JP2011179628A - High-pressure dry air supplying system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a high-pressure dry air supplying system which optimizes the operation of an air compressor, reduces the consumption of electric power, reduces an amount of the condensed water collected by a tank, and enhances maintenance performance of the tank. <P>SOLUTION: The high-pressure dry air supplying system 1 is structured so that the high pressure air stored in the tank 6 compressed by the air compressor 2 is dehumidified by a mist separator 12 to turn into high pressure dry air, which is supplied to a facility apparatus 21, wherein a check valve 22 to prevent the high pressure dry air from reverse flowing to the mist separator is installed in the downstream of the mist separator, while a solenoid-operated opening/closing valve 19 is installed between the mist separator and the tank to change over between the supply and stop of the high pressure air from the tank to the mist separator, and further a second pressure switch 20 is installed which senses the pressure of the high pressure dry air downstream of the check valve and suppresses the drop of the tank internal pressure by closing the opening/closing valve when the sensed dry air pressure has exceeded the set value. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention can optimize the operation of the air compressor, reduce power consumption, reduce the amount of condensed water collected in the tank, and improve the maintainability of the tank. High pressure dry air supply system

  High-pressure air is used to drive and control equipment in various factory equipment and production equipment such as plasma display panels. When supplying high-pressure air to various types of equipment, it is necessary to remove the moisture from the high-pressure air and keep it dry because moisture is contained in the high-pressure air. Patent document 1 is known as an example of a system that prevents air containing moisture from being supplied to equipment.

  Patent Document 1 “Automatic Wastewater Treatment Device in Pneumatic Supply Circuit” prevents air containing moisture that has not been processed by an air dryer from flowing into the pneumatic circuit of the machine while the machine is at rest. At the same time, an electromagnetic switching valve provided on the inlet side of the air dryer, which opens and closes the pneumatic piping, is installed upstream of the electromagnetic switching valve, with the objective of enabling effective rust prevention treatment with an air dryer during machine operation. An air filter equipped with an automatic drain mechanism that automatically discharges drain when a certain amount of drain accumulates, and detects the operating / resting state of the machine. And switching control means for switching to an open position when the machine is operating.

JP-A-9-89200

  Some high pressure dry air supply systems of this type include an air compressor and a tank for storing high pressure air compressed by the air compressor. The high-pressure air stored in the tank is supplied from the tank to the equipment according to consumption by the equipment. The operation / stop of the air compressor can be switched depending on whether the internal pressure of the tank is maintained above the set pressure or below the set pressure. The air compressor that is stopped when the internal pressure of the tank is equal to or higher than the set pressure resumes operation when the internal pressure falls below the set pressure.

  A mist separator that dehumidifies high-pressure air from the tank is provided between the tank and the equipment. The mist separator converts the high-pressure air into high-pressure dry air and supplies it to the equipment. Among mist separators, there is an auto drain type that automatically drains drainage generated by dehumidification under atmospheric pressure in a discharge system that is open to the atmosphere. This auto drain type mist separator is suitable for automatic operation since drain discharge is automatic.

  In a mist separator having a structure that automatically discharges drainage under atmospheric pressure, when high-pressure air is in a pressurized state, high-pressure air circulates, and some high-pressure air leakage always occurs. If high-pressure air leaks at the mist separator, a considerable amount of high-pressure air will continue to flow out of the tank. If high-pressure air continues to flow out of the tank due to leakage at the mist separator, the internal pressure of the tank will drop below the set pressure, which will cause the air compressor to operate. Resumed. Even if the internal pressure of the tank once returned to the set pressure or higher due to the high pressure air from the air compressor, as long as a leak occurs in the mist separator, the internal pressure of the tank immediately falls below the set pressure. Will be restarted repeatedly.

  Due to leakage at the mist separator, the air compressor frequently restarts operation and increases the operation time regardless of the consumption at the equipment. It was not preferable from the viewpoint of reducing carbon dioxide emissions.

  On the other hand, when the air compressor collects the condensed water generated by compressing the air and discharges it in the tank, the condensed air accumulates in proportion to the operation time. If the operation time is long, a large amount of condensed water accumulates in the tank in a short time. The drainage treatment of the condensed water can be automatically performed when a certain amount of water is collected, but rust is easily generated in the tank due to the frequently accumulated water.

  This rust causes clogging when draining the condensed water from the tank. If clogging occurs, the drainage operation will be hindered. Therefore, in order to prevent the occurrence of rust and smooth 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 labor saving in equipment management. .

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

  A high-pressure dry air supply system according to the present invention has an air compressor and a tank for storing high-pressure air compressed by the air compressor. When the internal pressure of the tank decreases, the air compressor is operated, and the air compressor The condensed water generated by the compression is collected and drained into the tank, and the high-pressure air stored in the tank is dehumidified with a mist separator that discharges the drain under atmospheric pressure to supply high-pressure dry air to the equipment. In the high pressure dry air supply system, a non-return mechanism for preventing a back flow of the high pressure dry air to the mist separator is provided on the downstream side of the mist separator, and the mist from the tank is provided between the mist separator and the tank. In addition to providing an on-off valve that switches between supplying and stopping high-pressure air to the separator, A pressure switch that detects a high-pressure dry air pressure downstream of the stop mechanism and closes the on-off valve to suppress a decrease in the internal pressure of the tank when the high-pressure dry air pressure exceeds a set value. .

  A secondary tank that stores high-pressure dry air from the mist separator for supply to the equipment is provided downstream of the check mechanism.

  The mist separator is an auto drain type.

  In the high-pressure dry air supply system according to the present invention, the operation of the air compressor can be optimized, the power consumption can be reduced, and the amount of condensed water collected in the tank can be reduced. The maintainability can be improved.

It is a block diagram which shows suitable one Embodiment of the high pressure dry air supply system which concerns on this invention.

  Hereinafter, a preferred embodiment of a high-pressure dry air supply system according to the present invention will be described in detail with reference to the accompanying drawings. The high-pressure dry air supply system 1 according to the present embodiment, as shown in FIG. 1, converts the high-pressure air compressed by the air compressor 2 into dry high-pressure air, for example, a chip provided in a cart of a plasma display panel manufacturing facility. This is supplied to various equipment devices 21 such as a tube clamping mechanism 3, a nozzle lifting cylinder 4, and a vacuum valve 5.

  The air compressor 2 draws air (atmosphere) from the suction port and compresses it to create high-pressure air. A 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 collects the condensed water w generated by the air compressor 2 compressing the air. The tank 6 includes a drainage system 8 having an electromagnetic drain valve 7. The condensed water w collected in the tank 6 is drained from the drainage system 8 by opening the electromagnetic drain valve 7.

  The tank 6 is provided with a first pressure switch 9 that detects the internal pressure of the tank 6 and switches between 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 for storing high-pressure air is maintained at or above the set pressure, a stop signal is output to the air compressor 2 to set the internal pressure. When the pressure drops below the pressure, an operation signal is output to the air compressor 2.

  A secondary tank 11 is connected to the tank 6 via a pipe 10 through which high-pressure air flows. Between the secondary tank 11 and the tank 6, a mist separator 12 is provided that is attached to the pipe 10 and dehumidifies the high-pressure air from the tank 6 into high-pressure dry air. In the illustrated example, three mist separators 12 are arranged, and high pressure air is dehumidified in three stages to form high pressure dry air. Each mist separator 12 is an auto drain type suitable for automatic operation of factory facilities and production facilities, and has a drain system 12a that is open to the atmosphere, and drain generated by dehumidification of high-pressure air is automatically performed under atmospheric pressure. To discharge.

  A dryer 13 that is attached to the pipe 10 and further dries the high-pressure dry air after dehumidification is provided on the downstream side of the mist separator 12. A first regulator 14 that is attached to the pipe 10 and suppresses pressure fluctuations in the pipe 10 is provided downstream of the dryer 13.

  The secondary tank 11 is connected to the pipe 10 and is provided on the downstream side of the first regulator 14, that is, on the downstream side of the mist separator 12. The secondary tank 11 is connected to the tip tube clamping mechanism 3 and the like, which are various equipment 21, via the branched secondary pipe 15. The secondary pipe 15 includes an electromagnetic control valve 16 and an electromagnetic valve unit 17 that control supply / stop of high-pressure dry air to the clamp mechanism 3 and the nozzle lifting cylinder 4 and the like, and a second regulator that adjusts the pressure in the secondary pipe 15. 18 is provided. The secondary tank 11 temporarily stores the high-pressure dry air from the mist separator 12 to supply the clamp mechanism 3 and the like as a buffer tank that suppresses pressure fluctuations.

  Between the mist separator 12 and the tank 6, there is provided an electromagnetic opening / closing valve 19 that is attached to the pipe 10 and switches supply / stop of high-pressure air from the tank 6 to the mist separator 12. When the electromagnetic on-off valve 19 is opened, high-pressure air from the tank 6 is supplied to the mist separator 12. When the electromagnetic on-off valve 19 is closed, the high-pressure air is stored in the tank 6 without being sent out from the tank 6.

  At the downstream side of the first regulator 14, that is, the downstream side of the mist separator 12 and the upstream side of the secondary tank 11, high pressure dry air from the mist separator 12 is attached from the secondary tank 11 side to the pipe 10. A check valve 22 is provided as a check mechanism for preventing backflow toward the mist separator 12 side. Specifically, the check valve 22 is configured such that when the electromagnetic on-off valve 19 is closed, the high-pressure dry air sent to the secondary tank 11 side or the high-pressure dry air stored in the secondary tank 11 is discharged to the atmospheric pressure of the drain system 12a. The mist separator 12 that is open to the mist separator 12 is prevented from flowing back and leaking, and the internal pressure of the secondary tank 11 is also prevented from decreasing. The check mechanism is not limited to the check valve 22 and may be any means such as an electromagnetic control valve or a switching valve as long as it can prevent the backflow of high-pressure dry air.

  A second pressure switch 20 is provided downstream of the check valve 22 and attached to the pipe 10. The second pressure switch 20 detects the high-pressure dry air pressure downstream of the check valve 22 and switches between opening and closing of the electromagnetic on-off valve 19 according to the detected high-pressure dry air pressure. A set value of the high pressure dry air pressure downstream of the check valve 22 is set in the second pressure switch 20, and when the detected high pressure dry air pressure exceeds the set value, a close signal is output to the electromagnetic on-off valve 19. When the value falls below the set value, an open signal is output to the electromagnetic on-off valve 19.

  Accordingly, when the high-pressure dry air pressure detected by the second pressure switch 20 exceeds the set value and the electromagnetic on-off valve 19 is closed, the supply of high-pressure air from the tank 6 to the mist separator 12 is stopped. A decrease in the internal pressure is suppressed. On the other hand, when the detected high-pressure dry air pressure drops below the set value due to the consumption of high-pressure dry air in the equipment 21, the electromagnetic on-off valve 19 is opened, and the high-pressure air in the tank 6 is sent to the mist separator 12. It is treated with 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 valve opening pressure of the check valve 22 and the set pressure of the first pressure switch 9 is that the set pressure of the first pressure switch 9 is set to ensure the supply of high-pressure air from the tank 6 to the secondary tank 11. It is set higher than the valve opening pressure of the check valve 22. Thereby, the high pressure air from the tank 6 is opened to the secondary tank 11 side by opening the check valve 22.

  The relationship between the valve opening 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 20 is set lower than the valve opening 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.

  Further, on the downstream side of the check valve 22, when the maintenance is performed on the system 1 by connecting to the pipe 10, the space between the check valve 22 and the secondary tank 11 is evacuated to remain in the pipe 10. A manual open / close type residual pressure release valve 23 for releasing the pressure is provided. Reference numerals 24 and 25 are pressure gauges.

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

  When the high pressure dry air pressure downstream of the check valve 22 is equal to or lower than the set value due to the consumption of the high pressure dry air, the electromagnetic on-off valve 19 is opened by the second pressure switch 20. When the electromagnetic on-off valve 19 is opened, high-pressure air is supplied from the tank 6 to the mist separator 12. When the internal pressure of the tank 6 that supplies high-pressure air to the mist separator 12 is lower than the set pressure, the air compressor 2 is operated by the first pressure switch 9.

  Thereby, the tank 6 for 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 and sends it to the secondary tank 11 as the secondary tank 11. The tank 11 stores high-pressure dry air and sends the high-pressure dry air to the equipment 21.

  When the consumption of the high-pressure dry air is reduced 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 on-off valve 19. When the electromagnetic on-off valve 19 is closed, the supply of high-pressure air from the tank 6 to the mist separator 12 stops, the amount of high-pressure air stored 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.

  Thereafter, the electromagnetic on / off valve 19 is closed until the second pressure switch 20 outputs an open signal to the electromagnetic on / off valve 19 depending on the consumption state of the high-pressure dry air in the equipment 21, and the air compressor 2 is operated. The stop state can be maintained. Between the electromagnetic on-off valve 19 and the secondary tank 11, the check valve 22 can prevent the backflow of high-pressure dry air from the secondary tank 11 to the mist separator 12, and prevent a decrease in the internal pressure of the secondary tank 11. Can do. At this time, between the electromagnetic on-off valve 19 and the check valve 22, the high-pressure air continuously leaks automatically from the auto drain type mist separator 12, resulting in an atmospheric pressure state.

  Next, when the consumption of high-pressure dry air in the equipment 21 increases, the electromagnetic on-off valve 19 is opened by the second pressure switch 20. When the electromagnetic opening / closing valve 19 is opened, the high pressure air is sent 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 that has reached the check valve 22 opens the check valve 22 and is sent to the secondary tank 11. Thereby, 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 high pressure air being sent out, the first pressure switch 9 can restart the operation of the air compressor 2, and the high pressure air compressed by the air compressor 2 can be stored in the tank 6.

  Further, the condensed water w generated by the air compressor 2 compressing the air is collected in the tank 6, and the collected condensed water w is opened to the outside of the tank 6 by opening the electromagnetic drain valve 7 of the drainage system 8. It can be drained.

  In the high-pressure dry air supply system 1 according to the present embodiment described above, an electromagnetic on-off valve 19 is provided between the auto drain type mist separator 12 that generates a leak and the tank 6, and the mist separator 12 is disposed downstream of the mist separator 12. Since the check valve 22 for preventing the backflow of the high-pressure dry air from the separator 12 is provided and the second pressure switch 20 for detecting the high-pressure dry air pressure downstream of the check valve 22 and opening and closing the electromagnetic on-off valve 19 is provided. Only when the high pressure dry air needs to be supplied, that is, when the high pressure dry air pressure downstream of the check valve 22 is equal to or lower than the set value, the second pressure switch 20 needs to open the electromagnetic on-off valve 19 to supply and supply. When there is no air pressure, the second pressure switch 20 is used to prevent high pressure air from continuing to leak in the mist separator 12. Since the electromagnetic on-off valve 19 is closed, it is possible to prevent the internal pressure of the tank 6 from being lowered due to leakage at the mist separator 12 and causing the air compressor 2 to be operated frequently and wastefully. The operation of the compressor 2 can be optimized to reduce power consumption, 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 operation time can be shortened, the amount of the condensed water w recovered in the tank 6 can be reduced, thereby preventing the air compressor 2 from deteriorating and rusting. It is possible to maintain the drainage action smoothly by suppressing the occurrence of the occurrence of the trouble, and to reduce the trouble of cleaning and the like, improve the maintainability of the tank 6 and the drainage system 8, and save labor in equipment management.

  Since the check valve 22 is provided between the mist separator 12 and the secondary tank 11, the high-pressure dry air stored in the secondary tank 11 leaks from the mist separator 12 when the electromagnetic on-off valve 19 is closed. The high pressure dry air supplied through the mist separator 12 is always higher than the opening pressure of the check valve 22 when the electromagnetic on-off valve 19 is opened. The pressure can be maintained appropriately.

  Since the secondary tank 11 that stores the high-pressure dry air from the mist separator 12 for supplying the equipment 21 is provided on the downstream side of the check valve 22, the high-pressure dry air can be stably supplied to the equipment 21. Can do.

DESCRIPTION OF SYMBOLS 1 High pressure dry air supply system 2 Air compressor 6 Tank 11 Secondary tank 12 Mist separator 19 Electromagnetic on-off valve 20 2nd pressure switch 21 Equipment 22 Check valve w Condensed water

Claims (3)

An air compressor and a tank for storing high-pressure air compressed by the air compressor; when the internal pressure of the tank decreases, the air compressor is operated, and the condensed water generated by the air compressor compressing air is In the high-pressure dry air supply system in which the high-pressure air stored in the tank is dehumidified with a mist separator that discharges the drain under atmospheric pressure and is supplied to the equipment as high-pressure dry air.
Provided on the downstream side of the mist separator is a check mechanism that prevents the backflow of high-pressure dry air to the mist separator,
Between the mist separator and the tank is provided an on-off valve for switching supply / stop of high-pressure air from the tank to the mist separator,
A pressure switch is provided that detects a high-pressure dry air pressure downstream of the check mechanism and closes the on-off valve to suppress a decrease in the internal pressure of the tank when the high-pressure dry air pressure exceeds a set value. High pressure dry air supply system.   The high-pressure dry air supply system according to claim 1, wherein a secondary tank that stores high-pressure dry air from the mist separator for supply to the equipment is provided on the downstream side of the check mechanism.   The high-pressure dry air supply system according to claim 1 or 2, wherein the mist separator is an auto drain type.

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