be opened and closed by the activated carbon cartridge (C) flowing by the flow means 13, the lower heat shield membrane 28 is in contact with the lower surface of the flow means (13) While maintaining the state is to continue to drive the flow means (13). To this end, it is preferable that the upper heat shielding membrane 27 has a length longer than the lower heat shielding membrane 28 as shown in FIG. 3 to facilitate opening and closing, and the lower heat shielding membrane 28 is the upper heat shielding membrane. Compared with (27), it is preferable that the number of heat shield sheets be densely blocked at the bottom of the flow means 13.

More preferably, when the upper heat shielding membrane 27 is mounted on the first inlet 111, the first outlet 112, the second inlet 121, and the second outlet 122, an activated carbon cartridge C is provided. It is reasonable to be configured to contact the upper surface of the flow portion 13 in the flow direction. This is because the thermal barrier 27 is opened by increasing the area of the first inlet 111, the first outlet 112, the second inlet 121 and the second outlet 122 in contact with the upper surface of the flow portion (13) It is to reduce the loss.

More preferably, as shown in FIG. 4, the upper heat shielding membrane 27 forms a gap in the bracket 271 and includes a plurality of heat blocking sheets 272 attached to the plurality of heat blocking sheets 272. By double the thermal insulation to prevent heat loss. The bracket 271 has a plurality of attachment grooves (not shown in the drawing) configured to be attached to upper ends of the first inlet 111, the first outlet 112, the second inlet 121, and the second outlet 122. ) So that each heat shield sheet 272 is attached to the top of the attachment groove. Thus forming a plurality of heat shield sheet 272, the clearance between the heat shield sheet 272 by the bracket 271 is formed so that the heat shield efficiency between the heat shield sheet 272 to be used as a heat shield space. It is to double. In addition, the heat-dissipating sheet 272 constitutes a weight 273 at the lower end thereof, and after the activated carbon cartridge C flowing therethrough, the heat-dissipating sheet 272 is the first inlet 111, the first outlet ( 112, by reducing the speed of closing the second inlet 121 and the second outlet 122 it is possible to further reduce the heat loss.

More preferably, the heat shield sheet 272 is formed by weaving a yarn mixed with ceramic fiber yarn 272-1 and metal fiber yarn 272-2.

The reason for constructing the heat shield sheet 272 is that the yarn is to achieve heat shielding by using the ceramic fiber yarn (272-1), if the only configuration of the ceramic fiber yarn (272-1) is insufficient ductility The metal fiber yarn 272-2 is mixed. In other words, the material of the fiber yarn itself is provided with heat shielding and ductility, and in addition, the yarn is formed by weaving so that a plurality of pores are formed, thereby providing the heat shielding structure as the structure of the annual shielding sheet 272. .

As a result, the upper heat shielding membrane 27 shown in FIG. 4 is provided with heat shielding by the gap between the heat shielding sheets 272, and the ceramic fiber yarn 272-1 and the metal fiber yarn 272-2 are mixed. By using the yarn, the heat shielding property as well as the ductility is secured, and the heat shielding property is doubled by the formation of pores by the weaving of the yarn. By using the upper heat shielding membrane 27, the desorption chamber 11 and It is to prevent the heat loss of the cooling chamber 12.

In FIG. 4, an example of the upper thermal barrier layer 27 is illustrated, but in the case of the lower thermal barrier layer 28, as illustrated in FIG. 3, the bracket 281 and the plurality of thermal barrier sheets configured in the bracket 281 ( 282), the structure and the material can be configured in the same bar, the description thereof will be omitted. However, the weight 273 is not formed in the lower heat shield 28 as in the upper heat shield 27. It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the invention. Therefore, the technical scope of the present invention should not be limited to the contents described in the detailed description of the specification, but should be defined by the claims.

10: the present invention 11: the detachment chamber
12 cooling chamber 13 flow means
14: high temperature inlet line 15: desorption outlet line
17: cooling outflow line 18: combustor
19: activated carbon discharge line 20-1: first heat exchanger
20-2: second heat exchanger 21-3: third heat exchanger
22: combustion gas inlet line 23: combustion gas discharge line
24: second combustion gas discharge line 25: third combustion gas discharge line

Claims (9)

A desorption chamber having a first inlet on one side and a first outlet on the other side;
A cooling chamber having a second inlet on one side and a second outlet on the other side;
Flow means for flowing the activated carbon cartridge while passing through the first inlet, the first outlet, the second inlet, and the second outlet;
A high temperature inflow line communicating with the desorption chamber and allowing hot air to be injected onto the activated carbon cartridge;
A desorption and discharge line which communicates with the desorption chamber and discharges desorption air including a volatile organic compound desorbed from an activated carbon cartridge to a combustor;
A cooling inlet line for communicating cooling air to the activated carbon cartridge while communicating with the cooling chamber;
And a cooling outflow line communicating with the cooling chamber and outflowing the cooling air passing through the activated carbon cartridge to the outside.
The first inlet, the first outlet, the second inlet, and the second outlet are provided with thermal barriers so that the first inlet, the first outlet, the second inlet, and the second outlet are opened and closed by activated carbon cartridges flowing through the flow means. Co-continuous activated carbon regeneration device, characterized in that configured.
delete delete delete delete The method of claim 1,
The thermal barrier is composed of an upper heat shield formed at the upper end of the first inlet, the first outlet, the second inlet and the second outlet, and a lower heat shield formed at the bottom, the upper heat shield is longer than the lower heat shield Co-continuous activated carbon regeneration device, characterized in that the weight is configured at the bottom and long.
The method according to claim 6,
When the upper heat shield is mounted on the first inlet, the first outlet, the second inlet and the second outlet, the lower end portion is in contact with the upper surface of the flow portion in the direction in which the activated carbon cartridge flows, the continuous continuous activated carbon regeneration device .
The method of claim 1,
The thermal barrier is formed by a bracket formed in the joint continuous activated carbon regeneration apparatus, characterized in that consisting of a plurality of thermal barrier sheets attached.
The method of claim 8,
The thermally cut sheet is a continuous continuous activated carbon regeneration apparatus, characterized in that formed by weaving mixed ceramic fiber yarn and metal fiber yarn.

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