JP2015017557A - Air compressor - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an air compressor that allows highly accurate diagnosis in diagnosing the need of maintenance service etc. and takes a use environment of a user into consideration to prevent a failure of a machine.SOLUTION: The air compressor includes: self-diagnosis means 160 for self-diagnosing of a state of the air compressor 10 based on compressing time of a compression mechanism 11; and environmental information detection means 20, 21, 23, 25, 26 for detecting a power supply voltage, temperature, tank pressure, altitude, and humidity. The environmental information detection means 20, 21, 23, 25, 26 detects environmental information before the self-diagnosis means 160 implements self-diagnosis.

Description

  The present invention relates to an air compressor, and more particularly to an air compressor characterized by being able to diagnose the necessity of maintenance.

As a method for reporting the necessity of maintenance of the air compressor to the user, for example, in Patent Document 1, the operation time of the air compressor is measured, and when the operation time reaches a predetermined time, the maintenance time can be reported. A method is disclosed.
Patent Document 2 discloses a method of measuring a voltage, a temperature of compressed air, and the like and reporting a machine failure to a user based on the measurement result.

Japanese Patent No. 2858829 Japanese Patent Laid-Open No. 5-157055

  However, in the method described in Patent Document 1, since the user's usage environment is unknown, there is a problem that if the maintenance timing is determined uniformly based on the operation time, it is uncertain that parts will be consumed or performance will be reduced. was there. For example, when used in a harsh environment, maintenance is required early even if the operation time is short. For this reason, there is a problem that even if a performance degradation appears in a state where the operation time for reporting the maintenance time has not been reached, the performance degradation cannot be detected and reported at an early stage. In order to solve this problem, if the timing at which the maintenance time is reported is advanced, the timing at which the maintenance time is reported may be too early, and unnecessary maintenance may occur.

  In addition, the method described in Patent Document 2 described above can detect a machine failure, but cannot accurately determine a machine failure in consideration of a user's use environment. For this reason, similarly to the method described in Patent Document 1 described above, there is a problem that the determination of a mechanical failure becomes uncertain.

  In this way, with the conventional method, unnecessary maintenance occurs because the timing for reporting the maintenance time is too early, or the timing for reporting the maintenance time is too late, so it continues to be used until an abnormal state or failure state. There was a problem that the machine could not be used and the work was delayed and the repair cost increased.

  Accordingly, the present invention provides an air compressor that enables highly accurate diagnosis when diagnosing the necessity of maintenance and the like, and can prevent machine failure in consideration of the user's usage environment. This is the issue.

  The present invention has been made to solve the above-described problems, and is characterized by the following.

(Claim 1)
The invention described in claim 1 is characterized by the following points.
That is, the air compressor according to claim 1 is an air compressor capable of generating and storing compressed air, and includes a compression mechanism including a cylinder for generating compressed air, and driving the compression mechanism. Air compression based on at least one of detection results of a motor, a tank for storing compressed air generated by the compression mechanism, a compression time by the compression mechanism, a current consumption value of the motor, and a rotation speed of the motor Self-diagnosis means for self-diagnosis of the state of the machine, and environmental information detection means for detecting environmental information of at least one of power supply voltage, temperature, tank pressure, altitude, and humidity, the environmental information detection means, The environmental information is detected before the self-diagnosis is executed by the self-diagnosis means.

(Claim 2)
The invention described in claim 2 has the following features in addition to the features of the invention described in claim 1 described above.
That is, the self-diagnosis unit notifies that the environmental information does not satisfy the predetermined condition when it is determined that the environmental information detected by the environmental information detection unit does not satisfy the predetermined condition. Features.

(Claim 3)
The invention described in claim 3 is characterized by the following points in addition to the characteristics of the invention described in claim 1 or 2.
That is, the self-diagnosis unit does not execute the self-diagnosis when it is determined that the environment information detected by the environment information detection unit does not satisfy a predetermined condition.

  The first aspect of the present invention is as described above, and is a self-diagnostic state of the air compressor based on a detection result of at least one of a compression time by the compression mechanism, a motor current consumption value, and a motor rotation speed. Diagnostic information, and environmental information detection means for detecting environmental information of at least one of power supply voltage, temperature, tank pressure, altitude, and humidity, and the environmental information detection means performs the self-diagnosis by the self-diagnosis means. Detect environmental information before execution. That is, when diagnosing the necessity of maintenance or the like by self-diagnosis, environmental information that affects compression performance is detected in advance, so that self-diagnosis can be performed accurately according to the environmental information.

  For example, when the power supply voltage is used as the environmental information, if the power supply voltage is low, even if the compression performance is reduced, it is not due to a machine failure or parts wear. Therefore, in such a case, it can be determined that a decrease in compression performance has occurred for a reason other than a machine failure or component wear, so that unnecessary maintenance notification can be omitted.

  According to such a configuration, when diagnosing the necessity of maintenance or the like, a highly accurate diagnosis is possible, so that the maintenance time can be appropriately notified. For example, unnecessary maintenance occurs because the timing for reporting the maintenance time is too early, or the timing for reporting the maintenance timing is too late, and the machine can no longer be used by continuing to use it in an abnormal state or failure state. There are no problems such as slow work and high repair costs.

  Also, by detecting the environmental information, if there is a problem with the environmental information, the user can be prompted to use it in an optimum environment. For example, since it is possible to notify the user by detecting environmental information such as heavy use of extension cords that induce extreme performance degradation and low temperature environment, it is possible to prevent machine failures and parts wear.

  The invention according to claim 2 is as described above, and when the self-diagnosis unit determines that the environmental information detected by the environmental information detection unit does not satisfy a predetermined condition, the environmental information Informs that the predetermined condition is not satisfied. That is, when the environmental information does not satisfy a predetermined condition (for example, the power supply voltage is too low), the compression performance is expected to deteriorate, so that the self-diagnosis may be inaccurate. For example, even if a decrease in compression performance is detected by self-diagnosis, it is not possible to determine whether the cause is due to environmental conditions alone or whether the cause is machine failure or parts wear in addition to environmental conditions. There is. Even if the self-diagnosis result is notified in such a state, there is a possibility that it is not useful for the user. Therefore, when it is determined that the environmental information does not satisfy the predetermined condition, the environmental information does not satisfy the predetermined condition. Inform you. Then, it is possible to prompt the user to perform self-diagnosis again in an environment where the environmental information satisfies a predetermined condition.

  The invention according to claim 3 is as described above, and when the self-diagnosis means determines that the environmental information detected by the environmental information detection means does not satisfy a predetermined condition, the self-diagnosis means Do not execute. That is, when the environmental information does not satisfy a predetermined condition (for example, the power supply voltage is too low), the compression performance is expected to deteriorate, so that the self-diagnosis may be inaccurate. For example, even if a decrease in compression performance is detected by self-diagnosis, it is not possible to determine whether the cause is due to environmental conditions alone or whether the cause is machine failure or parts wear in addition to environmental conditions. There is. Even if the self-diagnosis result is notified in such a state, there is a possibility that it is not useful for the user. Therefore, when it is determined that the environmental information does not satisfy the predetermined condition, the self-diagnosis is not executed. Then, it is possible to prompt the user to perform self-diagnosis again in an environment where the environmental information satisfies a predetermined condition.

It is (a) top view and (b) side view of an air compressor. It is a block diagram which shows the internal structure of an air compressor. It is an image figure of an operation panel. It is a flowchart of the first half of a self-diagnosis process. It is a flowchart of the second half of the self-diagnosis process.

  The air compressor 10 according to the present embodiment is formed so as to be able to generate and store compressed air, and as shown in FIG. 1, a compression mechanism 11 having a cylinder for generating compressed air, and the compression And a tank 14 for storing the compressed air generated by the mechanism 11.

  The compression mechanism 11 is driven by a motor 12 built in the air compressor 10 and compresses air introduced into the cylinder by reciprocating the compression piston in the cylinder. The compressed air thus compressed in the cylinder is sent to the tank 14 and stored. The stored compressed air is supplied to an external device (for example, a compressed air driving tool) connected to the air extraction unit 13 and used.

  As shown in FIGS. 1A and 3, an operation panel 15 is provided on the upper surface of the air compressor 10. The operation panel 15 includes various buttons for operating the air compressor 10, LEDs for displaying the state of the air compressor 10, and the like.

  The operation of the air compressor 10 is controlled by a control device 100 (see FIG. 2) built in the air compressor 10. Although not particularly illustrated, the control device 100 is configured around a CPU and includes a ROM, a RAM, an I / O, and the like. Then, the CPU is configured to control various input devices and output devices by reading a program stored in the ROM.

(Input device)
As shown in FIG. 2, the input device of the control device 100 includes temperature detection means 20, pressure detection means 21, current detection means 22, voltage detection means 23, motor rotation speed detection means 24, power switch 30, and filling mode switching. A switch 31 and an operation mode changeover switch 32 are provided. In addition, as an input device, it is not limited to the input device shown in this FIG. 1, You may provide another input device.

(Temperature detection means 20)
The temperature detection means 20 is a temperature detection circuit that measures the ambient temperature of the inverter board constituting the control device 100. The temperature measured by the temperature detection means 20 is output as a signal to the control device 100 and used to check the state of the air compressor 10. This temperature detection means 20 is one of environmental information detection means for detecting environmental information of the air compressor 10.

(Pressure detection means 21)
The pressure detection means 21 is for detecting the pressure in the tank 14, and is specifically a pressure sensor provided in the tank 14. The pressure value measured by the pressure detection means 21 is output as a signal to the control device 100 and processed. The pressure detection means 21 is one of environmental information detection means for detecting environmental information of the air compressor 10.

(Current detection means 22)
The current detection means 22 is for measuring the current value supplied to the motor 12. The current value measured by the current detection means 22 is output as a signal to the control device 100 and processed. The current value measured by the current detection unit 22 may be a current value on the power source side of the motor 12 (power source supplied to the air compressor 10).

(Voltage detection means 23)
The voltage detection means 23 is for detecting the input voltage to the air compressor 10. The voltage value measured by the voltage detector 23 is output as a signal to the control device 100 and processed. This voltage detection means 23 is one of environmental information detection means for detecting environmental information of the air compressor 10.

(Motor rotational speed detection means 24)
The motor rotation speed detecting means 24 detects the rotation speed of the motor 12, and is constituted by, for example, an angular position sensor. The rotational speed measured by the motor rotational speed detection means 24 is output as a signal to the control device 100 for processing.

(Altitude detection means 25)
The altitude detecting means 25 is for detecting the altitude at which the air compressor 10 is installed. The altitude value measured by the altitude detecting means 25 is output as a signal to the control device 100 and processed. The altitude detection means 25 is one of environmental information detection means for detecting environmental information of the air compressor 10.

(Humidity detection means 26)
The humidity detection means 26 is for detecting the ambient humidity where the air compressor 10 is installed. The humidity measured by the humidity detecting means 26 is output as a signal to the control device 100 and processed. The humidity detection means 26 is one of environmental information detection means for detecting environmental information of the air compressor 10.

(Power switch 30)
The power switch 30 is a switch for starting the air compressor 10 and is disposed on the operation panel 15 described above. When the power switch 30 is pressed and the air compressor 10 is activated, the compression mechanism 11 is activated and the compressed air is stored in the tank 14 so that the air compressor 10 can be used.

(Filling mode selector switch 31)
The filling mode changeover switch 31 is a switch for setting the filling mode of the air compressor 10. In other words, the air compressor 10 according to the present embodiment can change the control range of the rotation speed of the motor 12 according to the use environment, and the rotation speed of the motor 12 can be changed by pressing the filling mode changeover switch 31. The control range can be set. The air compressor 10 according to the present embodiment increases, as a filling mode, a normal mode, a silent mode in which the rotation speed of the motor 12 is suppressed as compared with the normal mode, and a rotation speed of the motor 12 higher than that in the normal mode. A quick filling mode. When pressing of the filling mode changeover switch 31 is detected, the pressing signal is output to the control device 100 (filling mode setting means 140 described later) and processed.

(Operation mode switch 32)
The operation mode changeover switch 32 is a switch for setting the operation mode of the air compressor 10. That is, the air compressor 10 according to the present embodiment can change the pressure control range in accordance with the purpose of use, and the pressure control range can be set to an arbitrary range by pressing the operation mode switch 32. It is like that. For example, the pressure in the tank 14 is 1.1 to 1.5 MPa, 2.5 to 3.0 MPa, 3.2 to 4.0 MPa, or 3.9 to 4.4 MPa. Or you can select and set. When the pressing of the operation mode changeover switch 32 is detected, the pressing signal is output to the control device 100 (operation mode setting means 150 described later) and processed.

(Output device)
As shown in FIG. 2, the output device of the control device 100 includes a motor 12, a power display LED 35, a filling mode display LED 36, an operation mode display LED 37, a discharge level LED 38, a display unit 39, and a notification unit 40. And are provided. In addition, as an output device, it is not limited to the output device shown in this FIG. 2, You may provide another output device.

(Motor 12)
As described above, the motor 12 drives the compression mechanism 11 to reciprocate the compression piston within the cylinder. The motor 12 is configured to start and stop the compression operation by being driven and controlled by the control device 100 (drive control means 110 described later).

(Power indicator LED35)
The power display LED 35 is lit when the above-described power switch 30 is pressed and the air compressor 10 is activated. Further, when the power switch 30 is pressed and the air compressor 10 is shut down, the light is turned off.

(Filling mode display LED 36)
The filling mode display LED 36 is for displaying a filling mode selected by pressing the filling mode changeover switch 31 described above.

(Operation mode display LED37)
The operation mode display LED 37 is for displaying the operation mode selected by pressing the operation mode changeover switch 32 described above.

(Discharge level LED38)
The discharge level LED 38 displays the result of self-diagnosis performed by the self-diagnosis unit 160 described later. For example, the discharge level LED 38 is lit when there is no problem with the self-diagnosis result, and there is a problem with the self-diagnosis result (discharge level). When the value is low), it is controlled to blink.

(Display means 39)
The display means 39 is for displaying the pressure value in the tank 14 detected by the pressure detection means 21. In the present embodiment, a 2-digit 7-segment display is used, and numerical values can be digitally displayed.

  The display means 39 may be a 7-segment display having three or more digits, or may be a display (including a touch panel) having a high pixel number without being limited to the 7-segment display.

(Notification means 40)
The notifying means 40 is means for notifying an error of the air compressor 10 or the like. For example, a device that performs auditory display such as a buzzer or a device that performs visual display such as an LED.

(Control device 100)
Next, the control device 100 will be described in detail.
The control device 100 controls the various devices described above, and includes a drive control unit 110, a time measurement unit 120, a storage unit 130, a filling mode setting unit 140, an operation mode setting unit 150, a self-diagnosis unit 160, and the like. Functions as a means.
Control device 100 is not limited to the above-described means, and may include other means.

(Drive control means 110)
The drive control means 110 is a program for controlling the compression operation by the compression mechanism 11 by controlling the motor 12. This drive control means 110 refers to the air pressure in the tank 14 detected by the pressure detection means 21, and turns on / off the operation of the motor 12 so that the air pressure in the tank 14 becomes an appropriate pressure.

  Specifically, an on-pressure for starting the driving of the compression mechanism 11 and an off-pressure for stopping the driving of the compression mechanism 11 are determined in advance. It is determined whether or not the detected air pressure in the tank 14 has reached this on-pressure or off-pressure, and when it reaches, the operation of the motor 12 is turned on / off.

  At this time, the on pressure and the off pressure are determined by the operation mode set by the operation mode setting means 150 described later. For example, in the operation mode in which the pressure control range is 3.2 to 4.0 MPa, 3.2 MPa is an on pressure and 4.0 MPa is an off pressure. In this case, when the compressed air in the tank 14 is used and the pressure in the tank 14 is reduced to 3.2 MPa (on pressure), the motor 12 is operated until the pressure in the tank 14 becomes 4.0 MPa (off pressure). Let the air compress. By repeating this operation, the air pressure in the tank 14 is controlled to be an appropriate pressure.

  Note that the rotation speed of the motor 12 when performing the compression operation is determined by a filling mode set by a filling mode setting unit 140 described later. For example, the rotation speed of the motor 12 is limited to a maximum of 2900 min ^ -1 in the normal mode, limited to a maximum of 1800 min ^ -1 in the silent mode, and limited to a maximum of 3400 min ^ -1 in the rapid filling mode. To be controlled. With such control, for example, when working in the night or in a residential area, noise can be suppressed by using the silent mode, and if you want to use compressed air quickly, use the quick filling mode to save time. Can be shortened.

(Time measuring means 120)
The time measuring means 120 is a means for measuring time from a predetermined timing. For example, a CPU timer is used.

(Storage unit 130)
The storage unit 130 includes a nonvolatile memory, and stores programs and data.

(Filling mode setting means 140)
The filling mode setting means 140 is for setting the filling mode of the air compressor 10. Specifically, when pressing of the filling mode changeover switch 31 is detected, the pressing signal is received and processing for switching the filling mode is executed. The filling mode set by the filling mode setting unit 140 is stored in the storage unit 130 or the like and used for drive control of the motor 12 by the drive control unit 110.

(Operation mode setting means 150)
The operation mode setting means 150 is for setting the operation mode of the air compressor 10. Specifically, when pressing of the operation mode switching switch 32 is detected, the pressing signal is received, and processing for switching the operation mode is executed. The operation mode set by the operation mode setting means 150 is stored in the storage means 130 or the like and used for drive control of the motor 12 by the drive control means 110.

(Self-diagnosis means 160)
The self-diagnosis means 160 self-diagnose the state of the air compressor based on the compression time by the compression mechanism 11. The processing of the self-diagnosis unit 160 will be described in detail later.

(Self-diagnosis process execution flow)
Next, the self-diagnosis process according to the present embodiment will be specifically described.
The air compressor 10 according to the present embodiment includes the self-diagnosis unit 160 as described above, and can report a result of the self-diagnosis unit 160 performing the self-diagnosis to the user, thereby causing a machine failure or performance degradation. Can be reported to the user. Further, the self-diagnosis unit 160 acquires environmental information (power supply voltage, temperature, tank pressure, altitude, humidity) before executing the self-diagnosis, and checks whether the current environment is an environmental condition capable of self-diagnosis. It is like that. This self-diagnosis process will be described with reference to the flowcharts of FIGS.

  First, in step S100 shown in FIG. 4, it is detected that the power switch 30 has been pressed for 3 seconds or longer (in this embodiment, the self-diagnosis process is triggered by the power switch 30 being pressed for 3 seconds or longer). To start). Note that the start of the self-diagnosis process may be triggered by another operation (such as another switch operation). Then, the process proceeds to step S101.

  In step S101, environmental conditions are acquired. Specifically, the temperature detected by the temperature detecting means 20, the tank pressure detected by the pressure detecting means 21, the power supply voltage detected by the voltage detecting means 23, the altitude detected by the altitude detecting means 25, and the humidity detecting means 26 detected. Get each value of humidity. In this embodiment, the power supply voltage, temperature, tank pressure, altitude, and humidity are all acquired, but the embodiment of the present invention is not limited to this, and if at least one of these is acquired. Good. Then, the process proceeds to step S102.

  In step S102, it is checked whether the environmental information (power supply voltage, temperature, tank pressure, altitude, humidity) detected by the environmental information detection means satisfies a predetermined condition. This predetermined condition is set in advance based on the recommended use environment of the air compressor 10. If the predetermined condition is satisfied, the process proceeds to step S103. On the other hand, if the predetermined condition is not satisfied, the process proceeds to step S117 (see FIG. 5).

  When the process proceeds to step S117, the notification means 40 notifies that the environmental condition does not satisfy the predetermined condition (not suitable for use of the air compressor 10 or self-diagnosis), and the process is performed without executing the self-diagnosis. Exit.

  On the other hand, when the process proceeds to step S103, the filling mode is shifted to a self-diagnosis filling mode (for example, the normal mode), the driving of the motor 12 is started, and the self-diagnosis is started. Then, the process proceeds to step S104.

In step S104, it is checked whether the cancel condition is satisfied. For example, it is determined that the cancel condition is satisfied when it is detected that the switch is operated or the compressed air is used during the self-diagnosis. If the cancel condition is satisfied, the process proceeds to step S116 (see FIG. 5). On the other hand, if the cancellation condition is not satisfied, the process proceeds to step S105.
When the process proceeds to step S116, the notification means 40 notifies that the self-diagnosis has been canceled, and the process proceeds to step S114.

  On the other hand, if the process proceeds to step S105, it is checked whether the tank pressure has reached the threshold pressure. The threshold pressure is set in advance as a value between the on pressure and the off pressure. When the tank pressure reaches the threshold pressure (only the first time), the process proceeds to step S106. On the other hand, if the tank pressure has not reached the threshold pressure, or if the tank pressure has already reached the threshold pressure and has passed step S106, the process proceeds to step S107.

In step S106, time measurement by the time measurement unit 120 is started, voltage measurement by the voltage detection unit 23 is started, and integration processing is started. That is, in the present embodiment, since the self-diagnosis is performed by measuring the time from the threshold pressure to reaching the off-pressure, data collection for self-diagnosis is started. Then, the process proceeds to step S107.
Note that a predetermined pressure before reaching the off pressure from the threshold pressure may be set, and the time from the threshold pressure to reaching the predetermined pressure may be measured.

  In step S107, it is checked whether the tank pressure has reached the off pressure. If the off pressure has not been reached, the process returns to step S104. On the other hand, when the off pressure is reached, the process proceeds to step S108.

  In step S108, the drive of the motor 12 is stopped. Further, the time measurement by the time measurement means 120 and the voltage measurement by the voltage detection means 23 are also stopped. Then, the process proceeds to step S109 (see FIG. 5).

  In step S109, the integrated result of voltage measurement by the voltage detection means 23 is referred to. Specifically, an average voltage until the tank pressure reaches the off pressure from the threshold pressure is calculated. Then, the process proceeds to step S110.

  In step S110, it is checked whether the average voltage calculated in step S109 is less than a threshold voltage (for example, 90V). If the average voltage is less than the threshold voltage, the process proceeds to step S115. On the other hand, if the average voltage is not less than the threshold voltage, the process proceeds to step S111.

  When the process proceeds to step S115, the notification means 40 notifies that the environmental condition does not satisfy the predetermined condition (not suitable for use of the air compressor 10 or self-diagnosis), and the process proceeds to step S114.

  On the other hand, when the process proceeds to step S111, it is checked whether the measurement result of the time measuring unit 120, that is, the time until the tank pressure reaches the off pressure from the threshold pressure is equal to or less than the threshold time. If the measurement time is less than or equal to the threshold time, the process proceeds to step S112. On the other hand, if the measurement time is not less than the threshold time, the process proceeds to step S113.

  When the process proceeds to step S112, as a result of performing the self-diagnosis under the correct environmental conditions, there is no machine failure or performance degradation, so the discharge level LED 38 is turned on to notify the user that the self-diagnosis has passed. Then, the process proceeds to step S114.

If the process proceeds to step S113, there is a possibility of machine failure or performance degradation as a result of self-diagnosis under the correct environmental conditions. Therefore, the discharge level LED 38 is flashed to inform the user that the self-diagnosis has failed. Inform. Then, the process proceeds to step S114.
In step S114, the filling mode changed in step S103 is returned to the base, and the process ends.

(Summary)
As described above, according to the present embodiment, the self-diagnosis means 160 that self-diagnose the state of the air compressor 10 based on the compression time by the compression mechanism 11 and the power supply voltage, temperature, tank pressure, altitude, and humidity are determined. Environmental information detection means 20, 21, 23, 25, 26 for detecting the environmental information detection means 20, 21, 23, 25, 26 before the execution of the self-diagnosis by the self-diagnosis means 160. Detect information. That is, when diagnosing the necessity of maintenance or the like by self-diagnosis, environmental information that affects compression performance is detected in advance, so that self-diagnosis can be performed accurately according to the environmental information.

  For example, when the power supply voltage is used as the environmental information, if the power supply voltage is low, even if the compression performance is reduced, it is not due to a machine failure or parts wear. Therefore, in such a case, it can be determined that a decrease in compression performance has occurred for a reason other than a machine failure or component wear, so that unnecessary maintenance notification can be omitted.

  According to such a configuration, when diagnosing the necessity of maintenance or the like, a highly accurate diagnosis is possible, so that the maintenance time can be appropriately notified. For example, unnecessary maintenance occurs because the timing for reporting the maintenance time is too early, or the timing for reporting the maintenance timing is too late, and the machine can no longer be used by continuing to use it in an abnormal state or failure state. There are no problems such as slow work and high repair costs.

  Also, by detecting the environmental information, if there is a problem with the environmental information, the user can be prompted to use it in an optimum environment. For example, since it is possible to notify the user by detecting environmental information such as heavy use of extension cords that induce extreme performance degradation and low temperature environment, it is possible to prevent machine failures and parts wear.

  In addition, when the self-diagnosis unit 160 determines that the environmental information detected by the environmental information detection unit 20, 21, 23, 25, 26 does not satisfy a predetermined condition, the environmental information is a predetermined condition. Notifying that the condition is not satisfied and not performing self-diagnosis. That is, when the environmental information does not satisfy a predetermined condition (for example, the power supply voltage is too low), the compression performance is expected to deteriorate, so that the self-diagnosis may be inaccurate. For example, even if a decrease in compression performance is detected by self-diagnosis, it is not possible to determine whether the cause is due to environmental conditions alone or whether the cause is machine failure or parts wear in addition to environmental conditions. There is. Even if the self-diagnosis result is notified in such a state, there is a possibility that it is not useful for the user. Therefore, when it is determined that the environmental information does not satisfy the predetermined condition, the environmental information satisfies the predetermined condition. Notify and do not execute self-diagnosis. Then, it is possible to prompt the user to perform self-diagnosis again in an environment where the environmental information satisfies a predetermined condition.

  In this embodiment, when it is determined that the environmental information does not satisfy the predetermined condition, the self-diagnosis is not executed. However, the environmental information does not satisfy the predetermined condition. The self-diagnosis may be executed after notifying the user of this fact.

In addition, the self-diagnosis unit 160 according to the present embodiment performs self-diagnosis of the state of the air compressor 10 based on the compression time by the compression mechanism 11, but instead of or in addition to this, the motor The state of the air compressor 10 may be self-diagnosis based on the consumption current value of 12 or the rotation speed of the motor 12. That is, the state of the air compressor 10 may be self-diagnosis based on the detection result of at least one of the compression time by the compression mechanism 11, the current consumption value of the motor 12, and the rotation speed of the motor 12.
In addition, you may use the status information (for example, the temperature of the compression mechanism 11, the voltage of the motor 12, and rotation speed) as environmental information.

DESCRIPTION OF SYMBOLS 10 Air compressor 11 Compression mechanism 12 Motor 13 Air extraction part 14 Tank 15 Operation panel 20 Temperature detection means (environment information detection means)
21 Pressure detection means (environmental information detection means)
22 Current detection means 23 Voltage detection means (environmental information detection means)
24 motor rotation speed detection means 25 elevation detection means (environmental information detection means)
26 Humidity detection means (environmental information detection means)
30 Power switch 31 Fill mode switch 32 Operation mode switch 35 Power indicator LED
36 Filling mode indicator LED
37 Operation mode indicator LED
38 Discharge level LED
39 Display means 40 Notification means 100 Control device 110 Drive control means 120 Time measurement means 130 Storage means 140 Filling mode setting means 150 Operation mode setting means 160 Self-diagnosis means

Claims (3)

An air compressor capable of generating and storing compressed air,
A compression mechanism with a cylinder for generating compressed air;
A motor for driving the compression mechanism;
A tank for storing compressed air generated by the compression mechanism;
Self-diagnosis means for self-diagnosis of the state of the air compressor based on the detection result of at least one of the compression time by the compression mechanism, the current consumption value of the motor, and the rotation speed of the motor;
Environmental information detection means for detecting environmental information of at least one of power supply voltage, temperature, tank pressure, altitude, and humidity;
With
The air compressor is characterized in that the environmental information detection means detects environmental information before the self-diagnosis is executed by the self-diagnosis means.   The self-diagnosis means notifies that the environmental information does not satisfy the predetermined condition when it is determined that the environmental information detected by the environmental information detection means does not satisfy the predetermined condition. The air compressor according to claim 1.   The self-diagnosis unit does not execute a self-diagnosis when the environmental information detected by the environmental information detection unit does not satisfy a predetermined condition. air compressor.

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