TWI811690B - Rotor system with heat medium oil and method thereof - Google Patents

Abstract

The invention is a runner system with heat medium oil and a method thereof. It is mainly designed by adding a heat medium oil system. The heat medium oil system is provided with a heat medium oil tank, an air inlet heat exchanger and a furnace heat exchanger. Exchanger, the inlet heat exchanger is located on the exhaust gas inlet pipeline, and the furnace heat exchanger is located in the furnace of the direct-fired incinerator (TO), so that the source exhaust gas can pass through the inlet heat exchanger The hot side pipeline of the furnace is heated, and the incinerated gas can be processed through the hot side pipeline of the furnace heat exchanger and circulated back and forth through the heat medium oil system to improve the organic waste gas treatment efficiency.

Description

Rotary system with heat medium oil and method thereof

The present invention relates to a runner system with heat transfer oil and a method thereof, and in particular, to an organic waste gas treatment system or similar equipment that improves organic waste gas treatment efficiency and is suitable for the semiconductor industry, optoelectronics industry or chemical-related industries.

According to the current situation, volatile organic gases (VOC) are generated in the manufacturing and production process of the semiconductor industry or optoelectronic industry. Therefore, processing equipment for processing volatile organic gases (VOC) will be installed in each factory area to avoid the occurrence of volatile organic gases. (VOC) are directly discharged into the air causing air pollution. At present, most of the concentrated gas desorbed by the treatment equipment is transported to the incinerator for combustion, and then the burned gas is transported to the chimney for discharge.

However, in recent years, the government has attached great importance to air pollution, and has therefore set relevant air quality standards for chimney emission standards. At the same time, it will be reviewed periodically in accordance with the development of international regulatory trends.

Therefore, in view of the above-mentioned shortcomings, the inventor hopes to propose a runner system with heat medium oil and a method thereof that can improve the efficiency of organic waste gas treatment, so that the user can easily operate and assemble it, and has devoted himself to research, design and assembly. In order to provide user convenience, this is the motivation for the invention that the inventor intends to develop.

The main purpose of the present invention is to provide a runner system with heat medium oil and its The method is mainly by adding a heat medium oil system to the design. The heat medium oil system is equipped with a heat medium oil tank, an air inlet heat exchanger and a furnace heat exchanger. The air inlet heat exchanger is located in the exhaust gas On the air inlet pipe, the furnace heat exchanger is installed in the furnace of the direct-fired incinerator (TO), so that the source exhaust gas can be heated through the hot side pipe of the air inlet heat exchanger, and after incineration The gas can be processed through the hot side pipeline of the furnace heat exchanger and circulated back and forth through the thermal oil system, thereby improving the organic waste gas treatment efficiency and thereby increasing the overall practicality.

Another object of the present invention is to provide a runner system with heat medium oil and a method thereof, wherein the heat medium oil system is composed of a heat medium oil tank, an air inlet heat exchanger and a furnace heat exchanger. The heat medium oil tank of the heat medium oil system uses heat medium as the heat source, and the heat medium is liquid oil. The heat medium can pass through the air inlet heat medium oil output pipeline and the inlet heat medium oil input pipeline. The furnace heat medium oil output pipeline and the furnace heat medium oil input pipeline are used for cyclic heating, so that the relative humidity of the source exhaust gas can be reduced through circulation, thereby improving the adsorption efficiency into the adsorption zone of the adsorption wheel. , thereby increasing the overall adsorption property.

The second object of the present invention is to provide a rotor system with heat transfer oil and a method thereof. The desorption zone of the adsorption rotor needs to be carried out through hot gas. There are two sources of hot gas. The first one is The direct-fired incinerator (TO) is provided with a third heat exchanger. The third heat exchanger is located between the furnace heat exchanger and the first heat exchanger or between the second heat exchanger. between the furnace heat exchanger, and one end of the hot gas delivery pipeline is connected to the other side of the desorption zone of the adsorption rotor, and the other end of the hot gas delivery pipeline is connected to the third heat exchanger The other end of the third cold side pipeline of the device is connected, and the second type is provided with a heater, wherein the heater is an air-to-air heat exchanger, a liquid-to-air heat exchanger, an electric heater, or a gas heater. Any one of them, and the other end of the hot gas delivery pipeline is connected to the heater, and the hot gas delivery pipeline One end is connected to the other side of the desorption zone of the adsorption wheel, so that the desorption zone of the adsorption wheel can have a high-temperature desorption effect, thereby increasing the overall operability.

In order to further understand the features, characteristics and technical content of the present invention, please refer to the following detailed description and drawings of the present invention. However, the attached drawings are only for reference and illustration and are not intended to limit the present invention.

10: Direct-fired incinerator (TO)

101:Stove

102:furnace

11: Entrance

12:Export

20:First heat exchanger

21: First cold side pipeline

22:First hot side pipe

30: Second heat exchanger

31: Second cold side pipeline

32:Second hot side pipe

40:Third heat exchanger

41:Third cold side pipeline

42:Third hot side pipe

50:Heater

61: First cold side delivery pipeline

62: Second cold side delivery pipeline

70:Adsorption wheel

701: Adsorption area

702: Cooling area

703:Desorption zone

71:Exhaust gas intake pipe

711:Exhaust gas connecting pipe

7111: Exhaust gas connection control valve

712:Fan

72: Clean gas discharge pipeline

721:Fan

73: Cooling air intake pipe

74: Cooling air delivery pipeline

75:Hot gas delivery pipeline

76:Desorption concentrated gas pipeline

761:Fan

80:Chimney

90:Heat medium oil system

91:Heating medium oil tank

911: Intake heat medium oil output pipeline

912: Intake heat medium oil input pipeline

913: Furnace heat medium oil output pipeline

914: Furnace heat medium oil input pipeline

92:Inlet air heat exchanger

921:Cold side pipeline

922:Hot side pipe

93: Furnace heat exchanger

931:Cold side pipeline

932:Hot side pipe

S100: Source waste gas for transportation

S110: Source exhaust gas passes through the intake heat exchanger

S120: Adsorption wheel for adsorption

S130: Input cooling zone cooling air

S140: Desorption zone for desorption

S150: Desorption concentrated gas transportation

S160: Transportation of gas after incineration

S170: The incinerated gas passes through the furnace heat exchanger

S180: Gas outlet output after incineration

S200: Source waste gas for transportation

S210: Source exhaust gas passes through the intake heat exchanger

S220: Adsorption wheel for adsorption

S230: Input cooling zone cooling air

S240: Desorption in desorption zone

S250: Desorption concentrated gas transportation

S260: Transport the incinerated gas

S270: The incinerated gas passes through the furnace heat exchanger

S280: Gas outlet output after incineration

S300: Source waste gas for transportation

S310: Source exhaust gas passes through the intake heat exchanger

S320: Adsorption wheel for adsorption

S330: Input cooling zone cooling air

S340: Desorption zone for desorption

S350: Desorption concentrated gas transportation

S360: Transport the incinerated gas

S370: The incinerated gas passes through the furnace heat exchanger

S380: Gas outlet output after incineration

Figure 1 is a schematic system architecture diagram of a main implementation aspect of the present invention.

Figure 2 is a schematic diagram of a system architecture with a fan according to a main implementation aspect of the present invention.

Figure 3 is a schematic diagram of the system architecture at different positions of the third heat exchange device in the main implementation aspect of the present invention.

Figure 4 is a schematic diagram of the system architecture of different positions of the third heat exchange device and the fan in the main implementation form of the present invention.

Figure 5 is a schematic system architecture diagram of another implementation aspect of the present invention.

Figure 6 is a schematic diagram of a system architecture with a fan according to another embodiment of the present invention.

Figure 7 is a step flow chart of a main implementation aspect of the present invention.

Figure 8 is a step flow chart of the second embodiment of the present invention.

Figure 9 is a step flow chart of a third implementation aspect of the present invention.

Please refer to Figures 1 to 9, which are schematic diagrams of embodiments of the present invention. The best implementation mode of the runner system with thermal oil and the method of the present invention is applied to the semiconductor industry, optoelectronics industry or chemical related industries. Volatile organic waste gas treatment systems or similar equipment to have enhanced Organic waste gas treatment efficiency.

The runner system with heat medium oil of the present invention mainly includes a direct-fired incinerator (TO) 10, a first heat exchanger 20, a second heat exchanger 30, a third heat exchanger 40, The combined design of a first cold-side delivery pipeline 61, a second cold-side delivery pipeline 62, an adsorption wheel 70, a chimney 80 and a heat medium oil system 90 (as shown in Figures 1 to 2 ), wherein the first heat exchanger 20 is provided with a first cold side pipeline 21 and a first hot side pipeline 22, and the second heat exchanger 30 is provided with a second cold side pipeline 31 and a second hot side pipeline. Side pipe 32, the third heat exchanger 40 is provided with a third cold side pipe 41 and a third hot side pipe 42. In addition, the direct-fired incinerator (TO) 10 is provided with a burner 101 and a furnace 102. The burner 101 is connected with the furnace 102, and the first heat exchanger 20, the second heat exchanger 30 and The third heat exchangers 40 are respectively disposed in the furnace 102 of the direct-fired incinerator (TO) 10, and the direct-fired incinerator (TO) 10 is provided with an inlet 11 and an outlet 12, and the inlet 11 is It is located at the burner head 101, and the outlet 12 of the direct-fired incinerator (TO) 10 is connected to the chimney 80, thereby allowing organic waste gas to enter the burner head 101 through the inlet 11 for combustion. The burned gas can then pass through the furnace 102 and be discharged from the outlet 12 to the chimney 80 for discharge, thereby saving energy.

In addition, the adsorption wheel 70 of the present invention is provided with an adsorption area 701, a cooling area 702 and a desorption area 703. The adsorption wheel 70 is connected to a waste gas inlet pipeline 71, a clean gas discharge pipeline 72, and a cooling gas. An air intake pipeline 73, a cooling gas delivery pipeline 74, a hot gas delivery pipeline 75 and a desorption concentrated gas pipeline 76 (as shown in Figures 1 to 2). The adsorption wheel 70 is a zeolite concentration wheel or a concentration wheel made of other materials. One end of the exhaust gas inlet pipe 71 is connected to one side of the adsorption area 701 of the adsorption wheel 70, The exhaust gas inlet pipe 71 can transport the source exhaust gas to one side of the adsorption zone 701 of the adsorption wheel 70 , and one end of the clean gas discharge pipe 72 is connected to the other end of the adsorption zone 701 of the adsorption wheel 70 . One side is connected, and the other end of the clean air discharge pipe 72 is connected to the chimney 80, and the clean air discharge pipe 72 is provided with a fan 721 (as shown in Figure 2), so that the air can be emitted through the fan 721. The adsorbed gas in the clean gas discharge pipe 72 is pushed and pulled into the chimney 80 for discharge.

In addition, one side of the cooling zone 702 of the adsorption wheel 70 is connected to the cooling gas inlet pipe 73 for gas to enter the cooling zone 702 of the adsorption wheel 70 for cooling. The cooling of the adsorption wheel 70 The other side of the zone 702 is connected to one end of the cooling air delivery pipeline 74, and the other end of the cooling air delivery pipeline 74 is connected to one end of the third cold side pipeline 41 of the third heat exchanger 40 (such as 1 to 2), the gas entering the cooling zone 702 of the adsorption wheel 70 is transported to the third heat exchanger 40 for heat exchange. Furthermore, one end of the hot gas delivery pipeline 75 is connected to the other side of the desorption zone 703 of the adsorption wheel 70 , and the other end of the hot gas delivery pipeline 75 is connected to the third heat exchanger 40 . The other end of the third cold-side pipeline 41 is connected so that the high-temperature hot gas for heat exchange through the third heat exchanger 40 can be transported to the desorption zone 703 of the adsorption rotor 70 through the hot gas transport pipeline 75 Used for desorption.

The cooling zone 702 of the adsorption wheel 70 is provided with two embodiments. In the first embodiment, the cooling air inlet pipe 73 connected to one side of the cooling zone 702 of the adsorption wheel 70 is Fresh air or outside air is allowed to enter (as shown in Figure 1), and the cooling zone 702 of the adsorption wheel 70 is provided with cooling through the fresh air or outside air. Another second embodiment is that the exhaust gas inlet pipe 71 is provided with an exhaust gas communication pipe 711, and the The other end of the exhaust gas connecting pipe 711 is connected to the cooling air intake pipe 73 (as shown in Figure 2), so that the source exhaust gas in the exhaust gas intake pipe 71 can be passed through the exhaust gas connecting pipe 711. It is transported to the cooling zone 702 of the adsorption wheel 70 for cooling. In addition, the exhaust gas communication pipe 711 is provided with an exhaust gas communication control valve 7111 (as shown in Figure 2) to control the air volume of the exhaust gas communication pipe 711. .

In addition, one end of the desorbed concentrated gas pipeline 76 is connected to one side of the desorption zone 703 of the adsorption wheel 70 , and the other end of the desorbed concentrated gas pipeline 76 is connected to the first heat exchanger 20 One end of the first cold side pipeline 21 is connected, and the other end of the first cold side pipeline 21 of the first heat exchanger 20 is connected to one end of the first cold side delivery pipeline 61. The first cold side The other end of the delivery pipeline 61 is connected to one end of the second cold side pipeline 31 of the second heat exchanger 30, and the other end of the second cold side pipeline 31 of the second heat exchanger 30 is connected to the second cold side pipeline 31 of the second heat exchanger 30. One end of the second cold-side delivery pipeline 62 is connected, and the other end of the second cold-side delivery pipeline 62 is connected with the inlet 11 of the direct-fired incinerator (TO) 10 (as shown in Figures 1 to 2 as shown), so that the desorbed concentrated gas desorbed at high temperature can be transported to one end of the first cold side pipeline 21 of the first heat exchanger 20 through the desorbed concentrated gas pipeline 76, And is transported from the other end of the first cold-side pipeline 21 of the first heat exchanger 20 to one end of the first cold-side transport pipeline 61, and from the other end of the first cold-side transport pipeline 61 to be transported to one end of the second cold side pipeline 31 of the second heat exchanger 30, and then transported to the second cold side through the other end of the second cold side pipeline 31 of the second heat exchanger 30 One end of the transport pipeline 62 is finally transported from the other end of the second cold-side transport pipeline 62 to the inlet 11 of the direct-fired incinerator (TO) 10, so that the direct-fired incinerator (TO) TO) 10 burner 101 to perform high temperature cracking to reduce volatile organic compounds. In addition, the desorption concentrated gas pipeline 76 is provided with a fan 761 (as shown in Figure 2) to push and pull the desorbed concentrated gas into one end of the first cold side pipe 21 of the first heat exchanger 20.

Furthermore, the present invention is mainly designed by adding a heat medium oil system 90. The heat medium oil system 90 is provided with a heat medium oil tank 91, an air intake heat exchanger 92 and a furnace heat exchanger 93, and the heat medium oil system 90 is provided with a heat medium oil tank 91, an air intake heat exchanger 92 and a furnace heat exchanger 93. The medium oil tank 91 is provided with an inlet heat medium oil output pipeline 911, an inlet heat medium oil input pipeline 912, a furnace heat medium oil output pipeline 913 and a furnace heat medium oil input pipeline 914 (as shown in No. 1 (shown in Figure 2 to Figure 2), and the air inlet heat exchanger 92 is located on the exhaust gas inlet pipe 71, and the air inlet heat exchanger 92 is provided with a cold side pipe 921 and a hot side pipe. 922, and one end of the cold side pipeline 921 is connected to the air inlet heat medium oil output pipeline 911 of the heat medium oil tank 91, and the other end of the cold side pipeline 921 is connected to the air inlet of the heat medium oil tank 91 The heat medium oil input pipeline 912 is connected. The exhaust gas from the exhaust gas inlet pipeline 71 first enters one end of the hot side pipeline 922 of the intake heat exchanger 92, and then passes through the hot side of the intake heat exchanger 92. The other end of the pipeline 922 is output and transported to one side of the adsorption area 701 of the adsorption rotor 70 through the exhaust gas inlet pipeline 71 . In addition, the exhaust gas inlet pipe 71 is provided with a fan 712 (as shown in Figure 2) to push and pull the source exhaust gas into one end of the hot side pipe 922 of the intake heat exchanger 92.

In addition, the furnace heat exchanger 93 is located in the furnace 102 of the direct-fired incinerator (TO) 10, and the furnace heat exchanger 93 is provided with a cold side pipeline 931 and a hot side pipeline 932 (as shown in the 1 to 2), and one end of the cold side pipeline 931 is connected to the furnace heat medium oil output pipeline 913 of the heat medium oil tank 91, and the other end of the cold side pipeline 931 is connected to the The furnace heat medium oil input pipeline 914 of the heat medium oil tank 91 is connected, and one end of the hot side pipeline 932 of the furnace heat exchanger 93 is connected to the second end of the second heat exchanger 30 The other end of the hot side pipe 32 is connected (as shown in Figures 1 to 2), and the other end of the hot side pipe 932 of the furnace heat exchanger 93 is connected to the third end of the third heat exchanger 40. One end of the hot side pipe 42 is connected.

The heat medium oil tank 91 of the heat medium oil system 90 mentioned above uses heat medium as the heat source, and the heat medium is liquid oil. The heat medium can pass through the inlet heat medium oil output pipeline 911 and the inlet. The gas heat medium oil input pipeline 912, the furnace heat medium oil output pipeline 913, and the furnace heat medium oil input pipeline 914 are used for cyclic heating, so that the relative humidity of the source exhaust gas can be reduced through circulation, so as to improve Enter the adsorption area 701 of the adsorption wheel 70 to achieve the adsorption efficiency.

The burner head 101 of the above-mentioned direct-fired incinerator (TO) 10 can first transport the incinerated gas to one side of the second hot side pipe 32 of the second heat exchanger 30 for heat exchange. The incinerated gas is then transported from the other side of the second hot side pipe 32 of the second heat exchanger 30 to the hot side pipe 932 of the furnace heat exchanger 93 (as shown in Figure 1 to 2), and after the incinerated gas passes through the hot side pipe 932 of the furnace heat exchanger 93, it is then transported to one side of the third hot side pipe 42 of the third heat exchanger 40 for processing. After heat exchange, the incinerated gas is then transported to the first hot side pipe 22 of the first heat exchanger 20 through the other side of the third hot side pipe 42 of the third heat exchanger 40 one side for heat exchange, and finally transported to the outlet 12 of the direct-fired incinerator (TO) 10 from the other side of the first hot-side pipeline 22 of the first heat exchanger 20, and then from the direct-fired incinerator (TO) 10. The output 12 of the combustion incinerator (TO) 10 is transported to the chimney 80 (as shown in Figures 1 to 2), so as to be discharged through the chimney 80.

In addition, the furnace heat exchanger 93 of the present invention can cooperate with the third heat exchanger 40 The incinerated gas with higher temperature is needed to adjust the position in the furnace 102 of the direct-fired incinerator (TO) 10. The burner head 101 of the direct-fired incinerator (TO) 10 can burn the incinerated gas. The gas is first transported to one side of the second hot side pipe 32 of the second heat exchanger 30 for heat exchange, and then is transported to the other side of the second hot side pipe 32 of the second heat exchanger 30 . The incinerated gas is then transported to the third hot side pipe 42 of the third heat exchanger 40 (as shown in Figures 3 to 4), and the incinerated gas passes through the third heat side pipe 42 of the third heat exchanger 40. After the third hot side pipeline 42, it is then transported to one side of the hot side pipeline 932 of the furnace heat exchanger 93 for heat exchange, and then through the other side of the hot side pipeline 932 of the furnace heat exchanger 93. The incinerated gas is then transported to one side of the first hot side pipe 22 of the first heat exchanger 20 for heat exchange, and finally through the first hot side pipe of the first heat exchanger 20 22 to the outlet 12 of the direct-fired incinerator (TO) 10, and then to the chimney 80 (as shown in Figures 3 to 4). as shown in the figure) to discharge through the chimney 80.

Furthermore, another embodiment of the runner system with heat medium oil of the present invention (as shown in Figures 5 to 6), in which the direct-fired incinerator (TO) 10, the first heat exchanger The device 20, the second heat exchanger 30, the first cold side delivery pipeline 61, the second cold side delivery pipeline 62, the adsorption runner 70, the chimney 80 and the heat medium oil system 90 adopt the same design as above, so , the above-mentioned direct-fired incinerator (TO) 10, the first heat exchanger 20, the second heat exchanger 30, the first cold-side conveying pipe 61, the second cold-side conveying pipe 62, the adsorption wheel 70, The contents of the chimney 80 and the thermal oil system 90 are not repeated. Please refer to the above description.

The above difference is that in another embodiment, the other end of the hot gas delivery pipeline 75 is originally connected to the furnace 102 of the direct-fired incinerator (TO) 10. The third heat exchanger 40 is removed, and the other end of the hot gas delivery pipeline 75 is connected to a heater 50 located outside the furnace 102 of the direct-fired incinerator (TO) 10 (as shown in Figure 5 to As shown in Figure 6), the heater 50 is any one of an air-to-air heat exchanger, a liquid-to-air heat exchanger, an electric heater, and a gas heater, so that the cooling zone 702 of the adsorption wheel 70 The other end of the cooling air delivery pipeline 74 connected to the other side is connected to the heater 50 (as shown in Figures 5 to 6), so that the cooling gas entering the cooling zone 702 of the adsorption wheel 70 The gas is transported into the heater 50 for heating, and one end of the hot gas transport pipeline 75 is connected to the other side of the desorption zone 703 of the adsorption rotor 70 , and the other end of the hot gas transport pipeline 75 is connected to The heater 50 is connected so that the high-temperature hot gas heated by the heater 50 can be transported to the desorption zone 703 of the adsorption wheel 70 through the hot gas delivery pipe 75 for desorption.

The runner method with heat medium oil of the present invention mainly includes a direct-fired incinerator (TO) 10, a first heat exchanger 20, a second heat exchanger 30, a third heat exchanger 40, The combined design of a first cold-side delivery pipeline 61, a second cold-side delivery pipeline 62, an adsorption wheel 70, a chimney 80 and a heat medium oil system 90 (as shown in Figures 1 to 2 ), wherein the first heat exchanger 20 is provided with a first cold side pipeline 21 and a first hot side pipeline 22, and the second heat exchanger 30 is provided with a second cold side pipeline 31 and a second hot side pipeline. side pipe 32, the third heat exchanger 40 is provided with a third cold side pipe 41 and a third hot side pipe 42, one end of the first cold side delivery pipe 61 is connected to the first cold side pipe The other end of the first cold side transport pipeline 61 is connected to one end of the second cold side pipeline 31, and one end of the second cold side transport pipeline 62 is connected to the second cold side pipeline 62. The other end of the side pipe 31 is connected, and the other end of the second cold side delivery pipe 62 is connected to the inlet 1 of the direct-fired incinerator (TO) 10 1 connection. In addition, the direct-fired incinerator (TO) 10 is provided with a burner 101 and a furnace 102. The burner 101 is connected with the furnace 102, and the first heat exchanger 20, the second heat exchanger 30 and The third heat exchangers 40 are respectively disposed in the furnace 102 of the direct-fired incinerator (TO) (as shown in Figures 1 to 2), and the direct-fired incinerator (TO) 10 is provided with Inlet 11 and outlet 12, and the inlet 11 is located at the burner 101, and the outlet 12 of the direct-fired incinerator (TO) 10 is connected to the chimney 80, and the heat medium oil system 90 is provided with a The heat medium oil tank 91, an air inlet heat exchanger 92 and a furnace heat exchanger 93. The heat medium oil tank 91 is provided with an air inlet heat medium oil output pipeline 911, an air inlet heat medium oil input pipeline 912, and an inlet heat medium oil input pipeline 912. The furnace heat medium oil output pipeline 913 and a furnace heat medium oil input pipeline 914 (as shown in Figures 1 to 2), thereby allowing the organic waste gas to enter the burner head 101 through the inlet 11 Combustion is carried out, and the burned gas can pass through the furnace 102 and be discharged from the outlet 12 to the chimney 80 for discharge, so as to save energy.

In addition, the adsorption wheel 70 of the present invention is provided with an adsorption area 701, a cooling area 702 and a desorption area 703. The adsorption wheel 70 is connected to a waste gas inlet pipeline 71, a clean gas discharge pipeline 72, and a cooling gas. An air intake pipeline 73, a cooling gas delivery pipeline 74, a hot gas delivery pipeline 75 and a desorption concentrated gas pipeline 76 (as shown in Figures 1 to 2). The adsorption wheel 70 is a zeolite concentration wheel or a concentration wheel made of other materials.

The heat medium oil tank of the heat medium oil system 90 uses heat medium as the heat source, and the heat medium is liquid oil. The heat medium can pass through the air inlet heat medium oil output pipeline 911 and the inlet heat medium. The oil input pipeline 912, the furnace heat medium oil output pipeline 913 and the furnace heat medium oil input pipeline 914 are used for cyclic heating, so that the relative humidity of the source exhaust gas can be reduced through the circulation method, so as to have the ability to improve the flow into the adsorption transfer The adsorption efficiency of the adsorption area 701 of the wheel 70. Other than that The air inlet heat exchanger 92 is provided on the exhaust gas inlet pipe 71. The air inlet heat exchanger 92 is provided with a cold side pipe 921 and a hot side pipe 922 (as shown in Figures 1 to 2). (shown), one end of the cold side pipeline 921 is connected to the inlet heat medium oil output pipeline 911 of the heat medium oil tank 91, and the other end of the cold side pipeline 921 is connected to the inlet heat transfer pipe 911 of the heat medium oil tank 91. The medium oil input pipeline 912 is connected. Furthermore, the furnace heat exchanger 93 is located in the furnace 102 of the direct-fired incinerator (TO) 10, and the furnace heat exchanger 93 is provided with a cold side pipeline 931 and a hot side pipeline 932 (such as 1 to 2), one end of the cold side pipeline 931 is connected to the furnace heat medium oil output pipeline 913 of the heat medium oil tank 91, and the other end of the cold side pipeline 931 is connected to the heat medium oil tank 91. The furnace heat transfer oil input pipeline 914 of the transfer oil tank 91 is connected.

The method steps of the main implementation mode (as shown in Figure 7) include: Step S100: Source exhaust gas is transported: the source exhaust gas is transported to the hot side of the intake heat exchanger 92 through the exhaust gas inlet pipeline 71 One end of pipeline 922. After completing the above step S100, the next step S110 is performed.

In addition, the next step S110 is to pass the source exhaust gas through the intake air heat exchanger: after the source exhaust gas passes through the hot side pipe 922 of the intake air heat exchanger 92, it then passes through the hot side pipe of the intake air heat exchanger 92. The other end of the exhaust gas 922 is output and transported to one side of the adsorption area 701 of the adsorption rotor 70 through the exhaust gas inlet pipe 71 . After completing the above step S110, the next step S120 is performed.

In the above-mentioned step S100 and step S110, the source exhaust gas of the exhaust gas intake pipe first enters one end of the hot side pipe 922 of the intake air heat exchanger 92, and then passes through the hot side pipe of the intake air heat exchanger 92. The other end of the path 922 is output and transported to one side of the adsorption area of the adsorption rotor through the exhaust gas inlet pipe. In addition, the exhaust gas inlet pipe 71 is provided with There is a fan 712 (as shown in Figure 2) that can push and pull the source exhaust gas into one end of the hot side pipe 922 of the air inlet heat exchanger 92.

In addition, the next step is step S120, where the adsorption wheel performs adsorption: after adsorption through the adsorption area 701 of the adsorption wheel 70, the adsorbed gas is passed through the net from the other side of the adsorption area 701 of the adsorption wheel 70. The other end of the gas discharge pipe 72 is output. After completing the above step S120, the next step S130 is performed.

In the above-mentioned step S120, one end of the clean gas discharge pipe 72 is connected to the other side of the adsorption area 701 of the adsorption wheel 70, and the other end of the clean gas discharge pipe 72 is connected to the chimney 80 (such as 1 to 2), and the clean air discharge pipe 72 is provided with a fan 721 (as shown in Figure 2), so that the air in the clean gas discharge pipe 72 can be discharged through the fan 721. The adsorbed gas is pushed and pulled into the chimney 80 for discharge.

In addition, the next step S130 is to input cooling air to the cooling zone: the cooling air is transported to the cooling zone 702 of the adsorption wheel 70 through the other end of the cooling air inlet pipe 73 for cooling, and then passes through the cooling air delivery pipe. The other end of the path 74 is used to transport the cooling air passing through the cooling zone 702 of the adsorption rotor 70 to one end of the third cold side pipe 41 of the third heat exchanger 40 . After completing the above step S130, the next step S140 is performed.

In the above-mentioned step S130, one side of the cooling zone 702 of the adsorption wheel 70 is connected to the cooling gas inlet pipe 73, so that the gas can enter the cooling zone 702 of the adsorption wheel 70 for cooling, and the adsorption The other side of the cooling zone 702 of the runner 70 is connected to one end of the cooling air delivery pipeline 74 (as shown in Figures 1 to 2), and the other end of the cooling air delivery pipeline 74 is connected to the third The third cold side pipe 41 of the heat exchanger 40 One end is connected to transport the gas entering the cooling zone 702 of the adsorption wheel 70 to the third heat exchanger 40 for heat exchange.

The cooling zone 702 of the above-mentioned adsorption wheel 70 is provided with two implementation modes. In the first implementation mode, the cooling air inlet pipe 73 connected to one side of the cooling zone 702 of the adsorption wheel 70 is for supplying air. Fresh air or outside air enters (as shown in Figure 1), and the cooling zone 702 of the adsorption wheel 70 is provided with cooling through the fresh air or outside air. Another second embodiment is that the exhaust gas inlet pipe 71 is provided with an exhaust gas connecting pipe 711 (as shown in Figure 2), and the other end of the exhaust gas connecting pipe 711 is connected to the cooling air inlet pipe. 73 connection, so that the source exhaust gas in the exhaust gas inlet pipe 71 can be transported to the cooling zone 702 of the adsorption wheel 70 for cooling through the exhaust gas connecting pipe 711. In addition, the exhaust gas connecting pipe 711 is provided with There is an exhaust gas communication control valve 7111 (as shown in Figure 2) to control the air volume of the exhaust gas communication pipeline 711.

In addition, the next step is step S140 for desorption in the desorption zone: the hot gas is transported to the adsorption rotor through the hot gas transport pipeline 75 connected to the other end of the third cold side pipeline 41 of the third heat exchanger 40. The desorption zone 703 of the wheel 70 performs desorption, and then the desorbed concentrated gas is transported to one end of the first cold side pipeline 21 of the first heat exchanger 20 through the other end of the desorbed concentrated gas pipeline 76 . After completing the above step S140, the next step S150 is performed.

In the above step S140, one end of the hot gas delivery pipeline 75 is connected to the other side of the desorption zone 703 of the adsorption wheel 70, and the other end of the hot gas delivery pipeline 75 is connected to the third heat exchanger. The other end of the third cold-side pipeline 41 of 40 is connected (as shown in Figures 1 to 2), so that the high temperature for heat exchange through the third heat exchanger 40 can be connected. The warm gas is transported to the desorption area 703 of the adsorption wheel 70 through the hot gas delivery pipe 75 for desorption.

In addition, the next step is step S150 of desorbed concentrated gas transportation: the desorbed concentrated gas then passes through the first cold side transportation pipeline 61 connected to the other end of the first cold side pipeline 21 of the first heat exchanger 20 to be transported to one end of the second cold side pipeline 31 of the second heat exchanger 30 and then transported through the second cold side connected to the other end of the second cold side pipeline 31 of the second heat exchanger 30 The pipeline 62 is used to deliver it to the inlet 11 of the direct-fired incinerator (TO) 10 . After completing the above step S150, the next step S160 is performed.

In the above step S150, the other end of the first cold side pipeline 21 of the first heat exchanger 20 is connected to one end of the first cold side delivery pipeline 61, and the other end of the first cold side delivery pipeline 61 Then it is connected to one end of the second cold side pipeline 31 of the second heat exchanger 30, and the other end of the second cold side pipeline 31 of the second heat exchanger 30 is connected to the second cold side delivery pipeline. One end of the second cold-side delivery pipeline 62 is connected to the inlet 11 of the direct-fired incinerator (TO) 10 (as shown in Figures 1 to 2), so that the The desorbed concentrated gas desorbed at high temperature can be transported to one end of the first cold side pipeline 21 of the first heat exchanger 20 through the desorbed concentrated gas pipeline 76, and is transported by the first heat exchanger The other end of the first cold side pipeline 21 of the device 20 is transported to one end of the first cold side transport pipeline 61, and the other end of the first cold side transport pipeline 61 is transported to the second heat One end of the second cold side pipeline 31 of the exchanger 30 is then transported from the other end of the second cold side pipeline 31 of the second heat exchanger 30 to one end of the second cold side delivery pipeline 62 , and finally transported to the inlet 11 of the direct-fired incinerator (TO) 10 from the other end of the second cold-side conveying pipe 62, so that the burner head 101 of the direct-fired incinerator (TO) 10 for high temperature cracking solution to reduce volatile organic compounds. In addition, the desorbed concentrated gas pipeline 76 is provided with a fan 761 (as shown in Figure 2) to push and pull the desorbed concentrated gas into one end of the first cold side pipeline 21 of the first heat exchanger 20 within.

In addition, the next step S160 is to transport the burned gas: transport the burned gas generated by the burner head 101 of the direct-fired incinerator (TO) 10 to the second heat exchanger 30 One end of the second hot side pipe 32 is transported from the other end of the second hot side pipe 32 of the second heat exchanger 30 to one end of the hot side pipe 932 of the furnace heat exchanger 93 . After completing the above step S160, the next step S170 is performed.

In addition, the next step S170 is to pass the incinerated gas through the furnace heat exchanger: after the incinerated gas passes through the hot side pipe 932 of the furnace heat exchanger 93, it passes through the hot side pipe of the furnace heat exchanger 93. The other end of 932 is output to one end of the third hot side pipeline 42 of the third heat exchanger 40 . After completing the above step S170, the next step S180 is performed.

In addition, the next step S180 is the gas outlet output after incineration: the incinerated gas is then transported to the first heat exchanger 20 from the other end of the third hot side pipeline 42 of the third heat exchanger 40 One end of the first hot-side pipeline 22 is finally transported to the outlet 12 of the direct-fired incinerator (TO) 10 through the other end of the first hot-side pipeline 22 of the first heat exchanger 20 .

The burner head 101 of the direct-fired incinerator (TO) 10 can transport the incinerated gas to one side of the second hot side pipe 32 of the second heat exchanger 30 for heat exchange (such as As shown in Figures 1 to 2), the incinerated gas is then transported to the furnace heat exchanger 93 through the other side of the second hot side pipe 32 of the second heat exchanger 30 In the hot side pipe 932, and after the incinerated gas passes through the hot side pipe 932 of the furnace heat exchanger 93, it is then transported to one side of the third hot side pipe 42 of the third heat exchanger 40. Heat exchange is performed, and then the incinerated gas is transported to the first hot side pipe of the first heat exchanger 20 from the other side of the third hot side pipe 42 of the third heat exchanger 40 22 for heat exchange, and finally transported to the outlet 12 of the direct-fired incinerator (TO) 10 from the other side of the first hot side pipeline 22 of the first heat exchanger 20, and then from the The outlet 12 of the direct-fired incinerator (TO) 10 is conveyed to the chimney 80 (as shown in Figures 1 to 2) for discharge through the chimney 80.

In addition, in the main implementation mode of the runner method with heat medium oil of the present invention (as shown in Figure 7), step S100 is to transport the source exhaust gas, step S110 is to pass the source exhaust gas through the air inlet heat exchanger, and step S120 is to adsorb the runner. Adsorption, step S130 input cooling gas into the cooling zone, step S140 desorption in the desorption zone, step S150 transportation of desorbed concentrated gas, step S160 transportation of incinerated gas, step S170 incineration of the gas through the furnace heat exchanger and step S180. The gas outlet output after incineration has been explained above. Please refer to the above explanation.

In addition, the furnace heat exchanger 93 of the present invention can adjust the position in the furnace 102 of the direct-fired incinerator (TO) 10 in conjunction with the third heat exchanger 40 that requires higher temperature incinerated gas. In the second embodiment with the third heat exchanger 40 (as shown in Figure 8), step S200 is to transport the source exhaust gas, step S210 is to pass the source exhaust gas through the inlet heat exchanger, step S220 is to adsorb the source exhaust gas, and step S220 is to adsorb the source exhaust gas. S230 input cooling gas into the cooling zone, step S240 desorption in the desorption zone, and step S250 desorption concentrated gas transportation all adopt the source of step S100 in the main implementation mode (as shown in Figure 7). The exhaust gas is transported, the source exhaust gas passes through the inlet heat exchanger in step S110, the adsorption wheel performs adsorption in step S120, the cooling gas is input to the cooling zone in step S130, the desorption zone performs desorption in step S140, and the desorption concentrated gas transportation in step S150 is the same. Design, the only difference lies in the content of conveying the incinerated gas in step S160, passing the incinerated gas through the furnace heat exchanger in step S170, and outputting the incinerated gas outlet in step S180.

The difference of the second embodiment with the third heat exchanger 40 is that the incinerated gas is transported in step S260: the incinerated gas generated by burning the burner head 101 of the direct-fired incinerator (TO) 10 The gas is transported to one end of the second hot side pipeline 32 of the second heat exchanger 30, and is transported to the third heat exchanger from the other end of the second hot side pipeline 32 of the second heat exchanger 30. 40 to one end of the third hot side pipeline 42. After completing the above step S260, the next step S270 is performed.

In addition, the next step S270 is to pass the incinerated gas through the furnace heat exchanger: the incinerated gas is transported to the furnace heat exchanger 93 from the other end of the third hot side pipeline 42 of the third heat exchanger 40 One end of the hot side pipe 932 , the incinerated gas passes through the hot side pipe 932 of the furnace heat exchanger 93 , and then is output from the other end of the hot side pipe 932 of the furnace heat exchanger 93 . After completing the above step S270, the next step S280 is performed.

In addition, the next step S280 is the output of the incinerated gas outlet: the incinerated gas is then transported to the first heat exchanger of the first heat exchanger 20 through the other end of the hot side pipeline 932 of the furnace heat exchanger 93. One end of the side pipe 22 is finally transported to the outlet 12 of the direct-fired incinerator (TO) 10 by the other end of the first hot side pipe 22 of the first heat exchanger 20 .

The burner head 101 of the direct-fired incinerator (TO) 10 can first transport the incinerated gas to one side of the second hot side pipe 32 of the second heat exchanger 30 for heat exchange, and then The incinerated gas is transported from the other side of the second hot side pipe 32 of the second heat exchanger 30 to the third hot side pipe 42 of the third heat exchanger 40 (such as the third 4) and the burned gas passes through the third hot side pipe 42 of the third heat exchanger 40, and then is transported to one side of the hot side pipe 932 of the furnace heat exchanger 93. Heat exchange is performed, and then the incinerated gas is transported to one side of the first hot side pipeline 22 of the first heat exchanger 20 through the other side of the hot side pipeline 932 of the furnace heat exchanger 93. side for heat exchange, and finally transported to the outlet 12 of the direct-fired incinerator (TO) 10 from the other side of the first hot-side pipe 22 of the first heat exchanger 20, and then from the direct-fired incinerator (TO) 10 The outlet 12 of the incinerator (TO) 10 is conveyed to the chimney 80 (as shown in Figures 3 to 4) for discharge through the chimney 80.

Furthermore, in the main implementation mode of the runner method with heat medium oil of the present invention (as shown in Figure 7), step S100 of source exhaust gas is transported, step S110 of source exhaust gas passes through the air inlet heat exchanger, and step S120 is carried out by the adsorption runner. Adsorption, step S130 input cooling gas into the cooling zone, step S140 desorption in the desorption zone, step S150 transportation of desorbed concentrated gas, step S160 transportation of incinerated gas, step S170 incineration of the gas through the furnace heat exchanger and step S180. The gas outlet output after incineration has been explained above. Please refer to the above explanation.

In the third embodiment (as shown in Figure 9), step S300 is to transport the source waste gas, step S310 is to pass the source waste gas through the inlet heat exchanger, S320 is an adsorption wheel for adsorption, step S350 is to transport the desorbed concentrated gas, and step S350 is to transport the source waste gas. S360 The air after burning The main implementation mode (as shown in Figure 7) is used to transport the source exhaust gas in step S100, the source exhaust gas in step S110 is adsorbed through the air inlet heat exchanger, the adsorption wheel in S120, and the desorption in step S150. The design of conveying the concentrated gas and conveying the incinerated gas in step S160 is the same. The only difference is that in step S130, the cooling gas is input into the cooling zone, in step S140, the desorption zone is desorbed, and in step S170, the incinerated gas passes through the furnace heat exchanger and the steps Contents of gas outlet output after S180 incineration.

Therefore, the above-mentioned contents are the same as the transportation of the source exhaust gas in step S300, the adsorption of the source exhaust gas through the inlet heat exchanger in step S310, the adsorption rotor in S320, the transportation of desorbed concentrated gas in step S350, and the transportation of the incinerated gas in step S360. Repeat, please refer to the instructions above. The following will focus on step S330 of the third embodiment (as shown in Figure 9) in which the cooling gas is input to the cooling zone, desorption is performed in the desorption zone in step S340, the incinerated gas passes through the furnace heat exchanger in step S370, and incineration is performed in step S380. The gas outlet output will be explained later.

The difference of the third embodiment is that the cooling air is input to the cooling zone in step S330: the cooling air is delivered to the cooling zone 702 of the adsorption wheel 70 through the other end of the cooling air inlet pipe 73 for cooling, and then through the The other end of the cooling air delivery pipeline 74 is used to output the cooling air passing through the cooling zone 702 of the adsorption rotor 70 . After completing the above step S330, the next step S340 is performed.

In addition, the next step is step S340 for desorption in the desorption zone: one end of the hot gas delivery pipeline 75 is connected to the desorption zone 703 of the adsorption wheel 70 , and is carried out by the desorption zone 703 of the adsorption wheel 70 After desorption, the desorbed concentrated gas is transported to one end of the first cold side pipeline 21 of the first heat exchanger 20 through the desorbed concentrated gas pipeline 76 .

In the above-mentioned steps S330 and S340, the third heat exchanger 40 originally connected to the other end of the hot gas delivery pipeline 75 and located in the furnace 102 of the direct-fired incinerator (TO) 10 is removed, and the The other end of the hot gas delivery pipeline 75 is connected to a heater 50 (as shown in Figures 5 to 6) located outside the furnace 102 of the direct-fired incinerator (TO) 10, where the heater 50 It is any one of an air-to-air heat exchanger, a liquid-to-air heat exchanger, an electric heater, and a gas heater. The cooling air delivery pipeline is connected to the other side of the cooling zone 702 of the adsorption wheel 70 The other end of 74 is connected to the heater 50 to transport the gas entering the cooling zone 702 of the adsorption wheel 70 to the heater 50 for heating (as shown in Figures 5 to 6), and One end of the hot gas delivery pipeline 75 is connected to the other side of the desorption zone 703 of the adsorption wheel 70, and the other end of the hot gas delivery pipeline 75 is connected to the heater 50, so that the heated gas can be The high-temperature hot gas heated by the device 50 is transported to the desorption area of the adsorption wheel 70 through the hot gas delivery pipe 75 for desorption use 703 .

Furthermore, in step S370, the incinerated gas passes through the furnace heat exchanger: after the incinerated gas passes through the hot side pipeline 932 of the furnace heat exchanger 93, it passes through the other side of the hot side pipeline 932 of the furnace heat exchanger 93. One end is output to one end of the first hot side pipe 22 of the first heat exchanger 20 . After completing the above step S370, the next step S380 is performed.

In addition, the next step S380 is the gas outlet output after incineration: the incinerated gas is finally transported to the direct-fired incinerator (TO) from the other end of the first hot side pipeline 22 of the first heat exchanger 20 )10 to exit 12.

In the above-mentioned step S370 and step S380, the burner head 101 of the direct-fired incinerator (TO) 10 can transport the incinerated gas to the second heat exchanger first. One side of the second hot side pipe 32 of the second heat exchanger 30 is used for heat exchange, and then the incinerated gas is transported to the other side of the second hot side pipe 32 of the second heat exchanger 30. In the furnace heat exchanger 93, and after the incinerated gas passes through the furnace heat exchanger 93, it is then transported to one side of the first hot side pipeline 22 of the first heat exchanger 20 for heat exchange (such as No. 5 (shown in Figures to Figure 6), and finally transported from the other side of the first hot side pipe 22 of the first heat exchanger 20 to the outlet 12 of the direct-fired incinerator (TO) 10, and then from the The outlet 12 of the direct-fired incinerator (TO) 10 is delivered to the chimney 80 for discharge through the chimney 80 .

From the above detailed description, those who are familiar with this art can understand that the present invention can indeed achieve the aforementioned objectives, and has complied with the provisions of the patent law, and is ready to file an invention patent application.

However, the above are only preferred embodiments of the present invention, and should not be used to limit the scope of the present invention; therefore, any simple equivalent changes and modifications made based on the patent scope of the present invention and the content of the invention description , should still fall within the scope covered by the patent of this invention.

10: Direct-fired incinerator (TO)

101:Stove

102:furnace

11: Entrance

12:Export

20:First heat exchanger

21: First cold side pipeline

22:First hot side pipe

30: Second heat exchanger

31: Second cold side pipeline

32:Second hot side pipe

40:Third heat exchanger

41:Third cold side pipeline

42:Third hot side pipe

61: First cold side delivery pipeline

62: Second cold side delivery pipeline

70:Adsorption wheel

701: Adsorption area

702: Cooling area

703:Desorption zone

71:Exhaust gas intake pipe

72: Clean gas discharge pipeline

73: Cooling air intake pipe

74: Cooling air delivery pipeline

75:Hot gas delivery pipeline

76:Desorption concentrated gas pipeline

80:Chimney

90:Heat medium oil system

91:Heating medium oil tank

911: Intake heat medium oil output pipeline

912: Intake heat medium oil input pipeline

913: Furnace heat medium oil output pipeline

914: Furnace heat medium oil input pipeline

92:Inlet air heat exchanger

921:Cold side pipeline

922:Hot side pipe

93: Furnace heat exchanger

931:Cold side pipeline

932:Hot side pipe

Claims (22)

A runner system with heat transfer oil, including: A direct-fired incinerator (TO) is provided with a burner head and a furnace, and the burner head is connected with the furnace. The direct-fired incinerator (TO) is provided with an inlet and a furnace. Exit, the entrance is located at the burner head; A first heat exchanger. The first heat exchanger is located in the furnace of the direct-fired incinerator (TO). The first heat exchanger is provided with a first cold side pipe and a first hot side pipe. road; A second heat exchanger, the second heat exchanger is located in the furnace of the direct-fired incinerator (TO), and the second heat exchanger is provided with a second cold side pipe and a second hot side pipe road; A third heat exchanger. The third heat exchanger is located in the furnace of the direct-fired incinerator (TO). The third heat exchanger is equipped with a third cold side pipe and a third hot side pipe. road; A first cold-side delivery pipeline, one end of the first cold-side delivery pipeline is connected to the other end of the first cold-side pipeline, and the other end of the first cold-side delivery pipeline is connected to the second cold-side delivery pipeline. One end of the side pipe is connected; A second cold-side delivery pipeline, one end of the second cold-side delivery pipeline is connected to the other end of the second cold-side pipeline, and the other end of the second cold-side delivery pipeline is connected to the direct-fired Incinerator (TO) inlet connection; An adsorption runner. The adsorption runner is provided with an adsorption zone, a cooling zone and a desorption zone. The adsorption runner is connected to a waste gas inlet pipeline, a clean gas discharge pipeline, a cooling air inlet pipeline, A cooling gas delivery pipeline, a hot gas delivery pipeline and a desorption concentrated gas pipeline. One end of the exhaust gas inlet pipeline is connected to one side of the adsorption area of the adsorption rotor, and the clean gas discharge pipeline One end is connected to the other side of the adsorption area of the adsorption wheel, and one end of the cooling air inlet pipe is connected to One side of the cooling zone of the adsorption rotor is connected, one end of the cooling gas delivery pipeline is connected with the other side of the cooling zone of the adsorption rotor, and the other end of the cooling gas delivery pipeline is connected with the third heat source. One end of the third cold side pipeline of the exchanger is connected, one end of the hot gas transport pipeline is connected to the other side of the desorption zone of the adsorption rotor, and the other end of the hot gas transport pipeline is connected to the third hot gas pipeline. The other end of the third cold side pipeline of the exchanger is connected. One end of the desorbed concentrated gas pipeline is connected to one side of the desorption zone of the adsorption rotor. The other end of the desorbed concentrated gas pipeline is connected to One end of the first cold side pipe of the first heat exchanger is connected; a chimney to which the other end of the net gas discharge pipe is connected; and A heat medium oil system. The heat medium oil system is provided with a heat medium oil tank, an air inlet heat exchanger and a furnace heat exchanger. The heat medium oil tank is equipped with an air inlet heat medium oil output pipeline, an air inlet heat exchanger A heat transfer oil input pipeline, a furnace heat transfer oil output pipeline and a furnace heat transfer oil input pipeline. The air inlet heat exchanger is located on the exhaust gas inlet pipeline. The air inlet heat exchanger is provided with a A cold side pipeline and a hot side pipeline. One end of the cold side pipeline is connected to the inlet heat medium oil output pipeline of the heat medium oil tank, and the other end of the cold side pipeline is connected to the heat medium oil tank. The intake heat medium oil input pipeline is connected. The exhaust gas from the exhaust gas intake pipeline first enters one end of the hot side pipeline of the intake heat exchanger, and then passes through the hot side pipeline of the intake heat exchanger. The other end is output and transported to one side of the adsorption area of the adsorption wheel through the exhaust gas inlet pipe. The furnace heat exchanger is located in the furnace of the direct-fired incinerator (TO). The furnace heat The exchanger is equipped with a cold side pipeline and a hot side pipeline. One end of the cold side pipeline is connected to the furnace heat medium oil output pipeline of the heat medium oil tank, and the other end of the cold side pipeline is connected to the heat medium oil tank. The furnace heat medium oil input pipeline of the heat medium oil tank is connected. One end of the hot side pipeline of the furnace heat exchanger is connected to the other end of the second hot side pipeline of the second heat exchanger. The furnace heat exchanger The other end of the hot side pipe is connected to the third heat exchanger Connect one end of the third hot side pipe of the converter. A runner system with heat transfer oil, including: A direct-fired incinerator (TO) is provided with a burner head and a furnace, and the burner head is connected with the furnace. The direct-fired incinerator (TO) is provided with an inlet and a furnace. Exit, the entrance is located at the burner head; A first heat exchanger. The first heat exchanger is located in the furnace of the direct-fired incinerator (TO). The first heat exchanger is provided with a first cold side pipe and a first hot side pipe. road; A second heat exchanger, the second heat exchanger is located in the furnace of the direct-fired incinerator (TO), and the second heat exchanger is provided with a second cold side pipe and a second hot side pipe road; A third heat exchanger. The third heat exchanger is located in the furnace of the direct-fired incinerator (TO). The third heat exchanger is equipped with a third cold side pipe and a third hot side pipe. road; A first cold-side delivery pipeline, one end of the first cold-side delivery pipeline is connected to the other end of the first cold-side pipeline, and the other end of the first cold-side delivery pipeline is connected to the second cold-side delivery pipeline. One end of the side pipe is connected; A second cold-side delivery pipeline, one end of the second cold-side delivery pipeline is connected to the other end of the second cold-side pipeline, and the other end of the second cold-side delivery pipeline is connected to the direct-fired Incinerator (TO) inlet connection; An adsorption runner. The adsorption runner is provided with an adsorption zone, a cooling zone and a desorption zone. The adsorption runner is connected to a waste gas inlet pipeline, a clean gas discharge pipeline, a cooling air inlet pipeline, A cooling gas delivery pipeline, a hot gas delivery pipeline and a desorption concentrated gas pipeline. One end of the exhaust gas inlet pipeline is connected to one side of the adsorption area of the adsorption rotor, and the clean gas discharge pipeline One end is connected to the other side of the adsorption area of the adsorption wheel, and one end of the cooling air inlet pipe is connected to One side of the cooling zone of the adsorption rotor is connected, one end of the cooling gas delivery pipeline is connected with the other side of the cooling zone of the adsorption rotor, and the other end of the cooling gas delivery pipeline is connected with the third heat source. One end of the third cold side pipeline of the exchanger is connected, one end of the hot gas transport pipeline is connected to the other side of the desorption zone of the adsorption rotor, and the other end of the hot gas transport pipeline is connected to the third hot gas pipeline. The other end of the third cold side pipeline of the exchanger is connected. One end of the desorbed concentrated gas pipeline is connected to one side of the desorption zone of the adsorption rotor. The other end of the desorbed concentrated gas pipeline is connected to One end of the first cold side pipe of the first heat exchanger is connected; a chimney to which the other end of the net gas discharge pipe is connected; and A heat medium oil system. The heat medium oil system is provided with a heat medium oil tank, an air inlet heat exchanger and a furnace heat exchanger. The heat medium oil tank is equipped with an air inlet heat medium oil output pipeline, an air inlet heat exchanger A heat transfer oil input pipeline, a furnace heat transfer oil output pipeline and a furnace heat transfer oil input pipeline. The air inlet heat exchanger is located on the exhaust gas inlet pipeline. The air inlet heat exchanger is provided with a A cold side pipeline and a hot side pipeline. One end of the cold side pipeline is connected to the inlet heat medium oil output pipeline of the heat medium oil tank, and the other end of the cold side pipeline is connected to the heat medium oil tank. The intake heat medium oil input pipeline is connected. The exhaust gas from the exhaust gas intake pipeline first enters one end of the hot side pipeline of the intake heat exchanger, and then passes through the hot side pipeline of the intake heat exchanger. The other end is output and transported to one side of the adsorption area of the adsorption wheel through the exhaust gas inlet pipe. The furnace heat exchanger is located in the furnace of the direct-fired incinerator (TO). The furnace heat The exchanger is equipped with a cold side pipeline and a hot side pipeline. One end of the cold side pipeline is connected to the furnace heat medium oil output pipeline of the heat medium oil tank, and the other end of the cold side pipeline is connected to the heat medium oil tank. The furnace heat medium oil input pipeline of the heat medium oil tank is connected. One end of the hot side pipeline of the furnace heat exchanger is connected to the other end of the third hot side pipeline of the third heat exchanger. The furnace heat exchanger The other end of the hot side pipe is connected to the first heat exchanger Connect one end of the first hot side pipeline of the converter. A runner system with heat transfer oil, including: A direct-fired incinerator (TO) is provided with a burner head and a furnace, and the burner head is connected with the furnace. The direct-fired incinerator (TO) is provided with an inlet and a furnace. Exit, the entrance is located at the burner head; A first heat exchanger. The first heat exchanger is located in the furnace of the direct-fired incinerator (TO). The first heat exchanger is provided with a first cold side pipe and a first hot side pipe. road; A second heat exchanger, the second heat exchanger is located in the furnace of the direct-fired incinerator (TO), and the second heat exchanger is provided with a second cold side pipe and a second hot side pipe road; A first cold-side delivery pipeline, one end of the first cold-side delivery pipeline is connected to the other end of the first cold-side pipeline, and the other end of the first cold-side delivery pipeline is connected to the second cold-side delivery pipeline. One end of the side pipe is connected; A second cold-side delivery pipeline, one end of the second cold-side delivery pipeline is connected to the other end of the second cold-side pipeline, and the other end of the second cold-side delivery pipeline is connected to the direct-fired Incinerator (TO) inlet connection; An adsorption runner. The adsorption runner is provided with an adsorption zone, a cooling zone and a desorption zone. The adsorption runner is connected to a waste gas inlet pipeline, a clean gas discharge pipeline, a cooling air inlet pipeline, A cooling gas delivery pipeline, a hot gas delivery pipeline and a desorption concentrated gas pipeline. One end of the exhaust gas inlet pipeline is connected to one side of the adsorption area of the adsorption rotor, and the clean gas discharge pipeline One end is connected to the other side of the adsorption zone of the adsorption rotor, one end of the cooling air inlet pipe is connected to one side of the cooling zone of the adsorption rotor, and one end of the cooling air delivery pipe is connected to the The other side of the cooling zone of the adsorption wheel is connected, and one end of the hot gas delivery pipeline is connected to the adsorption wheel. The other side of the desorption zone is connected. One end of the desorption concentrated gas pipeline is connected to one side of the desorption zone of the adsorption rotor. The other end of the desorption concentrated gas pipeline is connected with the first heat exchanger. Connect one end of the first cold side pipe of the device; a chimney to which the other end of the net gas discharge pipe is connected; and A heat medium oil system. The heat medium oil system is provided with a heat medium oil tank, an air inlet heat exchanger and a furnace heat exchanger. The heat medium oil tank is equipped with an air inlet heat medium oil output pipeline, an air inlet heat exchanger A heat transfer oil input pipeline, a furnace heat transfer oil output pipeline and a furnace heat transfer oil input pipeline. The air inlet heat exchanger is located on the exhaust gas inlet pipeline. The air inlet heat exchanger is provided with a A cold side pipeline and a hot side pipeline. One end of the cold side pipeline is connected to the inlet heat medium oil output pipeline of the heat medium oil tank, and the other end of the cold side pipeline is connected to the heat medium oil tank. The intake heat medium oil input pipeline is connected. The exhaust gas from the exhaust gas intake pipeline first enters one end of the hot side pipeline of the intake heat exchanger, and then passes through the hot side pipeline of the intake heat exchanger. The other end is output and transported to one side of the adsorption area of the adsorption wheel through the exhaust gas inlet pipe. The furnace heat exchanger is located in the furnace of the direct-fired incinerator (TO). The furnace heat The exchanger is equipped with a cold side pipeline and a hot side pipeline. One end of the cold side pipeline is connected to the furnace heat medium oil output pipeline of the heat medium oil tank, and the other end of the cold side pipeline is connected to the heat medium oil tank. The furnace heat medium oil input pipeline of the heat medium oil tank is connected. One end of the hot side pipeline of the furnace heat exchanger is connected to the other end of the second hot side pipeline of the second heat exchanger. The furnace heat exchanger The other end of the hot side pipe is connected to one end of the first hot side pipe of the first heat exchanger. For example, in the runner system with heat transfer oil described in Item 1, 2 or 3 of the patent application, the outlet of the direct-fired incinerator (TO) is further connected to the chimney. For example, the runner system with heat medium oil described in item 1, 2 or 3 of the patent application, wherein the cooling The air intake pipeline further supplies fresh air or outside air to enter. For example, in the runner system with heat medium oil described in item 1, 2 or 3 of the patent application, the exhaust gas inlet pipeline is further provided with an exhaust gas connecting pipeline, and the exhaust gas connecting pipeline is connected to the cooling air inlet. The exhaust gas pipeline is connected to the exhaust gas pipeline, and the exhaust gas communication pipeline is further provided with an exhaust gas communication control valve to control the air volume of the exhaust gas communication pipeline. For example, in the runner system with heat transfer oil described in Item 1, 2 or 3 of the patent application, the desorbed concentrated gas pipeline is further equipped with a fan. For example, in the runner system with heat medium oil described in Item 1, 2 or 3 of the patent application, the clean air discharge pipeline is further equipped with a fan. For example, in the runner system with heat transfer oil described in Item 1, 2 or 3 of the patent application, the exhaust gas inlet pipeline is further equipped with a fan. For example, in the runner system with heat medium oil described in item 3 of the patent application, the other end of the cooling gas delivery pipeline is further connected to a heater, and the other end of the hot gas delivery pipeline is further connected to the heater. The heater is connected to the heater, wherein the heater is further any one of an air-to-air heat exchanger, a liquid-to-air heat exchanger, an electric heater, and a gas heater. For example, the runner system with heat medium oil described in item 1, 2 or 3 of the patent application scope, wherein the heat medium oil tank of the heat medium oil system further uses heat medium as the heat source, and the heat medium is liquid oil. , the heat medium can be used for cyclic heating through the inlet heat medium oil output pipeline, the inlet heat medium oil input pipeline, the furnace heat medium oil output pipeline, and the furnace heat medium oil input pipeline. A runner method with heat medium oil, which is mainly provided with a direct-fired incinerator (TO), a first heat exchanger, a second heat exchanger, a third heat exchanger, and a first cold side conveyor pipeline, a second cold-side conveying pipeline, an adsorption runner, a chimney and a heat transfer oil system. The direct-fired The incinerator (TO) is provided with a furnace head and a furnace, and the furnace head is connected with the furnace. The direct-fired incinerator (TO) is provided with an inlet and an outlet, and the entrance is located at the furnace head. The first heat exchanger is provided with a first cold side pipeline and a first hot side pipeline, the second heat exchanger is provided with a second cold side pipeline and a second hot side pipeline, and the third heat exchanger is provided with a first cold side pipeline and a first hot side pipeline. The device is provided with a third cold side pipeline and a third hot side pipeline. One end of the first cold side delivery pipeline is connected to the other end of the first cold side pipeline. The first cold side delivery pipeline The other end of the second cold side pipeline is connected to one end of the second cold side pipeline, one end of the second cold side delivery pipeline is connected to the other end of the second cold side pipeline, and the other end of the second cold side delivery pipeline One end is connected to the inlet of the direct-fired incinerator (TO). The adsorption runner is equipped with an adsorption zone, a cooling zone and a desorption zone. The adsorption runner is connected to a waste gas inlet pipeline and a clean gas discharge pipeline, a cooling air inlet pipeline, a cooling air delivery pipeline, a hot gas delivery pipeline and a desorbed concentrated gas pipeline. The heat medium oil system is equipped with a heat medium oil tank and an air inlet heat exchanger. and a furnace heat exchanger. The heat medium oil tank is provided with an inlet heat medium oil output pipeline, an inlet heat medium oil input pipeline, a furnace heat medium oil output pipeline, and a furnace heat medium oil input pipeline. , the air inlet heat exchanger is located on the exhaust gas inlet pipe. The air inlet heat exchanger is provided with a cold side pipe and a hot side pipe. One end of the cold side pipe is connected to the heat medium oil tank. The inlet heat medium oil output pipeline is connected, and the other end of the cold side pipeline is connected to the inlet heat medium oil input pipeline of the heat medium oil tank. The furnace heat exchanger is located in the direct-fired incinerator. In the furnace of (TO), the furnace heat exchanger is equipped with a cold side pipeline and a hot side pipeline. One end of the cold side pipeline is connected to the furnace heat medium oil output pipeline of the heat medium oil tank. The other end of the cold side pipeline is connected to the furnace heat medium oil input pipeline of the heat medium oil tank, and the main steps of this method include: The source exhaust gas is transported: the source exhaust gas is transported to the inlet heat exchanger through the exhaust gas inlet pipeline. One end of the hot side pipe of the exchanger; The source exhaust gas passes through the air inlet heat exchanger: After the source exhaust gas passes through the hot side pipe of the inlet air heat exchanger, it is output from the other end of the hot side pipe of the air inlet heat exchanger and enters through the exhaust gas. The pipeline is used to transport it to one side of the adsorption area of the adsorption wheel; Adsorption by the adsorption wheel: After adsorption through the adsorption zone of the adsorption wheel, the adsorbed gas is output from the other side of the adsorption zone of the adsorption wheel through the other end of the clean gas discharge pipe; Input the cooling air into the cooling zone: deliver the cooling air to the cooling zone of the adsorption wheel through the other end of the cooling air inlet pipe for cooling, and then pass the cooling air through the adsorption wheel through the other end of the cooling air delivery pipe. The cooling air in the cooling zone is delivered to one end of the third cold side pipe of the third heat exchanger; Desorption in the desorption zone: The hot gas is transported to the desorption zone of the adsorption rotor for desorption through the hot gas delivery pipeline connected to the other end of the third cold side pipeline of the third heat exchanger, and then through The other end of the desorbed concentrated gas pipeline is used to transport the desorbed concentrated gas to one end of the first cold side pipeline of the first heat exchanger; Desorption concentrated gas transportation: The desorption concentrated gas is then transported to the second heat exchanger through the first cold side transportation pipeline connected to the other end of the first cold side pipeline of the first heat exchanger. One end of the second cold-side pipeline is transported to the direct-fired incinerator (TO) through the second cold-side delivery pipeline connected to the other end of the second cold-side pipeline of the second heat exchanger. Inlet; transporting the incinerated gas: transport the incinerated gas generated by the burner head of the direct-fired incinerator (TO) to one end of the second hot side pipe of the second heat exchanger, And transported from the other end of the second hot side pipeline of the second heat exchanger to the hot side of the furnace heat exchanger One end of the pipe; The incinerated gas passes through the furnace heat exchanger: after the incinerated gas passes through the hot side pipe of the furnace heat exchanger, it is output to the third heat exchanger from the other end of the hot side pipe of the furnace heat exchanger. one end of the third hot side pipe; and Output of the incinerated gas outlet: The incinerated gas is then transported from the other end of the third hot side pipe of the third heat exchanger to one end of the first hot side pipe of the first heat exchanger, and finally by The other end of the first hot side pipe of the first heat exchanger is delivered to the outlet of the direct-fired incinerator (TO). A runner method with heat medium oil, which is mainly provided with a direct-fired incinerator (TO), a first heat exchanger, a second heat exchanger, a third heat exchanger, and a first cold side conveyor pipeline, a second cold-side conveying pipeline, an adsorption runner, a chimney and a thermal oil system. The direct-fired incinerator (TO) is provided with a burner and a furnace, and the burner and the furnace are are connected. The direct-fired incinerator (TO) is provided with an inlet and an outlet. The inlet is located at the burner head. The first heat exchanger is provided with a first cold side pipe and a first hot side pipe. pipeline, the second heat exchanger is provided with a second cold side pipeline and a second hot side pipeline, the third heat exchanger is provided with a third cold side pipeline and a third hot side pipeline, and the third heat exchanger is provided with a third cold side pipeline and a third hot side pipeline. One end of a cold-side delivery pipeline is connected to the other end of the first cold-side pipeline, and the other end of the first cold-side delivery pipeline is connected to one end of the second cold-side pipeline. The second cold-side pipeline One end of the side delivery pipeline is connected to the other end of the second cold side pipeline, and the other end of the second cold side delivery pipeline is connected to the inlet of the direct-fired incinerator (TO). The adsorption wheel It is equipped with an adsorption area, a cooling area and a desorption area. The adsorption rotor is connected with a waste gas inlet pipeline, a clean gas discharge pipeline, a cooling air inlet pipeline, a cooling air transport pipeline, and a hot gas transportation pipeline and a desorbed concentrated gas pipeline. The heat medium oil system is equipped with a heat medium oil tank, a An air inlet heat exchanger and a furnace heat exchanger. The heat medium oil tank is provided with an air inlet heat medium oil output pipeline, an air inlet heat medium oil input pipeline, a furnace heat medium oil output pipeline and a furnace heat medium oil tank. The oil input pipeline is provided with an air inlet heat exchanger located on the exhaust gas inlet pipeline. The air inlet heat exchanger is provided with a cold side pipeline and a hot side pipeline. One end of the cold side pipeline is It is connected to the air inlet heat medium oil output pipeline of the heat medium oil tank. The other end of the cold side pipeline is connected to the air inlet heat medium oil input pipeline of the heat medium oil tank. The furnace heat exchanger is located on the In the furnace of a direct-fired incinerator (TO), the furnace heat exchanger is equipped with a cold side pipeline and a hot side pipeline. One end of the cold side pipeline is connected to the furnace heat medium oil output of the heat medium oil tank. Pipe connection, the other end of the cold side pipe is connected to the furnace heat medium oil input pipe of the heat medium oil tank, and the main steps of this method include: Transport the source waste gas: transport the source waste gas through the waste gas inlet pipe to one end of the hot side pipe of the air inlet heat exchanger; The source exhaust gas passes through the air inlet heat exchanger: After the source exhaust gas passes through the hot side pipe of the inlet air heat exchanger, it is output from the other end of the hot side pipe of the air inlet heat exchanger and enters through the exhaust gas. The pipeline is used to transport it to one side of the adsorption area of the adsorption wheel; Adsorption by the adsorption wheel: After adsorption through the adsorption zone of the adsorption wheel, the adsorbed gas is output from the other side of the adsorption zone of the adsorption wheel through the other end of the clean gas discharge pipe; Input the cooling air into the cooling zone: deliver the cooling air to the cooling zone of the adsorption wheel through the other end of the cooling air inlet pipe for cooling, and then pass the cooling air through the adsorption wheel through the other end of the cooling air delivery pipe. The cooling air in the cooling zone is delivered to one end of the third cold side pipe of the third heat exchanger; Desorption in the desorption zone: The hot gas is transported to the desorption zone of the adsorption rotor for desorption through the hot gas delivery pipeline connected to the other end of the third cold side pipeline of the third heat exchanger, and then through The other end of the desorbed concentrated gas pipeline is used to transport the desorbed concentrated gas to one end of the first cold side pipeline of the first heat exchanger; Desorption concentrated gas transportation: The desorption concentrated gas is then transported to the second heat exchanger through the first cold side transportation pipeline connected to the other end of the first cold side pipeline of the first heat exchanger. One end of the second cold-side pipeline is transported to the direct-fired incinerator (TO) through the second cold-side delivery pipeline connected to the other end of the second cold-side pipeline of the second heat exchanger. Entrance; Transporting the incinerated gas: transporting the incinerated gas produced by the burner head of the direct-fired incinerator (TO) to one end of the second hot side pipeline of the second heat exchanger, and by The other end of the second hot side pipe of the second heat exchanger is delivered to one end of the third hot side pipe of the third heat exchanger; The incinerated gas passes through the furnace heat exchanger: the incinerated gas is transported from the other end of the third hot side pipe of the third heat exchanger to one end of the hot side pipe of the furnace heat exchanger. After the gas passes through the hot side pipe of the furnace heat exchanger, it is output from the other end of the hot side pipe of the furnace heat exchanger; and Output of the incinerated gas outlet: The incinerated gas is transported from the other end of the hot side pipe of the furnace heat exchanger to one end of the first hot side pipe of the first heat exchanger, and finally from the first heat exchanger. The other end of the first hot side pipe of the exchanger is delivered to the outlet of the direct-fired incinerator (TO). A runner method with heat medium oil, which is mainly provided with a direct-fired incinerator (TO), a first heat exchanger, a second heat exchanger, a first cold side conveying pipeline, and a second cold side The direct-fired incinerator (TO) is equipped with a side conveying pipeline, an adsorption runner, a chimney and a thermal oil system. There is a burner and a furnace. The burner is connected with the furnace. The direct-fired incinerator (TO) is provided with an inlet and an outlet. The inlet is located at the burner. The first heat exchanger is provided with There is a first cold side pipeline and a first hot side pipeline. The second heat exchanger is provided with a second cold side pipeline and a second hot side pipeline. One end of the first cold side delivery pipeline is connected to the The other end of the first cold side pipeline is connected, the other end of the first cold side delivery pipeline is connected to one end of the second cold side pipeline, and one end of the second cold side delivery pipeline is connected to the second The other end of the cold side pipeline is connected, and the other end of the second cold side delivery pipeline is connected to the inlet of the direct-fired incinerator (TO). The adsorption rotor is equipped with an adsorption zone, a cooling zone and a desorption zone. area, the adsorption rotor system is connected to a waste gas inlet pipeline, a clean gas discharge pipeline, a cooling gas inlet pipeline, a cooling gas transportation pipeline, a hot gas transportation pipeline and a desorption concentrated gas pipeline , the heat medium oil system is equipped with a heat medium oil tank, an air inlet heat exchanger and a furnace heat exchanger. The heat medium oil tank is equipped with an air inlet heat medium oil output pipe and an air inlet heat medium oil input pipe. pipeline, a furnace heat medium oil output pipeline and a furnace heat medium oil input pipeline. The air inlet heat exchanger is located on the exhaust gas inlet pipe. The air inlet heat exchanger is equipped with a cold side pipe and A hot side pipeline, one end of the cold side pipeline is connected to the inlet heat medium oil output pipeline of the heat medium oil tank, and the other end of the cold side pipeline is connected to the inlet heat medium oil of the heat medium oil tank. Input pipeline connection, the furnace heat exchanger is installed in the furnace of the direct-fired incinerator (TO), the furnace heat exchanger is equipped with a cold side pipeline and a hot side pipeline, the cold side pipeline One end of the cold side pipe is connected to the furnace heat medium oil output pipeline of the heat medium oil tank, and the other end of the cold side pipeline is connected to the furnace heat medium oil input pipeline of the heat medium oil tank. The main steps of the method include : Source exhaust gas is transported: the source exhaust gas is transported to one end of the hot side pipeline of the intake heat exchanger through the exhaust gas inlet pipe; The source exhaust gas passes through the intake heat exchanger: the source exhaust gas passes through the hot side pipe of the intake heat exchanger After that, it is output from the other end of the hot side pipe of the air inlet heat exchanger and transported to one side of the adsorption area of the adsorption rotor through the exhaust gas inlet pipe; Adsorption by the adsorption wheel: After adsorption through the adsorption zone of the adsorption wheel, the adsorbed gas is output from the other side of the adsorption zone of the adsorption wheel through the other end of the clean gas discharge pipe; Input the cooling air into the cooling zone: deliver the cooling air to the cooling zone of the adsorption wheel through the other end of the cooling air inlet pipe for cooling, and then pass the cooling air through the adsorption wheel through the other end of the cooling air delivery pipe. The cooling air output of the cooling zone; Desorption in the desorption zone: One end of the hot gas delivery pipeline is connected to the desorption zone of the adsorption wheel, and desorption is performed by the desorption zone of the adsorption wheel, and then through the desorption concentrated gas pipeline. Transport the desorbed concentrated gas to one end of the first cold side pipeline of the first heat exchanger; Desorption concentrated gas transportation: The desorption concentrated gas is then transported to the second heat exchanger through the first cold side transportation pipeline connected to the other end of the first cold side pipeline of the first heat exchanger. One end of the second cold-side pipeline is transported to the direct-fired incinerator (TO) through the second cold-side delivery pipeline connected to the other end of the second cold-side pipeline of the second heat exchanger. Entrance; Transporting the incinerated gas: transporting the incinerated gas produced by the burner head of the direct-fired incinerator (TO) to one end of the second hot side pipeline of the second heat exchanger, and by The other end of the second hot side pipe of the second heat exchanger is delivered to one end of the hot side pipe of the furnace heat exchanger; The incinerated gas passes through the furnace heat exchanger: after the incinerated gas passes through the hot side pipeline of the furnace heat exchanger, it is output to the first heat exchanger from the other end of the hot side pipeline of the furnace heat exchanger. One end of the first hot side pipeline; and the gas outlet output after incineration: the incinerated gas is finally transported to the direct-fired incinerator ( TO) export. For example, in the runner method with heat transfer oil described in Item 12, 13 or 14 of the patent application, the outlet of the direct-fired incinerator (TO) is further connected to the chimney. For example, in the runner method with heat medium oil described in Item 12, 13 or 14 of the patent application, the cooling air inlet pipeline is further provided for fresh air or outside air to enter. For example, in the runner method with heat medium oil described in item 12, 13 or 14 of the patent application, the exhaust gas inlet pipeline is further provided with an exhaust gas connecting pipeline, and the exhaust gas connecting pipeline is connected to the cooling air inlet. The exhaust gas pipeline is connected to the exhaust gas pipeline, and the exhaust gas communication pipeline is further provided with an exhaust gas communication control valve to control the air volume of the exhaust gas communication pipeline. For example, in the runner method with heat transfer oil described in Item 12, 13 or 14 of the patent application, the desorbed concentrated gas pipeline is further equipped with a fan. For example, in the runner method with heat medium oil described in Item 12, 13 or 14 of the patent application, the clean air discharge pipeline is further equipped with a fan. For example, in the runner method with heat medium oil described in Item 12, 13 or 14 of the patent application, the exhaust gas inlet pipeline is further equipped with a fan. For example, in the runner method with heat medium oil described in item 14 of the patent application, the other end of the cooling gas delivery pipeline is further connected to a heater, and the other end of the hot gas delivery pipeline is further connected to the heater. The heater is connected to the heater, wherein the heater is further any one of an air-to-air heat exchanger, a liquid-to-air heat exchanger, an electric heater, and a gas heater. For example, the runner with heat medium oil described in Item 12, 13 or 14 of the patent application scope Method, in which the heat medium oil tank of the heat medium oil system further uses heat medium as a heat source. The heat medium is liquid oil. The heat medium can pass through the air inlet heat medium oil output pipeline and the inlet heat medium. The oil input pipeline, the furnace heat medium oil output pipeline and the furnace heat medium oil input pipeline are used for circulating heating.

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