JP5985230B2 - Booster inspection device and booster inspection method - Google Patents

Description

  The present invention relates to a booster inspection apparatus and a booster inspection method.

  In the technique disclosed in Patent Document 1, a pressurized supply liquid chamber of an injection unit filled with a sealing agent is connected to a tire by a joint hose, and compressed air discharged from a compressor of a booster is supplied to the pressurized supply liquid chamber. To do. The pressure increasing device performs tire puncture repair by pumping the sealing agent and compressed air in the pressurized supply liquid chamber to the tire.

  For example, as disclosed in Patent Document 2, a compressor provided in a booster device is provided with an intake valve and an exhaust valve in a cylinder, and when a motor is driven, the piston of the compressor reciprocates, and the cylinder is moved from the intake valve to the cylinder. The air sucked in is compressed, and the compressed air is discharged from the exhaust valve.

  On the other hand, the tire needs to be used at a preset internal pressure. For this reason, the pressure booster for filling the sealant is equipped with a pressure gauge on the compressed air discharge side of the compressor to check whether the compressed air pressure of the compressor (internal pressure of the tire) has reached an appropriate pressure. it can.

  By the way, when the sealing agent is filled in the tire, it is an emergency state of the vehicle in which the tire is mounted, and an accurate operation of the pressure booster itself is required, and it is necessary to accurately send compressed air from the pressure booster to the tire. . From here, patent document 3 is disclosing the technique which prevents the leakage of fluids, such as compressed air generated when a pressure | voltage riser is connected to a tire.

JP 2006-1888033 A JP 2005-248808 A JP 2008-175345 A

  The present invention has been made in view of the above-described facts, and there is provided a boosting device inspecting apparatus and a boosting device inspecting method for inspecting whether or not a boosting device used for filling a sealing agent or the like operates properly. For the purpose of provision.

Inspection device of the boost device according to claim 1 of the present invention, a pressure gauge for measuring a compressor unit for generating compressed air by driving the compressor, the connection pipe to enable supplying the compressed air to the tire, the pressure in the connecting pipe And a booster provided with a safety valve for suppressing the pressure of the compressed air supplied from the compressor unit through the connecting pipe from exceeding a predetermined pressure, the inside of the booster reaches the inspection start pressure and the compressor An inspection device for a booster used for a test including a leak test for inspecting a leak of compressed air from a pressure change in the booster after the generation of compressed air in the unit is stopped, an air tank having a predetermined capacity; one end is connected to the air tank, the said connection tube of the booster to be connected to the other end, depending on the pressure in the connecting pipe of the booster A first pipe member for changing the pressure in the air tank, the connecting pipe of the booster is connected to one end, and a second pipe member external pressure source is connected to the other end, the second A pressure adjusting means provided in a piping member and adjusting the pressure of compressed air supplied from the external pressure source to set the pressure in the connecting pipe of the boosting device, and connection of the connecting pipe of the boosting device Switching means for switching the tip to the connection part of the external pressure source or the air tank via the pressure adjusting means .

In the pressure booster inspection apparatus according to the first aspect, by providing the air tank, the compressed air supplied from the pressure booster can be stored. When inspecting the leakage of compressed air from the booster, the booster is stopped in a state where the booster is filled with compressed air in the air tank to a predetermined pressure. As a result, if a leak occurs in the booster, the compressed air in the air tank leaks from the booster and the pressure decreases. At this time, since the amount of compressed air stored is increased by providing the air tank, the pressure drop is moderate, and it is possible to determine the presence or absence of leakage in accordance with actual use.
In addition, the inspection device connects the connecting pipe of the boosting device and the external pressure source by the second piping member provided with the pressure adjusting means, so that the boosting device is preliminarily connected with the compressed air supplied from the external pressure source. By using the set adjustment pressure, the pressure gauge provided in the pressure increasing device can be inspected.
Further, the inspection device includes a switching unit that switches the connection destination of the connection pipe of the pressure increasing device to an external pressure source or an air tank, thereby preventing the compressed air from unnecessarily flowing into the air tank.

Inspection device of the boost device according to claim 2 sends one end is connected to the air tank, the compressed air supplied from the external pressure source by Rukoto said external pressure source is connected to the other end to said air tank a third pipe member, provided in said third pipe member opening and closing means for opening and closing the conduit of the third pipe member, the pipe path of the third pipe member to be opened by said opening and closing means And pressure limiting means for setting the pressure in the air tank, which is raised by the compressed air supplied from the external pressure source, to a preset limiting pressure.

  According to the second aspect of the present invention, the inside of the air tank can be preliminarily pressurized with the pressure supplied from the external pressure source at least as the supply amount of the compressed air per unit time of the pressure increasing device.

4. The pressure booster inspection apparatus according to claim 3 , wherein the pressure adjusting means includes a plurality of regulators each having a different set pressure, and a regulator that supplies compressed air from the plurality of regulators to the connection pipe of the pressure booster. Selecting means for selecting.

According to the third aspect of the present invention, the pressure gauge of the booster can be inspected at a plurality of stages of pressure.

Inspection device of the boost device according to claim 4, a power supply means for supplying power of a predetermined voltage to the booster, the current consumption of the booster, wherein the compressor by the electric power supplied from said power supply means is driven Current measuring means for measuring.

According to invention of Claim 4, the power consumption when starting a pressure | voltage riser can be measured.

Inspection method of the step-up device according to claim 5, a pressure gauge for measuring a compressor unit for generating compressed air by driving the compressor, the connection pipe to enable supplying the compressed air to the tire, the pressure in the connecting pipe, And a method for inspecting a pressure increasing device having a safety valve that suppresses the pressure of the compressed air supplied from the compressor unit from being increased to a predetermined pressure or higher via the connection pipe, and comprising a predetermined capacity air tank And a boosting step of supplying compressed air from the booster so that the pressure in the air tank that changes according to the pressure change in the booster becomes a preset inspection start pressure. A stop step of stopping the booster after the inside of the air tank reaches the inspection start pressure, and a process after the booster is stopped A time measuring step for measuring the interval, and a leakage pressure measuring step for measuring the pressure detected by the pressure gauge when the elapsed time reaches a predetermined time as a pressure for determining leakage of compressed air from the pressure increasing device; ,including.

The method for inspecting a booster according to claim 6 is the method in which an external pressure is set so that the pressure in the air tank is lower than the test start pressure before supplying compressed air from the booster to the air tank. A pressurizing step of supplying compressed air from a source.

The pressure booster inspection method according to claim 7 is a pressure adjustment step of supplying compressed air from the external pressure source to the pressure booster so that the booster whose operation has been stopped has a preset pressure. Measuring the pressure indicated by the pressure gauge of the pressure increasing device as the adjustment pressure as a pressure for determining the suitability of the pressure gauge, and before the pointer pressure measuring step is completed, Perform the pressurization step.

  As described above, according to the present invention, there is an effect that the operation of the boosting device can be easily and accurately inspected.

It is a perspective view which shows the external appearance of the inspection apparatus which concerns on this Embodiment. It is a perspective view which shows an example of use of the pressure | voltage riser which concerns on this Embodiment. It is a functional block diagram which shows the piping system of an inspection apparatus. It is a functional block diagram which shows schematic structure of a control part. It is a functional block diagram showing an example of a timer circuit. (A) And (B) is a timing chart which shows an example of operation | movement of a timer circuit. It is a table | surface figure which shows the outline of the operation state of each component according to a test | inspection item. It is a flowchart which shows an example of the test | inspection order in a test | inspection apparatus. It is a flowchart which shows an example of the electric current test | inspection with respect to a pressure | voltage rise apparatus. It is a schematic system diagram which shows an example of the pipe line which the compressed air passes in an electric current test | inspection. It is a flowchart which shows an example of the relief pressure test | inspection with respect to a pressure | voltage rise apparatus. It is a schematic system diagram which shows an example of the pipe line which the compressed air passes in a relief pressure test | inspection. It is a flowchart which shows an example of a gauge precision test | inspection with respect to the pressure gauge of a pressure | voltage rise apparatus. (A) And (B) is a schematic system diagram which shows an example of the pipe line which the compressed air passes in a gauge precision test | inspection, (A) shows a test | inspection of a high voltage | pressure side, (B) shows a test | inspection of a low voltage | pressure side. It is a flowchart which shows an example of the leak test | inspection with respect to a pressure | voltage rise apparatus. (A)-(C) is a schematic system diagram showing an example of a pipeline through which compressed air passes in a leak test, (A) is before the booster is started, (B) is during startup of the booster, (C) is It shows after the booster is stopped.

  Hereinafter, an example of an embodiment of the present invention will be described in detail with reference to the drawings. FIG. 1 shows an overview of an inspection apparatus (hereinafter referred to as “inspection apparatus 10”) for a booster according to the present embodiment. This inspection device 10 is used for inspection of a booster device by connecting the booster device.

  FIG. 2 shows a tire pressure booster (hereinafter referred to as “pressure booster 12”) as an example of a pressure booster. The pressure increasing device 12 seals a puncture hole of the tire 14 without replacing the tire 14 and the wheel 16 when a pneumatic tire (hereinafter referred to as “tire 14”) mounted on a vehicle such as an automobile punctures. Is used to repressurize the internal pressure of the tire 14 to a specified pressure.

  The pressure increasing device 12 is equipped with a liquid agent container 16 containing a sealing agent for repairing a puncture hole of the tire 14. The pressure increasing device 12 includes in the housing 110 a compressor unit 112 that includes a compressor that generates compressed air and a motor that drives the compressor (both not shown), and a mounting portion 114 to which the liquid agent container 16 is mounted.

  As the liquid container 16 attached to the pressure increasing device 12, a container containing a larger amount of sealing agent than the amount specified according to the type, size, etc. of the tire 14 to be punctured is used.

  As a compressor used in the compressor unit 112, an intake valve and an exhaust valve are provided in a cylinder, and a piston reciprocates in the cylinder by a rotational drive of a motor, so that air sucked from the intake valve is compressed and discharged from the exhaust valve. A reciprocating type for discharging is applied. The compressor is not limited to the reciprocating type.

  The compressor unit 112 accommodates a compressor, a motor, and a gear that transmits the rotation of the motor to the compressor. In addition, the well-known structure which discharges compressed air can apply the compressor and the drive mechanism of a compressor, and abbreviate | omits description here for details.

  The compressed air discharge side of the compressor unit 112 and the mounting portion 114 are connected by an air pipe 116, and compressed air is supplied from the compressor unit 112 to the mounting portion 114 via the air pipe 116.

  The booster 12 is provided with a power switch 118 and a pressure gauge 120. Further, the booster 12 includes a power cable 122 having one end connected to a power unit (not shown). A plug 124 to be inserted into a power socket such as a cigarette socket installed in the vehicle is attached to the tip of the power cable 122.

  The booster 12 draws the power cable 122 from the housing 110 and inserts the plug 124 into the socket of the vehicle, whereby electric power of a predetermined voltage (DC 12V electric power) is supplied from a battery provided in the vehicle. In the booster 12, the compressor is operated by turning on the power switch 118 in a state where electric power is supplied, and the compressed air is discharged from the compressor unit 112. In the booster 12, the compressor unit 112 stops discharging compressed air when the power switch 118 is turned off.

  The liquid agent container 16 is attached to the attachment portion 114 via the injection unit 126. The injection unit 126 has a pressurized liquid supply chamber into which the sealing agent flows when the container opening is opened by being connected to the container opening of the liquid agent container 16. The mounting unit 114 is mounted with an injection unit 126 to which the liquid container 16 is mounted. The liquid agent container 16 is attached to the attachment part 114 via the injection unit 126 so that the container opening is opened and the sealing agent flows into the pressurized liquid supply chamber, and compressed air is introduced into the liquid agent container 16 from the container opening. Supply is possible.

  When the user mounts the pressure increasing device 12 on the vehicle, the injection unit 126 is detached from the mounting portion 114 and mounted on the liquid container 16. In addition, when the product is shipped, the injection unit 126 is mounted on the mounting portion 114 with the opening on the liquid agent container 16 side closed tightly with a cap or the like.

  One end of a joint hose 128 is connected to the injection unit 126, and the inside of the joint hose 128 is communicated with the pressurized liquid supply chamber of the injection unit 126. A valve adapter 130 is attached to the other end of the joint hose 128. In the pressure increasing device 12, the sealing agent and the compressed air can be supplied into the tire 14 by connecting the valve adapter 130 to an air valve (not shown) of the tire 14.

  The pressure increasing device 12 supplies compressed air into the liquid agent container 16 to increase the pressure in the liquid agent container 16 and supply the sealing agent flowing into the pressurized supply chamber into the tire 14. Thereby, the pressure booster 12 fills the tire 14 with the sealing agent. In the pressure increasing device 12, when substantially the entire amount of the sealing agent is supplied from the liquid container 16 to the tire 14, the compressed air is supplied to the tire 14 following the sealing agent to increase the internal pressure. The compressor unit 112 is provided with a safety valve (pressure valve) 132 to prevent the air pressure from exceeding a specified level by allowing the compressed air to escape.

  The pressure gauge 120 indicates the internal pressure of the tire 14 because the inside of the air pipe 116 communicates with the inside of the tire 14, and the pointer swings according to the internal pressure of the tire 14. When the sealing agent and compressed air are supplied using the pressure increasing device 12, the power switch 118 is turned off by confirming that the internal pressure of the tire 14 has reached the specified pressure based on the numerical value indicated by the pointer of the pressure gauge 120. Stop supply of agent and compressed air.

  In addition, when the sealing agent is filled in the tire 14 for repairing the puncture of the tire 14, the tire 14 into which the sealing agent is injected is preliminarily traveled over a certain distance (for example, 10 km) after filling. By this preliminary traveling, the sealing agent is uniformly diffused on the inner surface of the tire 14, so that the puncture hole in the tire 14 is blocked by the sealing agent.

  Further, after the preliminary traveling is completed, the internal pressure in the tire 14 is measured again, and the internal pressure of the tire 14 is set to the specified pressure by retransmitting the compressed air from the booster 12 as necessary. Thereby, the puncture repair of the tire 14 is completed, and the repaired tire 14 can be used to travel at a constant speed or less (for example, 80 km / h or less) within a certain distance range.

  Thus, the booster 12 has a simple and compact configuration that does not have a tank for storing compressed air, and it is easy to secure a space when mounted on a vehicle. Further, the pressure increasing device 12 supplies the sealing agent and the compressed air from the liquid container 16 to the tire 14 by supplying compressed air to the liquid container 16 in an emergency state of the tire.

  The inspection device 10 is used for inspecting whether or not the booster device 12 used in an emergency state of a tire is in a state where it can be accurately operated.

  As shown in FIG. 1, the inspection apparatus 10 according to the present embodiment includes a box-shaped casing 18. In the inspection apparatus 10, an air pipe is formed in the casing 18, and a control unit that controls the operation of the inspection apparatus 10 is accommodated. Further, the inspection apparatus 10 has the front side in FIG. 1 as the front side, and the panel on this side is hereinafter referred to as a front panel 20A.

  The casing 18 is provided with a table 22 below the front panel 20A. The table 22 is formed with a work placement unit 24 on which the booster 12 (not shown in FIG. 1) to be inspected is placed. When inspecting a large number of boosting devices 12 by the inspection device 10, the boosting devices 12 are sequentially placed on the work placement unit 24 of the table 22. An elastic sheet or the like is affixed to the work placement unit 24 to prevent scratches and slippage of the booster 12.

  In FIG. 3, the functional system diagram of the pipe line of the inspection apparatus 10 is shown. The inspection device 10 is provided with an input joint 26 that serves as an input port for compressed air from the booster 12 as a connection portion. Further, the inspection apparatus 10 is provided with an external input joint 28 as an external connection portion. An external pressure source 30 is connected to the external input joint 28.

  The inspection apparatus 10 is supplied with compressed air from the external pressure source by connecting the external pressure source 30 to the external input joint 28. As such an external pressure source 30, a dedicated compressor such as a so-called bebicon or a compressor shared with other equipment can be used. Moreover, when piping which supplies compressed air to each facility in a factory is laid, it can also be used as the external pressure source 30 by connecting this piping.

  Further, the inspection device 10 can supply the compressed air from the pressure increasing device 12 and the compressed air to the pressure increasing device 12 by connecting the valve adapter 130 of the pressure increasing device 12 to the input joint 26.

  The inspection device 10 is provided with switching valves 32 and 34. The switching valves 32 and 34 are manually operated to switch the communication destination to the port A (C-A) or the port B (C-B) with the common port C. Hereinafter, the ports A, B, and C of the switching valve 32 are expressed as ports 32A, 32B, and 32C, and the ports A, B, and C of the switching valve 34 are expressed as ports 34A, 34B, and 34C. In the present embodiment, the manual type is applied as the switching valves 32 and 34, but it is also possible to use an electric switching valve.

  The switching valves 32 and 34 are arranged between the input joint 26 and the external input joint 28 as the switching valve 32 on the input joint 26 side and as the switching valve 34 on the external input joint 28 side. In the switching valve 32 and the switching valve 34, the port 30 </ b> B of the switching valve 30 is connected to the port 32 </ b> C of the switching valve 32.

One end of a pipe 36A serving as a first pipe member is connected to the input joint 26, and a switching valve 32 is provided in the pipe 36A. The pipe 36A is provided with a pressure gauge 38 for measuring the pressure in the pipe 36A (pressure of compressed air), a pressure sensor 40 for detecting the pressure in the pipe 36A, and a safety valve 42. The safety valve 42 prevents an increase in pressure in the inspection device 10 and the pressure booster 12 when the safety valve 132 of the pressure booster 12 has failed.

On the other hand, the inspection apparatus 10 includes two filter regulators 44 and 46. The external input joint 28 is connected to one end of a pipe 36B serving as a second pipe member and one end of a pipe 36C serving as a third pipe member . The filter regulator 44 is provided in the pipe 36B, and the filter regulator 46 is provided in the pipe 36C. Each of the filter regulators 44 and 46 removes moisture (humidity) contained in the compressed air when the compressed air is supplied from the external pressure source 30.

  The inspection apparatus 10 uses two regulators 48 and 50 as pressure adjusting means, and sets the regulators 48 and 50 to different adjustment pressures. In the present embodiment, a so-called precision regulator with high pressure adjustment accuracy is used. Hereinafter, the regulators 48 and 50 are referred to as precision regulators 48 and 50.

  The pipe 36B is connected to the port 32B of the switching valve 32, and the switching valve 34 and precision regulators 48 and 50 are attached to the pipe 36B. The precision regulator 48 is provided between the port 34A of the switching valve 34 and the filter regulator 44, and the precision regulator 50 is provided between the port 34B of the switching valve 34 and the filter regulator 44.

  In the inspection apparatus 10, the switching valve 34 functions as selection means, and the switching valve 34 is switched to the port 34 </ b> A side, so that the compressed air supplied from the external pressure source 30 passes through the filter regulator 44 and the precision regulator 48. Send to the switching valve 32 side. Moreover, the inspection apparatus 10 passes the filter regulator 44 and the precision regulator 50, and sends the compressed air supplied from the external pressure source 30 to the switching valve 32 side because the switching valve 34 is switched to the port 34B side.

  The inspection apparatus 10 includes a high relief regulator 52 that functions as a limiting unit, and two electromagnetic valves 54 and 56. The high relief regulator 52 and the electromagnetic valve 54 are provided in the pipe 36C and function as an opening / closing means, and the electromagnetic valve 56 is provided in the pipe 36A to which the switching valve 32 is attached. Thereby, in the inspection apparatus 10, the compressed air of the external pressure source 30 supplied via the filter regulator 46 and the high relief regulator 52 is moved to the solenoid valve 56 side by opening the solenoid valve 54 on the high relief regulator 52 side. Sent. Further, the inspection device 10 is configured such that when the switching valve 32 is switched to the port 32A side, the electromagnetic valve 56 is opened, so that the compressed air is transferred between the booster 12 and the solenoid valve 56 side of the solenoid valve 54. Distribution becomes possible.

  By the way, the pressure booster 12 according to the present embodiment is configured not to have a tank for storing compressed air. In contrast, the inspection apparatus 10 according to the present embodiment includes a buffer tank 60 as an air tank. The buffer tank 60 is connected to the pipes 36A and 36C. That is, the buffer tank 60 is connected to a connection portion between the pipes 36A and 36C, and the solenoid valve 54 is opened, so that compressed air is supplied from the external pressure source 30 and the solenoid valve 56 is opened, whereby the booster 12 is opened. Compressed air can be supplied.

  In the inspection device 10, the amount of compressed air accumulated is increased by providing the buffer tank 60 when inspecting the pressure increasing device 12 that does not include a tank or the like for accumulating compressed air. Thereby, in the test | inspection apparatus 10, when test | inspecting the leak (henceforth leakage) of compressed air, for example, a pressure change can be made loose.

  The capacity (volume) of the buffer tank 60 when the booster 12 is inspected can be set to the same capacity as that of the liquid container 16 used in the booster 12. Accordingly, in the present embodiment, the capacity of the buffer tank 60 is set to 350 ml as an example. The capacity of the buffer tank 60 is not limited to this. For example, by reducing the capacity of the buffer tank 60, the pressure change increases, but the accumulation time for accumulating the compressed air to a predetermined pressure can be shortened. Further, when the capacity of the buffer tank 60 is increased, the accumulation time for accumulating the compressed air up to a predetermined pressure becomes longer, but the pressure change can be moderated. From here, the capacity required for the buffer tank 60 may be determined, and a tank with the determined capacity may be used.

  In the inspection apparatus 10, a pressure sensor 62 is provided between the electromagnetic valves 54 and 56. The inspection apparatus 10 detects the pressure (air pressure) of the compressed air in the buffer tank 60 by the pressure sensor 62. The buffer tank 60 is provided with a drain valve 58, and the compressed air can be discharged from the buffer tank 60 by opening the drain valve 58.

  As shown in FIG. 1, the inspection apparatus 10 is provided with a switching lever 32D for manual operation of the switching valve 32 and a switching lever 34D of the switching valve 34 on the front panel 20A.

In the inspection apparatus 10, a pressure gauge 38 is attached to the front panel 20A, and filter regulators 44 and 46, precision regulators 48 and 50, and a high relief regulator 52 are attached to one side panel 20B.

  Thereby, in the inspection apparatus 10, the adjustment pressure for the precision regulators 48 and 50 can be set, the flow path of the compressed air can be switched using the switching valves 32 and 34, and the pressure of the compressed air with the booster 12 can be visually confirmed. It has become. In the inspection apparatus 10, the drain valve 58 is pulled out from the side panel 20 </ b> B, which facilitates the discharge of the compressed air in the buffer tank 60 after the completion of the inspection for the booster 12.

  FIG. 4 shows a schematic configuration of the control unit 64 that controls the operation of the inspection apparatus 10. As shown in FIG. 1, the inspection apparatus 10 is provided with a power switch 66 (not shown in FIG. 4) of a power supply unit (not shown) on the front panel 20A. In the inspection apparatus 10, by turning on the power switch 66, power of a predetermined voltage is supplied from the power supply unit to the control unit 64 and becomes operable.

  As shown in FIG. 4, the control unit 64 includes a control unit 68 that operates with power of a predetermined voltage supplied from a power supply unit (not shown). The control unit 68 includes a sequencer 70 and a timer circuit 72 that functions as time measuring means.

  As the sequencer 70, a general configuration including a microcomputer, an input interface, an output interface, and a storage unit (not shown) for storing data and programs can be applied. Such a sequencer 70 operates the output device connected to the output interface according to the input signal from the input device connected to the input interface based on the program and data stored in the storage unit.

  Pressure sensors 40 and 62 are connected to the control unit 68 as the input device. In addition, the inspection device 10 is provided with a foot switch 74, a sensor switch 76, and a voltage changeover switch 78 operated by an operator who inspects the booster device 12.

  As shown in FIG. 1, the sensor switch 76 and the voltage changeover switch 78 are provided on the front panel 20A and are operated by an operator during inspection. The foot switch 74 (not shown in FIG. 1) is placed at the operator's foot and is turned on / off by the operator during inspection.

  As shown in FIG. 4, a foot switch 74, a sensor switch 76, and a voltage changeover switch 78 are connected to the control unit 68. The control unit 68 is connected with electromagnetic valves 54 and 56 as output devices.

  On the other hand, the control unit 64 includes a power supply unit 80 that supplies power to the booster 12. The power supply unit 80 includes a socket 82 corresponding to a socket provided in a vehicle in which the booster 12 is used. As shown in FIG. 1, in the inspection apparatus 10, a socket 82 is attached to the front panel 20 </ b> A so as to facilitate connection work during inspection of the booster 12. In the inspection apparatus 10, the plug 124 (see FIG. 2) of the booster 12 is inserted into the socket 82, so that the booster 12 is operated with electric power supplied from the inspection apparatus 10.

  As shown in FIG. 4, the power supply unit 80 includes a stabilized power supply 84 that outputs a plurality of DC voltages and a voltage switching unit 86 that selects an output voltage. The inspection apparatus 10 according to the present embodiment includes a voltage (for example, 12V, hereinafter referred to as N voltage) of a vehicle battery in which the booster 12 is used, and a voltage exceeding the maximum voltage supplied from the vehicle (for example, 15V, below). , H voltage) is set as the inspection voltage of the booster 12.

  The control unit 68 operates the voltage switching unit 86 in accordance with the operation state of the voltage switching switch 78. Thereby, in the inspection apparatus 10, when the N voltage is selected by the voltage changeover switch 78, the N voltage DC power is supplied to the booster 12 and the H voltage is selected by the voltage changeover switch 78. The DC power of H voltage is supplied to the booster 12. Note that the inspection voltage of the booster 12 is not limited to two types, and three or more types of voltages may be set, and any voltage required for the inspection can be applied.

  The inspection apparatus 10 also includes an ammeter 88 that measures a current (hereinafter referred to as current consumption) that flows when the booster 12 operates. As shown in FIG. 1, in the inspection apparatus 10, an ammeter 88 is attached to the front panel 20A. Thereby, the operator can visually recognize the power consumption during the operation of the booster 12. The inspection apparatus 10 uses a so-called analog ammeter 88, but is not limited to this, for example, converts a current value detected by a current sensor into a digital signal, and displays the converted current value on a display or the like. A known configuration such as a configuration to be applied can be applied.

  As shown in FIG. 4, the control unit 64 includes a lamp unit 90. The lamp unit 90 is connected to the control unit 68. The timer circuit 72 uses the lamp unit 90 to display the elapsed timing during the operation of the booster 12.

  FIG. 5 shows an outline of the timer circuit 72 provided in the inspection apparatus 10. As an example, the inspection apparatus 10 includes two systems of timer circuits 72A and 72B. The timer circuits 72A and 72B have the same basic configuration, but may have different configurations.

  The timer circuits 72A and 72B include a timer relay 92 and a delay circuit 94. A foot switch 74 is connected to the timer circuit 72A. In the timer circuit 72A, the reset signal Rest is input to the timer relay 92 when the foot switch 74 is turned on. In the timer circuit 72A, the ON signal of the foot switch 74 is input to the delay circuit 94. When the ON signal of the foot switch 74 is input, the delay circuit 94 outputs a signal (input signal IN) to the timer relay 92 after the set delay time td has elapsed.

  The lamp unit 90 includes a plurality of point light sources used for the timer circuit 72. In the present embodiment, two LEDs 96G and 96R are used for the timer circuit 72A, and two LEDs 98G and 98R are used for the timer circuit 72B. As shown in FIG. 1, in the inspection apparatus 10, two lamp cases are attached to the front panel 20A. In one lamp case, LEDs 96G and 98G are housed, and when one of the LEDs 96G and 98G is lit, for example, it emits green light (hereinafter referred to as a lamp 100G as a whole). The other lamp case accommodates the LEDs 96R and 98R, and when one of the LEDs 96R and 98R is lit, for example, it emits red light (hereinafter referred to as the lamp 100R together).

  As shown in FIG. 5, in the timer circuit 72A, LEDs 96G and 96R are connected to the timer relay 92, and blink according to the output signal of the timer relay 92. Here, the blinking of the LEDs 96G and 96R in the timer circuit 72A will be described with reference to FIG. In the timer circuit 92, the LED 96G is turned off when the output signal T1 of the timer relay 92 is at a high level, and the LED 96G is turned on at a low level. In the timer circuit 92, the LED 96R is turned off when the output signal T2 of the timer relay 92 is at a high level, and the LED 96R is turned on at a low level.

  As shown in FIG. 6A, in the timer circuit 72A, when the foot switch 74 is depressed and turned on, the reset signal Rest is input to the timer relay 92. The timer relay 92 sets the outputs T1 and T2 to the low level when the foot switch 74 is turned off and the reset signal Rest is turned off. Thereby, the LEDs 96G and 96R are turned on. In the inspection apparatus 10, when the LEDs 96G and 96R are turned on, the lamps 100G and 100R of the front panel 20A are turned on.

  Further, the delay circuit 94 starts to operate when the foot switch 74 is turned on, and starts a predetermined delay time td (for example, a time set within td = 0.5 sec to 1.0 sec). ), An ON signal is output. The timer relay 92 resets and starts the built-in timer when the ON signal is input as the input signal IN.

Thereafter, the timer relay 92, the time is set for the output T1 t _{1 (e.g.,} the time set in the 2Sec～8sec) has elapsed, the output T1 High level. Thereby, the LED 96G (lamp 100G) is turned off in the timer circuit 72A. Also, timer relay 92, time set for the output T2 t _{2 (e.g.,} the time set in the 7Sec～13sec) has elapsed, the output T2 High level. Thereby, in the timer circuit 72A, the LED 96R (lamp 100R) is turned off.

Here, the timer circuit 72A, is shorter by a predetermined time than the time _{t 1} time _{t 2 (t 1 <t 2} ). Accordingly, the timer circuit 72A is reset when the foot switch 94 is turned on, and lights the LEDs 96G and 96R when the foot switch 74 is turned off. Thereafter, when the input signal IN is input, time measurement is started, and the LEDs 96G and 96R are stopped in order.

  The operator can grasp the timing of work in accordance with the operation of the foot switch 74 by turning on / off the lamps 100G, 100R in accordance with the turning on / off of the LEDs 96G, 96R of the timer circuit 72A. At this time, the operator recognizes that the lamp 100G is turned off as a notice of turning off the lamp 100R.

  On the other hand, the timer circuit 72B includes a one-shot circuit 102 in addition to the delay circuit 94, as shown in FIG. In the timer circuit 72B, the LED 98G is turned on / off according to the output T1 of the timer relay 92, and the LED 98R is turned on / off according to the output T2 of the timer relay 92.

  For example, the pressure sensor 40 is connected to the timer circuit 72B via the sensor switch 76 to the delay circuit 94 and the one-shot circuit 102. A pull-down resistor 104 is connected to the delay circuit 94 and the one-shot circuit 102. Further, the delay circuit 94 and the one-shot circuit 104 are supplied with a power signal output by the sequencer 70 in response to the operation / operation stop of the power supply unit 80, for example. The power supply signal is turned off when the sequencer 70 stops the power supply unit 80 or the stabilized power supply 84 in order to stop the operation of the booster 12. Further, the output (pressure signal) based on the pressure detected by the pressure sensor 40 is output by the sequencer 70 when the pressure detected by the pressure sensor 40 reaches a preset pressure Ps.

  FIG. 6B shows a timing chart of the timer circuit 72A. In the timer circuit 72B, when the power supply unit 80 that supplies power to the booster device 12 is operating, the power supply signal is kept on (High level), and the sequencer 70 operates the power supply unit to stop the operation of the booster device 12. When 80 is stopped, the power signal is turned off.

  The sequencer 70 detects the pressure by the pressure sensor 40 when the sensor switch 76 is turned on. The sequencer 70 turns on the pressure signal when the pressure detected by the pressure sensor 40 reaches the pressure Ps. In addition, the sequencer 70 turns on the pressure signal, stops power supply to the booster 12, and outputs an off signal as a power signal.

  In the timer circuit 72B, the power signal is turned off, and an on signal corresponding to the pressure detected by the pressure sensor 40 is input to the delay circuit 94 and the one-shot circuit 102. The one-shot circuit 102 outputs a one-shot pulse reset signal Rest when an ON signal is input. The delay circuit 94 outputs a signal that becomes the input signal IN with a delay of a predetermined delay time td with respect to the ON timing of the pressure signal.

The timer relay 92 turns on and off the LEDs 98G and 98R by changing the outputs T1 and T2 based on the reset signal Rest and the input signal IN. At this time, by making the time t ₁ shorter than the time t ₂ by a predetermined time, the timer circuit 72B allows the timer circuit 72B to stop when the detected pressure of the pressure sensor 40 reaches the pressure Ps and the power supply unit 80 (boost device 12) stops. The relay 92 is reset. Thereafter, the timer relay 92 of the timer circuit 72B turns on the LEDs 98G and 98R when the delay time td elapses at the same timing as the timer relay 92 of the timer circuit 72A, and the elapsed time (time) after the input signal IN is input. The LEDs 98G and 98R are sequentially turned off according to t ₁ and t ₂ ).

  As a result, the operator stops the operation of the booster 12 when the detected pressure of the pressure sensor 40 reaches the pressure Ps by turning on and off the lamps 100G and 100R in accordance with the turning on / off of the LEDs 98G and 98R of the timer circuit 72B. It is possible to grasp the timing of the inspection work after it is made.

Here, the timer circuit 72A, has been described without distinguishing the time _t 1, _{t 2} of 72B, the times _t 1, _{t 2,} a timer circuit 72A, different time to fit in the inspection work to be applied to each 72B It may be set to.

  The lamp unit 90 includes, for example, a lamp 104 that is turned on according to the operation state of the electromagnetic valves 54 and 56. As shown in FIG. 1, the lamp 104 is provided on the front panel 20A of the inspection apparatus 10 so as to be lit in a color (for example, orange) different from the lamps 100G and 100R. Thereby, the operator can confirm whether the passage route of the compressed air in the inspection apparatus 10 is in an initial state, for example.

  Below, the test | inspection of the pressure | voltage riser 12 using the test | inspection apparatus 10 is demonstrated as an effect | action of this Embodiment.

  In the inspection device 10, current inspection, relief pressure inspection, cage accuracy inspection, and leakage inspection of the booster 12 are set as inspection items for the booster 12, and these inspections are executed in a preset order. The In the inspection apparatus 10, the set pressures of the filter regulators 44, 46, the precision regulators 48, 50, and the high relief regulator 52 are adjusted based on the measured pressure of the pressure gauge 120 provided in the booster 12 and the relief pressure of the safety valve 132. ing.

  The inspection device 10 operates the switching valves 32 and 34 and the electromagnetic valves 54 and 56 to switch the piping path through which the compressed air passes according to the inspection item. In the inspection apparatus 10, the foot switch 74, the sensor switch 76, and the voltage changeover switch 78 are operated according to the inspection item, and the operation (run / stop) of the booster 12 is performed. FIG. 7 shows a list of operation states of the switching valves 32 and 34, the electromagnetic valves 54 and 56, the foot switch 74, the pressure sensor switch 76, the voltage switching switch 78, and the booster 12 for each inspection item.

  FIG. 8 shows the flow of inspection processing using the inspection apparatus 10. In the inspection apparatus 10, initial setting is performed in the first step 200. In this initial setting, the booster 12 is placed on the work placement unit 24 of the table 22. In the initial setting, the valve adapter 130 provided in the joint hose 128 of the booster 12 is connected to the input joint 26 and the plug 124 of the power cable 122 is provided in the socket 182 provided on the front panel 20A of the inspection device 10. Plug in.

  Thereby, the test operation of the booster 12 can be performed, and compressed air can be circulated between the inspection device 10 and the booster 12. The external pressure source 30 is connected to the external input joint 28 of the inspection apparatus 10 in advance.

  When the initial setting is completed and the preparation for the test of the booster 12 is completed, the process proceeds to step 202 to perform a current test. In the current inspection, the voltage supplied to the booster 12 is set to the H voltage.

  FIG. 9 shows an outline of the current inspection process. In this flowchart, the operation is performed in a state where the voltage switch 78 is switched to the H voltage (the initial state), and in the first step 220, the power switch 118 of the lifting device 12 is turned on. In the next step 222, it is confirmed whether or not the lifting device 12 has been started.

  When the operator confirms that the booster 12 has been started, the operator makes an affirmative determination in step 222 and proceeds to step 234. In this step 234, the elapsed time since the booster 12 is started using the timer circuit 72A is measured, and whether or not the time preset in the next step 226 (for example, time ts = 10 sec) has elapsed is determined. Check.

  In FIG. 10, the path | route of the compressed air in an electric current test | inspection is shown as the continuous line. In the inspection device 10, when performing a current inspection, the switching valve 32 is switched to the port 32A, and the electromagnetic valve 54 is turned off (closed). Thereby, the compressed air supplied from the booster 12 is stopped by the electromagnetic valve 54. Therefore, even if the inspection apparatus 10 is provided with the buffer tank 60, the booster 12 can be fully loaded in a short time.

  The current consumption of the booster 12 is maximized when the compressor (compressor unit) has a maximum load, and the compressor has a maximum load when the safety valve 132 is activated. In other words, in the inspection apparatus 10, the volume of the compressed air supplied from the booster 12 is reduced by turning off the electromagnetic valve 56, so that the booster 12 reaches the maximum load in a short time.

The timer circuit 72A, by setting the time _{t 2} the set time ts, the foot switch 74 is operated, the lamp 100G, to turn on the 100R. Thereafter, the timer circuit 72A turns off the lamp 100G when a predetermined time (time t ₁ ) elapses, and turns off the lamp 100R when the elapsed time reaches time t ₂ .

In the timer circuit 72A, by setting the time _{t 2} the set time ts the load of the booster 12 has reached the maximum, lamp 100G, the extinction of the 100R may be a standard.

  In the flowchart of FIG. 9, when a predetermined time (time ts) has elapsed and an affirmative determination is made in step 226, the current value indicated by the ammeter 88 attached to the front panel 20A is read by the operator in step 228. In the next step 230, it is confirmed whether or not the current value is within a preset range (within reference).

  In general, the voltage output from the battery of the vehicle via the socket is an N voltage (for example, 12 V). However, when the vehicle uses an engine (internal combustion engine) as a drive source, the booster 12 is used in an engine start state. . For this reason, the booster 12 may be supplied with a voltage higher than the N voltage.

  The power consumption of the booster 12 is determined by the motor that drives the compressor and the motor load. For example, the power consumption varies depending on the frictional resistance of the piston, and if the frictional resistance is large, the power consumption also increases. In other words, in the booster 12, the load on the motor is not limited depending on each assembled part and the assembled state of each part. From here, the test | inspection apparatus 10 performs the electric current test | inspection of the voltage booster 12 with the H voltage exceeding the maximum voltage supplied with the engine of a vehicle in a starting state.

  If the current value indicated by the ammeter 88 is within the reference, an affirmative determination is made at step 230 and the routine proceeds to step 232 where the power switch 118 of the booster 12 is turned off and the booster 12 is stopped. Thus, when it is confirmed that the booster 12 is stopped, an affirmative determination is made in step 234, and the current test of the booster 12 is completed.

  If the start-up of the booster device 12 is not confirmed, a negative determination is made in step 222. If the current value measured by the ammeter 88 exceeds the current value set as a reference, the process proceeds to step 230. Negative determination is made. On the other hand, if the stop of the booster 12 is not confirmed despite the power switch 118 being turned off, a negative determination is made in step 234. If a negative determination is made in any of step 222, step 230, or step 234, the process proceeds to step 236, and the test for the booster 12 is terminated at that stage.

  In this manner, the inspection device 10 performs a current inspection of the booster 12 at a high voltage, thereby preventing the booster 12 from blowing a fuse provided in the vehicle during puncture repair of the vehicle tire. it can.

  In the flowchart of FIG. 8, when the current inspection of the booster 12 is completed, the process proceeds to step 204 and a relief inspection is performed. Note that if the current test has been completed, it is not necessary to execute step 204 and subsequent steps (stop the test for the booster 12).

  In the relief inspection, whether or not the operation of the safety valve 132 provided in the booster 12 is appropriate is confirmed using the pressure gauge 120 provided in the booster 12.

  FIG. 11 shows an outline of the relief pressure inspection process. The relief pressure inspection is executed by switching the voltage changeover switch 78 from the H voltage to the N voltage (see FIG. 7). In the relief pressure test, there is a part that performs the same process as the process in the current test described above. In FIG. 11, the step numbers in FIG. 9 are added to the process operations that are the same as those in FIG.

  In this flowchart, in the first step 240, the power switch 118 of the lifting device 12 is turned on. In the next step 242, it is confirmed whether or not the booster 12 has been started. When the start-up of the booster 12 is confirmed, an affirmative determination is made at step 242 and the routine proceeds to step 244. In this step 244, measurement of the elapsed time since the booster 12 is started using the timer circuit 72A is started, and whether or not the time preset in the next step 246 (for example, time ts = 10 sec) has elapsed. To check.

  As shown in FIG. 12, when the relief pressure test is performed, the switching valve 32 is switched to the port 32A, and the electromagnetic valve 56 is closed. Only the voltage supplied from the power supply unit 80 to the booster 12 is different, and the states of the switching valve 32 and the electromagnetic valve 56 are equivalent to the above-described current inspection (see FIG. 10). Therefore, by performing the current test before the relief pressure test, the inside of the test apparatus 10 is in a pressurized state, and the test apparatus 10 reduces the pressure in the pipeline to which compressed air is supplied from the booster 12 for a short time. Thus, the relief pressure of the safety valve 132 can be increased.

  In the relief pressure test, when the pressure in the pipeline reaches the operating pressure of the safety valve 132 due to the pressure increase, the safety valve 132 of the pressure increasing device 12 is operated to suppress the pressure increase.

  In the flowchart of FIG. 11, if a preset time has elapsed and an affirmative determination is made in step 246, the process proceeds to step 248, and the numerical value (instructed pressure) indicated by the pointer of the pressure gauge 120 of the booster 12 is read. In the next step 250, it is confirmed whether or not the pressure indicated by the pressure gauge 120 is within the reference. That is, it is confirmed whether the numerical value indicated by the pointer of the pressure gauge 120 is too high or too low with respect to the relief pressure set in the safety valve 132.

  In the pressure increasing device 12, the pointer of the pressure gauge 120 indicates the relief pressure of the safety valve 132 by operating the safety valve 132. Here, when the relief pressure of the safety valve 132 is not appropriate, or when the pressure gauge 120 cannot detect an appropriate pressure, the numerical value indicated by the pointer of the pressure gauge 120 is out of the reference value or reference range.

  From this point, if the numerical value indicated by the pointer of the pressure gauge 120 is within the allowable range, it is determined that the relief pressure of the safety valve 132 is appropriate, an affirmative determination is made in step 250, and the process proceeds to step 252. In step 252, the power switch 118 of the booster 12 is turned off. After that, when it is confirmed that the booster 12 is stopped, an affirmative determination is made in step 254 and the relief pressure test is completed.

  If a negative determination is made in step 242, a negative determination is made in step 250, and a negative determination is made in step 254, the process proceeds to step 256 and the inspection process for the booster device 12 is terminated.

  As described above, the inspection of the relief pressure of the safety valve 132 provided in the pressure increasing device 12 is performed by using the pressure gauge 120 provided in the pressure increasing device 12, whereby the relief pressure abnormality of the safety valve 132 or the measurement of the pressure gauge 120 is measured. At least one of the defects can be inspected.

  Here, the inspection is performed based on the numerical value indicated by the pointer of the pressure gauge 120 provided in the booster 12, but the numerical value (pressure) indicated by the pointer of the pressure gauge 120 of the booster 12 and the inspection device 10 Whether the pressure gauge 38 or the safety valve 132 is appropriate may be determined by comparing with a numerical value indicated by a pointer of the pressure gauge 38 provided.

  On the other hand, in the flowchart of FIG. 8, when the relief pressure test of the booster 12 is completed, the process proceeds to step 206, and the gauge accuracy test of the pressure gauge 120 provided in the booster 12 is performed.

  The inspection apparatus 10 includes two precision regulators 48 and 50 that are set to different adjustment pressures as the set pressure. The adjustment pressures of the precision regulators 48 and 50 are set lower than the relief pressure of the safety valve 132 of the pressure increasing device 12, and one adjustment pressure of the precision regulators 48 and 50 is set lower than the other adjustment pressure. In the present embodiment, the adjustment pressure of the precision regulator 48 is set higher than the adjustment pressure of the precision regulator 50. In the following, a system for supplying compressed air to the booster 12 using the precision regulator 48 is referred to as the high pressure side. A system for supplying compressed air to the booster 12 using the precision regulator 50 will be described as a low pressure side.

  For example, when the relief pressure of the safety valve 132 of the booster 12 is 300 kPa, the adjustment pressures of the precision regulators 48 and 50 are set to 250 kPa for the high-pressure precision regulator 48 and 200 kPa for the low-pressure precision regulator 50. . In addition, the combination of adjustment pressure is not restricted to this.

  FIG. 13 shows an outline of processing of gauge accuracy inspection (pressure gauge accuracy inspection). In the inspection device 10, when the gauge accuracy inspection is performed, the pressure increasing device 12 is stopped, and in the first step 260, the compressed air supply system to the pressure increasing device 12 is set to the high pressure side.

  As shown in FIG. 14A, when the gauge accuracy inspection on the high pressure side is performed, the switching valve 32 is switched to the port 32B side, and the switching valve 34 is switched to the port 34A side. As a result, a flow path of compressed air from the external pressure source 30 to the pressure increasing device 12 through the precision regulator 48 is formed.

  Thereby, the compressed air supplied from the external pressure source 30 passes through the precision regulator 48. The compressed air that has passed through the switching valve 34 passes through the switching valve 32 and reaches the booster 12 because the switching valve 32 is switched to the port 32B. At this time, the pressure adjusted by the precision regulator 48 is applied to the pressure gauge 120 of the booster 12 because the compressor of the booster 12 is stopped.

  In the flowchart of FIG. 13, in the next step 262, the pointer of the pressure gauge 120 (pressure indicated by the pressure gauge 120) of the pressure increasing device 12 is read. In the next step 264, it is confirmed whether or not the read pressure is within a predetermined range based on the pressure adjusted by the precision regulator 48.

  Here, if the numerical value indicated by the pointer of the pressure gauge 120 is within a predetermined error range with the adjustment pressure of the precision regulator 48 as a reference, an affirmative determination is made in step 264 and the routine proceeds to step 266. In step 266, the compressed air supply system to the booster 12 is switched to the low pressure side.

  As shown in FIG. 14B, when the gauge accuracy inspection on the low pressure side is performed, the switching valve 32 remains on the port 32B side and the switching valve 34 is switched to the port 34B side. As a result, a compressed air flow path is formed from the external pressure source 30 through the precision regulator 50 to the booster 12.

  In the flowchart of FIG. 13, in the next step 268, the numerical value indicated by the pointer of the pressure gauge 120 of the booster 12 is read. In the next step 270, it is confirmed whether or not the read pressure is within a predetermined range based on the pressure adjusted by the precision regulator 50.

  Accordingly, when it is confirmed that the numerical value indicated by the pointer of the pressure gauge 120 is within a predetermined error range (reference range) based on the adjustment pressure of the precision regulator 50, an affirmative determination is made in step 270 to complete the gauge accuracy inspection. .

  In this gauge accuracy inspection, if at least one of the high pressure side and the low pressure side indicates that the numerical value indicated by the pointer of the pressure gauge 120 is out of the reference range and a negative determination is made in step 264 or step 270, the process proceeds to step 272. Then, the inspection process for the booster 12 is finished. Here, the high-pressure side inspection is performed first, but the low-pressure side inspection may be performed first.

  In the flowchart of FIG. 8, when the gauge accuracy inspection is completed, the process proceeds to step 280 to perform a leakage inspection on the booster 12. In this leakage inspection, it is confirmed whether or not there is a leakage of compressed air between the compressor (compressor unit 112) of the pressure increasing device 12 and the valve adapter 130 of the joint hose 128.

  Further, the inspection device 10 uses the timer circuit 72B described above for the leakage inspection. At this time, the set pressure Pa with respect to the detection pressure of the pressure sensor 40 is set to a relief pressure (for example, a relief valve 132 provided in the pressure increase device 12). 300 kpa).

  FIG. 15 shows the flow of processing for leakage inspection. In this flowchart, the power switch 118 of the booster 12 is turned on in the first step 280. As a result, the inspection device 10 can control the start / stop of the booster 12.

  As shown in FIG. 16A, in the inspection apparatus 10, when performing a leakage inspection, the power supply to the booster 12 is stopped. In the inspection apparatus 10, the switching valve 32 is switched to the port 32 </ b> A side and the electromagnetic valve 56 is opened (turned on) to form a flow path for compressed air between the booster 12 and the buffer tank 60. Yes. Thereby, the compressed air generated by starting up the pressure increasing device 12 is sent toward the buffer tank 60.

  On the other hand, in the inspection apparatus 10, the electromagnetic valve 54 is opened during the leakage inspection (see FIG. 7). Thereby, the compressed air from the external pressure source 30 is supplied to the buffer tank 60 through the high relief regulator 52. That is, the inspection apparatus 10 performs a leakage inspection with the buffer tank 60 in a pressurized state by compressed air supplied from the external pressure source 30.

  As described above, the compressed air from the external pressure source 30 is supplied to the buffer tank 60 via the high relief regulator 52. At this time, the high relief regulator 52 limits the pressure in the buffer tank 60. In the inspection apparatus 10, the adjustment pressure set in the high relief regulator becomes the limit pressure, and the pressurization pressure of the buffer tank 60 is set. In the present embodiment, as an example, the adjustment pressure of the high relief regulator 52 is set to 150 kPa as an example.

  Further, the inspection apparatus 10 performs a gauge accuracy inspection prior to the leakage inspection. As shown in FIGS. 14A and 14B, when the gauge accuracy inspection is performed, the electromagnetic valve 54 is opened and the electromagnetic valve 56 is closed, and the compressed air from the external pressure source 30 to the buffer tank 60 is A flow path is formed. Thereby, in the test | inspection apparatus 10, the buffer tank 60 can be made into a pressurized state prior to a leak test, and it can transfer to a leak test smoothly from a gauge precision test.

  In the flowchart of FIG. 15, the sequencer 70 is activated by turning on an inspection switch (not shown) in the next step 282, and for example, the following steps 284 to 300 are executed. The sequencer 70 turns on the sensor switch 76 when operating the timer circuit 72B, and the sensor switch 76 can also be used as an inspection switch in the leakage inspection.

  First, in step 284, the sequencer 70 reads the pressure of the compressed air in the buffer tank 60 detected by the pressure sensor 62, and in step 286, whether the detected pressure is a predetermined value (for example, the pressure is 210 kPa) or less. Confirm whether or not. Since the buffer tank 60 is already supplied from the external pressure source 30 via the high relief regulator 52, it is determined that at least the adjustment pressure of the high relief regulator 52 has been reached. In addition, when the previous booster 12 is inspected, the compressed air in the buffer tank 60 may be forgotten and the pressure may exceed a predetermined value. At this time, since the compressed air is discharged by the high relief regulator 52, it waits for the pressure in the buffer tank 60 to drop to a predetermined value.

  When the pressure detected by the pressure sensor 62 becomes equal to or less than the predetermined value, an affirmative determination is made in step 286, the process proceeds to step 288, and power supply to the booster 12 is started by operating the voltage switching unit 86 or the like. At the same time, in step 290, the power supply signal to the timer circuit 72B is turned on, and in step 292, the electromagnetic valve 54 on the external pressure source 30 side is turned off.

  Thereby, as shown in FIG. 16B, a path through which the compressed air passes from the pressure booster 12 to the buffer tank 60 is formed. Further, the booster 12 starts with the electric power supplied from the power supply unit 80 and sends the compressed air to the buffer tank 60. Thereby, the pressure rise between the booster 12 and the buffer tank 60 is achieved. Here, in order to increase the pressure in the buffer tank 60, compressed air supplied from the external pressure source 30 can be used. In the inspection apparatus 10, the booster 12 is started to be in a warm-up state. Thereby, in the test | inspection apparatus 10, the leakage when the pressure | voltage riser 12 stops during actual use can be test | inspected.

  In the flowchart of FIG. 15, the pressure P detected by the pressure sensor 40 on the booster 12 side is read in the next step 294 (detection of the pressure P). In the next step 296, it is confirmed whether or not the detected pressure P has reached the set pressure Ps. The set pressure Ps is the relief pressure of the safety valve 132 provided in the booster 12. The set pressure Pa may be equal to or lower than the relief pressure of the safety valve 132, but within the pressure range below the relief pressure. A high pressure is preferred.

  Here, when the compressed air supplied from the pressure increasing device 12 is accumulated in the buffer tank 60, the detected pressure P of the pressure sensor 40 increases, and when the set pressure Ps is reached (P ≧ Ps), an affirmative determination is made in step 296. To step 298. In step 298, power supply to the booster 12 is stopped by turning off the power supply unit 80, for example. As a result, the generation and supply of compressed air by the booster 12 is stopped, and when there is a leak of compressed air in the booster 12, the compressed air in the buffer tank 60 flows to the booster 12 (see FIG. 16C). )

  At the same time, in step 300, the sequencer 70 turns off the power signal output to the timer circuit 72B and turns on the pressure signal. Thereby, the timer circuit 72B is reset / started.

  When the timer circuit 72B is reset / started, the inspection apparatus 10 turns on the lamps 100G and 100R provided on the front panel 20A and turns off the lamps 100G and 100R in order according to the elapsed time.

  Here, when it is confirmed that a preset time (for example, 10 sec) has elapsed by turning on / off the lamps 100G and 100R, an affirmative determination is made in step 302, and the routine proceeds to step 304. In step 304, the operator reads the pressure (numerical value indicated by the pointer) indicated by the pressure gauge 120 provided in the pressure increasing device 12, and in the next step 306, whether the pressure change is within a preset reference range. Confirm whether or not.

  As a result, if the pressure change is small, it is determined that there is no leakage in the booster 12 (Yes in step 306), and the leakage inspection is completed. When the pressure change is large, there is a possibility that leakage occurs in the booster 12. In this case, if a negative determination is made in step 306, the process proceeds to step 308, and the inspection process for the booster 12 is finished.

  As described above, in the inspection apparatus 10, by using the timer circuit 72B, the elapsed time can be determined by turning off the lamp 100R without measuring the time while the operator looks at the clock. At this time, in the inspection apparatus 10, the lamp 100G can be used to predict the turn-off timing of the lamp 100R. Therefore, even when the numerical value indicated by the pointer of the pressure gauge 120 is read by the blinking of the lamp 100R, the reading timing is not greatly shifted.

  On the other hand, when performing a leak test on the booster 12 that does not have a tank for storing compressed air, it is difficult to perform a proper leak test using only the compressed air stored in the pipe. That is, when the compressed air is accumulated only in the pipe line, the amount of accumulated compressed air is small and the pressure changes in a short time. For this reason, it is difficult to determine the degree of change in pressure, and an appropriate leak test may not be determined.

  Here, in the inspection apparatus 10, the amount of accumulated compressed air is increased by providing the buffer tank 60. As a result, the pressure change is extremely small in a range where it is determined that no leakage has occurred with respect to the booster 12. Further, even if it is determined that the booster 12 is leaking, the pressure change becomes gradual.

  Therefore, even when a pressure change is detected using the pressure gauge 120 provided in the pressure increasing device 12, it is very easy to read the numerical value indicated by the pointer of the pressure gauge 120, and leakage from the read numerical value (scale) is possible. It is possible to accurately determine whether or not there is any.

  Generally, providing the buffer tank 60 takes time to fill the buffer tank 60 with compressed air to a predetermined pressure. On the other hand, the inspection apparatus 10 does not perform the leakage inspection first among the plurality of inspection items, but performs the leakage inspection after the gauge accuracy inspection using the compressed air supplied from the external pressure source 30. In the inspection apparatus 10, compressed air is supplied from the external pressure source 30 to the buffer tank 60 during the gauge accuracy inspection. Thereby, in the inspection apparatus 10, the buffer tank 60 is in a pressurized state by the time the leak inspection using the buffer tank 60 is performed, and the time for setting the inside of the buffer tank 60 to a predetermined pressure when performing the leak inspection is shortened. Yes.

  On the other hand, in the inspection apparatus 10, the pressure gauge 120 is inspected without operating the booster 12 by using compressed air supplied from the regulators (precision regulators) 48 and 50 and the external pressure source 30. The external pressure source 30 has a larger supply amount of air (compressed air) per unit time than the booster 12. For this reason, the test | inspection of the pressure gauge 120 using the regulators 48 and 50 can be performed rapidly.

  In addition, the booster 12 has a smaller amount of air supplied per unit time than the external pressure source 30. For this reason, even if the pointer of the pressure gauge 120 shows a preset numerical value using the compressed air supplied from the booster 12, the deflection of the pointer becomes unstable. In contrast, in the inspection apparatus 10, the use of compressed air supplied from the external pressure source 30 can stabilize the deflection of the pointer of the pressure gauge 120.

  Furthermore, in the inspection apparatus 10, since the inside of the buffer tank 60 is pressurized in advance using the compressed air supplied from the external pressure source 30, the time required for setting the pressure in the buffer tank 60 to a predetermined pressure is shortened. can do.

  In the present embodiment, the external pressure source 30 is used to pressurize the buffer tank 60. For example, the pressurization of the buffer tank 60 is performed when a current test or a relief pressure test is performed. The solenoid valve 54 may be closed and the solenoid valve 56 may be opened before the booster 10 is stopped, and the solenoid valve 56 may be closed at a timing when the booster 10 is stopped. In this way, the compressed air may be gradually accumulated in the buffer tank 60. At this time, in the inspection apparatus 10, the volume of the buffer tank 60 is approximately the same as that of the liquid container 16 and is smaller than that of a general tank, so that the pressure state of the buffer tank 60 can be easily obtained. Is possible.

  In the present embodiment, the booster 12 is inspected in the order of current inspection, relief pressure inspection, gauge accuracy inspection, and leakage inspection, but the inspection order is not limited to this. For example, if it is confirmed that the booster 12 is started, it can be performed in an arbitrary order. In this embodiment, the current test and the relief pressure test are performed separately, but the current test and the relief pressure test may be performed simultaneously.

  That is, in the relief pressure test, the booster device 12 is operated at the maximum load, and when the relief pressure test is performed, the power supplied to the booster device 12 may be an H voltage.

  In the above-described embodiment, the operator operates the inspection apparatus 10 and the sequencer 70 executes the process as necessary, so that the booster 12 is inspected. However, the present invention is not limited to this. Alternatively, the computer may execute the inspection program so that each process is performed.

  In this case, for example, reading of the numerical value indicated by the pointer of the pressure gauge 120 of the booster 12 is performed by imaging the display of the pressure gauge 120 using an imaging device such as a camera and performing image processing on the captured image. A configuration such as recognizing a numerical value indicated by a guideline can be applied.

  Moreover, this Embodiment demonstrated above shows one aspect | mode of this invention, and does not limit the apparatus and components which are applied to this invention. Any configuration can be applied to the present invention as long as it has the disclosed functions.

DESCRIPTION OF SYMBOLS 10 Inspection apparatus 12 Pressure | voltage riser 14 Tire 26 Input joint 28 External input joint 30 External pressure source 32, 34 Switching valve 36A, 36B, 36C Piping 38 Pressure gauge 40, 62 Pressure sensor 48, 50 Precision regulator 54, 56 Electromagnetic valve 60 Buffer Tank 70 Sequencer 72 (72A, 72B) Timer circuit 80 Power supply unit 82 Voltage switching unit 88 Ammeter 112 Compressor unit 118 Power switch 120 Pressure gauge 132 Safety valve

Claims (7)

Compressor unit for generating compressed air by driving the compressor, the connection pipe to enable supplying the compressed air to the tire, the pressure gauge for measuring the pressure in the connecting pipe, and the supply from the compressor unit through the connecting pipe For a booster provided with a safety valve that suppresses the pressure of compressed air from exceeding a predetermined pressure, the booster after the inside of the booster reaches an inspection start pressure and stops generating compressed air in the compressor unit An inspection device for a booster used for inspection including a leakage inspection for inspecting a leakage of compressed air from a pressure change therein,
An air tank of a predetermined capacity;
One end is connected to the air tank, the said connection tube of the booster to be connected to the other terminal, the according to pressure of the connection pipe of the booster first changing the pressure in said air tank Piping members;
A second piping member having one end connected to the connecting pipe of the booster and the other end connected to an external pressure source;
A pressure adjusting means provided in the second piping member and adjusting the pressure of compressed air supplied from the external pressure source to set the inside of the connecting pipe of the pressure increasing device as a set pressure;
Switching means for switching the connection destination of the connection pipe of the booster to the connection portion of the external pressure source or the air tank via the pressure adjustment means;
An inspection apparatus for a booster device including: One end is connected to the air tank, a third pipe member sending the compressed air to the air tank the other end an external pressure source is supplied from the external pressure source by Rukoto connected,
Provided in the third pipe member, opening and closing means for opening and closing the conduit of the third pipe member,
Pressure limiting means for setting the pressure in the air tank, which is raised by the compressed air supplied from the external pressure source by opening the pipe line of the third piping member by the opening / closing means, to a preset limiting pressure; ,
The pressure | voltage riser test | inspection apparatus of Claim 1 containing this. A plurality of regulators each having a different set pressure;
Selecting means for selecting a regulator for supplying compressed air from the plurality of regulators to the connecting pipe of the booster ;
The apparatus for inspecting a booster according to claim 1 or 2, comprising: Power supply means for supplying power of a predetermined voltage to the booster ;
Current measuring means for measuring current consumption of the booster driven by the compressor with the power supplied from the power supply means;
Inspection device of the boost device according to any one of claims 1 to 3 comprising a. A compressor unit that generates compressed air by driving a compressor, a connecting pipe that can supply the compressed air to a tire, a pressure gauge that measures the pressure in the connecting pipe, and a supply from the compressor unit via the connecting pipe A method for inspecting a booster device for inspecting a booster device provided with a safety valve that suppresses the pressure of the compressed air from exceeding a predetermined pressure,
Compressed air is supplied from the booster so that the pressure in the air tank of a predetermined capacity communicates with the booster so that the pressure in the air tank that changes according to the pressure change in the booster becomes the preset inspection start pressure. A boosting step to supply;
A stop step of stopping the booster after the inside of the air tank reaches the inspection start pressure;
A time measuring step of measuring an elapsed time since the booster was stopped;
A leakage pressure measuring step for measuring a pressure detected by the pressure gauge when the elapsed time reaches a predetermined time as a pressure for determining leakage of compressed air from the pressure increasing device;
Inspection method of including boost devices. Prior to the supply of compressed air from the booster to the air tank, a pressurizing step of supplying compressed air from an external pressure source so that the pressure in the air tank becomes a limit pressure lower than the inspection start pressure ,
A method for inspecting a booster device according to claim 5 . A pressure adjustment step of supplying compressed air from the external pressure source to the booster so that the booster that has been deactivated has a preset adjustment pressure;
A pointer pressure measuring step for measuring the pressure indicated by the pressure gauge of the pressure increasing device as the adjustment pressure as a pressure for determining whether the pressure gauge is appropriate ;
Unrealized, the inspection method of the step-up device according to claim 6, wherein the pointer pressure measurement step to execute the pressurization step before terminating the.

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