KR101193663B1 - Dried high pressure air supply system - Google Patents

Abstract

[Problem] It is possible to optimize the operation of the air compressor, to reduce the power consumption, to reduce the amount of cohesive water recovered in the tank, and to supply the high-pressure dry air that can improve the maintenance of the tank. Provide a system.
[Remedy] High pressure dry air supply system (1), which depressurizes the high pressure air stored in the tank (6) by the air compressor (2) and dehumidifies the mist separator (12) and supplies the high pressure dry air to the equipment (21). In the downstream side of the mist separator, the check valve 22 which prevents the backflow of the high pressure dry air to the mist separator is provided, and supply and stop of the high pressure air from a tank to a mist separator between a mist separator and a tank are carried out. The solenoid opening and closing valve 19 for switching the pressure sensor is provided, and the high pressure dry air pressure downstream of the check valve is detected. When the high pressure dry air pressure exceeds the set value, the solenoid opening and closing valve is closed to maintain the internal pressure of the tank. The 2nd pressure switch 20 which suppresses a fall was provided.

Description

High pressure dry air supply system {DRIED HIGH PRESSURE AIR SUPPLY SYSTEM}

According to the present invention, it is possible to optimize the operation of the air compressor, to reduce the power consumption, to reduce the amount of condensed water recovered in the tank, and to improve the maintenance of the tank. High pressure dry air supply system.

BACKGROUND ART High pressure air is used for driving and controlling equipment in various factory facilities and production facilities such as plasma display panels. In the case of supplying high pressure air to various equipment, if water is contained in the high pressure air, problems will occur. Therefore, it is necessary to remove moisture from the high pressure air and dry it. Patent document 1 is known as an example of the system which prevents air containing water from being supplied to the equipment.

The "automatic drainage treatment device in the pneumatic supply circuit" of Patent Document 1 prevents the flow of air containing moisture that has not been processed by the air dryer into the pneumatic circuit of the machine when the machine is at rest. In addition, an object of the present invention is to provide an effective rust prevention treatment by the air dryer during operation of the machine. When a certain amount of drain is collected, the air filter is equipped with an auto drain mechanism that automatically discharges the drain, and the operation / stop state of the machine is detected. And valve switching control means for switching to the open position when the machine is in operation.

[Patent Document 1] Japanese Patent Application Laid-Open No. 9-89200

One supply system for this type of high pressure dry air has an air compressor and a tank for storing the high pressure air compressed by the air compressor. The high pressure air stored in the tank is supplied from the tank to the equipment in accordance with the consumption of the equipment. The pressure is switched depending on whether the internal pressure of the operation / stop tank of the air compressor is maintained above the set pressure or lower than the set pressure. The air compressor, in which the internal pressure of the tank stops above the set pressure, resumes operation when the internal pressure falls below the set pressure.

A mist separator that dehumidifies the high pressure air from the tank is provided between the tank and the equipment, and the mist separator is supplied with the high pressure dry air to the equipment. Among the mist separators, there is an auto drain type that automatically discharges the drain generated by dehumidification at atmospheric pressure to a discharge system that is open to the atmosphere. The mist separator of this auto drain type is suitable for automatic operation because drain discharge is automatic.

In a mist separator having a structure in which the drain is automatically discharged under atmospheric pressure, when the high pressure air is in a pressurized state, the high pressure air flows and there is always some leakage of the high pressure air. If there is leakage of high pressure air in the mist separator, a considerable amount of high pressure air will continue to flow out of the tank. Although the leak in the mist separator causes a small amount of consumption in the equipment, if the high pressure air continues to flow out of the tank, the internal pressure of the tank is lower than the set pressure, and the operation of the air compressor is resumed. Even if the internal pressure of the high pressure air from the air compressor returns to the set pressure or more, once the leak occurs in the mist separator, the internal pressure of the tank immediately falls below the set pressure, and the air compressor is restarted repeatedly each time. Will be.

Due to the leakage in the mist separator, regardless of the consumption of the equipment, the air compressor frequently restarts operation and prolongs the operation time, is a waste of power use, and saves energy and reduces carbon dioxide emissions. It was not preferable from the viewpoint of.

On the other hand, when the air compressor collects and drains the coagulated water generated by compressing the air to the tank, the coagulated water is high in proportion to the operating time. A large amount of condensed water collects in the tank. Although the drainage treatment of the coagulated water can be performed automatically at a point where a certain amount of water is collected, rust is likely to be generated by the coagulated water that frequently accumulates inside the tank.

When the agglomerated water is drained from this melted tank, it causes a blockage of holes. If the blockage occurs, it will cause drainage. Therefore, in order to prevent the occurrence of rust and to smooth the drainage of the condensed water, it is necessary to frequently perform maintenance such as cleaning the tank, which is not preferable from the viewpoint of energy saving of equipment management.

The present invention was devised in view of the above-described conventional problems, and it is possible to optimize the operation of the air compressor, to reduce the power consumption, and to reduce the amount of coagulation water recovered to the tank. An object of the present invention is to provide a high-pressure dry air supply system that can improve maintenance.

The high pressure dry air supply system according to the present invention has an air compressor and a tank for storing the high pressure air compressed by the air compressor. The condensed water generated by compression is collected and drained to this tank, and the high pressure air stored in this tank is dehumidified by a mist separator that discharges the drain under atmospheric pressure, and is supplied to the equipment as a high pressure dry air. In the system, a check mechanism is provided on the downstream side of the mist separator to prevent the backflow of the high-pressure dry air to the mist separator, and the mist separator is separated from the tank between the mist separator and the tank. Installing an on / off valve to switch supply / stop of high pressure air to the furnace In addition, it is provided with a pressure switch for detecting the high pressure dry air pressure downstream of the check mechanism, when the high pressure dry air pressure exceeds the set value to close the on-off valve to suppress the decrease in the internal pressure of the tank It features.

A secondary tank for storing the high pressure dry air from the mist separator to be supplied to the equipment is installed downstream of the check mechanism.

The mist separator is characterized in that the auto drain type.

In the high-pressure dry air supply system according to the present invention, it is possible to optimize the operation of the air compressor, to reduce the power consumption, and to reduce the amount of coagulated water recovered in the tank, thereby improving the maintenance of the tank. have.

1 is a configuration diagram showing a preferred embodiment of the high-pressure dry air supply system according to the present invention.

EMBODIMENT OF THE INVENTION Below, one preferred embodiment of the high pressure dry air supply system which concerns on this invention is described in detail with reference to an accompanying drawing. As shown in FIG. 1, the high pressure dry air supply system 1 which concerns on this embodiment makes the high pressure air compressed by the air compressor 2 dry high pressure air, for example, of the manufacturing facilities of a plasma display panel. Supply to the various equipments 21, such as the clamping mechanism 3 of a chip tube, the nozzle lifting cylinder 4, the vacuum valve 5, etc. which are provided in a cart.

The air compressor 2 sucks air (atmosphere) from the suction port and compresses it to produce a high pressure air. The tank 6 is connected to the discharge port of the air compressor 2. The tank 6 stores the high pressure air compressed by the air compressor 2 and recovers the agglomerated water w generated by the air compressor 2 compressing the air. The tank 6 has a drain system 8 having an electromagnetic drain valve 7. By opening the electromagnetic drain valve 7, the condensed water w recovered in the tank 6 is drained from the drain system 8.

The tank 6 is provided with a first pressure switch 9 for detecting the internal pressure of the tank 6 and for switching the operation and stop of the air compressor 2 in accordance with the detected internal pressure. When the set pressure is set in the first pressure switch 9 and the internal pressure of the tank 6 storing the high pressure air is maintained at or above the set pressure, a stop signal is output to the air compressor 2 and the internal pressure is When the pressure falls below this set pressure, an operation signal is output to the air compressor 2.

The secondary tank 11 is connected to the tank 6 via the piping 10 which distributes a high pressure air. A mist separator 12 is installed between the secondary tank 11 and the tank 6 in a pipe 10 to dehumidify the high pressure air from the tank 6 and make the high pressure dry air. In the illustrated example, three mist separators 12 are arranged, and dehumidification of the high pressure air is performed in three stages to form a high pressure dry air. Each mist separator 12 is an auto drain type suitable for automatic operation of a factory facility or a production facility. The mist separator 12 has an open drain system 12a, and automatically discharges a drain generated by dehumidification of a high pressure air under atmospheric pressure.

On the downstream side of the mist separator 12, a dryer 13 is installed on the pipe 10 to further dry the high-pressure dry air after dehumidification. On the downstream side of the dryer 13, a first regulator 14 mounted to the pipe 10 to suppress pressure fluctuations in the pipe 10 is provided.

The secondary tank 11 is connected to the pipe 10 and is provided downstream of the first regulator 14, that is, downstream of the mist separator 12. In addition, the secondary tank 11 is connected to the clamping mechanism 3 of the chip tube which is various equipment 21 via the branched secondary piping 15, etc. As shown in FIG. The secondary piping 15 has an electromagnetic control valve 16, a solenoid valve unit 17, and a secondary piping 15 which control supply and stop of the high pressure dry air to the clamp mechanism 3, the nozzle lift cylinder 4, and the like. The 2nd regulator 18 which adjusts the internal pressure is provided. The secondary tank 11 is a buffer tank that suppresses pressure fluctuation and temporarily stores the high pressure dry air from the mist separator 12 to supply the clamp mechanism 3 or the like.

Between the mist separator 12 and the tank 6, an electromagnetic opening and closing valve 19 is installed in the pipe 10 to switch supply and stop of the high pressure air from the tank 6 to the mist separator 12. . When the electromagnetic open / close valve 19 is opened, the high pressure air from the tank 6 is supplied to the mist separator 12. When the electromagnetic open / close valve 19 is closed, the high pressure air is not sent out from the tank 6 but is stored in the tank 6.

The downstream side of the first regulator 14, that is, the downstream side of the mist separator 12, is mounted on the pipe 10 on the upstream side of the secondary tank 11 so that the high pressure dry air from the mist separator 12 is supplied to the secondary tank. A check valve 22 is provided as a check mechanism for preventing the flow back from the (11) side toward the mist separator 12 side. Specifically, the check valve 22 is a high-pressure dry air fed into the secondary tank 11 when the solenoid valve 19 is closed, or the high-pressure dry air stored in the secondary tank 11 is drain system 12a. ) Is prevented from flowing back and leaking into the mist separator 12 which is open under atmospheric pressure, and at the same time, the internal pressure of the secondary tank 11 is prevented from dropping. The check mechanism is not limited to the check valve 22 and may be any means, such as an electronic control valve or a switching valve, as long as the reverse flow of the high pressure dry air can be prevented.

On the downstream side of the check valve 22, it is attached to the piping 10, and the 2nd pressure switch 20 is provided. The second pressure switch 20 detects the high pressure dry air pressure downstream of the check valve 22 and switches the opening and closing of the solenoid valve 19 according to the detected high pressure dry air pressure. The set value of the high pressure dry air pressure downstream of the check valve 22 is set to the 2nd pressure switch 20, and when the detected high pressure dry air pressure exceeds the set value, it outputs a close signal to the solenoid valve 19. When the temperature falls below the set value, the open signal is output to the solenoid valve 19.

Accordingly, the high pressure dry air pressure detected by the second pressure switch 20 exceeds the set value, and the electromagnetic opening and closing valve 19 is closed, thereby supplying the high pressure air from the tank 6 to the mist separator 12. It stops and the fall of the internal pressure of the tank 6 is suppressed. On the other hand, when the detected high pressure dry air pressure drops below the set value due to the consumption of the high pressure dry air in the equipment 21, the solenoid valve 19 opens, and the high pressure air of the tank 6 is a mist separator ( 12) is processed by a high pressure dry air, and supplied to the secondary tank (11). The second pressure switch 20 may be provided in the secondary tank 11 to detect the internal pressure of the secondary tank 11.

The relationship between the open valve pressure of the check valve 22 and the set pressure of the first pressure switch 9 is used to ensure the supply of high pressure air from the tank 6 to the secondary tank 11 so as to ensure supply of the high pressure air to the first pressure switch 9. ) Is set higher than the open valve pressure of the check valve 22. As a result, the high pressure air from the tank 6 opens the check valve 22 and flows to the secondary tank 11 side.

In addition, the relationship between the opening valve pressure of the check valve 22 and the set value of the second pressure switch 20 is such that the high pressure dry air can smoothly flow into the secondary tank 11 through the check valve 22. The set value of the pressure switch 20 is set lower than the open valve pressure of the check valve 22. Therefore, the set value of the second pressure switch 20 is set lower than the set pressure of the first pressure switch 9.

In addition, the downstream side of the check valve 22 is connected to the pipe 10, and when the maintenance of the system 1 is performed, the pipe 10 is exhausted from between the check valve 22 and the secondary tank 11. A manual opening / closing residual pressure release valve 23 for releasing the residual pressure therein is provided. In addition, 24 and 25 are pressure gauges.

Next, the operation of the high pressure dry air supply system 1 according to the present embodiment will be described. A situation where the high pressure dry air is continuously consumed in the equipment 21 is described below as an initial state.

When the high pressure dry air pressure downstream of the check valve 22 is below the set value due to the consumption of the high pressure dry air, the solenoid opening and closing valve 19 is opened by the second pressure switch 20. When the electromagnetic open / close valve 19 is open, the high pressure air is supplied from the tank 6 to the mist separator 12. When the internal pressure of the tank 6 supplying the high pressure air to the mist separator 12 is lower than the set pressure, the air compressor 2 is driven by the first pressure switch 9.

As a result, the tank 6 storing the high pressure air compressed by the air compressor 2 sends the high pressure air to the mist separator 12, and the mist separator 12 dehumidifies the high pressure air to form the secondary tank as the high pressure dry air. The secondary tank 11 stores the high pressure dry air, and sends the high pressure dry air to the equipment 21.

When the consumption of the high pressure dry air becomes small and the high pressure dry air pressure downstream of the check valve 22 exceeds the set value, the second pressure switch 20 closes the electromagnetic open / close valve 19. When the electromagnetic open / close valve 19 is closed, supply of the high pressure air from the tank 6 to the mist separator 12 is stopped, and the storage amount of the high pressure air in the tank 6 increases, and the internal pressure exceeds the set pressure. When the set pressure is exceeded, the first pressure switch 9 stops the operation of the air compressor 2.

After that, due to the consumption of the high-pressure dry air in the equipment 21, the electromagnetic open / close valve 19 is closed until the second pressure switch 20 outputs the open signal to the electromagnetic open / close valve 19. In the closed state, the operation stop state of the air compressor 2 can be maintained. Between the solenoid valve 19 and the secondary tank 11, the backflow of the high pressure dry air from the secondary tank 11 to the mist separator 12 can be prevented by the check valve 22, and the secondary tank 11 It is possible to prevent the internal pressure from decreasing. At this time, the high pressure air is automatically leaked from the auto drain type mist separator 12 to the atmospheric pressure state between the electromagnetic open / close valve 19 and the check valve 22.

Next, when the consumption of the high pressure dry air in the equipment 21 increases, the electromagnetic opening and closing valve 19 is opened by the second pressure switch 20. When the solenoid valve 19 is opened, the high pressure air is fed from the tank 6 to the mist separator 12, and the dehumidified high pressure dry air reaches the check valve 22. The high pressure dry air reaching the check valve 22 is opened to the secondary tank 11 by opening the check valve 22. Thereby, the high pressure dry air can be supplied to the secondary tank 11. In the tank 6 in which the internal pressure has decreased due to the discharge of the high pressure air, the first pressure switch 9 resumes the operation of the air compressor 2, and the high pressure air compressed by the air compressor 2 is transferred to the tank 6. Can be stored.

In addition, the agglomerated water w generated by the air compressor 2 compressing air is recovered to the tank 6, and the collected agglomerated water w opens the electromagnetic drain valve 7 of the drain system 8. By this, the tank 6 can be drained outward.

In the high pressure dry air supply system 1 which concerns on this embodiment demonstrated above, the electromagnetic opening / closing valve 19 is provided between the auto drain type | mold separator 12 of the leak type | mold, and the tank 6, and the mist separator ( On the downstream side of 12), a check valve 22 for preventing the backflow of the high-pressure dry air from the mist separator 12 is provided, and the high-pressure dry air pressure downstream of the check valve 22 is detected to detect and close the solenoid valve. Since the 2nd pressure switch 20 which opens and closes 19 is provided, when it is necessary to supply a high pressure dry air, ie, when the high pressure dry air pressure downstream of the check valve 22 is below a set value, In order to prevent the high pressure air from leaking continuously in the mist separator 12 when the electronic switch valve 19 is opened and supplied by the pressure switch 20, it is not necessary to supply the electron to the second pressure switch 20. By closing the closing valve 19, the internal pressure of the tank 6 is lowered due to the leak in the mist separator 12, thereby preventing the air compressor 2 from being operated frequently and unnecessarily. As a result, the operation of the air compressor 2 can be optimized, power consumption can be reduced, and energy saving and carbon dioxide emission reduction can be achieved.

In addition, since the operation of the air compressor 2 can be optimized and the operating time can be shortened, the amount of agglomerated water w recovered in the tank 6 can be reduced, whereby the air compressor 2 Can be prevented from deteriorating, and rust can be prevented from occurring and the drainage can be smoothly maintained, thereby reducing the labor of cleaning and improving maintenance of the tank 6 and the drainage system 8. As a result, device management can be enhanced.

Moreover, when the check valve 22 is installed between the mist separator 12 and the secondary tank 11, when the electromagnetic opening / closing valve 19 is closed, the high pressure dry air stored in the secondary tank 11 is mist separator. The leakage from (12) can be prevented, and at the time of opening of the solenoid valve 19, the high pressure dry air supplied through the mist separator 12 is always higher than the opening valve pressure of the check valve 22. , The pressure of the high-pressure dry air supplied to the secondary tank 11 can be maintained appropriately.

By installing the secondary tank 11 for storing the high pressure dry air from the mist separator 12 in order to supply the high pressure dry air from the mist separator 12 to the installation equipment 21 on the downstream side of the check valve 22, the high pressure dry air is supplied to the installation equipment 21. It can supply stably.

1 High Pressure Dry Air Supply System 2 Air Compressor
6 Tank 11 Second Tank
12 Mist Separator 19 Solenoid Valve
20 Second pressure switch 21 Equipment
22 Check valve w Coagulated water

Claims (3)

It has an air compressor and a tank for storing the high pressure air compressed by the air compressor, and when the internal pressure of the tank decreases, the air compressor is operated, and the condensed water generated by the air compressor compressing the air is recovered to the tank. In the high pressure dry air supply system in which the high pressure air stored in the tank is dehumidified by a mist separator that discharges the drain under atmospheric pressure and supplied to the equipment as a high pressure dry air.
A reverse check mechanism is provided on the downstream side of the mist separator to prevent the reverse flow of the high-pressure dry air to the mist separator,
An on-off valve is provided between the mist separator and the tank to switch supply and stop of high pressure air from the tank to the mist separator.
And a pressure switch for detecting a high pressure dry air pressure downstream of the check mechanism and closing the on / off valve when the high pressure dry air pressure exceeds a set value to suppress a decrease in the internal pressure of the tank. High pressure dry air supply system. The method according to claim 1,
And a secondary tank for storing the high pressure dry air from the mist separator to supply the equipment to a downstream side of the check mechanism. The method according to claim 1 or 2,
And the mist separator is of an auto drain type.

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