KR101030679B1 - Harmful gas ventilation device - Google Patents

Abstract

PURPOSE: A toxic gas discharging apparatus is provided to discharge liquid formed inside a duct by dew condensation to the outside according to the flow of gas. CONSTITUTION: A toxic gas discharging apparatus(100) comprises a booth(110), a lower duct(120), an upper duct(130), and an exhaust unit(140). The booth provides a space for processes. The lower duct comprises an intake port(121) connected to the upper end of the booth. The gas created in the booth moves through the lower duct. The upper duct discharges the gas passing through the lower duct. The exhaust unit discharges the gas of the upper duct. A gas flow assistant element(114) is installed on the lower part of the intake port within the booth.

Description

Hazardous Gas Discharge Device {HARMFUL GAS VENTILATION DEVICE}

The present invention relates to a harmful gas discharge device that can discharge harmful gases generated during various processes such as battery charging, plating and smelting.

Areas with many factories are more soot than other areas and have a characteristic odor. One of the causes of factory area fumes is that harmful gases are not sufficiently purified and released into the atmosphere. If the harmful gas generated from the factory is released to the atmosphere without being purified, the fumes are moved to other areas through the wind to pollute the air.If the fumes are moved to the ground through precipitation or snowfall, they pollute the surface. In addition to being absorbed from the ground, it contaminates groundwater. Therefore, in the factory where soot is generated during the process, the soot generated during the process should be sufficiently purified and discharged to the atmosphere.

There are a number of processes in which harmful gases are generated. For example, chemical manufacturing plants that manufacture chemicals using strong acids or alkalis, semiconductor manufacturing processes that use strong base materials such as NaOH or KOH, and battery manufacturing and battery charging processes that use sulfuric acid as an electrolyte. Hazardous gases are generated in many industrial processes.

Workers who work in workplaces where these harmful gases are generated are often exposed to direct or indirect exposure to harmful gases, compared to workers who do not emit hazardous gases. Even if the worker wears protective equipment to protect the worker's body from the harmful gas, it is not a fundamental solution to prevent the harmful gas.

Moreover, in the case of workers who work for a long time in the workplace where harmful gas is generated, harmful components may accumulate in the body due to long exposure of the harmful gas, which is fatal to the health of the worker. This is required.

'Noxious gas discharge device for battery charging process' of Korean Patent Laid-Open Publication No. 2005-0105107, which is one of the conventional systems for removing noxious gases, removes harmful gases and water vapor generated in the process of charging the battery 2. System. In the system, the pressure difference between the inside and the outside of the system is generated through the suction force sucked by the exhaust means 30, so that the harmful gas and the water vapor move with mobility.

However, since the harmful gas and water vapor generated in the booth 10 are not discharged smoothly from both side portions of the booth, the harmful gas and water vapor are loaded into the booth, so that the worker works inside the booth 10 during the filling process. If it is necessary, it is not easy for workers to enter without protective equipment due to the harmful gas loaded. The worker has a problem that may be threatened by the worker's health by breathing harmful gas remaining in the booth 10 without being discharged even after the filling is over.

And conventionally, if the condensation phenomenon occurs in the duct 20 pipe by moving the harmful gas and water vapor in the booth, the phenomenon that the liquid is accumulated in the duct 20 pipe, the duct 20 when a lot of liquid is generated When the liquid flows to the inside of the tube and the liquid is not discharged, the liquid flows back to the discharged battery 53 in the process of discharging the liquid into the discharge tube 53 located on the intake pipe side. In this case, the liquid reacts with the electrolyte of the battery. There was a problem that there is a risk of explosion and fire.

In addition, in the past, there was a point of inefficient operation of the system because it was not possible to discharge the gas by controlling the amount of harmful gas emissions according to the amount of harmful gas generated.

The present invention has been made in order to improve the above problems, the object of the harmful gas discharge device of the present invention is to provide a device that smoothly discharge the harmful gas in the booth where the harmful gas is generated.

In addition, an object of the present invention is to prevent the liquid generated due to condensation inside the upper duct to flow back to the lower duct, and to discharge the liquid inside the upper duct to the outside of the upper duct.

In addition, the present invention can control the flow of the gas discharged to the outside of the device according to the amount of harmful gas generated increases or decreases.

The harmful gas discharge device according to the present invention is provided with a booth for providing a space for performing a processing process of the injected object, the inlet is provided to be communicated from the top of the booth, the lower portion formed to move the gas generated in the booth A duct, an upper duct communicating with the lower duct, for discharging gas through the lower duct, and an exhausting means for evacuating the gas of the upper duct, the lower inlet being located in the booth from the booth to the lower duct. It is characterized in that the gas flow assistance means for smoothing the flow of the incoming gas is provided.

At this time, the gas flow assistance means is characterized in that it comprises a baffle is formed perforated, the support is connected to the top of the booth to support the baffle.

On the other hand, the harmful gas discharge device according to the present invention is a booth that provides a space for performing the processing process of the input, the lower duct is formed so that the gas generated in the booth is vertically communicated from the top of the booth, A horizontal duct communicating with the lower duct, the upper duct for discharging gas through the lower duct and an exhaust means for discharging the gas of the upper duct, wherein the lower duct includes an inlet for communicating at an upper end of the booth; And an exhaust port provided to exhaust the gas in the gas flow direction of the upper duct, and an exhaust control means provided in the lower duct pipe to adjust the amount of gas discharged from the booth. .

In this case, the exhaust control means is coupled to the lower duct by an axis on the cross section passing through the center of the cross section of the lower duct, characterized in that it is provided in a plate shape that can rotate about the axis.

On the other hand, the harmful gas discharge device according to the present invention is a booth providing a space for performing the processing process of the input, the lower duct is formed so that the gas generated in the booth is communicated from the top of the booth, the lower It includes an upper duct for communicating with the duct for exhausting the gas through the lower duct and exhaust means for exhausting the gas of the upper duct, the upper duct is provided with an expansion pipe extending than the diameter of the upper duct, It is characterized in that the liquid discharge path is connected to the expansion pipe so that the liquid generated in the upper duct can be discharged.

At this time, the booth is formed with an inlet for inserting the storage battery on one side, the transfer means for moving the storage battery is inserted into the inlet, the discharge port for discharging the charged battery is formed on the other side, the input storage battery It is characterized in that a space for charging the battery by connecting the power to the terminal of the.

And the upper duct further comprises a gas purifier for filtering harmful components of the gas passing through the expansion pipe.

In addition, the gas purifier, the reaction liquid injector is sprayed with a reaction liquid for removing the acidic or alkaline components contained in the gas, the venturi plate for filtering particulate contaminants contained in the gas flowing into the gas purifier and the It is characterized in that it comprises a dehumidifying apparatus for removing the reaction solution.

As described above, according to the present invention, harmful gases and water vapor (hereinafter, referred to as "gas") generated inside the booth are actively convection inside the booth, so that the flow to the duct is improved and the worker is safe. It is effective to work in the booth.

In addition, since the liquid formed due to condensation inside the duct pipe is moved to the liquid discharge pipe according to the flow of gas in the upper duct, the liquid can be easily discharged to the outside of the upper duct. It can reduce the risk of accidents.

In addition, when less harmful gas is generated, it is possible to reduce the amount of exhausted gas than when harmful gas is generated, thereby reducing the power consumption of operating the exhaust means unnecessarily.

1 shows a harmful gas discharge device according to an embodiment of the present invention.
Figure 2 shows a part of the harmful gas discharge device according to an embodiment of the present invention.
3 (a) to (c) is a view showing the angle formed between the exhaust control plate and the pipe cross-section that is part of the harmful gas discharge device according to an embodiment of the present invention.
Figure 4 is a cross-sectional view showing a form in which the lower duct which is part of the harmful gas discharge device in accordance with an embodiment of the present invention communicated with the upper duct.
5 is a cross-sectional view illustrating a form in which an expansion pipe and a liquid discharge passage communicate with each other in an upper duct that is a part of a harmful gas discharge device according to an exemplary embodiment of the present invention.
Figure 6 (a) is an enlarged view showing the venturi plate in the gas purifier which is part of the harmful gas discharge device according to an embodiment of the present invention.
Figure 6 (b) is an enlarged view showing a dehumidifier in the gas purifier which is part of the harmful gas discharge device according to an embodiment of the present invention.

Preferred embodiments of the present invention will be described in more detail with reference to the accompanying drawings, but the well-known technical parts will be omitted or compressed for brevity of description.

<Configuration of harmful gas discharge device>

In the following harmful gas discharge device, a case of toxic gas discharge generated when charging the battery will be described by way of example, but the present invention is not limited thereto. It can be generated, and in each of these processes it is possible to apply the harmful gas discharge device of the present invention. Hazardous gas discharge device 100 according to an embodiment of the present invention is a booth 110, lower duct 120, upper duct 130, exhaust means 140, gas purifier 150 and flue 160 It is comprised, and it demonstrates with reference to FIG.

1 is a view showing the harmful gas discharge device 100.

The booth 110 connects a power source to a terminal of the battery for a predetermined time in order to charge the battery and replenishes the electrolyte to provide a space for charging. In other words, it provides a space for performing the processing process of the injected object.

The booth 110 is provided with an inlet 111, outlet 112, the conveying means 113 and gas flow assistance means.

The inlet 111 is configured in the form of a door that can be opened and closed so that the battery can enter the booth 110 through the transfer means 113 for charging and is formed on one side of the booth 110.

Discharge port 112 is configured in the form of a door that can be opened and closed so that the battery after the charging of the battery is completed from the booth 110 to the outside and is formed on the other side of the booth (110).

The inlet 111 and the outlet 112 are closed at the time of charging the battery, in order to reduce power consumption by preventing external air from flowing unnecessarily to rotate the fan during battery charging.

The transfer means 113 is implemented as a conveyor belt to move the storage battery to the booth 110 for charging the storage battery.

Gas flow assistance means serves to smooth the flow of gas flowing into the lower duct 120 from the booth (110).

Gas flow assistance means according to an embodiment of the present invention comprises a baffle 114 and the support (115).

The baffle 114 is fixed to the ceiling of the booth 110 through a support 115 to be described later, and is installed inside the booth 110 at regular intervals from the inlet 121 to be described later. Due to the perforations formed on the surface of the baffle 114 serves to induce the flow of gas having a linear direction and the rotational direction in the booth 110.

The support 115 serves to fix the baffle 114 to the ceiling of the booth 110, and the position at which the baffle 114 is fixed through the support 115 is supported at the circumferential portion of the inlet 121 to be described later. 115 is fixed and coupled with the baffle 114 through the fixed support 115. For reference, the number of the support 115 is not limited, but it should be able to fix the baffle 114 by maintaining the load.

2 is a diagram illustrating a form in which the baffle 114 according to an embodiment of the present invention is installed in the booth 110. Referring to FIG. 2, the flow of gas induced by the baffle 114 installed inside the booth 110 will be described.

Flow a is a "flow of gas with a straight directional", flow b is a "flow of gas with a rotatable", flow a appears through the perforations formed in the baffle 114, flow b is baffle 114 And appear to be moved to the space between the support 115.

Conventionally, the gas flow a is mainly formed in the booth 110 toward the intake port 121, which will be described later, so that the gas in the upper side portion of the booth 110 is not exhausted smoothly but is loaded but the baffle 114 is installed to As the flow b was formed, the flowability in the booth 110 was improved.

Lower duct 120 is composed of a tube, the tube is configured in a vertically bent form. The lower duct 120 is formed with an inlet port 121, an exhaust control means, an exhaust port 123 and the vibration preventing tube 124.

The intake port 121 is a hole formed in the ceiling of the booth 110 and formed so that the gas generated during charging of the battery is moved and discharged.

3 (a) to (c) is a view showing the angle formed between the exhaust control plate 122 and the tube cross-section (S) according to an embodiment of the present invention. The exhaust control plate 122 will be described with reference to FIG. 3.

Exhaust control means according to an embodiment of the present invention comprises an exhaust control plate 122 coupled to the shaft (A) inside the lower duct (120).

In the lower duct 120, the gas is formed between the inlet port 121 and the exhaust port 123 which will be described later, and the amount of gas that is moved through the inlet port 121 in the booth 110 is adjusted through the exhaust control plate 122. Thus, gas flow can be regulated throughout the system. The shaft A of the exhaust control plate 122 is formed inside the lower duct 120, so that the exhaust control plate 122 is opened or closed automatically or manually so as to adjust the amount of gas that is moved through the lower duct 120. do.

First, (a) of FIG. 3 is an angle θ ₁ formed between the pipe cross section S and the exhaust control plate 122 to form a right angle. In this case, the flow of gas that is moved from the lower duct 120 to the upper duct 130 is maintained to the maximum.

3 (b) shows that the angle θ ₂ formed between the cross section S of the pipe and the exhaust control plate 122 is 0 ° <θ ₂ <90 °, and it is relatively lower than that of FIG. 3 (a). The flow is less.

3 (c) shows an angle θ ₃ formed between the pipe cross section S and the exhaust control plate 122 to form 0 °, and the gas moved from the lower duct 120 to the upper duct 130 is an exhaust control plate. Since it is impossible to pass through the 122, it cannot be moved to the upper duct 130.

When the number of accumulators to be charged is small, the angle of the exhaust control plate 122 and the pipe cross section S may be reduced to reduce the amount of gas discharged.

The exhaust port 123 is formed in the form of a hole through which the gas introduced through the inlet 121 at the other side of the lower duct 120 can flow out.

The anti-vibration pipe 124 may be installed in a direction in which gas moving in the lower duct 120 flows into the exhaust control plate 122 or in a direction in which gas exiting the exhaust control plate 122 flows out.

Due to the curved shape of the anti-vibration tube 124, the anti-vibration tube 124 exhibits a property of being stretched. Due to the nature of the anti-vibration tube 124, even if vibration is generated in the lower duct 120, the vibration is prevented from being transmitted to the booth 110, and conversely, even if vibration is generated in the booth 110, the lower duct 120 The transmission of vibrations is prevented.

4 is a diagram illustrating a form in which the lower duct 120 communicates with the upper duct 130. Referring to FIG. 4, the lower duct 120 and the upper duct 130 communicate with each other. The diameter of the lower duct 120 is c and the diameter of the upper duct 130 is d.

And when communicating with the upper duct 130 at the exhaust port 123 side of the lower duct 120, the lower duct 120 and the upper duct 130 has a central axis and the lower duct 120 is in the shape of the upper duct Coupled with 130. Difference in diameter between the lower duct 120 and the upper duct 130, that is, c is a shorter than the length of d and the upper duct 120 in the form of the lower duct 120 has the same central axis between the upper, lower duct 120 Since it is in communication with the 130, even if the liquid is standing in the upper duct 130 to the degree that the liquid flows to the lower duct 120 will not flow back.

The upper duct 130 is formed with an expansion tube 131, a liquid discharge passage 132 and an anti-vibration tube 133.

Figure 5 is a cross-sectional view showing a form in which the expansion pipe 131 and the liquid discharge passage 132 in the upper duct 130 in accordance with the present invention.

The expansion pipe 131 has a diameter difference due to its larger diameter than the upper duct 130, the expansion pipe 131 and the upper duct 130 may be connected to each other by welding, and the liquid discharge passage 132 may be an expansion pipe. The tube is divided in 131.

The liquid discharge passage 132 is formed outside the upper duct 130, and when the gas introduced into the upper duct 130 condenses inside the upper duct 130 due to condensation, the liquid is generated. It is possible to exit to the outside of the upper duct 130 through the discharge passage (132).

The anti-vibration tube 133 may be installed in a direction in which gas moving inside the upper duct 120 flows into the gas purifier 150 or in a direction in which gas exiting the gas purifier 150 flows out.

The anti-vibration tube 133 has a curved shape, and thus the anti-vibration tube 133 exhibits a property of being stretched. Due to the nature of the anti-vibration tube 133, even if vibration is generated in the upper duct 130, the vibration is prevented from being transmitted to the exhaust means 140 and the flue 160, and conversely, the exhaust means 140 and the flue ( Although vibration is generated at 160, the vibration is prevented from being transmitted to the upper duct 130.

Looking at the cross-sectional view of the expansion tube 131 coupled to the upper duct 130 with reference to Figure 5 when the gas and liquid moved in the upper duct 130 passes through the expansion tube 131, Since the diameter is larger than that of the upper duct 130, the height of the upper duct 130 and the expansion tube 131 is formed due to the diameter difference between the expansion pipe 131 and the upper duct 130. Although the flow of gas is continuously maintained even though it passes through the expansion pipe 131 through 130, in the case of liquid, when the gas flows into the expansion pipe 131, the gas cannot rise back to the upper duct 130 and the expansion pipe 131. The liquid is discharged through the liquid discharge passage 132 formed at the.

That is, due to the structure of the expansion pipe 131, when the liquid is introduced into the expansion pipe 131 through the upper duct 130, the liquid of the expansion pipe 131 cannot move toward the upper duct 130, so that the liquid Backflow is prevented.

Therefore, the liquid due to the condensation inside the upper duct 130 has a mobility such as flow e is divided in the expansion pipe 131 is moved toward the liquid discharge path 132 formed to the outside, the gas is flow f It is moved. The flow e is the flow of liquid inside the upper duct 130, which moves in the same direction as the flow f in which the gas moves, but the flow e falls from the upper duct 130 toward the lower liquid outlet 132. By exiting the upper duct 130, the gas is continuously moved in the direction of the exhaust means 140 to be described later, such as flow f.

Exhaust means 140 generates a suction force through the rotation of the fan to suck the gas and liquid toward the exhaust means 140, wherein the booth 110 is formed with a lower pressure than the booth 110 outside the booth 110 The outside air may naturally flow into the booth 110. The gas inside the booth 110 includes not only air introduced from the outside but also gas generated during charging of the battery as described above, and the gas inside the booth 110 is lowered by the pressure generated by the exhaust means 140. The duct 120 is moved toward the upper duct 130 to be discharged.

The gas purifier 150 is installed between the expansion pipe 131 of the upper duct 130 and the exhaust means 140 which will be described later to filter out harmful components of the gas that has passed through the expansion pipe 131. It comprises a device 151, a venturi plate 152 and a dehumidifier 153.

The reaction solution injector 151 may remove the acidic substance using an alkaline solution such as NaOH to purify the acidic gas contained in the gas passing through the expansion tube. In addition, it may be used as a pretreatment process for treating pollutants that react quickly to a specific reactant depending on the characteristics of the substance present in the gas. When the substance to be removed is an alkaline substance, HCl and Spray with the same acidic material. A gas-liquid reaction occurs in which a pollutant of a gas contained in a noxious gas reacts with a reaction solution. The gas-liquid reaction removes contaminants from a gas.

Venturi plate 152 is a plate formed with a plurality of Venturi (Venturi) structure, as shown in Figure 6 (a) is a venturi structure is a narrow diameter of the tube having a constant diameter, Due to the venturi structure, the gases and liquids passing through the venturi structure are temporarily increased in pressure, resulting in changes in flow rate and flow rate. That is, the reaction solution injected to remove the acidic or alkaline substances from the reaction solution injector 151 is moved to the venturi plate 152 to react with the contaminants present in the gas while passing through the venturi structure. A gas-liquid reaction occurs in which contaminants are removed. In the venturi plate 152, relatively large contaminants are removed.

The dehumidifier 153, as shown in Figure 6 (b), there are a plurality of plates, each plate consists of an internal structure having a diagonal shape, each plate arranged in a plurality of layers of the overall diagonal shape To form a flow path. Each plate used for forming such a diagonal flow path is called a diagonal flow path plate.

The pressure loss is minimized when gas passes through a plurality of diagonal flow path plates. At this time, if the arrangement of the diagonal flow path plates is 6 or more stages, gas-liquid reaction is performed in 1 to 3 stages, and the reaction liquid is removed in 4 to 6 stages. do. The contaminant of the contaminated gas is removed by reacting the reaction liquid with the gas while passing through the contaminated gas path, and after the gas-liquid reaction, the reaction liquid can be removed through an additional circulation device of the reaction liquid. It can also be reused by moving to the reaction solution injector (151).

Flue 160 is a tube formed so that the gas is moved by the suction force by the exhaust means 140 to exit the upper duct 130, the flue 160 has a form protruding to the outside. The flue 160 may additionally install a fan (not shown) in the pipe in which the flue 160 is formed to discharge the gas out of the flue 160 through a suction force.

As described above, the detailed description of the present invention has been made by the embodiments with reference to the accompanying drawings. However, since the above-described embodiments have only been described with reference to preferred embodiments of the present invention, the present invention is limited only to the described embodiments. It is not to be understood that the scope of the invention should be understood by the claims and equivalent concepts described below.

100: harmful gas discharge device
110: booth
120: lower duct
130: upper duct
140: exhaust means
150: gas purifier
160: year

Claims (9)

A booth providing a space for performing a processing process of the injected object;
A lower duct provided with an inlet for communicating at an upper end of the booth and configured to move a gas generated in the booth;
An upper duct communicating with the lower duct for discharging gas through the lower duct; And
And exhaust means for exhausting the gas in the upper duct;
Under the intake port in the booth,
Gas flow assistance means for smoothly flowing the gas flowing into the lower duct in the booth;
The booth is,
An inlet for inserting the battery is formed on one side, a transport means for moving the battery inserted into the inlet is provided, an outlet for discharging the charged battery is formed on the other side, the power supply to the terminal of the battery Hazardous gas discharge device, characterized in that the space is formed for connecting to charge the battery. A booth providing a space for performing a processing process of the injected object;
A lower duct provided with an inlet for communicating at an upper end of the booth and configured to move a gas generated in the booth;
An upper duct communicating with the lower duct for discharging gas through the lower duct; And
And exhaust means for exhausting the gas in the upper duct;
Under the intake port in the booth,
Gas flow assistance means for smoothly flowing the gas flowing into the lower duct in the booth;
The gas flow assist means,
Baffles with perforations formed;
And a supporter connected to an upper end of the booth to support the baffle. A booth providing a space for performing a processing process of the injected object;
A lower duct communicating vertically at an upper end of the booth to move a gas generated in the booth;
An upper duct communicating horizontally with the lower duct for discharging gas through the lower duct; And
And exhaust means for exhausting the gas in the upper duct;
In the lower duct,
An air inlet for communicating at an upper end of the booth;
An exhaust port provided to exhaust gas in a gas flow direction of the upper duct; And
Exhaust control means provided in the lower duct pipe for adjusting the amount of gas discharged from the booth and is provided,
The booth is,
An inlet for inserting the battery is formed on one side, a transport means for moving the battery inserted into the inlet is provided, an outlet for discharging the charged battery is formed on the other side, the power supply to the terminal of the battery Hazardous gas discharge device, characterized in that the space is formed for connecting to charge the battery. The method of claim 3,
The exhaust control means,
Toxic gas discharge device characterized in that it is provided in a plate shape that is coupled to the lower duct by an axis on the cross section passing through the center of the cross section of the lower duct can rotate about the axis. A booth providing a space for performing a processing process of the injected object;
A lower duct communicating with an upper end of the booth to allow gas generated in the booth to move;
An upper duct communicating with the lower duct for discharging gas through the lower duct; And
And exhaust means for exhausting the gas in the upper duct;
In the upper duct,
An expansion pipe is expanded than the diameter of the upper duct is provided,
Hazardous gas discharge device characterized in that is formed; is connected to the expansion pipe is a liquid discharge path for discharging the liquid generated in the upper duct The method of claim 2,
The booth is,
An inlet for inserting the battery is formed on one side, a transport means for moving the battery inserted into the inlet is provided, an outlet for discharging the charged battery is formed on the other side, the power supply to the terminal of the battery Hazardous gas discharge device, characterized in that the space is formed for connecting to charge the battery. 6. The method of claim 5,
The booth is,
An inlet for inserting the battery is formed on one side, a transport means for moving the battery inserted into the inlet is provided, an outlet for discharging the charged battery is formed on the other side, the power supply to the terminal of the battery Hazardous gas discharge device, characterized in that the space is formed for connecting to charge the battery. The method according to any one of claims 1 to 7,
The upper duct,
Hazardous gas discharge device further comprises; gas purifier for removing harmful components of the gas; The method of claim 8,
The gas purifier,
A reaction liquid injector into which a reaction liquid for removing acidic or alkaline components contained in the gas is injected;
A venturi plate for filtering particulate contaminants contained in the gas introduced into the gas purifier; And
A dehumidifier for removing the reaction solution; Hazardous gas discharge device comprising a

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