JP2013019621A - Cutoff valve device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To easily and surely confirm an operation of a cutoff valve such as a solenoid valve used in a cutoff valve device for cutting off the flow of a refrigerant in an air conditioner and the like.SOLUTION: The cutoff valve device 14 including a first cutoff valve 9 disposed in an inlet refrigerant flow channel, a second cutoff valve 10 disposed in an outlet refrigerant flow channel, and an external input means 22 for inputting an output signal of a refrigerant leakage detector 7, and opening and cutting off the inlet and outlet refrigerant flow channels by opening and closing the first and second cutoff valves on the basis of a state of the external input means, further includes driving means R1, R2 for independently driving the first cutoff valve and the second cutoff valve. The cutoff valve device may include display means L1, L3 for displaying the operated cutoff valves in checking the first and second cutoff valves, and the display means may display a valve opening or closing state of the operated cutoff valve in checking the first and second cutoff valves. The first and second cutoff valves may be solenoid valves.

Description

  The present invention relates to a shut-off valve device that blocks a refrigerant flow and prevents the refrigerant from leaking when a refrigerant used in an air conditioner, a refrigeration / refrigeration apparatus, or the like leaks.

  In recent years, leakage of refrigerant from air conditioners, refrigeration / refrigeration equipment, and the like has become a problem from the viewpoint of preventing global warming. Therefore, a refrigerant leak detector is installed, and its external output means is connected to the shut-off valve device. When a refrigerant leak is detected, an alarm signal is output from the external output means of the refrigerant leak detector and received. The shut-off valve device has closed the two solenoid valves (shut-off valves) installed in the inlet and outlet refrigerant flow paths of indoor units, etc. to stop the refrigerant flow and prevent the refrigerant from leaking outside. It is being considered. An example of such a shutoff valve and shutoff valve device is described in Patent Document 1.

Japanese Patent Publication No. 61-513

  The shut-off valve device as described above often inspects two solenoid valves at the time of new installation, repair, replacement or periodic inspection, and whether or not each solenoid valve operates normally. That is, in many cases, the operation of opening and closing the valve is confirmed. Since this type of shut-off valve device is installed for the purpose of shutting off the refrigerant flow path when refrigerant leakage occurs, two units generally attached to the refrigerant flow path at the inlet and outlet of an indoor unit or the like The opening timing and closing timing of the solenoid valve are the same.

  However, confirmation of the opening and closing operation of the solenoid valve used in the shut-off valve device is usually performed by sound and vibration during operation of each solenoid valve, so the two solenoid valves are opened and closed with the same timing. As a result, even if one solenoid valve was not operating due to a failure, etc., if the other solenoid valve operates normally, operation noise and vibration are generated. There was no problem.

  Therefore, the present invention has been made in view of the problems in the above-described conventional shut-off valve device, and can easily and reliably check the operation of shut-off valves such as two electromagnetic valves used in the shut-off valve device. With the goal.

  To achieve the above object, the present invention inputs a first shut-off valve attached to an inlet refrigerant flow path, a second shut-off valve attached to an outlet refrigerant flow path, and an output signal of the refrigerant leak detector. A shutoff valve device that opens or shuts off the inlet and outlet refrigerant channels by opening and closing the first and second shutoff valves based on the state of the external input means. And a driving means for independently driving the first shut-off valve and the second shut-off valve.

  According to the present invention, since the drive means for opening and closing each shut-off valve are provided independently, the first and second shut-off valves are checked when checking the first and second shut-off valves. It is possible to prevent the valves from opening and closing at the same time. That is, since only one of the shut-off valves can be opened and closed, for example, after the first shut-off valve is opened and closed without operating the second shut-off valve, the first shut-off valve is operated. The second shutoff valve can be opened and closed while the shutoff valve is not operated. Since only one of the shut-off valves is operated in this way, when the shut-off valve being operated is broken, the valve is not opened or closed, or both are not operated. Therefore, it can be easily determined that a failure has occurred.

  The shut-off valve device may be configured to include display means for displaying the shut-off valve that is operating when the first and second shut-off valves are inspected. As a result, even if no operating noise or vibration is generated from the shut-off valve during inspection, the shut-off valve to be operated can be identified by the display means, so that the faulty shut-off valve can be easily confirmed. Can do.

  The display means can display the open or closed state of the shut-off valve that is operating during the inspection of the first and second shut-off valves. As a result, whether or not the malfunction occurs when the valve is opened or closed by the display means, even in the case of a malfunction that does not generate operating noise or vibration during either the valve opening or the valve closing. Can be easily confirmed.

  In the shut-off valve device, the shut-off valve can be an electromagnetic valve.

  As described above, according to the present invention, it is possible to easily and surely confirm the operation of the shutoff valves such as the two solenoid valves used in the shutoff valve device.

It is a block diagram which shows an example of the air-conditioning equipment using the cutoff valve apparatus concerning this invention. It is a block diagram which shows one Embodiment of the cutoff valve apparatus concerning this invention. It is a flowchart for demonstrating operation | movement of the cutoff valve apparatus of FIG. It is a flowchart for demonstrating operation | movement of the cutoff valve apparatus of FIG. It is a flowchart for demonstrating the other example of operation | movement of the cutoff valve apparatus of FIG.

  Next, embodiments for carrying out the present invention will be described in detail with reference to the drawings.

  FIG. 1 shows an example of air conditioning equipment using a shutoff valve device according to the present invention, which is installed in a building or the like having a plurality of rooms. This figure shows a state in which the plurality of rooms are being cooled, and the direction in which the refrigerant flows is indicated by arrows.

  This air-conditioning equipment 1 is connected to an outdoor unit 12 including a compressor 2, a condenser 3, and an outdoor fan 3a, a pipe 15 in parallel with the outdoor unit 12, and an expansion valve 4 (4A to 4C). The refrigerant flows between the indoor units 13 (13A to 13C) including the evaporator 5 (5A to 5C) and the indoor fans 6 (6A to 6C), and the indoor units 13 and the outdoor units 12. Inlet side solenoid valve (first shutoff valve) 9 (9A-9C) and outlet side solenoid valve (second shutoff valve) 10 (10A-10C) installed in the inlet and outlet pipes, and shutoff valve control unit 8 The refrigerant leak detector 7 (7A to 7C) is installed in each room in which the indoor unit 13 is attached, and each shut-off valve device 14 (14A to 14C) provided with (8A to 8C). The output is input to the shut-off valve control unit 8 of each shut-off valve device 14.

  In the air conditioner 1, the number of indoor units 13 connected to one outdoor unit 12 is arbitrary. In the present embodiment, three indoor units 13 are installed. However, one or four or more indoor units may be used. . The number of indoor units 13 connected to one shutoff valve device 14 is also arbitrary, and in the present embodiment, one indoor unit 13 is connected to one shutoff valve device 14, Three indoor units 13 may be connected in parallel to one shutoff valve device 14.

  Furthermore, the number of refrigerant leak detectors 7 for one indoor unit 13 and the number of indoor units 13 for one refrigerant leak detector 7 are also arbitrary. In the present embodiment, Although one refrigerant leak detector 7 is provided, one refrigerant leak detector 7 may be provided for three indoor units 13, and a refrigerant leak detector for one indoor unit 13. Three units 7 may be installed.

  As shown in FIG. 2, the shut-off valve control unit 8 of the shut-off valve device 14 includes a power supply circuit (not shown) such as a switching power supply. Convert to DC power such as DC12V or DC5V.

  The microcomputer 21 of the shutoff valve control unit 8 includes a CPU 21a that executes a program, a ROM 21b that stores programs and constants, a RAM 21c that stores variables and various flags, and I / O necessary for input / output of signals with peripheral circuits. A port 21d and a timer 21e for measuring time are provided, and these components are connected to each other via an internal bus.

  The external input circuit 22 is a no-voltage contact input circuit composed of a photocoupler or the like, and is normally connected to a relay contact that is an external output means of the refrigerant leak detector 7. The refrigerant leak detector 7 short-circuits the relay contact of the external output means when monitoring the refrigerant leak, that is, when no refrigerant leak is detected, and opens when the refrigerant leak is detected. The external input of the shut-off valve device 14 detects the open / closed state of the external output means of the refrigerant leak detector 7 by the external input circuit 22.

  As shown in FIG. 1, the inlet side electromagnetic valve 9 is attached to the inlet pipe of the indoor unit 13, and opens and blocks the flow of the refrigerant flowing into the indoor unit 13. Further, the outlet side solenoid valve 10 is attached to the outlet pipe of the indoor unit 13 and opens and blocks the flow of the refrigerant flowing out of the indoor unit 13. Both solenoid valves 9 and 10 open when energized to flow refrigerant, and close when the power is turned off to shut off the flow of refrigerant.

  The relay 1 (R1) shown in FIG. 2 is provided to drive the inlet side electromagnetic valve 9 as the first driving means, and when the contact is short-circuited, for example, a power supply of AC 200V is supplied to the inlet side electromagnetic valve 9. When the inlet side electromagnetic valve 9 is opened and the contact is opened, the power supply of AC 200V is cut off and the inlet side electromagnetic valve 9 is closed.

  The drive circuit RD1 of the relay 1 (R1) is configured by a transistor or the like, and amplifies a signal from the microcomputer 21 to drive the relay 1 (R1).

  The relay 2 (R2) is provided to drive the outlet side electromagnetic valve 10 as the second driving means. When the contact is short-circuited, for example, the outlet side electromagnetic valve 10 is energized with a power supply of AC 200V. When the valve 10 is opened and the contact is opened, the AC 200V power supply is cut off and the outlet side solenoid valve 10 is closed.

  The drive circuit RD2 of the relay 2 (R2) is configured by a transistor or the like, and amplifies a signal from the microcomputer 21 to drive the relay 2 (R2).

  The relay 3 (R3) functions as an external output means. When the solenoid valves 9 and 10 are opened, the contacts are opened. When the solenoid valves 9 and 10 are closed, the contacts are short-circuited. Is output to the outside. This external output means is generally connected to a centralized monitoring device of a building and used as an alarm signal.

  The drive circuit RD3 of the relay 3 (R3) is configured by a transistor or the like, and amplifies a signal from the microcomputer 21 to drive the relay 3 (R3).

  LED1 (green) L1 is a power lamp as one of the display means, and lights up while the power is on. The LED1 (green) L1 drive circuit LD1 is composed of a transistor or the like, and amplifies a signal from the microcomputer 21 to light the LED1 (green) L1. The LED 1 (green) L1 indicates that the inlet side solenoid valve 9 is in operation when the inlet side solenoid valve 9 is inspected. Specifically, the inlet side solenoid valve 9 is opened and closed. LED1 (green) L1 lights up during the operation.

  LED2 (orange) L2 is a valve-opening lamp as one of display means, and lights up when the external input is short-circuited and the solenoid valves 9 and 10 are opened. The drive circuit LD2 of the LED 2 (orange) L2 is composed of a transistor or the like, and amplifies a signal from the microcomputer 21 to light the LED 2 (orange) L2. The LED 2 (orange) L2 displays the open / closed state of the inlet side solenoid valve 9 or the outlet side solenoid valve 10 that is operating when the inlet side solenoid valve 9 or the outlet side solenoid valve 10 is inspected. Specifically, it is turned on when the inlet side solenoid valve 9 or the outlet side solenoid valve 10 is open, and is turned off when the inlet side solenoid valve 9 or the outlet side solenoid valve 10 is closed.

  The LED 3 (red) L3 is an alarm lamp as one of display means, and lights up when the external input is opened and the solenoid valves 9 and 10 are closed. The drive circuit LD3 of the LED 3 (red) L3 is composed of a transistor or the like, and amplifies a signal from the microcomputer 21 to light the LED 3 (red) L3. The LED 3 (red) L3 indicates that the outlet side solenoid valve 10 is in operation when the outlet side solenoid valve 10 is inspected. Specifically, the outlet side solenoid valve 10 is opened and closed. LED3 (red) L3 lights up during the operation.

  The shut-off valve device 14 has a self-holding function of closing the valve, and when the refrigerant leak detector 7 detects the refrigerant leak and opens the relay contact of the external output means, an external input circuit of the shut-off valve device 14 connected thereto. Since 22 is opened, the shut-off valve device 14 closes the solenoid valves 9 and 10, short-circuits the relay 3 (R 3), turns off the LED 2 (orange) L 2 that is the valve opening lamp, and turns off the alarm lamp. The LED 3 (red) L3 that is is turned on and this state is maintained. Thereafter, when the amount of refrigerant leakage in the room decreases due to refrigerant shutoff and ventilation, the refrigerant leak detector 7 returns the relay contact of the external output means to a short circuit, but the shutoff valve device 14 self-maintains once the valve is closed. Therefore, the solenoid valves 9 and 10 do not open.

  The return switch 23 cancels the self-holding of the solenoid valves 9 and 10 and when the return switch 23 is pressed for 3 seconds or longer, for example, the self-holding of the shut-off valve device 14 is released, and the electromagnetic The valves 9 and 10 are opened, the relay 3 (R3) is opened, the LED 3 (red) L3 that is an alarm lamp is turned off, and the LED 2 (orange) L2 that is a valve opening lamp is turned on.

  The depressing state of the return switch 23 is input to the microcomputer 21 via the return switch input circuit 24 composed of a resistor and a capacitor.

  Further, the electromagnetic valves 9 and 10 can be inspected by pressing the test switch 25 for 3 seconds or longer, for example. For example, when checking a lamp or a solenoid valve, if the test switch 25 is pressed for 3 seconds or longer, the LED 1 (green) L 1, LED 2 (orange) L 2, and LED 3 (red) L 3 turn on sequentially, and then the entrance The side solenoid valve 9 opens and closes, and then the outlet side solenoid valve 10 opens and closes.

  When the inlet side solenoid valve 9 is opened and closed during inspection of the solenoid valves 9 and 10, the LED 1 (green) L 1 is turned on, and the outlet side solenoid valve 10 is opened and closed. When operating, the LED 3 (red) L3 is turned on. Further, the LED 2 (orange) L2 is turned on when the solenoid valves 9, 10 are opened, and the LED 2 (orange) L2 is turned off when the solenoid valves 9, 10 are closed.

  The pressed state of the test switch 25 is input to the microcomputer 21 via the test switch input circuit 26 constituted by a resistor and a capacitor.

  The relay 3 (R3), which is an external output means, may be connected to, for example, a ventilation fan or an alarm device, and is not limited to a building centralized monitoring device. In the present embodiment, the valve closing state is self-holding. However, the present invention is not limited to this. For example, automatic return may be performed, and in this case, the return switch 23 is not necessary.

  Further, the number of the LEDs is arbitrary, and is not limited to three, but may be one, two, four or more. For example, it is not necessary to provide an alarm lamp or a power lamp. Further, an external input lamp that indicates the open / closed state of the external input by turning on / off may be added.

  Furthermore, the number of the switches is arbitrary, and may be three or one. For example, the return switch 23 may be provided. You may start by long press.

  In addition, although the switch operation method and the pressing time are arbitrary, in this embodiment, the test switch 25 is pressed and held for 3 seconds or longer as an operation method for starting inspection of the electromagnetic valves 9 and 10, but this is not limited thereto. For example, the test switch 25 may be held down for 5 seconds or longer, or the return switch 23 and the test switch 25 may be pressed simultaneously for 2 seconds or longer.

  In addition, the number of external inputs is arbitrary, and in the present embodiment, the number is one. However, the number of external inputs is not limited to this, and two or more external inputs may be provided so that a plurality of refrigerant leak detectors can be connected.

  In addition, the refrigerant | coolant to interrupt | block can be made into various refrigerant | coolants, such as R12, R22, R134a, R404A, R410A, R407C, R32, R1234yf, for example, The refrigerant | coolants to make object can be selected arbitrarily, These It is not limited to.

  Next, a series of inspections of the shutoff valve device 14 that inspects the LED1 (green) L1 to LED3 (red) L3, the inlet side electromagnetic valve 9, and the outlet side electromagnetic valve 10, for example, with reference mainly to FIGS. The operation will be described. The flowcharts of FIGS. 3 and 4 are for explaining a part of the program stored in the ROM 21b of the microcomputer 21. FIG. 3 shows an initial part and FIG. 4 shows a loop part. 3 and 4 and the following description, LED1 (green) L1, LED2 (orange) L2, and LED3 (red) L3 are simply referred to as LED1, LED2, and LED3, respectively, and the inlet side solenoid valve 9 Is denoted by SVin, and the outlet side solenoid valve 10 is denoted by SVout. 3 to 5, “◯” indicates that the LEDs 1 to 3 are not lit, “●” indicates that the LEDs 1 to 3 are lit, “open” indicates SVin and SVout are open, and “closed” indicates , SVin, and SVout are shown in a closed state, respectively.

  First, the initial process will be described with reference to FIG.

  In step S1, it is determined whether or not the test switch 25 is pressed for 3 seconds or more. If the test switch 25 is pressed for 3 seconds or more (step S1; Yes), the test flag Ft is set (1) in step S2, and the timer T1s for measuring 1 second is started in step S3. The measurement for 1 second is started. In step S4, the test counter Ct is cleared (0). In step S5, the LEDs 1, 2, and 3 are turned off, SVin and SVout are opened, and the initial process is finished. On the other hand, when the test switch 25 has not been pressed for 3 seconds or more (step S1; No), the processing is terminated without doing anything.

  Next, the loop portion will be described with reference to FIG.

  In step S11, it is determined whether or not the test flag Ft set in FIG. 3 is set (1). If the test flag Ft is set (1) (step S11; Yes), it is determined whether or not the test counter Ct is 0 in step S12. On the other hand, when the test flag Ft is not set (1) (step S11; No), the process ends without executing anything.

  In step S12, when the test counter Ct is 0 (step S12; Yes), in step S13, the timer T1s has timed out, that is, the LEDs 1, 2, and 3 are turned off in FIG. It is determined whether 1 second has elapsed since the valve was opened. If the timer T1s has expired (step S13; Yes), that is, if one second has elapsed since the LEDs 1, 2, and 3 were turned off and SVin and SVout were opened in FIG. In step S14, the LED 1 is turned on. In step S15, 1 is added to the test counter Ct (Ct = 1). In step S16, the timer T1s that measures 1 second is started again, and the process is completed. If the timer T1s has not expired (step S13; No), the process is terminated without doing anything.

  On the other hand, if Ct is not 0 in step S12 (step S12; No), it is determined in step S17 whether Ct is 1. When Ct is 1 (step S17; Yes), in step S18, it is determined whether or not the timer T1s has timed up, that is, whether or not 1 second has elapsed since the LED 1 was turned on. If the timer T1s has expired, that is, if one second has elapsed since the LED1 was turned on (step S18; Yes), the LED1 is turned off and the LED2 is turned on in step S19, and step S20 is executed. In step S21, 1 is added to Ct (Ct = 2), and in step S21, the timer T1s for measuring 1 second is started again, and the process is ended. If the timer T1s has not expired (step S18; No), the process is terminated without doing anything.

  If Ct is not 1 in step S17 (step S17; No), it is determined in step S22 whether Ct is 2. When Ct is 2 (step S22; Yes), in step S23, it is determined whether the timer T1s has timed up, that is, whether 1 second has elapsed since the LED 2 was turned on. If the timer T1s has expired, that is, if one second has elapsed since the LED 2 was turned on (step S23; Yes), the LED 2 is turned off and the LED 3 is turned on in step S24. In step S26, 1 is added to Ct (Ct = 3). In step S26, the timer T1s for measuring 1 second is started again, and the process is ended. When the timer T1s has not expired (step S23; No), the process is terminated without doing anything.

  In step S22, when Ct is not 2 (step S22; No), it is determined whether Ct is 3 in step S27. If Ct is 3 (step S27; Yes), in step S28, it is determined whether the timer T1s has timed up, that is, whether 1 second has elapsed since the LED 3 was turned on. If the timer T1s is up, that is, if 1 second has elapsed since the LED 3 was turned on (step S28; Yes), the LED 3 is turned off and the LEDs 1 and 2 are turned on in step S29. In step S30, 1 is added to Ct (Ct = 4), and in step S31, the timer T1s that measures 1 second is started again, and the process ends. If the timer T1s has not expired (step S28; No), the process is terminated without doing anything. Here, lighting of LED1 indicates that SVin is operating, and lighting of LED2 indicates that SVin is in a valve open state.

  If Ct is not 3 in step S27 (step S27; No), it is determined in step S32 whether Ct is 4. When Ct is 4 (step S32; Yes), in step S33, the timer T1s is timed up, that is, whether or not 1 second has elapsed since the LED 3 is turned off and the LEDs 1 and 2 are turned on. Judging. If the timer T1s has expired, that is, if LED 3 is turned off and one second has elapsed since LEDs 1 and 2 are turned on (step S33; Yes), SVin is closed in step S34. The LED 2 is turned off, 1 is added to Ct in step S35 (Ct = 5), and in step S36, the timer T1s that measures 1 second is started again, and the process ends. When the timer T1s has not expired (step S33; No), the process is terminated without doing anything. Here, the turn-off of the LED 2 indicates that SVin is in a closed state.

  If Ct is not 4 in step S32 (step S32; No), it is determined in step S37 whether Ct is 5. When Ct is 5 (step S37; Yes), in step S38, it is determined whether the timer T1s has timed up, that is, whether or not 1 second has elapsed since the SVin was closed and the LED 2 was turned off. to decide. When the timer T1s is up, that is, when SVin is closed and 1 second has elapsed since the LED 2 was turned off (step S38; Yes), in step S39, SVin is opened, The LED 2 is turned on, 1 is added to Ct in step S40 (Ct = 6), and in step S41, the timer T1s that measures 1 second is started again, and the process ends. If the timer T1s has not expired (step S38; No), the process is terminated without doing anything. Here, lighting of LED2 represents that SVin is in a valve open state.

  If Ct is not 5 in step S37 (step S37; No), it is determined in step S42 whether Ct is 6. If Ct is 6 (step S42; Yes), in step S43, whether or not the timer T1s has timed up, that is, whether or not 1 second has elapsed since the SVin was opened and the LED 2 was turned on. to decide. When the timer T1s is up, that is, when SVin is opened and 1 second has elapsed since the LED 2 was turned on (step S43; Yes), the LED 1 is turned off in step S44, and the LED 3 In step S45, 1 is added to Ct (Ct = 7), and in step S46, the timer T1s that measures 1 second is started again, and the process ends. If the timer T1s has not expired (step S43; No), the process is terminated without doing anything. Here, the turn-off of the LED 1 and the turn-on of the LED 3 represent the end of the operation of SVin and the operation of SVout. Further, the LED 2 that is lit represents the SVout open state.

  If Ct is not 6 in step S42 (step S42; No), it is determined in step S47 whether Ct is 7. If Ct is 7 (step S47; Yes), it is determined in step S48 whether the timer T1s has expired, that is, whether 1 second has elapsed since the LED 1 was turned off and the LED 3 was turned on. To do. When the timer T1s has expired, that is, when 1 second has elapsed since the LED 1 was turned off and the LED 3 was turned on (step S48; Yes), the SVout is closed in step S49, and the LED 2 In step S50, 1 is added to Ct (Ct = 8). In step S51, the timer T1s for measuring 1 second is started again, and the process is completed. If the timer T1s has not expired (step S48; No), the process is terminated without doing anything. Here, the turn-off of the LED 2 indicates that SVouth is in a closed state.

  If Ct is not 7 in step S47 (step S47; No), it is determined in step S52 whether Ct is 8. If Ct is 8 (step S52; Yes), in step S53, whether or not the timer T1s has timed up, that is, whether or not 1 second has elapsed after the SVout is closed and the LED 2 is turned off. to decide. When the timer T1s is up, that is, when SVout is closed and 1 second has elapsed since the LED 2 was turned off (step S53; Yes), in step S54, SVout is opened. In step S55, 1 is added to Ct (Ct = 9), and in step S56, a timer T1s that measures 1 second is started again, and the process is ended. When the timer T1s has not expired (step S53; No), the process is terminated without doing anything. Here, lighting of LED2 represents the valve open state of SVout.

  In step S52, when Ct is not 8 (step S52; No), Ct is 9, so in step S57, the timer T1s is timed up, that is, SVout is opened and LED2 is lit. It is determined whether or not 1 second has elapsed. When the timer T1s is up, that is, when SVout is opened and 1 second has elapsed since the LED 2 was turned on (step S57; Yes), the test flag Ft is cleared in step S58 ( 0) to finish the process. If the timer T1s has not expired (step S57; No), the process is terminated without doing anything.

  Next, another example of the operation of the shut-off valve device 14 will be described with reference to FIG. In this example, at the time of inspection, for example, LED1 represents the SVin open and closed state, and LED2 represents the SVout open and closed state. The operation of the initial part is the same as in FIG. 3, and the loop part is the same as steps S11 to S31 in FIG. The description of is omitted.

  If Ct is not 3 in step S77 (step S77; No), it is determined in step S82 whether Ct is 4. If Ct is 4 (step S82; Yes), in step S83, whether the timer T1s has expired, that is, whether 1 second has elapsed since the LED 3 is turned off and the LEDs 1 and 2 are turned on. Judging. If the timer T1s has expired, that is, if LED 3 is turned off and one second has elapsed since LEDs 1 and 2 were lit (step S83; Yes), SVin is closed in step S84. In step S85, 1 is added to Ct (Ct = 5), the timer T1s that measures 1 second is started again, and the process is completed. When the timer T1s has not expired (step S83; No), the process is terminated without doing anything. Here, the turn-off of the LED 1 indicates that SVin is in a closed state.

  If Ct is not 4 in step S82 (step S82; No), it is determined in step S87 whether Ct is 5. When Ct is 5 (step S87; Yes), in step S88, it is determined whether the timer T1s has timed up, that is, whether or not 1 second has elapsed since the SVin was closed and the LED1 was turned off. to decide. When the timer T1s has expired, that is, when SVin is closed and 1 second has elapsed since the LED1 was turned off (step S88; Yes), in step S89, SVin is opened, LED1 is turned on, 1 is added to Ct in step S90 (Ct = 6), timer T1s which measures 1 second is started again, and the process ends. If the timer T1s has not expired (step S88; No), the process is terminated without doing anything. Here, lighting of LED1 represents that SVin is in a valve open state.

  If Ct is not 5 in step S87 (step S87; No), it is determined in step S92 whether Ct is 6. When Ct is 6 (step S92; Yes), in step S93, it is determined whether the timer T1s has timed up, that is, whether or not 1 second has elapsed since the opening of SVin and turning on the LED1. to decide. When the timer T1s is up, that is, when SVin is opened and 1 second has elapsed since the LED1 was turned on (step S93; Yes), in step S94, SVout is closed, The LED 2 is turned off, 1 is added to Ct in step S95 (Ct = 7), and in step S96, the timer T1s that measures 1 second is started again, and the process is ended. If the timer T1s has not expired (step S93; No), the process is terminated without doing anything. Here, the turn-off of the LED 2 represents the SVout closed state.

  If Ct is not 6 in step S92 (step S92; No), it is determined in step S97 whether Ct is 7. If Ct is 7 (step S97; Yes), in step S98, whether or not the timer T1s has timed up, that is, whether or not 1 second has elapsed after the SVout is closed and the LED 2 is turned off. to decide. When the timer T1s has expired, that is, when SVout is closed and 1 second has elapsed after the LED 2 is turned off (step S98; Yes), in step S99, SVout is opened, The LED 2 is turned on, 1 is added to Ct in step S100 (Ct = 8), and in step S101, the timer T1s that measures 1 second is started again, and the process ends. If the timer T1s has not expired (step S98; No), the process is terminated without doing anything. Here, lighting of LED2 represents the valve open state of SVout.

  In step S97, when Ct is not 7 (step S97; No), Ct is 8, so in step S102, timer T1s is timed up, that is, SVout is opened and LED 2 is lit. It is determined whether or not 1 second has elapsed. When the timer T1s has expired, that is, when 1 second has elapsed since the SVout was opened and the LED 2 was turned on (step S102; Yes), the test flag Ft is cleared (step S103) 0) to finish the process. If the timer T1s has not expired (step S102; No), the process is terminated without doing anything.

  In the above embodiment, the solenoid valves 9, 10 (SVin, SVout) are used as the shut-off valve of the shut-off valve device 14, but other valves such as an electric valve may be used as the shut-off valve in addition to the solenoid valve. it can.

DESCRIPTION OF SYMBOLS 1 Air conditioning equipment 2 Compressor 3 Condenser 3a Outdoor fan 4 (4A-4C) Expansion valve 5 (5A-5C) Evaporator 6 (6A-6C) Indoor fan 7 (7A-7C) Refrigerant leak detector 8 (8A- 8C) Shutoff valve control unit 9 (9A to 9C) Inlet side solenoid valve 10 (10A to 10C) Outlet side solenoid valve 12 Outdoor unit 13 (13A to 13C) Indoor unit 14 (14A to 14C) Shutoff valve device 15 Piping 21 Microcomputer 21a CPU
21b ROM
21c RAM
21d I / O port 21e Timer 22 External input circuit 23 Return switch 24 Return switch input circuit 25 Test switch 26 Test switch input circuit L1 LED1 (green)
L2 LED2 (orange)
L3 LED3 (red)
LD1 LED1 (green) drive circuit LD2 LED2 (orange) drive circuit LD3 LED3 (red) drive circuit R1 Relay 1
R2 relay 2
R3 relay 3
RD1 Relay 1 drive circuit RD2 Relay 2 drive circuit RD3 Relay 3 drive circuit SVin Inlet side solenoid valve SVout Outlet side solenoid valve

Claims (4)

A first shut-off valve attached to the inlet refrigerant flow path;
A second shut-off valve attached to the outlet refrigerant flow path;
External input means for inputting the output signal of the refrigerant leak detector,
A shutoff valve device that opens or shuts off the inlet and outlet refrigerant channels by opening and closing the first and second shutoff valves based on the state of the external input means,
A shut-off valve device comprising drive means for independently driving the first shut-off valve and the second shut-off valve.   The shut-off valve device according to claim 1, further comprising display means for displaying a shut-off valve that is operated when the first and second shut-off valves are inspected.   3. The shutoff valve device according to claim 2, wherein the display unit displays an open or closed state of the shutoff valve that is operated when checking the first and second shutoff valves. 4.   The shut-off valve device according to claim 1, 2 or 3, wherein the shut-off valve is an electromagnetic valve.

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