TWM575086U - Double rotor system with high temperature desorption - Google Patents

Abstract

The present invention is a double-rotation system with high temperature desorption, mainly through an incineration device, a first adsorption reel, a first heating device, a second heating device, a second adsorption reel, and a third a combination of a heating device, a fourth heating device and a chimney, and a high-temperature desorption zone is respectively added through the first adsorption reel and the second adsorption reel for on-line operation (ON LINE) The residual high-boiling organic matter (VOC) can be separately removed, so that the first adsorption runner and the second adsorption runner can restore their adsorption capacity, thereby increasing the treatment efficiency of the volatile organic waste gas and reducing pollutants. The effect of emissions.

Description

Double wheel system with high temperature desorption

The present invention relates to a double-rotor system with high-temperature desorption, in particular to an exhaust gas treatment for a plant in the semiconductor industry, the photovoltaic industry or a chemical-related industry, which increases the efficiency of organic waste gas treatment.

At present, volatile organic gases (VOCs) are produced in the manufacturing process of the semiconductor industry or the optoelectronic industry. Therefore, processing equipment for treating volatile organic gases (VOC) is installed in each plant to avoid volatile organic gases (VOC). Directly discharged into the air and causing air pollution.

However, most of the processing equipment for installing volatile organic gases (VOC) in the plant currently use adsorption wheel to adsorb volatile organic gases (VOC). However, after using for a period of time, high-boiling substances are often difficult to desorb and remain. On the adsorption runner, the adsorption efficiency of the adsorption runner is directly affected. Therefore, the current treatment method is to entrust a professional manufacturer to periodically wash the adsorption runner to ensure the operation efficiency and airflow fluency of the adsorption runner.

However, when the above-mentioned regular washing and absorbing wheel is used, it is necessary to use a large amount of clean water for cleaning, and thus a large amount of waste water containing volatile organic gas (VOC), and at this time, waste water containing volatile organic gas (VOC). The chemical oxygen demand (COD) is very high and cannot be directly discharged from the in-plant wastewater treatment system. It must be commissioned by a professional qualified waste removal company. Processing is OK.

Therefore, in view of the above-mentioned deficiencies, the present creator can propose a high-speed desorption double-rotor system with high-temperature desorption effect, which allows the user to easily operate the assembly, and is dedicated to research and design to provide User convenience is the creative motive for the creator's desire to develop.

The main purpose of the present invention is to provide a double-rotation system with high temperature desorption, mainly through an incineration device, a first adsorption revolving wheel, a first heating device, a second heating device, and a second adsorption transfer. a combination of a wheel, a third heating device, a fourth heating device and a chimney, and a high temperature desorption zone is respectively added through the first adsorption wheel and the second adsorption wheel for online operation ( When ON LINE), the residual high-boiling organic matter (VOC) can be separately removed, so that the first adsorption runner and the second adsorption runner can restore their adsorption capacity, and increase the treatment efficiency of the volatile organic waste gas. And to achieve the effect of reducing pollutant emissions, thereby increasing the overall practicality.

Another object of the present invention is to provide a double-rotor system with high temperature desorption, through which a first hot gas bypass line is provided, and the first hot gas bypass line is One end is connected to the second heating device, and the other end of the second hot gas delivery pipe is connected to the second heating device, and then passes through one end of the second hot gas delivery pipe and the high temperature of the first adsorption runner The third hot gas delivery pipeline is provided with a third hot gas bypass pipeline, and the other end of the third hot gas bypass pipeline is connected to the fourth heating device, the fourth hot gas delivery pipeline The other end is connected to the fourth heating device, and is connected to the high temperature desorption region of the second adsorption runner through one end of the fourth hot gas delivery pipeline to enhance the entry into the first adsorption The high temperature desorption zone of the runner and the high temperature desorption zone of the second adsorption runner can reach a certain temperature (for example, 300 ° C), and have high temperature desorption efficiency, so that the overall processing efficiency can be improved from the past. 95% increased to over 97%, which in turn increased overall usability.

Another object of the present invention is to provide a double-rotor system with high temperature desorption, through which one side of the first adsorption wheel is connected to the other side and one side of the second adsorption wheel is connected to the other side. The pipe and the device can be in the same direction or in opposite directions, so that the first adsorption wheel and the second adsorption wheel can have different arrangement and combination performance, thereby increasing the overall operability.

In order to further understand the features, features and technical contents of the present invention, please refer to the following detailed description of the present invention and the accompanying drawings, which are only for reference and description, and are not intended to limit the present invention.

A‧‧‧ side

B‧‧‧The other side

100‧‧‧Incinerator

101‧‧‧ entrance

102‧‧‧Export

110‧‧‧First adsorption wheel

1101‧‧‧Adsorption zone

1102‧‧‧Cooling area

1103‧‧‧Decoupling area

1104‧‧‧High temperature desorption zone

111‧‧‧Exhaust air intake pipe

112‧‧‧First clean air discharge pipeline

113‧‧‧First cooling air intake line

114‧‧‧First cooling gas delivery line

115‧‧‧First hot gas delivery line

116‧‧‧First desorbed concentrated gas pipeline

1161‧‧‧Fan

117‧‧‧Second hot gas delivery line

118‧‧‧First high temperature desorption concentrated gas pipeline

120‧‧‧Second adsorption wheel

1201‧‧‧Adsorption zone

1202‧‧‧Cooling area

1203‧‧‧Decoupling area

1204‧‧‧High temperature desorption zone

121‧‧‧Second clean gas discharge pipeline

1211‧‧‧ fan

122‧‧‧Second cooling air intake line

123‧‧‧Second cooling gas delivery line

124‧‧‧third hot gas delivery pipeline

125‧‧‧Second desorbed concentrated gas pipeline

1251‧‧‧fan

126‧‧‧fourth hot gas delivery pipeline

127‧‧‧Second high temperature desorption concentrated gas pipeline

130‧‧‧First heating unit

140‧‧‧Second heating unit

150‧‧‧third heating device

160‧‧‧Fourth heating device

170‧‧‧ chimney

181‧‧‧Exhaust communication line

1811‧‧‧Exhaust gas communication control valve

182‧‧‧First clean gas communication line

1821‧‧‧First clean air communication control valve

191‧‧‧First hot gas bypass line

1911‧‧‧First hot gas bypass control valve

192‧‧‧ Third hot gas bypass line

1921‧‧‧ Third hot gas bypass control valve

200‧‧‧Incinerator

201‧‧‧ entrance

202‧‧‧Export

210‧‧‧First adsorption wheel

2101‧‧‧Adsorption zone

2102‧‧‧Cooling area

2103‧‧‧Decoupling area

2104‧‧‧High temperature desorption zone

211‧‧‧Exhaust air intake pipe

212‧‧‧First clean gas discharge pipeline

213‧‧‧First cooling air intake line

214‧‧‧First cooling gas delivery line

215‧‧‧First hot gas delivery line

216‧‧‧First desorbed concentrated gas pipeline

2161‧‧‧Fan

217‧‧‧Second hot gas delivery line

218‧‧‧First high temperature desorption concentrated gas pipeline

220‧‧‧Second adsorption wheel

2201‧‧‧Adsorption zone

2202‧‧‧Cooling area

2203‧‧‧Decoupling area

2204‧‧‧High temperature desorption zone

221‧‧‧Second clean gas discharge pipeline

2211‧‧‧fan

222‧‧‧Second cooling air intake line

223‧‧‧Second cooling gas delivery line

224‧‧‧third hot gas delivery pipeline

225‧‧‧Second detached concentrated gas pipeline

2251‧‧‧Fan

226‧‧‧fourth hot gas delivery pipeline

227‧‧‧Second high temperature desorption concentrated gas pipeline

230‧‧‧First heating unit

240‧‧‧Second heating unit

250‧‧‧third heating device

260‧‧‧fourth heating device

270‧‧ ‧ chimney

282‧‧‧First clean gas communication line

2821‧‧‧First clean air communication control valve

283‧‧‧Second clean gas communication line

2831‧‧‧Second clean air communication control valve

291‧‧‧First hot gas bypass line

2911‧‧‧First hot gas bypass control valve

292‧‧‧ third hot gas bypass line

2921‧‧‧ Third hot gas bypass control valve

300‧‧‧Incinerator

301‧‧‧ entrance

302‧‧‧Export

310‧‧‧First adsorption wheel

3101‧‧‧Adsorption zone

3102‧‧‧Cooling area

3103‧‧‧Decoupling area

3104‧‧‧High temperature desorption zone

311‧‧‧Exhaust air intake pipe

312‧‧‧First clean gas discharge pipeline

313‧‧‧First cooling air intake line

314‧‧‧First cooling gas delivery line

315‧‧‧First hot gas delivery line

316‧‧‧First desorbed concentrated gas pipeline

3161‧‧‧Fan

317‧‧‧Second hot gas delivery line

318‧‧‧First high temperature desorption concentrated gas pipeline

320‧‧‧Second adsorption wheel

3201‧‧‧Adsorption zone

3202‧‧‧Cooling area

3203‧‧‧Decoupling area

3204‧‧‧High temperature desorption zone

321‧‧‧Second clean gas discharge pipeline

3211‧‧‧fan

322‧‧‧Second cooling air intake line

323‧‧‧Second cooling gas delivery line

324‧‧‧third hot gas delivery line

325‧‧‧Second detached concentrated gas pipeline

3251‧‧‧ fan

326‧‧‧fourth hot gas delivery pipeline

327‧‧‧Second high temperature desorption concentrated gas pipeline

330‧‧‧First heating unit

340‧‧‧Second heating device

350‧‧‧ Third heating device

360‧‧‧fourth heating device

370‧‧‧ chimney

381‧‧‧Exhaust communication line

3811‧‧‧Exhaust gas communication control valve

383‧‧‧Second clean gas communication pipeline

3831‧‧‧Second clean air communication control valve

391‧‧‧First hot gas bypass line

3911‧‧‧First hot gas bypass control valve

392‧‧‧ Third hot gas bypass line

3921‧‧‧ Third hot gas bypass control valve

400‧‧‧Incinerator

401‧‧‧ entrance

402‧‧‧Export

410‧‧‧First adsorption wheel

4101‧‧‧Adsorption zone

4102‧‧‧Cooling area

4103‧‧‧Decoupling area

4104‧‧‧High temperature desorption zone

411‧‧‧Exhaust air intake pipe

412‧‧‧First clean gas discharge pipeline

413‧‧‧First cooling air intake line

414‧‧‧First cooling gas delivery line

415‧‧‧First hot gas delivery line

416‧‧‧First desorbed concentrated gas pipeline

4161‧‧‧ fan

417‧‧‧Second hot gas delivery line

418‧‧‧First high temperature desorption concentrated gas pipeline

420‧‧‧Second adsorption wheel

4201‧‧‧Adsorption zone

4202‧‧‧Cooling area

4203‧‧‧Decoupling area

4204‧‧‧High temperature desorption zone

421‧‧‧Second clean gas discharge pipeline

4211‧‧‧fan

422‧‧‧Second cooling air intake line

423‧‧‧Second cooling gas delivery line

424‧‧‧third hot gas delivery line

425‧‧‧Second desorbed concentrated gas pipeline

4251‧‧‧ fan

426‧‧‧fourth hot gas delivery pipeline

427‧‧‧Second high temperature desorption concentrated gas pipeline

430‧‧‧First heating unit

440‧‧‧second heating device

450‧‧‧ Third heating unit

460‧‧‧fourth heating device

470‧‧‧ chimney

484‧‧‧First clean gas first connecting line

4841‧‧‧First clean air first communication control valve

485‧‧‧First clean air second connecting line

4851‧‧‧First clean air second communication control valve

491‧‧‧First hot gas bypass line

4911‧‧‧First hot gas bypass control valve

492‧‧‧ Third hot gas bypass line

4921‧‧‧ Third hot gas bypass control valve

Figure 1 is a schematic diagram of the main system architecture of the first implementation architecture of this creation.

Figure 2 is a schematic diagram of another system architecture of the first implementation architecture of the present invention.

Figure 3 is a schematic diagram of the main system architecture of the second implementation architecture of the author.

Figure 4 is a schematic diagram of another system architecture of the second implementation architecture of the present invention.

Figure 5 is a schematic diagram of the main system architecture of the third implementation architecture of this creation.

Figure 6 is a schematic diagram of another system architecture of the third implementation architecture of the present invention.

Figure 7 is a schematic diagram of the main system architecture of the fourth implementation architecture of this creation.

Figure 8 is a schematic diagram of another system architecture of the fourth implementation architecture of the present invention.

Please refer to FIG. 1 to FIG. 8 , which are schematic diagrams of the present embodiment. The best implementation of the high-speed decoupling double-rotor system of this creation is applied to the exhaust gas treatment of the semiconductor industry, optoelectronic industry or chemical-related industries. Through the design of this creation, it is used for online operation (ON LINE) can remove the residual high-boiling organic waste gas (VOC), so that the adsorption wheel can restore its adsorption capacity, increase the treatment efficiency of volatile organic waste gas, and achieve the effect of reducing pollutant emissions.

The double-rotation system with high temperature desorption (as shown in Figures 1 and 2) of the first implementation of the present invention mainly passes through an incineration device 100, a first adsorption reel 110, and a first a combination design of a heating device 130, a second heating device 140, a second adsorption wheel 120, a third heating device 150, a fourth heating device 160, and a chimney 170, wherein the incinerator 100 is a direct-fired type Incinerator (TO) (not shown), catalytic furnace (not shown) or regenerative incinerator (RTO), and the first implementation of this creation is based on a regenerative incinerator ( RTO) is taken as an example, and the incinerator 100 described below is a regenerative incinerator (RTO), but the incinerator 100 of the present invention is not limited to a regenerative incinerator (RTO), and may be a direct-fired incinerator. (TO) (not shown) or catalyst furnace (not shown).

The first adsorption wheel 110 of the first implementation architecture of the present invention (as shown in FIGS. 1 and 2) is provided with an adsorption zone 1101, a cooling zone 1102, a desorption zone 1103, and a high temperature desorption zone 1104. The first adsorption reel 110 is a zeolite concentration revolver or a concentrated revolving wheel of other materials, and an exhaust gas intake line 111 is connected to one side A of the adsorption zone 1101 of the first adsorption reel 110, so that The adsorption zone 1101 of the first adsorption wheel 110 can adsorb the organic matter in the exhaust gas intake pipe 111, and the other side B of the adsorption zone 1101 of the first adsorption runner 110 and the first clean air discharge One of the pipelines 112 The end is connected, and the exhaust gas is adsorbed by the adsorption zone 1101 of the first adsorption reel 110 and then transported by the first clean gas discharge pipe 112.

The side A of the cooling zone 1102 of the first adsorption wheel 110 is connected to a first cooling gas inlet pipe 113 for gas to enter the cooling zone 1102 of the first adsorption wheel 110 for cooling use. The other side B of the cooling zone 1102 of the first adsorption wheel 110 is connected to a first cooling gas delivery line 114, and the other end of the first cooling gas delivery line 114 is connected to the first heating device 130. The first heating device 130 is any one of a heater, a pipe heater or a heat exchanger, and the heater (not shown) is any one of a heating wire, an electric heating pipe or a heating plate, and the pipe is heated. The device (not shown) is either a gaseous fuel or a liquid fuel. One end of the first hot gas delivery line 115 is connected to the other side B of the desorption area 1103 of the first adsorption reel 110, and the other end of the first hot gas delivery line 115 is the first The heating device 130 is connected to transmit the high-temperature hot gas heated or exchanged by the first heating device 130 to the desorption region 1103 of the first adsorption reel 110 through the first hot gas delivery line 115. Attached to use.

The cooling zone 1102 of the first adsorption wheel 110 is provided with two embodiments, wherein the first embodiment is the first cooling gas connected to one side A of the cooling zone 1102 of the first adsorption wheel 110. The intake line 113 is for fresh air or external air (as shown in FIG. 1), and the cooling zone 1102 for the first adsorption wheel 110 is cooled by the fresh air or the external air. In another embodiment, the exhaust gas intake line 111 is provided with an exhaust gas communication line 181, and the other end of the exhaust gas communication line 181 is connected to the first cooling gas inlet line 113 (eg, the second As shown in the figure), to pass through the exhaust pipe The 181 is used to transport the exhaust gas in the exhaust gas intake line 111 to the cooling zone 1102 of the first adsorption turret 110 for cooling use, and the exhaust gas communication line 181 is provided with an exhaust gas communication control valve 1811 for controlling The exhaust gas communicates with the air volume of the line 181.

Another end of the first desorption concentrated gas line 116 is connected to the side A of the desorption region 1103 of the first adsorption reel 110, and the other end of the first desorption concentrated gas line 116 is The incinerator 100 is connected, and when the incinerator 100 is a regenerative incinerator (RTO), the regenerative incinerator (RTO) is provided with an inlet 101 and an outlet 102, and the inlet 101 is connected to the first desorption The concentrated gas line 116 is connected so that the desorbed concentrated gas desorbed by the high temperature can be sent to the inlet 101 of the regenerative incinerator (RTO) through the first desorbed concentrated gas line 116 for desorption The concentrated gas can enter the regenerative incinerator (RTO) for pyrolysis to reduce volatile organic compounds, and the regenerative incinerator (RTO) outlet 102 is connected to a chimney 170 to be subjected to pyrolysis organics. The clean gas can be discharged from the chimney 170, and the first desorbed concentrated gas line 116 is provided with a fan 1161 to push and pull the desorbed concentrated gas into the inlet 101 of the regenerative incinerator (RTO). Inside, the desorbed concentrated gas can be pyrolyzed.

The first implementation architecture of the present invention (as shown in FIG. 1 and FIG. 2) mainly includes the first adsorption reel 110, in addition to the adsorption zone 1101, the cooling zone 1102, and the desorption zone 1103. The high temperature desorption zone 1104 can be used to remove the residual high boiling organic matter (VOC) when it is used for ON LINE, so that the first adsorption reel 110 can restore its adsorption capacity and make the first adsorption. The runner 110 can have four zones. The other side B of the high temperature desorption zone 1104 of the first adsorption transfer 110 is connected to one end of a second hot gas delivery line 117, and the other end of the second hot gas delivery line 117 is The second heating device 140 is connected, wherein the second heating device 140 is any one of a heater, a pipe heater or a heat exchanger. The heater (not shown) is a heating wire, an electric heating tube or a heating sheet. In any of the above, the duct heater (not shown) is any one of a gaseous fuel or a liquid fuel. The first hot gas delivery line 115 is provided with a first hot gas bypass line 191, and the other end of the first hot gas bypass line 191 is connected to the second heating device 140 so as to be able to pass the first The high temperature hot gas that is heated or exchanged by the heating device 130 is partially shunted and delivered to the second heating device 140 through the first hot gas bypass line 191 to enter the second hot gas delivery line 117. The high temperature hot gas can be raised to a certain temperature (for example, 300 ° C), and the high temperature hot gas in the second hot gas delivery line 117 is re-delivered to the high temperature desorption zone 1104 of the first adsorption reel 110 for high temperature desorption. The first hot gas bypass line 191 is provided with a first hot gas bypass control valve 1911 for controlling the air volume of the first hot gas bypass line 191.

Furthermore, one side A of the high temperature desorption zone 1104 of the first adsorption reel 110 is connected to a first high temperature desorption concentrated gas line 118, and the other end of the first high temperature desorption concentrated gas line 118 is And connecting to the first desorption concentrated gas line 116 to pass the high-temperature desorption concentrated gas desorbed by the high-temperature desorption zone 1104 of the first adsorption reel 110 through the first high-temperature desorption concentrated gas pipe The road 118 is sent to the first desorbed concentrated gas line 116, and then sent to the inlet 101 of the regenerative incinerator (RTO) through the first desorbed concentrated gas line 116 to allow the high temperature desorption of the concentrated gas. The pyrolysis incinerator (RTO) is introduced into the regenerative incinerator (RTO) together with the desorbed concentrated gas in the first desorbed concentrated gas line 116 for pyrolysis.

In addition, the second adsorption runner 120 is a zeolite concentration runner or other material. The second revolving wheel 120 is provided with an adsorption zone 1201, a cooling zone 1202, a desorption zone 1203 and a high temperature desorption zone 1204, and one of the adsorption zones 1201 of the second adsorption reel 120 The side A is connected to the other end of the first clean air discharge line 112, so that the gas in the first clean air discharge line 112 can be directly transferred to the adsorption area 1201 of the second adsorption wheel 120. The second side of the adsorption zone 1201 of the second adsorption runner 120 is connected to a second clean air discharge line 121, and the other end of the second clean air discharge line 121 is connected to a chimney 170. In order to facilitate the discharge of the gas adsorbed by the adsorption zone 1101 of the first adsorption wheel 110 and the adsorption zone 1201 of the second adsorption wheel 120 through the chimney 170, wherein the second clean gas discharge pipeline The 121 system is provided with a fan 1211 for increasing the flow rate of the gas to the chimney 170.

The side A of the cooling zone 1202 of the second adsorption wheel 120 is connected to a second cooling gas inlet pipe 122 for the gas to enter the cooling zone 1202 of the second adsorption wheel 120 for cooling use. The other side B of the cooling zone 1202 of the second adsorption wheel 120 is connected to a second cooling gas delivery line 123, and the other end of the second cooling gas delivery line 123 is connected to the third heating device 150. The third heating device 150 is any one of a heater, a pipe heater or a heat exchanger, and the heater (not shown) is any one of a heating wire, an electric heating pipe or a heating plate, and the pipe is heated. The device (not shown) is either a gaseous fuel or a liquid fuel. One end of the third hot gas delivery line 124 is connected to the other side B of the desorption area 1203 of the second adsorption reel 120, and the other end of the third hot gas delivery line 124 is connected to the third side. The heating device 150 is connected to pass the high-temperature hot gas heated or exchanged by the third heating device 150 through the first The three hot gas delivery line 124 is delivered to the desorption zone 1203 of the second adsorption reel 120 for desorption use.

The cooling zone 1202 of the second adsorption runner 120 is provided with two embodiments. The first embodiment is a second cooling gas connected to one side A of the cooling zone 1202 of the second adsorption runner 120. The intake line 122 is for fresh air or external air (as shown in FIG. 1), and the cooling zone 1202 for providing the second adsorption wheel 120 is cooled by the fresh air or the external air. In another embodiment, the first clean air discharge line 112 is provided with a first clean air communication line 182, and the other end of the first clean air communication line 182 is connected to the second cooling air. The line 122 is connected (as shown in FIG. 2) to enable the gas in the first clean gas discharge line 112 to be delivered to the second adsorption wheel 120 through the first clean air communication line 182. The area 1202 is used for cooling, and the first clean air communication line 182 is provided with a first clean air communication control valve 1821 to control the air volume of the first clean air communication line 182.

Another end of the second desorption concentrated gas line 125 is connected to one side A of the desorption region 1203 of the second adsorption reel 120, and the other end of the second desorption concentrated gas line 125 is The incinerator 100 is connected, and when the incinerator 100 is a regenerative incinerator (RTO), the regenerative incinerator (RTO) is provided with an inlet 101 and an outlet 102, and the inlet 101 is connected to the second desorption The concentrated gas line 125 is connected so that the desorbed concentrated gas desorbed by the high temperature can be sent to the inlet 101 of the regenerative incinerator (RTO) through the second desorbed concentrated gas line 125 for desorption The concentrated gas can enter the regenerative incinerator (RTO) for pyrolysis to reduce volatile organic compounds, and the regenerative incinerator (RTO) outlet 102 is connected to the chimney 170 to be pyrolyzed. The clean gas after the machine can be discharged by the chimney 170, and the second desorbed concentrated gas line 125 is provided with a fan 1251 to push and pull the desorbed concentrated gas into the regenerative incinerator (RTO). In the inlet 101, the desorbed concentrated gas is allowed to undergo high temperature cracking.

The first implementation architecture of the present invention (as shown in FIGS. 1 and 2) mainly includes the second adsorption reel 120, in addition to the adsorption zone 1201, the cooling zone 1202, and the desorption zone 1203. The high temperature desorption zone 1204 can be used to remove the residual high boiling organic matter (VOC) during on-line operation (ON LINE), so that the second adsorption reel 120 can restore its adsorption capacity, so that the second adsorption The runner 120 can have four zones. The other side B of the high temperature desorption zone 1204 of the second adsorption reel 120 is connected to one end of a fourth hot gas delivery line 126, and the other end of the fourth hot gas delivery line 126 is connected to the fourth The heating device 160 is connected, wherein the fourth heating device 160 is any one of a heater, a pipe heater or a heat exchanger, and the heater (not shown) is a heating wire, an electric heating pipe or a heating film. First, the pipeline heater (not shown) is any one of a gaseous fuel or a liquid fuel. The third hot gas delivery line 124 is provided with a third hot gas bypass line 192, and the other end of the third hot gas bypass line 192 is connected to the fourth heating device 160 so as to be able to pass through the third The high temperature hot gas that is heated or exchanged by the heating device 150 is partially shunted and delivered to the fourth heating device 160 through the third hot gas bypass line 192 to enter the fourth hot gas delivery line 126. The high temperature hot gas can be raised to a certain temperature (for example, 300 ° C), and the high temperature hot gas in the fourth hot gas delivery line 126 is re-delivered to the high temperature desorption zone 1204 of the second adsorption reel 120 for high temperature desorption. The third hot gas bypass line 192 is provided with a third hot gas bypass control valve 1921 to control the air volume of the third hot gas bypass line 192.

Furthermore, one side A of the high temperature desorption zone 1204 of the second adsorption reel 120 is connected to a second high temperature desorption concentrated gas line 127, and the other end of the second high temperature desorption concentrated gas line 127 is And connecting to the second desorption concentrated gas line 125 to pass the high-temperature desorption concentrated gas desorbed by the high-temperature desorption zone 1204 of the second adsorption reel 120 through the second high-temperature desorption concentrated gas pipe The road 127 is sent to the second desorbed concentrated gas line 125, and then sent to the inlet 101 of the regenerative incinerator (RTO) through the second desorbed concentrated gas line 125, so that the high temperature desorbing concentrated gas can The desorbed concentrated gas in the second desorbed concentrated gas line 125 is introduced into the regenerative incinerator (RTO) for pyrolysis.

The second embodiment of the present invention (as shown in Figures 3 and 4) has a high-speed desorption double-rotor system, mainly through an incineration device 200, a first adsorption reel 210, and a first A combination of a heating device 230, a second heating device 240, a second adsorption wheel 220, a third heating device 250, a fourth heating device 260, and a chimney 270. The second implementation architecture of the present invention differs from the first implementation architecture of the present invention in that one side A and the other side B of the first adsorption reel 210 and the other side B and the second side of the second adsorption reel 220 are on the other side. Part of the piping and equipment connected to B is in the opposite direction. The following will further explain the content of the second implementation framework of this creation.

The incinerator 200 is a direct combustion incinerator (TO) (not shown), a catalytic converter (not shown) or a regenerative incinerator (RTO), and the second creation. The embodiment of the implementation architecture is exemplified by a regenerative incinerator (RTO), and the incinerator 200 described below is a regenerative incinerator (RTO), but the incinerator 200 of the second embodiment of the present invention does not store heat. Incinerator (RTO) is limited to direct combustion incinerator (TO) (not shown) or touch Medium furnace (not shown).

The first adsorption reel 210 of the second implementation architecture of the present invention (as shown in FIGS. 3 and 4) is provided with an adsorption zone 2101, a cooling zone 2102, a desorption zone 2103, and a high temperature desorption zone 2104. The first adsorption reel 210 is a zeolite concentration reel or a concentrated revolving wheel of other materials, and an exhaust gas intake line 211 is connected to one side A of the adsorption zone 2101 of the first adsorption reel 210, so that The adsorption zone 2101 of the first adsorption wheel 210 can adsorb the organic matter in the exhaust gas intake pipe 211, and the other side B of the adsorption zone 2101 of the first adsorption runner 210 and the first clean air discharge One end of the pipeline 212 is connected, and the exhaust gas is adsorbed by the adsorption zone 2101 of the first adsorption runner 210 and then transported by the first clean gas discharge pipeline 212.

The other side B of the cooling zone 2102 of the first adsorption wheel 210 is connected to a first cooling gas inlet pipe 213 for the gas to enter the cooling zone 2102 of the first adsorption wheel 210 for cooling use. One side A of the cooling zone 2102 of the first adsorption wheel 210 is connected to a first cooling gas delivery line 214, and the other end of the first cooling gas delivery line 214 is connected to the first heating device 230. The first heating device 230 is any one of a heater, a pipe heater or a heat exchanger, and the heater (not shown) is any one of a heating wire, an electric heating pipe or a heating plate, and the pipe is heated. The device (not shown) is either a gaseous fuel or a liquid fuel. One end of the first hot gas delivery line 215 is connected to one side A of the desorption area 2103 of the first adsorption reel 210, and the other end of the first hot gas delivery line 215 is connected to the first heating. The device 230 is connected to transmit high-temperature hot gas heated or exchanged by the first heating device 230 through the first hot gas delivery line 215 to the desorption region 2103 of the first adsorption reel 210. Use for desorption.

The cooling zone 2102 of the first adsorption wheel 210 is provided with two embodiments, wherein the first embodiment is the first cooling connected to the other side B of the cooling zone 2102 of the first adsorption wheel 210. The air intake line 213 is for the fresh air or the outside air to enter (as shown in FIG. 3), and the cooling zone 2102 for providing the first adsorption wheel 210 is cooled by the fresh air or the external air. In another embodiment, the first clean air discharge line 212 is provided with a first clean air communication line 282, and the other end of the first clean air supply line 282 is coupled to the first cooling air intake. The pipe 213 is connected (as shown in FIG. 4) so as to pass through the first clean gas communication line 282 to pass the first clean gas discharge pipe 212 through the adsorption zone 2101 of the first adsorption runner 210. The adsorbed gas is sent to the cooling zone 2102 of the first adsorption runner 210 for cooling use, and the first clean gas communication pipeline 282 is provided with a first clean air communication control valve 2821 to control the first net. The air volume of the gas communication line 282.

Another end of the first desorption concentrated gas line 216 is connected to the other side B of the desorption region 2103 of the first adsorption reel 210, and the other end of the first desorption concentrated gas line 216 is The incinerator 200 is connected to the incinerator 200, and when the incinerator 200 is a regenerative incinerator (RTO), the regenerative incinerator (RTO) is provided with an inlet 201 and an outlet 202, and the inlet 201 is connected to the first off A concentrated gas line 216 is connected to enable the desorbed concentrated gas desorbed by the high temperature to be sent to the inlet 201 of the regenerative incinerator (RTO) through the first desorbed concentrated gas line 216. The concentrated gas can enter the regenerative incinerator (RTO) for pyrolysis to reduce volatile organic compounds, and the regenerative incinerator (RTO) outlet 202 is connected to a chimney 270 for pyrolysis The clean gas after the organic matter can be discharged from the chimney 270, and the first desorbed concentrated gas line 216 is provided with a fan 2161 to push and pull the desorbed concentrated gas into the inlet of the regenerative incinerator (RTO). In 201, the desorbed concentrated gas is allowed to undergo high temperature cracking.

The second implementation architecture of the present invention (as shown in FIGS. 3 and 4) mainly includes the first adsorption reel 210, in addition to the adsorption zone 2101, the cooling zone 2102, and the desorption zone 2103. The high temperature desorption zone 2104 can be used to remove the residual high boiling organic matter (VOC) when it is used for ON LINE, so that the first adsorption reel 210 can restore its adsorption capacity and make the first adsorption. The runner 210 can have four zones. One side A of the high temperature desorption zone 2104 of the first adsorption reel 210 is connected to one end of a second hot gas delivery line 217, and the other end of the second hot gas delivery line 217 is coupled to the second heating. The device 240 is connected, wherein the second heating device 240 is any one of a heater, a pipe heater or a heat exchanger, and the heater (not shown) is any one of a heating wire, an electric heating tube or a heating sheet. The pipeline heater (not shown) is any one of a gaseous fuel or a liquid fuel. The first hot gas delivery line 215 is provided with a first hot gas bypass line 291, and the other end of the first hot gas bypass line 291 is connected to the second heating device 240 so as to be able to pass the first The high temperature hot gas that is heated or exchanged by the heating device 230 is partially shunted and sent to the second heating device 240 through the first hot gas bypass line 291 to enter the second hot gas delivery line 217. The high temperature hot gas can be raised to a certain temperature (for example, 300 ° C), and the high temperature hot gas in the second hot gas delivery line 217 is again sent to the high temperature desorption zone 2104 of the first adsorption reel 210 for high temperature desorption. The first hot gas bypass line 291 is provided with a first hot gas bypass control valve 2911 for controlling the air volume of the first hot gas bypass line 291.

Furthermore, the other side B of the high temperature desorption zone 2104 of the first adsorption reel 210 is connected to a first high temperature desorption concentrated gas line 218, and the other end of the first high temperature desorption concentrated gas line 218 Is connected to the first desorbed concentrated gas line 216 to permeate the high temperature desorbed concentrated gas desorbed through the high temperature desorption zone 2104 of the first adsorption reel 210 through the first high temperature desorbed concentrated gas The line 218 is sent to the first desorbed concentrated gas line 216, and then sent to the inlet 201 of the regenerative incinerator (RTO) through the first desorbed concentrated gas line 216 to desorb the concentrated gas at a high temperature. It can enter the regenerative incinerator (RTO) together with the desorbed concentrated gas in the first desorbed concentrated gas line 216 for pyrolysis.

The second adsorption runner 220 is a zeolite concentration runner or a concentrated runner of other materials, and the second adsorption runner 220 is provided with an adsorption zone 2201, a cooling zone 2202, a desorption zone 2203, and a high temperature off. An area 2204, and the 2201 side A of the adsorption zone of the second adsorption wheel 220 is connected to the other end of the first clean gas discharge line 212 to make the gas in the first clean gas discharge line 212 The second side of the adsorption zone 2201 of the second adsorption wheel 220 is connected to a second clean air discharge line 221, and the other side of the adsorption zone 2201 of the second adsorption wheel 220 is directly connected to the adsorption zone 2201. The other end of the second clean air discharge line 221 is connected to a chimney 270 to facilitate the gas adsorbed by the adsorption zone 2101 of the first adsorption runner 210 and the adsorption zone 2201 of the second adsorption runner 220. The discharge is performed through the chimney 270, wherein the second clean air discharge line 221 is provided with a fan 2211 to increase the flow rate of the gas to flow to the chimney 270.

In addition, the other side B of the cooling zone 2202 of the second adsorption runner 220 A second cooling gas inlet line 222 is connected to allow the gas to enter the cooling zone 2202 of the second adsorption wheel 220 for cooling use, and the side A of the cooling zone 2202 of the second adsorption wheel 220 is connected. a second cooling gas delivery line 223, the other end of the second cooling gas delivery line 223 is connected to the third heating device 250, wherein the third heating device 250 is a heater, a pipe heater or a heat exchange Any one of the heaters (not shown) is any one of a heating wire, an electric heating tube or a heating sheet, and the pipeline heater (not shown) is any one of a gaseous fuel or a liquid fuel. . One end of the third hot gas delivery line 224 is connected to one side A of the desorption area 2203 of the second adsorption reel 220, and the other end of the third hot gas delivery line 224 is connected to the third heating. The device 250 is connected to enable the high-temperature hot gas heated or exchanged by the third heating device 250 to be transported to the desorption region 2203 of the second adsorption reel 220 through the third hot gas delivery line 224 for desorption. use.

The cooling zone 2202 of the second adsorption wheel 220 is provided with two embodiments, wherein the first embodiment is the second cooling connected to the other side B of the cooling zone 2202 of the second adsorption wheel 220. The air intake line 222 is for fresh air or external air (as shown in FIG. 3), and the cooling zone 2202 of the second adsorption wheel 220 is cooled by the fresh air or the external air. In another embodiment, the second clean air discharge line 221 is provided with a second clean air communication line 283, and the other end of the second clean air communication line 283 is connected to the second cooling air intake. The line 222 is connected (as shown in FIG. 4) to transmit the gas in the second clean gas discharge line 221 to the second adsorption wheel 220 through the second clean air communication line 283. The area 2202 is used for cooling, and the second clean air communication line 283 is provided with a second clean air communication control valve 2831 to control the The air volume of the second clean air communication line 283.

Another end of the second desorbed concentrated gas line 225 is connected to the other side B of the desorption zone 2203 of the second adsorption reel 220, and the other end of the second desorption concentrated gas line 225 is The incinerator 200 is connected to the incinerator 200, and when the incinerator 200 is a regenerative incinerator (RTO), the regenerative incinerator (RTO) is provided with an inlet 201 and an outlet 202, and the inlet 201 is connected to the second A concentrated gas line 225 is connected to enable the desorbed concentrated gas desorbed by the high temperature to be transmitted to the inlet 201 of the regenerative incinerator (RTO) through the second desorbed concentrated gas line 225. The concentrated gas can enter the regenerative incinerator (RTO) for pyrolysis to reduce volatile organic compounds, and the regenerative incinerator (RTO) outlet 202 is connected to the chimney 270 for pyrolysis The clean gas after the organic matter can be discharged from the chimney 270, and the second desorbed concentrated gas line 225 is provided with a fan 2251 to push and pull the desorbed concentrated gas into the inlet of the regenerative incinerator (RTO). In 201, the desorbed concentrated gas is allowed to undergo high temperature cracking.

In the second implementation architecture of the present invention (as shown in FIG. 3 and FIG. 4 ), the second adsorption reel 220 is provided with an adsorption zone 2201 , a cooling zone 2202 and a desorption zone 2203 . The high temperature desorption zone 2204 can be used to remove the residual high boiling organic matter (VOC) when it is used for ON LINE, so that the second adsorption reel 220 can restore its adsorption capacity and make the second adsorption. The runner 220 can have four zones. One side A of the high temperature desorption zone 2204 of the second adsorption reel 220 is connected to one end of a fourth hot gas delivery line 226, and the other end of the fourth hot gas delivery line 226 is connected to the fourth heating. The device 260 is connected, wherein the fourth heating device 260 is any one of a heater, a pipe heater or a heat exchanger, and the heater (not shown) is a heating wire and an electric heating tube. Or any of the heating fins, the duct heater (not shown) is any one of a gaseous fuel or a liquid fuel. The third hot gas delivery line 224 is provided with a third hot gas bypass line 292, and the other end of the third hot gas bypass line 292 is connected to the fourth heating device 260 so as to be able to pass through the third The high temperature hot gas that is heated or exchanged by the heating device 250 is partially shunted and delivered to the fourth heating device 260 through the third hot gas bypass line 292 to enter the fourth hot gas delivery line 226. The high temperature hot gas can be raised to a certain temperature (for example, 300 ° C), and the high temperature hot gas in the fourth hot gas delivery line 226 is re-delivered to the high temperature desorption zone 2204 of the second adsorption reel 220 for high temperature desorption. The third hot gas bypass line 292 is provided with a third hot gas bypass control valve 2921 to control the air volume of the third hot gas bypass line 292.

Furthermore, the other side B of the high temperature desorption zone 2204 of the second adsorption reel 220 is connected to a second high temperature desorption concentrated gas line 227, and the other end of the second high temperature desorption concentrated gas line 227 Is connected to the second desorption concentrated gas line 225 to pass the high temperature desorption concentrated gas desorbed by the high temperature desorption zone 2204 of the second adsorption reel 220 through the second high temperature desorption concentrated gas The line 227 is sent to the second desorbed concentrated gas line 225, and then sent to the inlet 201 of the regenerative incinerator (RTO) through the second desorbed concentrated gas line 225 to desorb the concentrated gas at a high temperature. It can enter the regenerative incinerator (RTO) together with the desorbed concentrated gas in the second desorbed concentrated gas line 225 for pyrolysis.

The third embodiment of the present invention (as shown in Figures 5 and 6) has a high-speed desorption double-rotor system, mainly through an incineration device 300, a first adsorption reel 310, and a first Heating device 330, a second heating device 340, and a second adsorption runner 320, a combination of a third heating device 350, a fourth heating device 360, and a chimney 370. The difference between the third implementation architecture of the present creation and the first implementation architecture of the present invention is that the pipelines and devices connected to one side A and the other side B of the first adsorption runner 310 are unchanged, and the second adsorption The piping and the device connected to one side A and the other side B of the runner 330 are in opposite directions. The following will further explain the content of the third implementation framework of this creation.

The incinerator 300 is a direct combustion incinerator (TO) (not shown), a catalytic converter (not shown) or a regenerative incinerator (RTO), and the third creation The embodiment of the implementation architecture is exemplified by a regenerative incinerator (RTO), and the incinerator 300 described below is a regenerative incinerator (RTO), but the incinerator 300 of the third embodiment of the present invention does not store heat. In the case of a type incinerator (RTO), it can also be a direct-fired incinerator (TO) (not shown) or a catalytic converter (not shown).

The first adsorption reel 310 of the third implementation architecture of the present invention (as shown in FIGS. 5 and 6) is provided with an adsorption zone 3101, a cooling zone 3102, a desorption zone 3103, and a high temperature desorption zone 3104. The first adsorption reel 310 is a zeolite concentration revolver or a concentrated revolving wheel of other materials, and an exhaust gas intake line 311 is connected to one side A of the adsorption zone 3101 of the first adsorption reel 310, so that The adsorption zone 3101 of the first adsorption runner 310 can adsorb the organic matter in the exhaust gas intake pipe 311, and the other side B of the adsorption zone 3101 of the first adsorption runner 310 and the first clean air discharge One end of the pipeline 312 is connected, and the exhaust gas is adsorbed by the adsorption zone 3101 of the first adsorption runner 310 and then transported by the first clean gas discharge pipeline 312.

The side A of the cooling zone 3102 of the first adsorption wheel 310 is connected to a first cooling gas inlet pipe 313 for gas to enter the first adsorption wheel 310. The cooling zone 3102 is used for cooling, and the other side B of the cooling zone 3102 of the first adsorption wheel 310 is connected to a first cooling gas delivery line 314, and the other end of the first cooling gas delivery line 314 is Connected to the first heating device 330, wherein the first heating device 330 is any one of a heater, a pipe heater or a heat exchanger, and the heater (not shown) is a heating wire, an electric heating pipe or an electric heating device. In any of the sheets, the duct heater (not shown) is any one of a gaseous fuel or a liquid fuel. One end of the first hot gas delivery line 315 is connected to the other side B of the desorption area 3103 of the first adsorption reel 310, and the other end of the first hot gas delivery line 315 is the first The heating device 330 is connected to transmit the high-temperature hot gas heated or exchanged by the first heating device 330 to the desorption region 3103 of the first adsorption reel 310 through the first hot gas delivery line 315. Attached to use.

The cooling zone 3102 of the first adsorption wheel 310 is provided with two embodiments, wherein the first embodiment is the first cooling gas connected to one side A of the cooling zone 3102 of the first adsorption wheel 310. The intake line 313 is for fresh air or external air (as shown in FIG. 5), and the cooling zone 3102 for the first adsorption wheel 310 is cooled by the fresh air or the external air. In another embodiment, the exhaust gas inlet line 311 is provided with an exhaust gas communication line 381, and the other end of the exhaust gas communication line 381 is connected to the first cooling gas inlet line 313 (for example, the sixth As shown in the figure, the exhaust gas in the exhaust gas intake pipe 311 can be sent to the cooling zone 3102 of the first adsorption runner 310 through the exhaust gas communication line 381 for cooling use, and the exhaust gas communication pipe The 381 is provided with an exhaust gas communication control valve 3811 for controlling the air volume of the exhaust gas communication line 381.

Another end of the first desorption concentrated gas line 316 is coupled to the first suction One side A of the desorption zone 3103 of the reel 310 is connected, and the other end of the first desorption concentrate gas line 316 is connected to the incinerator 300, and when the incinerator 300 is a regenerative incinerator (RTO) The regenerative incinerator (RTO) is provided with an inlet 301 and an outlet 302, and the inlet 301 is connected to the first desorbed concentrated gas line 316 so as to be desorbed by high temperature desorption. The concentrated gas is sent to the inlet 301 of the regenerative incinerator (RTO) through the first desorbed concentrated gas line 316, and the desorbed concentrated gas can enter the regenerative incinerator (RTO) for pyrolysis. The volatile organic compound is reduced, and the outlet 302 of the regenerative incinerator (RTO) is connected to a chimney 370 to discharge the clean gas after pyrolysis of the organic matter from the chimney 370, and the first desorption is concentrated. The gas line 316 is provided with a fan 3161 to push and pull the desorbed concentrated gas into the inlet 301 of the regenerative incinerator (RTO) to allow the desorbed concentrated gas to be pyrolyzed.

The third implementation architecture of the present invention (as shown in FIGS. 5 and 6) mainly includes the first adsorption reel 310, in addition to the adsorption zone 3101, the cooling zone 3102, and the desorption zone 3103. The high temperature desorption zone 3104 can be used to remove the residual high boiling organic matter (VOC) when it is used for ON LINE, so that the first adsorption reel 310 can restore its adsorption capacity and make the first adsorption. The runner 310 can have four zones. The other side B of the high temperature desorption zone 3104 of the first adsorption reel 310 is connected to one end of a second hot gas delivery line 317, and the other end of the second hot gas delivery line 317 is connected to the second end. The heating device 340 is connected, wherein the second heating device 340 is any one of a heater, a pipe heater or a heat exchanger, and the heater (not shown) is a heating wire, an electric heating pipe or a heating film. First, the pipeline heater (not shown) is any one of a gaseous fuel or a liquid fuel. The first hot gas delivery line 315 is provided with a first hot gas bypass. The other end of the first hot gas bypass line 391 is connected to the second heating device 340 to partially divert and pass the high-temperature hot gas energy heated or exchanged by the first heating device 330. The first hot gas bypass line 391 is sent to the second heating device 340 to raise the high temperature hot gas entering the second hot gas delivery line 317 to a certain temperature (for example, 300 ° C), and the second The high temperature hot gas in the hot gas delivery line 317 is again sent to the high temperature desorption zone 3104 of the first adsorption reel 310 for high temperature desorption, and the first hot gas bypass line 391 is provided with a first hot gas. The control valve 3911 is bypassed to control the amount of wind of the first hot gas bypass line 391.

Furthermore, one side A of the high temperature desorption zone 3104 of the first adsorption reel 310 is connected to a first high temperature desorption concentrated gas line 318, and the other end of the first high temperature desorption concentrated gas line 318 is And connecting to the first desorption concentrated gas line 316 to pass the high-temperature desorption concentrated gas desorbed through the high-temperature desorption zone 3104 of the first adsorption reel 310 through the first high-temperature desorption concentrated gas pipe The road 318 is sent to the first desorbed concentrated gas line 316, and then sent to the inlet 301 of the regenerative incinerator (RTO) through the first desorbed concentrated gas line 316 to allow the high temperature desorption of the concentrated gas. The desorption concentrated gas in the first desorbed concentrated gas line 316 enters the regenerative incinerator (RTO) for pyrolysis.

The second adsorption runner 320 is a zeolite concentration runner or a concentrated runner of other materials, and the second adsorption runner 320 is provided with an adsorption zone 3201, a cooling zone 3202, a desorption zone 3203, and a high temperature off. The area 3204, and the side A of the adsorption zone 3201 of the second adsorption runner 320 is connected to the other end of the first clean gas discharge line 312 to make the gas in the first clean gas discharge line 312 Can be directly delivered to the second suction The adsorption zone 3201 of the reel wheel 320 is adsorbed, and the other side B of the adsorption zone 3201 of the second adsorption reel 320 is connected to a second clean gas discharge pipe 321, and the second clean gas discharge pipe is connected. The other end of the 321 is connected to a chimney 370 for facilitating the passage of the gas adsorbed by the adsorption zone 3101 of the first adsorption reel 310 and the adsorption zone 3201 of the second adsorption reel 320 through the chimney 370. The second clean air discharge line 321 is provided with a fan 3211 to increase the flow rate of the gas to flow to the chimney 370.

The other side B of the cooling zone 3202 of the second adsorption wheel 320 is connected to a second cooling gas inlet line 322 for gas to enter the cooling zone 3202 of the second adsorption wheel 320 for cooling use. One side A of the cooling zone 3202 of the second adsorption runner 320 is connected to a second cooling gas delivery line 323, and the other end of the second cooling gas delivery line 323 is connected to the third heating device 350. The third heating device 350 is any one of a heater, a pipe heater or a heat exchanger, and the heater (not shown) is any one of a heating wire, an electric heating pipe or a heating plate, and the pipe is heated. The device (not shown) is either a gaseous fuel or a liquid fuel. One end of the third hot gas delivery line 324 is connected to one side A of the desorption area 3203 of the second adsorption reel 320, and the other end of the third hot gas delivery line 324 is connected to the third heating. The device 350 is connected to transmit the high-temperature hot gas heated or exchanged by the third heating device 350 to the desorption region 3203 of the second adsorption reel 320 through the third hot gas delivery line 324 for desorption. use.

The cooling zone 3202 of the second adsorption runner 320 is provided with two embodiments, wherein the first embodiment is the cooling zone 32 of the second adsorption runner 320. The second cooling gas intake line 322 connected to the other side B of 02 is for fresh air or external air to enter (as shown in FIG. 5), and the second adsorption transfer is provided by the fresh air or external air. The cooling zone 3202 of the wheel 320 is cooled. In another embodiment, the second clean air discharge line 321 is provided with a second clean air communication line 383, and the other end of the second clean air communication line 383 is connected to the second cooling air intake. A line 322 is connected (as shown in FIG. 6) to transmit the gas in the second clean gas discharge line 321 to the second adsorption wheel 320 through the second clean gas communication line 383. The area 3202 is used for cooling, and the second clean air communication line 383 is provided with a second clean air communication control valve 3831 to control the air volume of the second clean air communication line 383.

Another end of the second desorbed concentrated gas line 325 is connected to the other side B of the desorption zone 3203 of the second adsorption reel 320, and the other end of the second desorbed concentrated gas line 325 is Connected to the incinerator 300, and when the incinerator 300 is a regenerative incinerator (RTO), the regenerative incinerator (RTO) is provided with an inlet 301 and an outlet 302, and the inlet 301 is connected to the second A concentrated gas line 325 is connected to enable the desorbed concentrated gas desorbed by the high temperature to be sent to the inlet 301 of the regenerative incinerator (RTO) through the second desorbed concentrated gas line 325. The concentrated gas can enter the regenerative incinerator (RTO) for pyrolysis to reduce volatile organic compounds, and the regenerative incinerator (RTO) outlet 302 is connected to the chimney 370 for pyrolysis The clean gas after the organic matter can be discharged from the chimney 370, and the second desorbed concentrated gas line 325 is provided with a fan 3251 to push and pull the desorbed concentrated gas into the inlet of the regenerative incinerator (RTO). In 301, the desorbed concentrated gas is allowed to undergo high temperature cracking.

And the third implementation framework of this creation (as shown in Figures 5 and 6) is mainly In addition to the adsorption zone 3201, the cooling zone 3202 and the desorption zone 3203, the second adsorption reel 320 is provided with a high temperature desorption zone 3204 for use in online operation (ON LINE). The high boiling organic matter (VOC) is released, allowing the second adsorption runner 320 to recover its adsorption capacity, so that the second adsorption runner 320 can have four regions. One side A of the high temperature desorption zone 3204 of the second adsorption reel 320 is connected to one end of a fourth hot gas delivery line 326, and the other end of the fourth hot gas delivery line 326 is connected to the fourth heating. The device 360 is connected, wherein the fourth heating device 360 is any one of a heater, a pipe heater or a heat exchanger, and the heater (not shown) is any one of a heating wire, an electric heating tube or a heating sheet. The pipeline heater (not shown) is any one of a gaseous fuel or a liquid fuel. The third hot gas delivery line 324 is provided with a third hot gas bypass line 392, and the other end of the third hot gas bypass line 392 is connected to the fourth heating device 360 so as to be able to pass through the third The high temperature hot gas that is heated or exchanged by the heating device 350 is partially shunted and delivered to the fourth heating device 360 through the third hot gas bypass line 392 to enter the fourth hot gas delivery line 326. The high temperature hot gas can be raised to a certain temperature (for example, 300 ° C), and the high temperature hot gas in the fourth hot gas delivery line 326 is re-delivered to the high temperature desorption zone 3204 of the second adsorption reel 320 for high temperature desorption. The third hot gas bypass line 392 is provided with a third hot gas bypass control valve 3921 to control the air volume of the third hot gas bypass line 392.

Furthermore, the other side B of the high temperature desorption zone 3204 of the second adsorption reel 320 is connected to a second high temperature desorption concentrated gas line 327, and the other end of the second high temperature desorption concentrated gas line 327 is connected. Is connected to the second desorbed concentrated gas line 325 to desorb the high temperature desorbed by the high temperature desorption zone 3204 of the second adsorption reel 320 The concentrated gas can be delivered to the second desorbed concentrated gas line 325 through the second high temperature desorbed concentrated gas line 327, and then sent to the regenerative incinerator through the second desorbed concentrated gas line 325 ( The inlet 301 of the RTO) allows the high temperature desorption concentrated gas to enter the regenerative incinerator (RTO) together with the desorbed concentrated gas in the second desorbed concentrated gas line 325 for pyrolysis.

The fourth embodiment of the present invention (as shown in Figures 7 and 8) has a high-speed desorption double-rotor system, mainly through an incineration device 400, a first adsorption reel 410, and a first A combination of a heating device 430, a second heating device 440, a second adsorption wheel 420, a third heating device 450, a fourth heating device 460, and a chimney 470. The difference between the fourth implementation architecture of the present invention and the first implementation architecture of the present invention is that the pipelines and devices connected to one side A and the other side B of the first adsorption runner 410 are in opposite directions. The piping and the device connected to one side A and the other side B of the second adsorption reel 420 are unchanged. The following will further explain the content of the fourth implementation framework of this creation.

The incinerator 400 is a direct combustion incinerator (TO) (not shown), a catalytic converter (not shown) or a regenerative incinerator (RTO), and the fourth type of creation. The embodiment of the implementation architecture is exemplified by a regenerative incinerator (RTO), and the incinerator 400 described below is a regenerative incinerator (RTO), but the incinerator 400 of the fourth embodiment of the present invention does not store heat. In the case of a type incinerator (RTO), it can also be a direct-fired incinerator (TO) (not shown) or a catalytic converter (not shown).

The first adsorption revolving 410 of the fourth implementation framework of the present invention (as shown in FIGS. 7 and 8) is provided with an adsorption zone 4101, a cooling zone 4102, a desorption zone 4103, and a high temperature desorption zone 4104. The first adsorption runner 410 is a zeolite concentration runner or a concentrating wheel of another material, and an exhaust gas intake line 411 is connected to one side A of the adsorption zone 4101 of the first adsorption wheel 410, so that the adsorption zone 4101 of the first adsorption wheel 410 can adsorb the The organic matter in the exhaust gas intake pipe 411, and the other side B of the adsorption zone 4101 of the first adsorption runner 410 is connected to one end of the first clean air discharge pipe 412, so that the exhaust gas passes through the first The adsorption zone 4101 of the adsorption reel 410 is transported by the first clean gas discharge line 412 after adsorbing organic matter.

The other side B of the cooling zone 4102 of the first adsorption wheel 410 is connected to a first cooling gas inlet pipe 413 for gas to enter the cooling zone 4102 of the first adsorption wheel 410 for cooling use. One side A of the cooling zone 4102 of the first adsorption wheel 410 is connected to a first cooling gas delivery line 414, and the other end of the first cooling gas delivery line 414 is connected to the first heating device 430. The first heating device 430 is any one of a heater, a pipe heater or a heat exchanger, and the heater (not shown) is any one of a heating wire, an electric heating pipe or a heating plate, and the pipe is heated. The device (not shown) is either a gaseous fuel or a liquid fuel. One end of the first hot gas delivery line 415 is connected to the side A of the desorption area 4103 of the first adsorption reel 410, and the other end of the first hot gas delivery line 415 is connected to the first heating. The device 430 is connected to transmit the high-temperature hot gas heated or exchanged by the first heating device 430 through the first hot gas delivery line 415 to the desorption region 4103 of the first adsorption reel 410 for desorption. use.

The cooling zone 4102 of the first adsorption wheel 410 is provided with two embodiments, wherein the first embodiment is the first cooling connected to the other side B of the cooling zone 4102 of the first adsorption wheel 410. The air intake line 413 is for fresh air or outside The gas enters (as shown in Fig. 7), and the cooling zone 4102 of the first adsorption turret 410 is cooled by the fresh air or the external air. In another embodiment, the first clean air discharge line 412 is provided with a first clean air first communication line 484, and the other end of the first clean air first communication line 484 is a first cooling gas intake line 413 is connected (as shown in FIG. 8) to pass the first clean air first communication line 484 to pass the first clean air discharge line 412 through the first The gas adsorbed by the adsorption zone 4101 of the adsorption runner 410 is sent to the cooling zone 4102 of the first adsorption runner 410 for cooling use, and the first clean gas first communication conduit 484 is provided with a first net. The gas first communicates with the control valve 4841 to control the amount of air of the first clean gas first communication line 484.

Another end of the first desorbed concentrated gas line 416 is connected to the other side B of the desorption region 4103 of the first adsorption reel 410, and the other end of the first desorption concentrated gas line 416 is Connected to the incineration device 400, and when the incinerator 400 is a regenerative incinerator (RTO), the regenerative incinerator (RTO) is provided with an inlet 401 and an outlet 402, and the inlet 401 is connected to the first A concentrated gas line 416 is connected to enable the desorbed concentrated gas desorbed at a high temperature to be transmitted to the inlet 401 of the regenerative incinerator (RTO) through the first desorbed concentrated gas line 416. The concentrated gas can enter the regenerative incinerator (RTO) for pyrolysis to reduce volatile organic compounds, and the regenerative incinerator (RTO) outlet 402 is connected to a chimney 470 for pyrolysis The clean gas after the organic matter can be discharged from the chimney 470, and the first desorbed concentrated gas line 416 is provided with a fan 4161 to push and pull the desorbed concentrated gas into the inlet of the regenerative incinerator (RTO). In 401, the desorbed concentrated gas is allowed to undergo high temperature cracking.

The fourth implementation framework of this creation (as shown in Figures 7 and 8) is mainly In addition to the adsorption zone 4101, the cooling zone 4102 and the desorption zone 4103, the first adsorption reel 410 is provided with a high temperature desorption zone 4104 for use in online operation (ON LINE). The high boiling organic matter (VOC) is released, allowing the first adsorption runner 410 to recover its adsorption capacity, so that the first adsorption runner 410 can have four regions. One side A of the high temperature desorption zone 4104 of the first adsorption reel 410 is connected to one end of a second hot gas delivery line 417, and the other end of the second hot gas delivery line 417 is coupled to the second heating. The device 440 is connected, wherein the second heating device 440 is any one of a heater, a pipe heater or a heat exchanger, and the heater (not shown) is any one of a heating wire, an electric heating tube or a heating sheet. The pipeline heater (not shown) is any one of a gaseous fuel or a liquid fuel. The first hot gas delivery line 415 is provided with a first hot gas bypass line 491, and the other end of the first hot gas bypass line 491 is connected to the second heating device 440 so as to be able to pass the first The high temperature hot gas that is heated or exchanged by the heating device 430 can be partially shunted and sent to the second heating device 440 through the first hot gas bypass line 491 to enter the second hot gas delivery line 417. The high temperature hot gas can be raised to a certain temperature (for example, 300 ° C), and the high temperature hot gas in the second hot gas delivery line 417 is again sent to the high temperature desorption zone 4104 of the first adsorption reel 410 for high temperature desorption. The first hot gas bypass line 491 is provided with a first hot gas bypass control valve 4911 for controlling the air volume of the first hot gas bypass line 491.

Furthermore, the other side B of the high temperature desorption zone 4104 of the first adsorption reel 410 is connected to a first high temperature desorption concentrated gas line 418, and the other end of the first high temperature desorption concentrated gas line 418 Is connected to the first desorbed concentrated gas line 416 to desorb the high temperature desorbed by the high temperature desorption zone 4104 of the first adsorption reel 410 The concentrated gas can be delivered to the first desorbed concentrated gas line 416 through the first high temperature desorption concentrated gas line 418, and then sent to the regenerative incinerator through the first desorbed concentrated gas line 416 ( The inlet 401 of the RTO) allows the high temperature desorption concentrated gas to enter the regenerative incinerator (RTO) together with the desorbed concentrated gas in the first desorbed concentrated gas line 416 for pyrolysis.

The second adsorption runner 420 is a zeolite concentration runner or a concentrated runner of other materials, and the second adsorption runner 420 is provided with an adsorption zone 4201, a cooling zone 4202, a desorption zone 4203, and a high temperature off. An area 4204, and a side A of the adsorption zone 4201 of the second adsorption runner 420 is connected to the other end of the first clean gas discharge line 412 to make the gas in the first clean gas discharge line 412 The second side of the adsorption zone 4201 of the second adsorption wheel 420 is connected to a second clean gas discharge line 421, and the other side B of the adsorption zone 4201 of the second adsorption wheel 420 is directly connected to the adsorption zone 4201. The other end of the second clean gas discharge line 421 is connected to a chimney 470 to facilitate the gas adsorbed by the adsorption zone 4201 of the second adsorption runner 420 through the adsorption zone 4101 of the first adsorption runner 410. The discharge is performed through the chimney 470, wherein the second clean air discharge line 421 is provided with a fan 4211 to increase the flow rate of the gas to the chimney 470.

The side A of the cooling zone 4202 of the second adsorption wheel 420 is connected to a second cooling gas inlet pipe 422 for the gas to enter the cooling zone 4202 of the second adsorption wheel 420 for cooling use. The other side B of the cooling zone 4202 of the second adsorption runner 420 is connected to a second cooling gas delivery line 423, and the other end of the second cooling gas delivery line 423 is connected to the third heating device 450. Wherein the third heating device The 450 is a heater, a pipe heater or a heat exchanger, and the heater (not shown) is any one of a heating wire, an electric heating pipe or a heating plate, and the pipe heater (not shown) ) is the use of either gaseous fuel or liquid fuel. One end of the third hot gas delivery line 424 is connected to the other side B of the desorption area 4203 of the second adsorption reel 420, and the other end of the third hot gas delivery line 424 is connected to the third side. The heating device 450 is connected to transmit the high-temperature hot gas heated or exchanged by the third heating device 450 to the desorption region 4203 of the second adsorption reel 420 through the third hot gas delivery line 424. Attached to use.

The cooling zone 4202 of the second adsorption runner 420 is provided with two embodiments, wherein the first embodiment is the second cooling gas connected to one side A of the cooling zone 4202 of the second adsorption runner 420. The intake line 422 is for fresh air or external air (as shown in FIG. 7), and the cooling zone 4202 for providing the second adsorption wheel 420 is cooled by the fresh air or the external air. In another embodiment, the first clean air discharge line 412 is provided with a first clean air second communication line 485, and the other end of the first clean air second communication line 485 is connected to the second a cooling air intake line 422 is connected (as shown in FIG. 8) to transmit the gas in the first clean air discharge line 412 to the second through the first clean air second communication line 485 The cooling zone 4202 of the adsorption wheel 420 is used for cooling, and the first clean air second communication pipe 485 is provided with a first clean air second communication control valve 4851 to control the first clean air second communication pipe. The amount of air on the road 485.

Another end of the second desorption concentrated gas line 425 is connected to one side A of the desorption region 4203 of the second adsorption reel 420, and the other end of the second desorption concentrated gas line 425 is The incineration device 400 is connected, and when the incineration device 400 is In the regenerative incinerator (RTO), the regenerative incinerator (RTO) is provided with an inlet 401 and an outlet 402, and the inlet 401 is connected to the second desorbed concentrated gas line 425 so as to be able to pass through the high temperature The desorbed concentrated gas is sent to the inlet 401 of the regenerative incinerator (RTO) through the second desorbed concentrated gas line 425 to allow the desorbed concentrated gas to enter the regenerative incinerator (RTO) Pyrolysis is performed to reduce volatile organic compounds, and an outlet 402 of the regenerative incinerator (RTO) is connected to the chimney 470 to discharge clean gas after pyrolysis of organic matter from the chimney 470. The second desorbed concentrated gas line 425 is provided with a blower 4251 to push and pull the desorbed concentrated gas into the inlet 401 of the regenerative incinerator (RTO) to enable the desorbed concentrated gas to be pyrolyzed.

The fourth implementation architecture of the present invention (as shown in FIGS. 7 and 8) mainly includes the second adsorption runner 420, in addition to the adsorption zone 4201, the cooling zone 4202, and the desorption zone 4203. The high temperature desorption zone 4204 can be used to remove the residual high boiling organic matter (VOC) when it is used for ON LINE, so that the second adsorption reel 420 can restore its adsorption capacity and make the second adsorption. The runner 420 can have four zones. The other side B of the high temperature desorption zone 4204 of the second adsorption reel 420 is connected to one end of a fourth hot gas delivery line 426, and the other end of the fourth hot gas delivery line 426 is connected to the fourth The heating device 460 is connected to the heating device 460. The fourth heating device 460 is any one of a heater, a pipe heater or a heat exchanger. The heater (not shown) is a heating wire, an electric heating tube or a heating sheet. First, the pipeline heater (not shown) is any one of a gaseous fuel or a liquid fuel. The third hot gas delivery line 424 is provided with a third hot gas bypass line 492, and the other end of the third hot gas bypass line 492 is connected to the fourth heating device 460 so as to be able to pass through the third Heating device 450 performs heating or heat exchange of high temperature heat The gas energy is partially diverted and delivered to the fourth heating device 460 through the third hot gas bypass line 492 to raise the high temperature hot gas entering the fourth hot gas delivery line 426 to a certain temperature (for example, 300). °C), and the high temperature hot gas in the fourth hot gas delivery line 426 is re-delivered to the high temperature desorption zone 4204 of the second adsorption reel 420 for high temperature desorption, and the third hot gas bypass line The 492 system is provided with a third hot gas bypass control valve 4921 for controlling the air volume of the third hot gas bypass line 492.

Furthermore, one side A of the high temperature desorption zone 4204 of the second adsorption reel 420 is connected to a second high temperature desorption concentrated gas line 427, and the other end of the second high temperature desorption concentrated gas line 427 is Connecting with the second desorption concentrated gas line 425 to pass the high temperature desorption concentrated gas desorbed by the high temperature desorption zone 4204 of the second adsorption reel 420 through the second high temperature desorption concentrated gas pipe The road 427 is sent to the second desorbed concentrated gas line 425, and then sent to the inlet 401 of the regenerative incinerator (RTO) through the second desorbed concentrated gas line 425, so that the high temperature desorbing concentrated gas can The desorbed concentrated gas in the second desorbed concentrated gas line 425 enters the regenerative incinerator (RTO) for pyrolysis.

By the above detailed description, it will be apparent to those skilled in the art that the present invention can achieve the foregoing objectives, and has been in compliance with the provisions of the Patent Law, and has filed a patent application.

However, the above is only the preferred embodiment of the present invention, and the scope of the creation of the present invention cannot be limited by this; therefore, the simple equivalent changes and modifications made by the scope of the patent application and the content of the creation specification are All should remain within the scope of this creation patent.

Claims (18)

A double-rotation system with high temperature desorption includes: an incineration device; a first adsorption reel having an adsorption zone, a cooling zone, a desorption zone and a high temperature desorption zone, The first adsorption reel is connected with an exhaust gas line, a first clean air discharge line, a first cooling gas intake line, a first cooling gas delivery line, a first hot gas delivery line, and a first adsorption gas line. a second hot gas delivery line, a first desorption concentrated gas line and a first high temperature desorption concentrated gas line, one end of the exhaust gas intake line is connected to one side of the adsorption zone of the first adsorption wheel One end of the first clean air discharge pipe is connected to the other side of the adsorption zone of the first adsorption runner, and one end of the first cooling gas intake pipe is connected to the cooling zone of the first adsorption runner One side of the first cooling gas delivery line is connected to the other side of the cooling zone of the first adsorption reel, and one end of the first hot gas delivery line is connected to the first adsorption reel The other side of the desorption zone is connected, and one end of the second hot gas delivery pipe is connected to the first adsorption transfer The other side of the high temperature desorption zone is connected, one end of the first desorption concentrated gas line is connected to one side of the desorption zone of the first adsorption reel, and the first desorption concentrated gas pipeline is further connected One end is connected to the incineration device, and one end of the first high temperature desorption concentrated gas line is connected to one side of the high temperature desorption zone of the first adsorption reel, and the first high temperature desorption concentrate gas line is further One end is connected to the first desorption concentrated gas pipeline; a second adsorption revolving wheel is provided with an adsorption zone, a cooling zone, a desorption zone and a high temperature desorption zone, and the second adsorption converter The wheel train is connected with a second clean air discharge line, a second cooling gas intake line, a second cooling gas delivery line, a third hot gas delivery line, a fourth hot gas delivery line, and a second Desorption concentrated gas line and a second high temperature desorption concentrated gas tube One end of the first clean gas discharge line is connected to one side of the adsorption zone of the second adsorption runner, and one end of the second clean gas discharge pipeline is connected to the adsorption zone of the second adsorption runner. The other side is connected, one end of the second cooling gas inlet pipe is connected to one side of the cooling zone of the second adsorption runner, and one end of the second cooling gas delivery pipe is connected to the second adsorption runner The other side of the cooling zone is connected, one end of the third hot gas delivery pipeline is connected to the other side of the desorption zone of the second adsorption runner, and one end of the fourth hot gas delivery pipeline is connected to the second The other side of the high temperature desorption zone of the adsorption reel is connected, and one end of the second desorption concentrated gas line is connected to one side of the desorption zone of the second adsorption reel, the second desorption concentrated gas pipe The other end of the road is connected to the incineration device, and one end of the second high temperature desorption concentrated gas line is connected to one side of the high temperature desorption zone of the second adsorption reel, and the second high temperature desorption concentrated gas pipe The other end of the road is connected to the second desorption concentrated gas line; a first heating device, the The other end of a cooling gas delivery line is connected to the first heating device, the other end of the first hot gas delivery line is connected to the first heating device; a second heating device, the first hot gas delivery line a first hot gas bypass line is disposed, the other end of the first hot gas bypass line is connected to the second heating device, and the other end of the second hot gas delivery line is connected to the second heating device; a third heating device, the other end of the second cooling gas delivery line is connected to the third heating device, the other end of the third hot gas delivery line is connected to the third heating device; a fourth heating device The third hot gas delivery line is provided with a third hot gas bypass line, and the other end of the third hot gas bypass line is connected to the fourth heating device, and the other end of the fourth hot gas delivery line is Connected to the fourth heating device; and a chimney, the other end of the second clean gas discharge pipe is connected to the chimney. A double-rotation system with high temperature desorption includes: an incineration device; a first adsorption reel having an adsorption zone, a cooling zone, a desorption zone and a high temperature desorption zone, The first adsorption reel is connected with an exhaust gas line, a first clean air discharge line, a first cooling gas intake line, a first cooling gas delivery line, a first hot gas delivery line, and a first adsorption gas line. a second hot gas delivery line, a first desorption concentrated gas line and a first high temperature desorption concentrated gas line, one end of the exhaust gas intake line is connected to one side of the adsorption zone of the first adsorption wheel One end of the first clean air discharge pipe is connected to the other side of the adsorption zone of the first adsorption runner, and one end of the first cooling gas intake pipe is connected to the cooling zone of the first adsorption runner The other side of the first cooling gas delivery line is connected to one side of the cooling zone of the first adsorption reel, and one end of the first hot gas delivery line is connected to the first adsorption reel One side of the detachment zone is connected, and one end of the second hot gas delivery pipe is connected to the first adsorption runner One side of the high temperature desorption zone is connected, and one end of the first desorption concentrated gas line is connected to the other side of the desorption zone of the first adsorption reel, and the other end of the first desorption concentrated gas line is Connected to the incineration device, one end of the first high temperature desorption concentrated gas line is connected to the other side of the high temperature desorption zone of the first adsorption reel, and the first high temperature desorption concentrate gas line is further One end is connected to the first desorption concentrated gas pipeline; a second adsorption revolving wheel is provided with an adsorption zone, a cooling zone, a desorption zone and a high temperature desorption zone, and the second adsorption converter The wheel train is connected with a second clean air discharge line, a second cooling gas intake line, a second cooling gas delivery line, a third hot gas delivery line, a fourth hot gas delivery line, and a second Desorbing a concentrated gas line and a second high temperature desorption concentrated gas line, one end of the first clean gas discharge line is connected to one of the adsorption zones of the second adsorption wheel a side of the second clean gas exhaust line is connected to the other side of the adsorption zone of the second adsorption runner, and one end of the second cooling gas inlet pipe is cooled by the second adsorption runner The other side of the zone is connected, one end of the second cooling gas delivery pipe is connected to one side of the cooling zone of the second adsorption runner, and one end of the third hot gas delivery pipeline is connected to the second adsorption runner One side of the desorption zone is connected, one end of the fourth hot gas delivery pipe is connected to one side of the high temperature desorption zone of the second adsorption reel, and one end of the second desorption concentrated gas pipeline is The other side of the desorption zone of the second adsorption reel is connected, and the other end of the second desorption concentrated gas pipeline is connected to the incineration device, and one end of the second high temperature desorption concentrated gas pipeline is connected to the first The other side of the high temperature desorption zone of the second adsorption rotor is connected, and the other end of the second high temperature desorption concentrated gas pipeline is connected to the second desorption concentrated gas pipeline; a first heating device, the first The other end of the cooling gas delivery line is connected to the first heating device, the first hot gas transmission The other end of the pipeline is connected to the first heating device; a second heating device is provided with a first hot gas bypass pipeline, and the other end of the first hot gas bypass pipeline is Connected to the second heating device, the other end of the second hot gas delivery line is connected to the second heating device; a third heating device, the other end of the second cooling gas delivery line is connected to the third heating The device is connected, the other end of the third hot gas delivery line is connected to the third heating device; a fourth heating device, the third hot gas delivery line is provided with a third hot gas bypass line, the third hot gas The other end of the bypass line is connected to the fourth heating device, the other end of the fourth hot gas delivery line is connected to the fourth heating device; and a chimney, the other end of the second clean gas discharge line It is connected to the chimney. A double-rotor system with high temperature desorption, comprising: An incineration device; a first adsorption reel having an adsorption zone, a cooling zone, a desorption zone and a high temperature desorption zone, wherein the first adsorption reel is connected with an exhaust pipe, a first a clean air discharge line, a first cooling gas inlet line, a first cooling gas delivery line, a first hot gas delivery line, a second hot gas delivery line, and a first desorbed concentrated gas tube And a first high temperature desorption concentrated gas pipeline, one end of the exhaust gas intake pipeline is connected to one side of the adsorption zone of the first adsorption runner, and one end of the first clean gas discharge pipeline is connected thereto The other side of the adsorption zone of the first adsorption runner is connected, and one end of the first cooling gas inlet conduit is connected to one side of the cooling zone of the first adsorption runner, and the first cooling gas delivery pipeline is connected One end is connected to the other side of the cooling zone of the first adsorption wheel, and one end of the first hot gas delivery pipe is connected to the other side of the desorption zone of the first adsorption reel, the second hot gas is conveyed One end of the pipeline is connected to the other side of the high temperature desorption zone of the first adsorption reel, the first off One end of the concentrated gas line is connected to one side of the desorption zone of the first adsorption reel, and the other end of the first desorption concentrated gas line is connected to the incineration device, the first high temperature desorption concentrated gas One end of the pipeline is connected to one side of the high temperature desorption zone of the first adsorption reel, and the other end of the first high temperature desorption concentrate gas pipeline is connected to the first desorption concentrated gas pipeline; a second adsorption reel, the second adsorption reel is provided with an adsorption zone, a cooling zone, a desorption zone and a high temperature desorption zone, and the second adsorption reel is connected with a second clean gas discharge pipe and a second cooling a gas inlet line, a second cooling gas delivery line, a third hot gas delivery line, a fourth hot gas delivery line, a second desorption concentrated gas line, and a second high temperature desorption concentrated gas tube One end of the first clean gas discharge line is connected to one side of the adsorption zone of the second adsorption runner, and one end of the second clean gas discharge pipeline is connected to the adsorption zone of the second adsorption runner. The other side Connecting, one end of the second cooling gas inlet line is connected to the other side of the cooling zone of the second adsorption wheel, and one end of the second cooling gas delivery line is cooled by the second adsorption wheel One side of the zone is connected, one end of the third hot gas delivery pipe is connected to one side of the desorption zone of the second adsorption reel, and one end of the fourth hot gas delivery pipe is connected to the second adsorption reel One side of the high temperature desorption zone is connected, one end of the second desorption concentrated gas line is connected to the other side of the desorption zone of the second adsorption reel, and the other end of the second desorption concentrated gas line is Connected to the incineration device, one end of the second high temperature desorption concentrated gas line is connected to the other side of the high temperature desorption zone of the second adsorption reel, and the second high temperature desorption concentration gas line is further One end is connected to the second desorption concentrated gas line; a first heating device, the other end of the first cooling gas delivery line is connected to the first heating device, and the other end of the first hot gas delivery line Connected to the first heating device; a second heating device, the first heat The conveying pipeline is provided with a first hot gas bypass pipeline, and the other end of the first hot gas bypass pipeline is connected to the second heating device, and the other end of the second hot gas delivery pipeline is connected to the second heating a third heating device, the other end of the second cooling gas delivery pipe is connected to the third heating device, and the other end of the third hot gas delivery pipe is connected to the third heating device; a fourth heating device, the third hot gas delivery line is provided with a third hot gas bypass line, and the other end of the third hot gas bypass line is connected to the fourth heating device, the fourth hot gas delivery line The other end is connected to the fourth heating device; and a chimney, the other end of the second clean air discharge pipe is connected to the chimney. A double-rotation system with high temperature desorption includes: an incineration device; a first adsorption wheel, the first adsorption wheel is provided with an adsorption zone, a cooling zone, a desorption zone and a high temperature desorption zone, and the first adsorption rotor is connected with an exhaust gas pipeline and a first clean gas discharge a pipeline, a first cooling gas inlet pipeline, a first cooling gas delivery pipeline, a first hot gas delivery pipeline, a second hot gas delivery pipeline, a first desorption concentrated gas pipeline, and a first a high temperature desorption concentrated gas pipeline, one end of the exhaust gas intake pipeline is connected to one side of the adsorption zone of the first adsorption runner, and one end of the first clean gas discharge pipeline is connected to the first adsorption converter The other side of the adsorption zone of the wheel is connected, one end of the first cooling gas inlet pipe is connected to the other side of the cooling zone of the first adsorption wheel, and one end of the first cooling gas delivery pipe is connected One side of the cooling zone of the first adsorption runner is connected, one end of the first hot gas delivery pipeline is connected to one side of the desorption zone of the first adsorption reel, and one end of the second hot gas delivery pipeline is Connected to one side of the high temperature desorption zone of the first adsorption reel, the first desorption concentrated gas line The end system is connected to the other side of the desorption zone of the first adsorption reel, and the other end of the first desorption concentrated gas line is connected to the incineration device, and the first high temperature desorbs one end of the concentrated gas pipeline Connected to the other side of the high temperature desorption zone of the first adsorption reel, the other end of the first high temperature desorption concentrated gas line is connected to the first desorption concentrated gas line; The second adsorption reels are provided with an adsorption zone, a cooling zone, a desorption zone and a high temperature desorption zone, and the second adsorption reel is connected with a second clean gas discharge pipe and a second cooling gas intake. a pipeline, a second cooling gas delivery pipeline, a third hot gas delivery pipeline, a fourth hot gas delivery pipeline, a second desorption concentrated gas pipeline, and a second high temperature desorption concentrated gas pipeline, One end of the first clean air discharge pipe is connected to one side of the adsorption zone of the second adsorption runner, and one end of the second clean gas discharge pipe is connected to the other side of the adsorption zone of the second adsorption runner Connecting, one end of the second cooling gas inlet pipe is connected to the cooling zone of the second adsorption runner a side connection, one end of the second cooling gas delivery line is connected to the other side of the cooling zone of the second adsorption reel, and one end of the third hot gas delivery line is desorbed from the second adsorption reel The other side of the zone is connected, one end of the fourth hot gas delivery pipe is connected to the other side of the high temperature desorption zone of the second adsorption reel, and one end of the second desorption concentrated gas pipeline is connected to the first One side of the desorption zone of the second adsorption rotor is connected, and the other end of the second desorption concentrated gas pipeline is connected to the incineration device, and one end of the second high temperature desorption concentrated gas pipeline is connected to the second adsorption One side of the high temperature desorption zone of the runner is connected, and the other end of the second high temperature desorption concentrated gas pipeline is connected to the second desorption concentrated gas pipeline; a first heating device, the first cooling gas is delivered The other end of the pipeline is connected to the first heating device, the other end of the first hot gas delivery pipeline is connected to the first heating device; and a second heating device is provided with a first hot gas delivery pipeline a hot gas bypass line, the other end of the first hot gas bypass line Connected to the second heating device, the other end of the second hot gas delivery line is connected to the second heating device; a third heating device, the other end of the second cooling gas delivery line is connected to the third heating The device is connected, the other end of the third hot gas delivery line is connected to the third heating device; a fourth heating device, the third hot gas delivery line is provided with a third hot gas bypass line, the third hot gas The other end of the bypass line is connected to the fourth heating device, the other end of the fourth hot gas delivery line is connected to the fourth heating device; and a chimney, the other end of the second clean gas discharge line It is connected to the chimney. The double-rotation system with high temperature desorption described in claim 1, 2, 3 or 4, wherein the incinerator is further a direct-fired incinerator (TO), a catalytic converter or a regenerative incinerator Any of (RTO). The double-rotation system with high temperature desorption according to claim 5, wherein the regenerative incinerator (RTO) is provided with an inlet and an outlet, and the inlet is connected to the desorption concentrated gas pipeline, The exit is connected to the chimney. The double-rotor system with high-temperature desorption as described in claim 1, 2, 3 or 4, wherein the first heating device, the second heating device, the third heating device, and the fourth heating device are further Any one of a heater, a pipe heater or a heat exchanger, wherein the heater is any one of a heating wire, an electric heating tube or a heating sheet, and the line heater is any one of a gaseous fuel or a liquid fuel. The double-rotor system with high-temperature desorption as described in claim 1, 2, 3 or 4, wherein the first hot gas bypass line is further provided with a first hot gas bypass control valve to control the The amount of air in the hot gas bypass line. The double-rotor system with high-temperature desorption as described in claim 1, 2, 3 or 4, wherein the third hot gas bypass line is further provided with a third hot gas bypass control valve to control the The amount of air in the hot gas bypass line. The double-rotation system with high-temperature desorption according to claim 1 or 3, wherein the exhaust gas intake pipe is further provided with an exhaust gas communication pipe, the exhaust gas communication pipe and the first cooling gas The intake pipe is connected, and the exhaust gas communication pipe is further provided with an exhaust gas communication control valve to control the air volume of the exhaust gas communication pipe. The double-rotation system with high-temperature desorption according to claim 1, wherein the first clean air discharge pipeline is further provided with a first clean air communication pipeline, and the first clean air communication pipeline The second clean air intake pipeline is further connected with a first clean air communication control valve to control the air volume of the first clean air communication pipeline. The double-rotation system with high-temperature desorption according to claim 2, wherein the first clean air discharge pipeline is further provided with a first clean air communication pipeline, and the first clean air communication pipeline system The first clean air inlet line is further connected with a first clean air communication control valve to control the air volume of the first clean air communication line. The double-rotation system with high-temperature desorption as described in claim 2 or 3, wherein the second clean air discharge line is further provided with a second clean air communication line, the second clean air communication tube The road system is connected to the second cooling gas intake pipeline, and the second clean air communication pipeline is further provided with a second clean air communication control valve to control the air volume of the second clean air communication pipeline. The double-rotation system with high temperature desorption according to claim 4, wherein the first clean air discharge pipeline is further provided with a first clean air first communication pipeline, the first clean air pipeline a communication line is connected to the first cooling gas inlet pipe, and the first clean gas first communication pipe is further provided with a first clean air first communication control valve to control the first net The air volume of the first communication line of the gas. The double-rotation system with high temperature desorption according to claim 4, wherein the first clean air discharge pipeline is further provided with a first clean air second communication pipeline, the first clean air second The connecting pipeline is connected to the second cooling gas inlet pipeline, and the first clean air second communication pipeline is further provided with a first clean air second communication control valve to control the first clean air second communication The air volume of the pipeline. The double-rotation system with high temperature desorption as described in claim 1, 2, 3 or 4, wherein the first desorbed concentrated gas line is further provided with a fan. The double-rotation system with high temperature desorption as described in claim 1, 2, 3 or 4, wherein the second desorbed concentrated gas line is further provided with a fan. The single-rotation system with high temperature desorption described in claim 1, 2, 3 or 4, wherein the second clean air discharge line is further provided with a fan.