JP5396713B2 - Air compressor - Google Patents

Description

  The present invention relates to an air compressor, and more specifically, motor means that is driven to generate compressed air, compressed air storage means that stores compressed air generated in response to driving of the motor means, and motor means. The present invention relates to an air compressor including a control unit that controls a driving amount.

  When a driving tool such as a nailing machine using compressed air is used at a construction site, it is necessary to install an air compressor that supplies compressed air to the driving tool. The air compressor has a structure in which compressed air is generated in the compressed air generation unit by driving the motor unit, and the generated air is stored in the tank unit to supply compressed air of a predetermined pressure to the driving tool. Yes.

  In the conventional air compressor, a physical power switch (so-called rocker switch) for driving the air compressor is provided, and a structure for starting driving the air compressor by setting this power switch to the ON side. (For example, refer to Patent Document 1).

In an air compressor equipped with such a physical power switch, even when the driving power is shut off (for example, shut off due to a breaker etc.), the power switch is set to the ON side. Was retained. For this reason, when the power is restored (re-supplied), the drive of the air compressor is automatically restarted by the power switch held on the ON side, and the air compressor is operated without the operator operating the power of the air compressor. Can be used continuously.
JP 2002-285967 A (refer to the power switch indicated by reference numeral 6 in FIG. 1)

  However, today, there are many air compressors equipped with a panel display button method for performing power ON / OFF operation using a touch panel or the like instead of a physical power switch. In an air compressor with a panel display button, the operation settings are reset when the power supply for driving is cut off, so the air compressor stops when power is restored (re-supplied) .

  For this reason, there is a problem that the operator needs to operate the panel display button of the air compressor and drive the air compressor again after the power is restored. In particular, when there is a distance from the place where the nailing machine etc. is used to the place where the air compressor is installed, the nailing machine etc. is used at a high place (for example, the upper floor of the building), and the air compressor is used at a low place (for example, If installed on the lower floor of the building, the work will be interrupted and the operator will need to move to the air compressor installation position (lower floor) to drive the air compressor, increasing the operational burden There was a problem of tending.

  Further, the air compressor is configured to maintain a predetermined pressure value by switching operation / pause of the motor unit according to the pressure state of the tank unit. For this reason, when the power supply is shut off and restored in a state where the pressure value of the tank portion is high, the pressure in the tank portion may be kept high. Therefore, the motor portion is not necessarily driven at full power. It had the feature that it was not necessary.

  The present invention has been made in view of the above problems. In an air compressor that does not employ a physical power switch (for example, a rocker switch), when the power is shut off during driving and then recovered, It is an object of the present invention to provide an air compressor capable of automatically controlling the drive of a motor unit according to a pressure state.

  In order to solve the above problems, an air compressor according to the present invention includes a motor unit that is driven to generate compressed air, and a compressed air storage unit that stores the compressed air generated according to the driving of the motor unit. And a control means for controlling the driving amount of the motor means, a pressure detection means for detecting the pressure state of the compressed air stored in the compressed air storage means, and a power supply to the motor means. Power supply voltage detecting means for detecting the value of the power supply voltage, and non-volatile recording means for recording information output from the control means, wherein the control means is a power supply voltage detected by the power supply voltage detecting means. When it is determined that the power supply from the power source is cut off based on the value of the motor, the presence or absence of driving of the motor means is determined, and the motor means is determined to be driving It is characterized by recording the information relating to the shutdown state to shutdown state by the determination of the motor means based on the pressure state detected by the pressure detecting means to said nonvolatile storage means.

  As described above, in the air compressor according to the present invention, when it is determined that the supply of electric power is cut off, the control unit determines the operation suspension state of the motor unit based on the pressure state detected by the pressure detection unit. Since information related to the operation stop state is recorded in the non-volatile recording means, the operation of the motor means can be resumed in an appropriate operation mode corresponding to the operation stop state before the interruption when power is restored.

  In particular, in the case of an air compressor, it is not necessary to simply restart the driving of the motor means after the power is restored, but the driving amount of the motor means is controlled according to the pressure state of the compressed air stored in the compressed air storage means. Otherwise, there is a problem that a desired pressure state cannot be maintained. For this reason, the non-volatile recording means records information on the operation stop state of the motor means determined based on the pressure state when the supply of power is cut off, so that the pressure of the compressed air can be increased from when the motor means is resumed. It becomes possible to reliably perform drive control suitable for the state.

  Further, in the air compressor, when the control unit determines that the power cut off based on the value of the power supply voltage detected by the power supply voltage detection unit is restored, the non-volatile recording unit performs the motor operation. The information on the operation suspension state of the means is read, the drive amount is adjusted according to the information on the operation suspension state, and the drive of the motor means is resumed.

  In the air compressor according to the present invention, when the interrupted power is restored, the control unit reads information on the operation suspension state of the motor unit from the nonvolatile recording unit, and drives according to the information on the operation suspension state. Since the motor means is resumed by adjusting the amount, even if a physical switch (for example, rocker switch) is not adopted as the power switch of the air compressor, it depends on the operation stop state before the stop after power recovery Thus, the driving of the motor means can be automatically restarted.

  Further, the air compressor may have a notifying means for notifying the resumption of driving of the motor means, and the control means may be notified by the notifying means to resume driving of the motor means. Good.

  In this way, the notification by the notification means is made and the driving of the motor means is resumed. Therefore, when the interrupted power is restored and the driving of the motor means is automatically resumed, the motor means automatically It is possible to notify the operator of the resumption of driving, and it is possible to suppress the occurrence of troubles associated with the driving of the air compressor.

  In addition, the air compressor has automatic return setting means for setting whether or not to resume driving of the motor means when the interrupted power is restored, and the control means is the power supply voltage detection means When the power supply from the power supply is determined to be cut off based on the value of the power supply voltage detected by the above, the setting information set by the automatic return setting means is recorded in the nonvolatile recording means and is cut off. When the power that has been restored is restored, the setting information is read from the nonvolatile recording means, and the motor means is driven only when the setting information is information indicating that the driving of the motor means is resumed. It may be restarted.

  As described above, the setting information set by the automatic return setting means is recorded in the non-volatile recording means, and the setting information is information indicating that the driving of the motor means is resumed when the interrupted power is restored. In such a case, it is possible to arbitrarily set the presence / absence of automatic return of the motor means by adopting a configuration in which the driving of the motor means is resumed. For this reason, when it is not desired that the motor means is automatically driven when the power is restored, it is possible to keep the air compressor driving stopped, thereby simplifying the air compressor drive control when the power is restored. And it becomes possible to set appropriately.

  According to the motor control device of the present invention, when it is determined that the supply of electric power has been cut off, the control means determines the operation stop state of the motor means based on the pressure state detected by the pressure detection means and operates. Since the information related to the hibernation state is recorded in the non-volatile recording means, when the power is restored, the operation of the motor means can be resumed in an appropriate operation mode corresponding to the operation hibernation state before the interruption.

  Hereinafter, the air compressor concerning the present invention is explained in detail using a drawing.

  FIG. 1 is a block diagram showing a schematic configuration of an air compressor according to the present invention. The air compressor 1 includes a tank unit (compressed air storage unit) 2, a compressed air generation unit 3, a motor unit (motor unit) 4, a control circuit unit 5, a panel display button (automatic return setting unit) 6, The display panel LED (notification unit) 7a and a buzzer output unit (notification unit) 7b are roughly configured.

  The tank unit 2 has a storage tank 8 for storing compressed air. The storage tank 8 stores the compressed air having a constant pressure generated by the compressed air generator 3 and is usually maintained at a pressure of about 3.5 MPa to 4.3 MPa.

  The storage tank 8 is provided with a plurality of compressed air outlets 9. In the present embodiment, a high-pressure outlet 9a for taking out high-pressure compressed air and a normal-pressure outlet 9b for taking out normal-pressure compressed air are provided. Each of the outlets 9a and 9b is provided with pressure reducing valves 10a and 10b for reducing the compressed air obtained from the respective outlets 9a and 9b to a desired pressure. In the high pressure outlet 9a, the pressure reducing valve 10a is provided. The pressure of the compressed air taken out is reduced to about 1.5 MPa to 2.50 MPa, and the pressure of the compressed air taken out by the pressure reducing valve 10b is reduced to about 0.7 MPa to 1.5 MPa at the normal pressure outlet 9b. .

  Since the compressed air in the storage tank 8 is normally maintained at a pressure of about 3.5 MPa to 4.3 MPa as described above, the compressed air taken out from the high pressure outlet 9a is also taken out from the normal pressure outlet 9b. In addition, the desired pressure described above can be maintained by the pressure reducing valves 10a and 10b. In addition, an air hose (not shown) can be attached to and detached from each of the outlets 9a and 9b in order to supply the compressed air decompressed by the pressure reducing valves 10a and 10b to a driving tool such as a nail driver. Yes.

  The storage tank 8 is provided with a pressure sensor (pressure detection means) 12 for detecting the pressure in the storage tank 8. The pressure sensor 12 has a function of converting a pressure change in the storage tank 8 into an electric signal by an internal pressure sensitive element, and the detected electric signal is transmitted to the control circuit unit 5.

  The compressed air generating unit 3 has a structure that generates compressed air by reciprocating a piston provided in the cylinder and compressing air drawn into the cylinder from the intake valve of the cylinder. The compressed air is supplied to the storage tank 8 of the tank unit 2 through the connection pipe 14.

  The motor unit 4 has a role of generating a driving force for reciprocating the piston of the compressed air generating unit 3. The motor unit 4 is provided with a stator 16 and a rotor 17 for generating a driving force. The stator 16 is formed with U-phase, V-phase, and W-phase windings 16a, 16b, and 16c, and a rotating magnetic field is formed by passing a current through the windings 16a to 16c.

  The rotor 17 is composed of a permanent magnet, and the rotor 17 is rotated by a rotating magnetic field formed by a current flowing through the windings 16a, 16b, and 16c of the stator 16. The operation of the piston of the compressed air generating unit 3 is performed by the rotational force of the rotor 17.

  As shown in FIG. 2, the control circuit unit 5 is roughly configured by a microprocessor (MPU: Micro Processing Unit, control means) 20, a converter circuit 21, and an inverter circuit 22.

  The converter circuit 21 is roughly configured by a rectifier circuit 24, a booster circuit 25, and a smoothing circuit 26, and so-called PAM (Pulse Amplitude Modulation) control is executed by the converter circuit 21. Here, the PAM control is a method of controlling the rotation speed of the motor unit 4 by changing the pulse height of the output voltage by the converter circuit 21. On the other hand, the inverter circuit 22 performs so-called PWM (Pulse Width Modulation) control. The PWM control is a method for controlling the rotation speed of the motor unit 4 by changing the pulse width of the output voltage.

  Compared with PWM control, PAM control has a characteristic that the motor unit 4 is less susceptible to lowering efficiency at low rotation and can cope with high rotation by increasing the voltage. It is a control method mainly used during operation and steady operation. On the other hand, the PWM control is a control method mainly used at the time of start-up or voltage drop. The microprocessor 20 executes control by suitably switching between PAM control by the converter circuit 21 and PWM control by the inverter circuit 22 according to the operating state of the air compressor 1.

  The rectifier circuit 24 and the smoothing circuit 26 of the converter circuit 21 have a role of converting into an AC voltage by rectifying and smoothing an AC power source (power source) 29 serving as a drive source of the air compressor 1. A switching element 25 a is provided inside the booster circuit 25, and has a role of controlling the amplitude of the DC voltage in accordance with a control command from the microprocessor 20. The booster circuit 25 is controlled via a booster controller 27 that has received a PAM command from the microprocessor 20.

  A power supply voltage detection unit (power supply voltage detection means) 28 is provided between the converter circuit 21 and the AC power supply 29. The voltage value detected by the power supply voltage detection unit 28 is a value of a primary voltage (hereinafter, this voltage is referred to as a power supply voltage) before the voltage value is boosted through the booster circuit 25 of the converter circuit 21, etc. 29 voltage values are shown. Therefore, it is possible to detect a change in the power supply voltage supplied from the AC power supply 29 by detecting the voltage value in the power supply voltage detection unit 28. The voltage value detected by the power supply voltage detection unit 28 is output to the microprocessor 20.

  The inverter circuit 22 has a function of converting the DC voltage pulse converted by the converter circuit 21 into positive and negative at regular intervals and converting the DC voltage into an AC voltage having a pseudo sine wave by converting the pulse width. doing. By adjusting the pulse width, it is possible to control the rotational speed of the motor unit 4 as described above. The microprocessor 20 controls the drive amount of the motor unit 4 by adjusting the output value for the inverter circuit 22.

  The microprocessor 20 is a control means for stabilizing the pressure of the compressed air in the tank unit 2 to 3.5 MPa to 4.3 MPa by performing drive control of the converter circuit 21 and the inverter circuit 22. The microprocessor 20 includes a central processing unit (CPU), a RAM (Random Access Memory) used as a temporary recording area such as a work memory, and a control processing program (described later, for example, in FIGS. 3 and 4). ROM for recording a program related to processing) and a program related to processing described later (for example, a time measuring task for determining time lapse (timekeeping) described later, control processing of the microprocessor 20 when power is turned off and when power is restored), etc. Functions such as (Read Only Memory) are realized by a one-chip LSI. Note that the microprocessor 20 can perform time determination processing based on the above-described time measurement task recorded in the ROM.

  Further, a flash memory (nonvolatile recording memory such as EEPROM (nonvolatile recording means)) 30 is connected to the microprocessor 20. The flash memory 30 can freely read and write data in accordance with instructions from the microprocessor 20, and keeps recorded data even when the power supply is cut off (provides non-volatility). ) Recording means. As will be described later, the microprocessor 20 can maintain the state of the air compressor 1 at the time of emergency stop by causing the flash memory 30 to record the operation mode, the pressure state of the tank unit 2, and the like.

  Further, the microprocessor 20 includes pressure information (pressure value information) in the storage tank 8 detected by the pressure sensor 12, power supply voltage value detected by the power supply voltage detection unit 28 (information on voltage value of the AC power supply 29). ), Operation information operated by the panel display button 6 is input.

  On the other hand, the microprocessor 20 is configured to be able to output control information (PAM command, PWM command) to the converter circuit 21 and the inverter circuit 22. The converter circuit 21 and the inverter circuit 22 execute drive control of the motor unit 4 based on control information (PAM command, PWM command) output by the microprocessor 20.

  The microprocessor 20 controls the switching element 25 a of the booster circuit 25 via the boost controller 27 by outputting a PAM command to the boost controller 27, thereby controlling the drive of the converter circuit 21. Similarly, the microprocessor 20 controls the inverter circuit 22 by outputting a PWM command to the inverter circuit 22.

The panel display button 6 is an input means for an operator to set driving of the air compressor 1 and the like. The panel display button 6 is provided outside the casing of the air compressor 1 and is schematically configured by a liquid crystal display unit having a touch panel function. The operator can perform a drive setting of the air compressor 1 and a drive start operation and a drive stop operation of the air compressor 1 by touching a button image displayed on the liquid crystal display unit. Operation information set via the panel display button 6 is transmitted to the microprocessor 20 and recorded in a predetermined area of the RAM.
Whether the operator operates the panel display button 6 to automatically start the air compressor 1 or keep the stopped state when the power supply is restored when the power supply from the power source is cut off. Setting information indicating whether or not (hereinafter, a setting for automatically starting the air compressor 1 is referred to as an automatic return mode) can be recorded in the RAM.

  The display panel LED 7a and the buzzer output unit 7b are provided outside the casing of the air compressor 1. The display panel LED 7a is, for example, an LED that emits red light, and can turn on / off / flash the LED in accordance with instructions from the microprocessor 20. The buzzer output unit 7b is a device that emits a warning sound or a warning sound, for example, and can output / stop a warning sound in accordance with an instruction from the microprocessor 20.

  Next, a control method of the microprocessor 20 when the power supply from the power source is interrupted while the air compressor 1 is driven will be described with reference to the flowchart shown in FIG.

  First, the microprocessor 20 determines whether or not a time of 10 msec has elapsed since the last time the voltage value of the power supply voltage was acquired based on the timekeeping task recorded in the ROM (step S.1). When the microprocessor 20 determines that the time of 10 msec has not elapsed (in the case of No in step S.1), the microprocessor 20 again. 1 is repeatedly executed.

  If it is determined that the time of 10 msec has elapsed (Yes in step S.1), the microprocessor 20 detects the power supply voltage value from the power supply voltage detection unit 28 (step S.2), and the power supply voltage value is It is determined whether or not the cutting level has been lowered (step S.3).

  Here, the case where the power supply voltage value is reduced to the disconnection level is not specifically the case where the power supply voltage value becomes 0, but the voltage that cannot be detected in a state where power is normally supplied. This includes cases where the value drops. For example, when the value of the power supply voltage becomes 30 VAC or less, the microprocessor 20 determines that the power supply voltage has dropped to the disconnection level.

  When the microprocessor 20 determines that the power supply voltage value has not decreased to the disconnection level (No in step S.3), the microprocessor 20 again. 1 is repeatedly executed. On the other hand, when it is determined that the power supply voltage value has decreased to the disconnection level (Yes in step S.3), the microprocessor 20 acquires operation information recorded in a predetermined area of the RAM (step S.4). ), It is determined whether or not the automatic return mode has been set by the operator (step S.5).

  When the automatic return mode is not set (No in step S.5), the microprocessor 20 stops all the drives including the inverter circuit 22 and the converter circuit 21 (step S.12) and performs the process. finish. Even when the power supply is suddenly cut off and the power supply voltage becomes 0 V, the driving power is supplied to the microprocessor 20 from the capacitor provided in the booster circuit 25 or the like for a certain time (2 to 2). Therefore, the microprocessor 20 can perform a series of processes shown in the flowchart of FIG. If the automatic return mode has been set (Yes in step S.5), the microprocessor 20 records the automatic return mode setting information (automatic return mode information) in the flash memory 30 (step S.5). 6).

  Next, the microprocessor 20 performs step S.1. Based on the operation information acquired in step 4, it is determined whether or not the air compressor 1 is in the operation mode (the operator is driving the air compressor 1 and the air compressor 1 is being driven) ( Step S.7). If it is determined that the operation mode is not in effect based on the operation information (No in step S.7), the microprocessor 20 stops all driving including the inverter circuit 22 and the converter circuit 21 (step S.12). ) End the process. When it is determined that the operation mode is in effect based on the operation information (Yes in step S.7), the microprocessor 20 records information (operation mode information) indicating that the operation mode is in the flash memory 30. (Step S.8).

  Next, the microprocessor 20 acquires pressure information in the tank unit 2 from the pressure sensor 12 (step S.9), and determines whether or not the motor unit 4 is in the OFF pressure stop state based on the pressure information (step S.9). Step S.10). The motor unit 4 is driven so as to maintain the pressure of the tank unit 2 in a state of generally about 3.5 MPa to 4.3 MPa. For this reason, when the pressure of the tank unit 2 reaches the upper limit level (about 4.0 MPa or more), the driving of the motor unit 4 is stopped, and the pressure of the tank unit 2 reaches the lower limit level (about 3.6 MPa or less). In this case, the driving of the motor unit 4 is resumed. The state in which the pressure in the tank unit 2 reaches the upper limit level and the driving of the motor unit 4 is stopped is referred to as an OFF pressure stop state, and the pressure in the tank unit 2 drops to the lower limit level. The state in which the driving of 4 is resumed is referred to as an ON pressure operating state.

  When it is determined that the motor unit 4 is not in the OFF pressure stop state based on the pressure information acquired from the pressure sensor 12 (No in step S.10), the microprocessor 20 includes an inverter circuit 22 and a converter circuit 21. All driving is stopped (step S.12), and the process is terminated. On the other hand, when it is determined that the motor unit 4 is in the OFF pressure stop state based on the pressure information acquired from the pressure sensor 12 (Yes in step S.10), the microprocessor 20 is in the OFF pressure stop state. Information indicating that it is present (OFF pressure stop state information) is recorded in the flash memory 30 (step S.11).

  Then, the microprocessor 20 stops all driving including the inverter circuit 22 and the converter circuit 21 (step S.12), and ends the processing.

  Next, a control method of the microprocessor 20 when the interrupted power supply is restored will be described with reference to the flowchart shown in FIG.

  When the power supply is resumed, the microprocessor 20 records information recorded in the flash memory 30, specifically, information on whether or not the automatic return mode is set, and information on whether or not the operation mode is in operation mode. Then, information on whether or not the OFF pressure has been stopped is acquired (step S.21).

  Next, the microprocessor 20 determines whether or not the automatic return mode has been set based on the acquired information (step S.22). If the automatic return mode has not been set (No in step S.22), the microprocessor 20 maintains the air compressor 1 in the stopped state (step S.23), and performs processing by restoring the power supply voltage. finish.

  On the other hand, if the automatic return mode has been set (Yes in step S.22), the microprocessor 20 has recorded information indicating that it is in the operation mode based on the acquired information. Is determined (step S.24). When the information indicating that the operation mode is being performed has not been recorded (No in step S.24), the microprocessor 20 maintains the air compressor 1 in the stopped state (step S.23), and the power supply voltage Terminate processing by recovery.

  On the other hand, when the information indicating that the operation mode is in progress is recorded (in the case of Yes in step S.24), the microprocessor 20 determines based on the acquired information that the OFF pressure has been stopped. Is recorded (step S.25). When information indicating that the vehicle is in the OFF pressure stop state has not been recorded (No in step S.25). The microprocessor 20 blinks the display panel LED 7a for a predetermined time, for example, 10 seconds, and outputs a warning sound from the buzzer output unit 7b. Then, the microprocessor 20 is driven by a normal driving method, more specifically, the air compressor 1 Is determined to be in the ON pressure operating state (step S.26). By driving the air compressor 1 by this normal driving method, the motor unit 4 starts to be driven and the compressed air is stored in the tank unit 2.

When information indicating that the OFF pressure has been stopped has been recorded (Yes in step S.25). The microprocessor 20 determines that the air compressor 1 has been stopped in the OFF pressure stop state, blinks the display panel LED 7a for a predetermined time, for example, 10 seconds, and outputs a warning sound from the buzzer output unit 7b. The compressor 1 is started to enter an OFF pressure stop state (step S.27). By setting the OFF pressure stop state in this manner, the driving of the motor unit 4 is resumed on the condition that the pressure value of the tank unit 2 has decreased to the lower limit level, and the pressure in the tank unit 2 is maintained at the optimum air pressure. Will be.
In order to ensure safety, when the operator operates (presses) the panel display button 6 while blinking for 10 seconds, the air compressor 1 is automatically stopped and restarted. It may be configured to maintain (step S.23).

  As described above, in the air compressor 1 according to the present invention, when the power supply voltage is interrupted, the microprocessor 20 operates the air compressor 1, more specifically, information on whether or not the operation mode is in progress. Then, information on whether or not the OFF pressure is stopped is recorded in the flash memory 30. For this reason, even if the power switch of the air compressor 1 does not employ a physical switch (for example, a rocker switch), the air compressor 1 operates in an appropriate mode according to the operation state before the stop after the power is restored. Can be automatically resumed.

  In particular, in the case of the air compressor 1, it is not necessary to simply drive the motor unit 4 after the power supply is restored, and it is necessary to control the driving of the motor unit 4 according to the pressure state of the tank unit 2. There is a problem that the pressure state cannot be maintained. Therefore, the microprocessor 20 determines whether or not the OFF pressure is stopped when the power supply voltage is cut off based on the pressure information of the tank unit 2 detected by the pressure sensor 12 and records it in the flash memory 30. Thus, after the power supply is restored, the drive control of the motor unit 4 can be appropriately performed according to the pressure state of the tank unit 2.

  Further, in the air compressor 1 according to the present embodiment, the operator can arbitrarily set the automatic return mode. For this reason, when it is not desired to automatically restart when the power supply voltage is restored, it is possible not to restart the air compressor 1 by not setting the automatic restoration mode. The presence or absence of can be set easily and appropriately.

  Further, when the air compressor 1 is automatically started after the power supply voltage is restored by setting the automatic return mode, the operator automatically detects the air compressor 1 by blinking the display panel LED 7a and outputting a warning sound from the buzzer output unit 7b. Since the return can be notified, it is possible to suppress the occurrence of troubles associated with the automatic driving restart of the air compressor 1.

  The air compressor according to the present invention has been described above with reference to the drawings. However, the air compressor according to the present invention is not limited to the one shown in the embodiment. It will be apparent to those skilled in the art that various changes and modifications can be made within the scope of the claims, and these are naturally within the technical scope of the present invention. Understood.

  For example, in the air compressor 1 according to the present embodiment, as shown in FIG. 3, the microprocessor 20 is not in the operation mode when the automatic return mode is not set (in the case of No in step S.5). In the case (No in Step S.7) and in the case where the OFF pressure is not stopped (No in Step S.10), all of the air compressor 1 is recorded without recording the information in the flash memory 30. The driving is stopped and the process is terminated. However, the control in the microprocessor 20 is not limited to the method shown in FIG. 3, and when the automatic return mode is not set (in the case of No in step S.5), the case is not in the operation mode. (No in Step S.7) and when not in the OFF pressure stop state (No in Step S.10), each information is recorded in the flash memory 30, respectively. Also good.

  By recording each piece of information in the flash memory 30 in this way, it becomes possible to reliably read out information related to each setting when the power supply voltage is restored, so that control processing errors can be reduced. Further, by using a method for recording each information in the flash memory 30, if any information is not recorded in the flash memory 30, an error has occurred in the processing of the microprocessor 20 when the power supply voltage is cut off. Since it can be presumed that the air compressor 1 is forcibly stopped, it is possible to prevent troubles due to errors from occurring.

Moreover, in the air compressor 1 which concerns on this Embodiment, although the case where both display panel LED7a and the buzzer output part 7b were installed was demonstrated, it is possible to fully alert | report to an operator. If so, it may be configured to install only one of the display panel LED 7a and the buzzer output unit 7b, or may be configured to include other notification means.
Furthermore, in the air compressor 1 according to the present embodiment, the air compressor 1 is started after the notification process by the display panel LED 7a and the buzzer output unit 7b is performed for 10 seconds. However, the notification process is not necessarily completed for 10 seconds. The configuration of starting the air compressor 1 later is not limited, and after the notification process is started (for example, when notification is performed for 5 seconds in the notification process for 10 seconds), the driving of the air compressor 1 is started. May be configured to resume the process.

It is a block diagram which shows schematic structure of the air compressor which concerns on this Embodiment. It is a block diagram which shows the control circuit part of the air compressor which concerns on this Embodiment. It is the flowchart which showed the process performed when a power supply voltage is interrupted | blocked by the microprocessor which concerns on this Embodiment. It is the flowchart which showed the process performed when a power supply voltage is recovered | restored by the microprocessor which concerns on this Embodiment.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Air compressor 2 ... Tank part (compressed air storage means)
3 ... Compressed air generation part 4 ... Motor part (motor means)
5 ... Control circuit 6 ... Panel display button (automatic return setting means)
7a ... Display panel LED (notification means)
7b ... buzzer output section (notification means)
DESCRIPTION OF SYMBOLS 8 ... Storage tank 9 ... Compressed air outlet 9a ... High pressure outlet 9b ... Normal pressure outlet 10a, 10b ... Pressure reducing valve 12 ... Pressure sensor (pressure detection means)
14 ... Connection pipe 16 ... Stator 16a, 16b, 16c ... Winding 17 ... Rotor 20 ... Microprocessor (control means)
DESCRIPTION OF SYMBOLS 21 ... Converter circuit 22 ... Inverter circuit 24 ... Rectifier circuit 25 ... Booster circuit 25a ... Switching element 26 ... Smoothing circuit 27 ... Booster controller 28 ... Power supply voltage detection part (power supply voltage detection means)
29 ... AC power supply
30 ... Flash memory (nonvolatile recording means)

Claims (3)

Motor means driven to generate compressed air;
Compressed air storage means for storing the compressed air generated in response to driving of the motor means;
Pressure detecting means for detecting the pressure state of the compressed air stored in the compressed air storing means;
An air compressor comprising control means for controlling the drive amount of the motor means,
Non-volatile recording means for recording information output from the control means;
Automatic return setting means for setting whether to restart the start of the air compressor when the interrupted power is restored,
The control means includes
During the start of the air compressor, information that is in the operation mode is recorded in the nonvolatile recording means,
Based on the pressure state detected by the pressure detection unit, the operation stop state of the motor unit is determined and information on the operation stop state is recorded in the nonvolatile recording unit,
When the setting for resuming the start of the air compressor is performed by the automatic return setting means, the information for resuming the start of the air compressor is recorded in the nonvolatile recording means,
When information indicating that the non-volatile recording means restarts activation of the air compressor is recorded when power is supplied to the air compressor, the non-volatile recording means causes the motor means to stop operating. Read the information about, and adjust the drive amount of the motor means according to the information about the operation stop state, and start the air compressor according to the operation state during the operation mode recorded in the nonvolatile recording means An air compressor characterized by resuming operation. Informing means for informing the restarting of the air compressor,
The air compressor according to claim 1, wherein the control unit causes the notification unit to perform notification when restarting the air compressor. Motor means driven to generate compressed air;
Compressed air storage means for storing the compressed air generated in response to driving of the motor means;
Pressure detecting means for detecting the pressure state of the compressed air stored in the compressed air storing means;
An air compressor comprising control means for controlling the drive amount of the motor means,
Non-volatile recording means for recording information output from the control means;
And operating means operated when starting and stopping the air compressor,
The control means includes
When the air compressor is started by the operation of the operation means, the drive amount of the motor means is controlled to start the air compressor,
During the start of the air compressor, information that is in the operation mode is recorded in the nonvolatile recording means,
Based on the pressure state detected by the pressure detection unit, the operation stop state of the motor unit is determined and information on the operation stop state is recorded in the nonvolatile recording unit,
When power is supplied to the air compressor, if information indicating that the operation mode is being recorded is recorded in the nonvolatile recording means, it is determined that the power that has been cut off has been restored,
The operation mode recorded in the non-volatile recording unit is read from the non-volatile recording unit and information relating to the operation suspension state of the motor unit is read, and the driving amount of the motor unit is adjusted according to the information related to the operation suspension state. An air compressor characterized in that the air compressor is restarted in accordance with the operation state.

Images