TWM472555U - Waste gas processing device - Google Patents

Description

Exhaust gas treatment device

The present invention relates to the technical field of exhaust gas purification treatment, and more particularly to an exhaust gas treatment device.

It is known that in semiconductor fabs, photovoltaic power plants, panel factories, and solar power plants, harmful exhaust gas is sometimes generated during the production of products such as wafers or various panels. For example, in a semiconductor fab, the harmful exhaust gas generated in the process includes monosilane (SiH ₄ ), chlorine (Cl ₂ ), PFC (perfluoro-compounds), etc. In the case of exhaust gas of a gas, four methods such as a wet method, an adsorption method, a thermal decomposition method, and a combustion method are generally used.

Wherein, the heating decomposition method refers to providing a heater in the exhaust gas treatment tank, and the heater forms a heating chamber in the exhaust gas treatment tank, and the heat is heated by the heater when the harmful exhaust gas enters the exhaust gas treatment tank and reaches the heating chamber. The radiation method heats the harmful exhaust gas, forcing the harmful substances contained in the harmful exhaust gas to be decomposed into harmless substances by high-temperature catalysis, and the wet method means passing the harmful exhaust gas through the water washing chamber provided with a plurality of sprinklers, by the sprinkler The sprayed water curtain is in contact with harmful exhaust gas, and dissolves harmful substances dissolved in harmful exhaust gas to achieve the effect of purifying harmful exhaust gas; as for the combustion method, the harmful exhaust gas is burned by using a flame to purify harmful exhaust gas. The effect is that the gas used to provide flame combustion is a mixture of fuel such as methane (CH ₄ ), ethane (C ₂ H ₆ ), and propane (C ₃ H ₈ ) and air in a predetermined ratio, wherein methane is burned. After that, harmful gases such as carbon monoxide (CO) are generated, causing secondary pollution. Therefore, the current semiconductor process exhaust gas treatment method adopted on the premise of environmental protection is to use the heat decomposition method with the wet method to achieve the effect of purifying the exhaust gas.

However, due to the lack of design of the exhaust gas treatment device in the conventional exhaust gas treatment device, the time for the harmful exhaust gas to be heated in the exhaust gas treatment tank is forced to be short, which leads to the acceptance of harmful exhaust gas when purifying the harmful exhaust gas by the heating decomposition method. Insufficient heating time, it is difficult to completely catalyze harmful substances in harmful exhaust gas, thus affecting the purification efficiency of harmful exhaust gas. Therefore, how to delay the heating time of harmful exhaust gas in the exhaust gas treatment tank, thereby improving the purification efficiency of harmful exhaust gas It has become an important issue that should be faced by those skilled in the art to be improved.

In view of the above, the object of the present invention is to provide an exhaust gas treatment device which can improve the purification efficiency of harmful exhaust gas by delaying the time during which the harmful exhaust gas is heated and purified in the exhaust gas treatment tank. In order to achieve the above object and solve the problem, the technical means of the exhaust gas treatment device of the present invention comprises: an exhaust gas treatment tank, forming an exhaust gas inlet and an exhaust gas outlet, and a surrounding ring is arranged in the exhaust gas treatment tank. a heater, a heating rod is disposed in the annular heater, and a heating chamber is formed between the annular heater and the heating rod; a partition is disposed between the annular heater and the heating rod, The separators are spaced apart to form a gas flow path within the heating chamber. Wherein, one of the gas flow passages communicates with the exhaust gas inlet port, and one of the gas flow passages communicates with the exhaust gas outlet port through the heating chamber, and the exhaust gas passes through the heating chamber through the gas flow passage from the exhaust gas inlet port. Flow to the exhaust gas outlet.

Accordingly, the present invention is a gas flow passage formed by providing a partition between the annular heater and the heating rod, and the gas flow passage is used to delay the passage of the harmful exhaust gas through the heating chamber, so that the exhaust gas can be sufficiently heated. In order to purify harmful substances contained in harmful exhaust gas, thereby avoiding environmental pollution.

In implementation, the novel further includes: the gas flow channel is a meandering flow channel. Accordingly, the harmful exhaust gas is heated in the heating chamber by delaying the passage of the harmful exhaust gas through the heating passage through the gas flow passage. The chamber is heated sufficiently to improve the purification efficiency of the exhaust gas.

The partition comprises an outer partition and an inner partition, the outer partition is disposed between the annular heater and the heating rod, and the inner partition is disposed between the outer partition and the heating rod, the gas flow The passage is formed by spacing the outer partition and the inner partition in the heating chamber. The gas flow path includes a first gas flow channel, a second gas flow channel, and a third gas flow channel. The first gas flow channel is formed between the annular heater and the outer separator, and the second The gas flow path is formed between the outer partition and the inner partition, and the third gas flow path is formed between the inner partition and the heating rod, and the inlet end of the gas flow passage sequentially passes through the first gas flow passage, The two gas flow channels and the third gas flow path are connected to the gas outlet end. Accordingly, the gas flow path is formed at intervals between the heating chamber by the outer partition plate and the inner partition plate, thereby delaying the passage of the harmful exhaust gas through the heating chamber to improve the purification efficiency of the harmful exhaust gas.

A water washing chamber is also included, and the water washing chamber is disposed at one end of the exhaust gas inlet or one end of the exhaust gas outlet. There are a plurality of washing chambers, and the washing chambers are respectively disposed at one end of the exhaust gas inlet and one end of the exhaust gas outlet. Accordingly, the water-soluble chamber is used to dissolve the harmful substances in the harmful exhaust gas, and the heated exhaust gas is cooled to facilitate discharge to the outside atmosphere without causing environmental pollution.

A high pressure air intake port is also included, formed on the exhaust gas treatment tank and communicating with the intake end of the gas flow passage. Accordingly, the high-pressure air is used to drive the harmful exhaust gas through the gas flow path, and to provide the oxygen required for the harmful substances contained in the harmful exhaust gas to undergo high-temperature catalysis.

The exhaust gas treatment tank is externally covered with a heat insulating layer. Accordingly, it is possible to reduce the influence of the high temperature emitted by the exhaust gas treatment tank when dealing with harmful exhaust gas to the external environment.

The exhaust gas treatment device is an exhaust gas treatment device disposed in a semiconductor fab, a photovoltaic power plant, a panel factory, and a solar power plant. Accordingly, the exhaust gas treatment device is used to purify harmful exhaust gas generated in processes such as semiconductors to avoid environmental pollution.

The above content and the subsequent embodiments and the drawings are briefly described in order to further explain the technical means adopted by the present invention to solve the problem and the effects thereof. The relevant details of the present invention that can be implemented will also be explained in the subsequent detailed description and drawings.

10‧‧‧Exhaust gas treatment tank

11‧‧‧Exhaust air intake

12‧‧‧Exhaust gas outlet

13‧‧‧High pressure air inlet

131‧‧‧High pressure air tube

20‧‧‧Ring heater

21‧‧‧heating chamber

22‧‧‧ gas flow path

221‧‧‧ intake end

222‧‧‧Exhaust end

223‧‧‧First gas flow path

224‧‧‧Second gas flow path

225‧‧‧ third gas flow path

30‧‧‧heating rod

40‧‧‧Baffle

41‧‧‧ outer partition

411‧‧‧ mouth

412‧‧‧The seat

42‧‧‧Internal partition

421‧‧‧ first mouth

422‧‧‧ Second Department

423‧‧‧The lower seat

50‧‧‧Insulation

60‧‧‧Washing room

61‧‧‧ sprinkler

70‧‧‧Exhaust pipe

1 is a schematic view showing the configuration of a first embodiment of the present invention.

2 is a schematic view showing the configuration of a second embodiment of the present invention.

Fig. 3 is a schematic view showing the configuration of a third embodiment of the present invention.

Figure 4 is a schematic view showing the configuration of a fourth embodiment of the present invention.

Figure 5 is a partially enlarged schematic view of Figure 4.

Referring to FIG. 1 , a schematic diagram of a configuration of a first embodiment of the present invention is disclosed. The present invention provides an exhaust gas treatment device including an exhaust gas treatment tank 10 , an annular heater 20 , a heating rod 30 and a partition plate . 40. The exhaust gas treatment tank 10 is a metal container, and the exhaust gas treatment tank 10 is formed with a communicating exhaust gas inlet port 11 and an exhaust gas outlet port 12, and the exhaust gas inlet port 11 is connected to an exhaust gas pipe 70. The exhaust gas is exhausted from the exhaust gas inlet port 11 into the exhaust gas treatment tank 10 by the exhaust pipe 70, and flows out from the exhaust gas outlet port 12, and the annular heater 20 is disposed around the exhaust gas treatment tank 10, and is heated in a ring shape. A heating rod 30 is disposed in the device 20 at intervals. In practice, the heating rod 30 may be disposed at a central position of the annular heater 20, and a heating chamber 21 is formed between the annular heater 20 and the heating rod 30. After the harmful exhaust gas enters the heating chamber 21, it is simultaneously catalyzed by the high heat generated by the annular heater 20 and the heating rod 30 to increase the effect of the harmful exhaust gas being heated and purified. In the present embodiment, the annular heater 20 and the heating rod 30 are electrothermal heaters. Compared with the combustion heater, the gas as a fuel can be prevented from generating harmful gases after combustion, resulting in secondary pollution.

The partition 40 is annular and is disposed around the annular heater 20 Between the heating rods 30, the heating chambers 21 are separated by a partition 40 to form a gas flow path 22, and an end of the gas flow path 22 adjacent to the exhaust gas inlet port 11 forms an intake end 221, and the gas flow path 22 An end of the exhaust gas outlet 12 is formed at an end of the exhaust gas outlet 12, and the exhaust gas flows into the gas flow passage 22 through the intake end 221 through the exhaust gas inlet port 11 and flows from the outlet end 222 to the exhaust gas outlet port 12 through the exhaust gas through the gas flow. The passage 22 extends the stroke of the exhaust gas through the heating chamber 21, thereby increasing the time during which the exhaust gas passes through the heating chamber 21, so that the exhaust gas can be sufficiently heated.

Further, please refer to FIG. 2 , which is a schematic diagram showing the configuration of the second embodiment of the present invention. The partition 40 shown in FIG. 1 may substantially include an outer partition 41 and an inner partition 42 , and the outer partition. 41 and the inner partition plate 42 are respectively a circular pipe body. The outer partition plate 41 is assembled on the top of the exhaust gas treatment tank 10 by a top seat portion 412 and extends toward the bottom. The inner partition plate 42 is a lower seat portion. The 423 group is disposed at the bottom of the exhaust gas treatment tank 10 and extends toward the top, the outer partition 41 is closed at one end of the top of the exhaust gas treatment tank 10, and the end extending to the bottom of the exhaust gas treatment tank 10 has a mouth portion 411, and the inner partition plate 42 is located at the exhaust gas. The bottom of the treatment tank 10 has a first mouth portion 421, and one end extending to the top of the exhaust gas treatment tank 10 has a second mouth portion 422, which is located at the annular heater 20 by the outer partition plate 41 and the inner partition plate 42 The heating chamber 21 between the heating rods 30 is spaced apart to form a serpentine gas flow path 22.

Further, referring to FIG. 2, the gas flow path 22 shown in FIG. 2 includes a first gas flow path 223, a second gas flow path 224, and a third gas flow path 225. The gas flow path 223 is formed between the annular heater 20 and the outer partition 41, and the second gas flow path 224 is formed between the outer partition 41 and the inner partition 42. The third gas flow path 225 is Formed between the inner partition plate 42 and the heating rod 30, after the harmful exhaust gas enters the heating chamber 21 via the exhaust gas inlet port 11, the first gas passage 223 enters the first gas flow passage 223 through the intake end 221, and then passes through the outer partition plate 41. The mouth portion 411 enters the second gas flow path 224, and is connected The third port portion 422 of the inner partition plate 42 enters the third gas flow path 225, and the gas outlet end 222 flows to the exhaust gas outlet port 12 through the first port portion 421 of the inner partition plate 42 and is provided by the annular heater. 20 and the heating rod 30 enable the harmful exhaust gas to maintain a stable temperature while passing through the first gas flow path 223 and the third gas flow path 225, thereby facilitating the purification efficiency of the harmful exhaust gas.

In addition, referring to FIG. 3, a schematic diagram of a configuration of a third embodiment of the present invention is disclosed, illustrating that the exhaust gas treatment device of the present invention further includes a water washing chamber 60, and the water washing chamber 60 refers to a configuration in a region where harmful exhaust gas passes. The sprinkler 61 dissolves the harmful substances dissolved in the harmful exhaust gas by the contact of the water curtain sprayed by the sprinkler 61 with the exhaust gas, thereby achieving the function of purifying the harmful exhaust gas. The water washing chamber 60 can be disposed at one end of the exhaust gas inlet port 11 or the exhaust gas outlet port 12 of the exhaust gas treatment tank 10, or at one end of the exhaust gas inlet port 11 and the exhaust gas outlet port 12 of the exhaust gas treatment tank 10. Wherein, the water washing chamber 60 disposed at one end of the exhaust gas inlet port 11 dissolves the harmful substances soluble in water in the harmful exhaust gas before being heated and purified, and is disposed at one end of the exhaust gas outlet port 12 The washing chamber 60 has a function of cooling the high-temperature exhaust gas in addition to dissolving harmful substances soluble in water contained in the harmful exhaust gas. In the present embodiment, a water washing chamber 60 is disposed at one end of the exhaust gas inlet port 11 of the exhaust gas treatment tank 10 and one end of the exhaust gas outlet port 12, so that the exhaust gas is soluble in the harmful exhaust gas before being subjected to the heat treatment. The harmful substances in the water are dissolved to prevent the harmful substances in the harmful exhaust gas from being deteriorated when subjected to heat treatment, thereby generating new harmful substances, and when the harmful exhaust gas is purified by heat, the water washing chamber 60 can be used. The original residue and the water-soluble harmful substances generated by the heat are dissolved, and the high-temperature exhaust gas is cooled, thereby improving the effect of purifying the harmful exhaust gas.

Next, referring to FIG. 4, a schematic diagram of a configuration of a fourth embodiment of the present invention is disclosed. The exhaust gas treatment device of the present invention further includes a high-pressure air inlet 13 formed on the wall of the exhaust gas treatment tank 10 and connected. The intake end 221 of the gas flow path 22 and the high-pressure air inlet 13 are connected to a high-pressure air pipe 131. The high-pressure air introduced by the high-pressure air pipe 131 contacts and mixes with the harmful exhaust gas to drive the harmful exhaust gas through the gas flow path 22 . And provide the oxygen (O ₂ ) required for harmful exhaust gas to undergo high temperature catalysis.

Referring to FIG. 5, a partial enlarged view of FIG. 4 is disclosed to illustrate that the temperature of the exhaust gas treatment tank 10 of the present invention is about 950 degrees Celsius to 1100 degrees Celsius when heating and purifying harmful exhaust gas, in order to avoid the generation of the exhaust gas treatment tank 10. The high temperature affects the environment and the human body. Therefore, a heat insulating layer 50 is coated on the surface of the exhaust gas treatment tank 10, except that the heat insulation layer 50 reduces the high temperature emitted by the exhaust gas treatment tank 10 and affects the external environment. The heat energy in the exhaust gas treatment tank 10 is prevented from being lost to the outside, and the temperature is lowered, thereby affecting the purification efficiency of the harmful exhaust gas.

In addition, the exhaust gas treatment device of the present invention is used to purify harmful exhaust gas generated in the process of industrially produced articles. In the present embodiment, the exhaust gas treatment device is disposed in a semiconductor fab, a photovoltaic power plant, a panel factory, or a solar power plant to purify harmful exhaust gas generated, for example, in a semiconductor process.

According to the description of the above embodiments, the exhaust gas treatment device of the present invention firstly uses a ring-shaped heater and a heating rod to simultaneously heat the harmful exhaust gas on both sides of the inside and the outside to prevent the harmful exhaust gas from lowering the purification rate due to uneven heating during heating. The outer partition and the inner partition are used to form a serpentine gas flow passage to prevent the harmful exhaust gas from being heated and purified in the exhaust gas treatment tank, thereby improving the purification efficiency of the harmful exhaust gas.

In the above, the present invention is only intended to be a preferred embodiment of the present invention, and is not intended to limit the present invention; any equivalent modifications or substitutions that are not departing from the spirit of the present invention should be included in the following patent application. Within the scope.

10‧‧‧Exhaust gas treatment tank

11‧‧‧Exhaust air intake

12‧‧‧Exhaust gas outlet

20‧‧‧Ring heater

21‧‧‧heating chamber

22‧‧‧ gas flow path

221‧‧‧ intake end

222‧‧‧Exhaust end

30‧‧‧heating rod

40‧‧‧Baffle

70‧‧‧Exhaust pipe

Claims (8)

An exhaust gas treatment device comprises: an exhaust gas treatment tank, forming an exhaust gas inlet and an exhaust gas outlet, and a ring heater is arranged around the exhaust gas treatment tank, and a heating is arranged in the annular heater a heating chamber is formed between the annular heater and the heating rod; a partition is disposed between the annular heater and the heating rod, and the heating chamber is formed with a gas flow passage through the partition; wherein One of the gas flow passages communicates with the exhaust gas inlet port, and one of the gas flow passages communicates with the exhaust gas outlet port through the heating chamber, and the exhaust gas flows from the exhaust gas inlet port through the gas flow passage through the heating chamber Exhaust gas outlet. The exhaust gas treatment device of claim 1, wherein the gas flow path is a meandering flow path. The exhaust gas treatment device of claim 1, wherein the partition comprises an outer partition and an inner partition, the outer partition is disposed between the annular heater and the heating rod, the inner partition The utility model is disposed between the outer partition and the heating rod, and the gas flow passage is formed by spacing the outer partition and the inner partition in the heating chamber. The exhaust gas treatment device of claim 3, wherein the gas flow path comprises a first gas flow path, a second gas flow path and a third gas flow path, the first gas flow path being formed in the ring Between the heater and the outer partition, the second gas flow path is formed between the outer partition and the inner partition, and the third gas flow path is formed between the inner partition and the heating rod, and the gas flow path The intake end sequentially communicates with the outlet end via the first gas flow path, the second gas flow path, and the third gas flow path. The exhaust gas treatment device according to claim 1, further comprising a water washing chamber disposed at one end of the exhaust gas inlet or one end of the exhaust gas outlet. The exhaust gas treatment device according to claim 5, wherein the plurality of water washing chambers are respectively disposed at one end of the exhaust gas inlet and one end of the exhaust gas outlet. An exhaust gas treatment device according to claim 1, wherein The utility model comprises a high-pressure air inlet formed on the exhaust gas treatment tank and communicating with the inlet end of the gas flow passage. The exhaust gas treatment device of claim 1, wherein the exhaust gas treatment tank is externally coated with a heat insulating layer.