JP5822745B2 - Gas compression device - Google Patents

Description

  The present invention relates to a gas compression apparatus suitable for use in compressing a gas such as air or nitrogen.

  Generally, as a gas compression device, for example, a device including a compressor body that sucks and compresses gas, an electric motor that drives the compressor body, and a tank that stores compressed gas generated by the compressor body is known. (For example, see Patent Documents 1 and 2). Such a conventional gas compression apparatus includes a control device including, for example, an inverter in order to control electric power supplied to the electric motor. This control device turns on the power supply to the electric motor when the tank pressure becomes a predetermined lower limit pressure value or less, and turns off the power supply to the electric motor when the tank pressure becomes a predetermined upper limit pressure value or more. To do.

  Further, the control device supplies more electric current to the electric motor than usual when the power supply voltage drops. At this time, for example, when the maximum value of the current limited by the capacity of the breaker or the like is reached, the control device reduces the rotation speed of the electric motor so that the current falls below a predetermined value. If the voltage continues to decrease and falls below a predetermined value set in advance, the control device has stopped supplying power to the electric motor.

Japanese Patent Laid-Open No. 1-240781 JP 2006-288053 A

  By the way, in the gas compressor according to the prior art, when the load on the compressor main body is large, electric power necessary for continuous operation of the compressor main body cannot be supplied, and the electric motor may be locked. The power required to restart the compressor body also depends on the fluctuations in the power supply voltage, the pressure in the tank when the compressor body is restarted, and the operating status of other electrical equipment connected to the same power source. May be insufficient. In this case, there has been a problem that abnormal noise occurs due to the electric motor locking or stepping out.

  The present invention has been made in view of the above-described problems of the prior art, and an object of the present invention is to provide a gas compression device capable of preventing an unintended stop in advance.

In order to solve the above-described problems, the present invention provides a compressor main body that sucks and compresses gas, an electric motor that drives the compressor main body, voltage detection means that detects a power supply voltage of the electric motor, A tank for storing the compressed gas generated by the compressor body, a pressure detection means for detecting the pressure of the tank, and the electric motor when the pressure detected by the pressure detection means falls below a predetermined lower limit pressure value. In the gas compression apparatus comprising the control means for turning on the power supply to the motor and turning off the power supply to the electric motor when a predetermined upper limit pressure value is exceeded, the control means comprises the voltage detection means depending on the voltage value detected by the change at least either one of upper limit pressure value and the lower limit pressure value, the control means, voltage detected by said voltage detecting means When in the low voltage condition that decline is characterized by raising the lower limit pressure value.

  According to the present invention, it is possible to appropriately control the state of startup and operation according to the use state of the power source, and to prevent an unintended stop beforehand.

It is a block diagram which shows the air compression apparatus by the 1st thru | or 3rd embodiment of this invention. It is a flowchart which shows the pressure switching control by 1st Embodiment. It is a characteristic diagram which shows the time change of the pressure in a tank, and a power supply voltage in the case of using the air compressor by a comparative example. It is a characteristic diagram which shows the time change of the pressure in a tank, and a power supply voltage in the case of using the air compressor by 1st Embodiment. It is a flowchart which shows the pressure switching control by 2nd Embodiment. It is explanatory drawing which shows the time change of a power supply voltage, and the histogram of a power supply voltage. It is a characteristic diagram which shows the time change of the pressure in a tank, and a power supply voltage in the case of using the air compressor by 2nd Embodiment. It is a flowchart which shows the pressure switching control by 3rd Embodiment. It is a characteristic diagram which shows the time change of the pressure in a tank, and a power supply voltage in the case of using the air compressor by a comparative example. It is a characteristic diagram which shows the time change of the pressure in a tank, and a power supply voltage in the case of using the air compressor by 3rd Embodiment.

  Hereinafter, as an example of a gas compressing apparatus according to an embodiment of the present invention, an air compressing apparatus will be described as an example and described in detail with reference to the accompanying drawings.

  First, FIG. 1 and FIG. 2 show a first embodiment. In FIG. 1, the air compressor 1 includes an electric motor 2 as a driving unit, and a compressor body 3 driven by the electric motor 2.

  Here, the electric motor 2 is configured by an inverter-controlled DCBL (DC Brushless) motor, for example. And the electric motor 2 is connected to the power supply PS via the control apparatus 10 mentioned later. As a result, the rotation speed of the electric motor 2 is controlled by the control device 10 and drives the compressor body 3. The electric motor 2 is not limited to a DCBL motor, and may be a three-phase induction motor, for example.

  Moreover, the compressor main body 3 is comprised by various compression mechanisms, such as a reciprocating type, a screw type, a scroll type, for example. The compressor body 3 compresses air sucked from the outside to generate compressed air, and discharges the compressed air toward the tank 5.

  The rotation sensor 4 constitutes a rotation angle detector that detects the rotation angle of the electric motor 2. The rotation sensor 4 is composed of, for example, a Hall element or the like, detects the magnetic flux of a magnet that rotates together with the output shaft of the electric motor 2, and outputs a detection signal to the CPU 15. Thus, the CPU 15 detects the rotation angle of the electric motor 2 based on the detection signal from the rotation sensor 4.

  The tank 5 is connected to the discharge side of the compressor body 3 and stores the compressed air discharged from the compressor body 3. An output pipe 8 having a check valve 6 and a throttle valve 7 is attached to the tank 5. Thus, the tank 5 is connected to an external pneumatic device (not shown) via the output pipe 8 and supplies compressed air toward the pneumatic device by opening the throttle valve 7.

  A pressure sensor 9 is attached to the tank 5. The pressure sensor 9 constitutes a pressure detection unit that detects the pressure in the tank 5. The pressure sensor 9 detects the pressure P of the compressed air in the tank 5 and outputs a detection signal corresponding to the pressure P.

  The control device 10 turns on the power supply to the electric motor 2 when the pressure P detected by the pressure sensor 9 becomes equal to or lower than a predetermined lower limit pressure value Pmin, and when the pressure P becomes equal to or higher than the predetermined upper limit pressure value Pmax. Control means for turning off the power supply to the electric motor 2 is configured. The control device 10 is connected between a power source PS that is supplied with, for example, a single-phase 100 V AC voltage and the electric motor 2. And the control apparatus 10 is comprised by the below-mentioned rectifier 11, the inverter circuit 12, the current detection circuit 13, the voltage detection circuit 14, the arithmetic processing unit 15 (henceforth CPU15), etc.

  The rectifier 11 is formed as a bridge circuit by a plurality of diodes, for example. The rectifier 11 is connected to the power source PS via a power switch (not shown) or the like, and full-wave rectifies the single-phase AC voltage of the power source PS. The rectified voltage is smoothed by a smoothing circuit (not shown) made of a capacitor or the like, and output to the inverter circuit 12 as a DC voltage. The rectifier 11 is not limited to a full-wave rectifier circuit, and may be configured to use a half-wave rectifier circuit or the like.

  The inverter circuit 12 constitutes a drive circuit that drives the electric motor 2. The inverter circuit 12 includes, for example, six power transistors and is connected to the output side of the rectifier 11 via a smoothing circuit. Then, when a DC voltage is input from the rectifier 11 or the like, the inverter circuit 12 performs pulse width modulation (PWM control) on the DC voltage in accordance with a control signal from the CPU 15 and outputs it to the electric motor 2. Although the rectifier 11 and the inverter circuit 12 are directly connected and the power rectified by the rectifier 11 is supplied directly to the inverter circuit 12, a power factor correction circuit or a booster is provided between the rectifier 11 and the inverter circuit 12. A circuit may be connected and provided.

  The current detection circuit 13 is located on the output side of the rectifier 11 and is provided, for example, connected to any one of a pair of DC power lines connecting the rectifier 11 and the inverter circuit 12. Then, when the inverter circuit 12 is driven and power is supplied from the power source PS to the electric motor 2, the current detection circuit 13 detects the current flowing through the DC power line as the drive current I supplied to the electric motor 2, A detection signal is output to the CPU 15.

  The voltage detection circuit 14 constitutes voltage detection means for detecting the power supply voltage V of the electric motor 2. The voltage detection circuit 14 is provided, for example, connected to a positive DC power line among a pair of DC power lines connecting the rectifier 11 and the inverter circuit 12. The voltage detection circuit 14 detects a DC voltage applied between the pair of DC power lines as the power supply voltage V of the electric motor 2 and outputs a detection signal to the CPU 15. Here, when the voltage drop from the power supply PS is small, the power supply voltage V has a rated voltage value of about 100V, for example. For example, when a voltage drop occurs due to a large number of electrical devices connected to the power supply PS, the power supply voltage V is lower than the rated voltage value.

  CPU15 comprises the control part which performs inverter control of the driving | running state of the electric motor 2, for example. The CPU 15 is constituted by a microcomputer, for example, and is connected to a storage device 16 including a ROM, a RAM, and the like.

  The storage device 16 includes, for example, a pressure open / close control program for controlling the compressor body 3 based on a detection signal from the pressure sensor 9, and a lower limit pressure value Pmin [MPa], an upper limit pressure value Pmax [MPa] used in this program, Low voltage lower limit pressure value PminL [MPa] and lower limit voltage value V0 [V] are stored in advance. Here, the upper limit pressure value Pmax and the lower limit pressure value Pmin are pressure values for maintaining the pressure P in the tank 5 in an appropriate range. For example, the upper limit pressure value Pmax is set to a pressure of about 3.0 MPa. At the same time, the lower limit pressure value Pmin is set to a pressure of about 2.6 MPa. The upper limit pressure value Pmax and the lower limit pressure value Pmin are not limited to these values, and are set as appropriate according to the specifications of the air compressor 1 and the like.

  The low voltage lower limit pressure value PminL is a value of the pressure P in the tank 5 that makes it difficult to use the pneumatic device, and is a use limit value of the pneumatic device. This lower voltage lower limit pressure value PminL is set to a value lower than the lower limit pressure value Pmin (PminL <Pmin). Furthermore, the lower limit voltage value V0 is a power supply voltage V that allows the electric motor 2 to start normally under a load of the lower limit pressure value Pmin. For example, the lower limit voltage value V0 is set to about 85V.

  A rotation sensor 4, a pressure sensor 9, a current detection circuit 13, and a voltage detection circuit 14 are connected to the input side of the CPU 15, and an inverter circuit 12 is connected to the output side of the CPU 15.

  Then, the CPU 15 calculates information on the rotation angle of the electric motor 2 obtained from the rotation sensor 4. The CPU 15 calculates the rotation angular velocity based on the information on the rotation angle, drives the inverter circuit 12 to achieve a desired rotation angular velocity, and rotates the electric motor 2.

  Further, the CPU 15 detects the drive current I of the electric motor 3 using the detection signal from the current detection circuit 13. When the drive current I becomes excessively large, the CPU 15 stops or decelerates the electric motor 2 to protect the electric motor 2 and the like.

  Further, the CPU 15 performs a control (pressure opening / closing control) for operating and stopping the compressor main body 3 according to the pressure P in the tank 5, so that the pressure P is set between the upper limit pressure value Pmax and the lower limit pressure value Pmin. The pressure value is maintained. That is, in the pressure switching control, for example, the operation of the compressor body 3 is stopped when the pressure P reaches the upper limit pressure value Pmax, and the compressor body 3 is restarted when the pressure P decreases to the lower limit pressure value Pmin. .

  Further, the CPU 15 reduces the lower limit pressure value Pmin when the power supply voltage V detected by the voltage detection circuit 14 is equal to or lower than a predetermined lower limit voltage value V0.

  Therefore, next, referring to FIG. 1 and FIG. 2, the pressure opening / closing control in which the control device 10 controls the driving and stopping of the electric motor 2 and the compressor body 3 in accordance with detection signals from the pressure sensor 9 and the voltage detection circuit 14 However, this will be described in detail.

  First, when the control device 10 is driven, the CPU 15 reads the pressure opening / closing control program shown in FIG. And according to this program, CPU15 performs the following processes for every predetermined sampling period (for example, 10-20 ms).

  First, in step 1, the pressure P in the tank 5 is measured using the detection signal from the pressure sensor 9. Next, in step 2, the power supply voltage V is measured using the detection signal from the voltage detection circuit 14.

  In the subsequent step 3, it is determined whether or not the compressor body 3 is in a compression operation, that is, whether or not the electric motor 2 is being driven. When it is determined as “YES” in Step 3, the electric motor 2 is driven and the compressor body 3 is performing the compression operation. For this reason, it moves to step 4 and determines whether the pressure P in the tank 5 is lower than the upper limit pressure value Pmax as a stop pressure (P <Pmax).

  And when it determines with "YES" at step 4, it is thought that the pressure P has not reached the upper limit pressure value Pmax and it is not necessary to stop the compression operation. For this reason, the present operating state is maintained, and the routine proceeds to step 10 and returns.

  On the other hand, when “NO” is determined in Step 4, the pressure P in the tank 5 is higher than the upper limit pressure value Pmax, and it is considered necessary to switch the compressor body 3 to the compression stop. For this reason, it moves to step 5 and CPU15 stops the electric motor 2 using the inverter circuit 12. FIG. Thereby, the compressor main body 3 stops the operation and switches to the compression stop. When step 5 is completed, the process proceeds to step 10 and returns.

  Moreover, when it determines with "NO" at step 3, the electric motor 2 has stopped and the compressor main body 3 has stopped discharge of compressed air. For this reason, it moves to step 6 and it is determined whether the pressure P is higher than the lower limit pressure value Pmin as the restart pressure (P> Pmin). And when it determines with "YES" at step 6, it is thought that the pressure P is higher than the minimum pressure value Pmin, and it is not necessary to replenish the tank 5 with compressed air. For this reason, it moves to step 10 and returns as it is.

  On the other hand, when “NO” is determined in step 6, it is considered that the pressure P in the tank 5 drops below the lower limit pressure value Pmin and the compressed air in the tank 5 is insufficient. Therefore, the process proceeds to the next step 7 to determine whether or not the power supply voltage V is higher than a predetermined lower limit voltage value V0 (V> V0). And when it determines with "YES" at step 7, it is thought that the power supply voltage V is holding | maintaining the value which can start the electric motor 2 normally. Therefore, the process proceeds to step 8, and the CPU 15 starts up the electric motor 2 using the inverter circuit 12. Thereby, the compressor body 3 starts the compression operation. When step 8 ends, the process proceeds to step 10 and returns.

  On the other hand, when it is determined as “NO” in step 7, it is considered that the power supply voltage V has decreased to a value lower than the predetermined lower limit voltage value V0 and has decreased to a value at which the electric motor 2 cannot be normally started. For this reason, the process proceeds to step 9 to determine whether or not the pressure P in the tank 5 is higher than the low voltage lower limit pressure value PminL (P> PminL). When it is determined “YES” in step 9, the pressure P is higher than the low voltage lower limit pressure value PminL, and the compressed air is replenished to the tank 5 in a state where the power supply voltage V is lower than the lower limit voltage value V 0. It is considered unnecessary. For this reason, it moves to step 10 and returns as it is.

  On the other hand, when “NO” is determined in Step 9, the pressure P is reduced to the lower voltage lower limit pressure value PminL or lower, and the tank 5 is compressed even when the power supply voltage V is lower than the lower voltage value V0. It may be necessary to refill with air. Therefore, the process proceeds to step 8, and the CPU 15 starts up the electric motor 2 using the inverter circuit 12. At this time, since the pressure P in the tank 5 has dropped below the lower limit pressure value PminL for low voltage, the load on the compressor body 3 is smaller than when the pressure P is about the lower limit pressure value Pmin. For this reason, even when the power supply voltage V is equal to or lower than the lower limit voltage value V0, the electric motor 2 can be easily started, and the compressor body 3 starts the compression operation. When step 8 ends, the process proceeds to step 10 and returns.

  The air compressor 1 according to the present embodiment has the above-described configuration. Next, the lowering pressure value Pmin lowering operation will be described with reference to FIGS.

  First, as a comparative example, the case where the lower limit pressure value Pmin is fixed will be described with reference to FIG. FIG. 3 shows temporal changes in the pressure P and the power supply voltage V in the tank when the air compressor according to the comparative example is used.

  The air compressor of the comparative example performs pressure opening / closing control in a state where the lower limit pressure value Pmin is fixed. For this reason, the compression operation is stopped when the pressure P in the tank rises to a predetermined upper limit pressure value Pmax, and the compression operation is resumed when the pressure P drops to the lower limit pressure value Pmin. Here, in addition to the air compressor being supplied with power from the same power source PS as other electric devices, the power supply wiring from the power source PS to the air compressor may be long. In this case, the power supply voltage V constantly changes with the activation of the air compressor and the activation and operation of other electric devices. For this reason, when the air compressor is driven when the power supply voltage V is lowered, the power supply voltage V is further lowered, and the output of the electric motor becomes smaller than the reaction force of the compressed air. May cause defects.

  Next, the case where the lower limit pressure value Pmin decreases according to the power supply voltage V as in the first embodiment will be described with reference to FIG. FIG. 4 shows temporal changes in the pressure P and the power supply voltage V in the tank 5 when the air compressor 1 according to the first embodiment is used.

  In the air compressor 1 according to the first embodiment, as in the comparative example, the compression operation is stopped when the pressure P in the tank 5 rises to a predetermined upper limit pressure value Pmax, and the compression operation is stopped when the pressure P decreases to the lower limit pressure value Pmin. To resume. However, in the first embodiment, unlike the comparative example, when the power supply voltage V is lower than the predetermined lower limit voltage value V0, the lower limit pressure value Pmin is decreased to the lower voltage lower limit pressure value PminL. For this reason, when the power supply voltage V becomes a low voltage (for example, 65 V) due to driving of other electric devices, the electric motor 2 does not start even if the pressure P in the tank 5 decreases to the lower limit pressure value Pmin. Then, when the other electric equipment is stopped and the power supply voltage V becomes higher than the lower limit voltage value V0, or when the pressure P in the tank 5 falls below the lower limit pressure value PminL for low voltage, the electric motor 2 Start up. As a result, the electric motor 2 can be started without anomaly while waiting for the power supply voltage V to rise or the load to drop, and an unintended stop of the electric motor 2 can be prevented.

  In particular, since the small and portable air compressor 1 is used at a construction site or the like, the power supply wiring becomes long and the power supply voltage V supplied to the electric motor 2 tends to decrease. On the other hand, other electric devices connected to the same power source PS are, for example, electric devices for construction work such as electric drills and electric saws, and are often used temporarily and are continuously used for a long time. There are few things to drive. In particular, since the power supply voltage V decreases for a short time when the electric device is started up, the power supply voltage V is higher than the lower limit voltage value V0 if the timing at which the air compressor 1 is restarted is shifted as in the first embodiment. It often recovers to a value and can be used in a state where the air compressor 1 and other electric equipment are connected to the same power source PS.

  Thus, according to the present embodiment, the control device 10 changes the lower limit pressure value Pmin according to the power supply voltage V detected by the voltage detection circuit 14. Specifically, the control device 10 holds the lower limit pressure value Pmin when the power supply voltage V is higher than the lower limit voltage value V0, and lowers the lower limit pressure value Pmin when the power supply voltage V drops below the lower limit voltage value V0. The lower limit pressure value PminL is reduced.

  For this reason, when the power supply voltage V decreases, the lower limit pressure value Pmin, which is the restart pressure, is changed to the lower voltage lower limit pressure value PminL according to the power supply voltage V, and the timing at which the electric motor 2 is started is changed. be able to. As a result, when the power supply voltage V is low and the power supplied from the power supply PS is small, the activation of the air compressor 1 is avoided, and the compressor main body 3 is kept at a timing when the power supply voltage V is kept sufficiently high. A state in which the air compressor 1 can be restarted and the air compressor 1 cannot be restarted can be prevented in advance. Moreover, since the load can be reduced by lowering the lower limit pressure value Pmin, the air compressor 1 can be started even with a relatively low power supply voltage V.

  Note that the low voltage lower limit pressure value PminL is a predetermined value determined in advance. However, the present invention is not limited to this, and the low voltage lower limit pressure value PminL may be a variable according to the use environment of the air compressor 1 or may be a function according to the power supply voltage V. For example, when the power supply voltage V is high, the low voltage lower limit pressure value PminL may be increased, and when the power supply voltage V is low, the low voltage lower limit pressure value PminL may be decreased.

  Next, FIGS. 5 and 6 show a second embodiment, and the feature of this embodiment is that the lower limit pressure value is increased when the power supply voltage is in a low voltage state. In the second embodiment, the same components as those in the first embodiment are denoted by the same reference numerals, and the description thereof is omitted.

  Similar to the air compressor 1 according to the first embodiment, the air compressor 21 according to the second embodiment includes an electric motor 2, a compressor body 3, a tank 5, a pressure sensor 9, a control device 10, and the like. Has been.

  However, in the second embodiment, the control device 10 performs the pressure switching control shown in FIG. 5 and increases the lower limit pressure value Pmin when the power supply voltage V is in a low voltage state in which the power supply voltage V tends to decrease. This is different from the first embodiment.

  Whether the power supply voltage V is in a low voltage state is determined using the power supply voltage histogram 22 shown in FIG. More specifically, for example, the power supply voltage V is measured every predetermined sampling period (for example, 10 to 20 ms), and the power supply status determination time T0 shown in FIG. A frequency distribution of the power supply voltage V over (for example, T0 = 5 s) is created. Then, in the histogram 22 shown in FIG. 6, the control device 10 has a sum of frequencies equal to or lower than a predetermined determination voltage value VL (for example, VL = 80 V) equal to or higher than a predetermined frequency of, for example, about several percent with respect to the whole. When it increases, it determines with it being in a low voltage state, and determines with a normal state at other times. The histogram 22 shown in FIG. 6 is updated, for example, every power status determination time T0.

  Therefore, the pressure switching control according to the second embodiment will be described with reference to FIG.

  First, when the control device 10 is driven, the CPU 15 reads the pressure opening / closing control program shown in FIG. And according to this program, CPU15 performs the following processes for every predetermined sampling period (for example, 10-20 ms).

  First, in step 11, the pressure P in the tank 5 is measured using the detection signal from the pressure sensor 9. Next, in step 12, the power supply voltage V is measured using the detection signal from the voltage detection circuit 14. Next, in step 13, as the power supply voltage state statistical process, a histogram 22 shown in FIG. 6 is created using the measured power supply voltage V.

  In subsequent step 14, it is determined whether or not the compressor body 3 is in a compression operation, that is, whether or not the electric motor 2 is driven. When it is determined as “YES” in step 14, the electric motor 2 is driven and the compressor main body 3 is performing the compression operation. For this reason, it moves to step 15 and determines whether the pressure P in the tank 5 is lower than the upper limit pressure value Pmax as a stop pressure (P <Pmax).

  And when it determines with "YES" at step 15, it is thought that the pressure P has not reached the upper limit pressure value Pmax, and it is not necessary to stop the compression operation. For this reason, the present operating state is maintained, and the routine goes to Step 22 and returns.

  On the other hand, when “NO” is determined in step 15, the pressure P in the tank 5 is higher than the upper limit pressure value Pmax, and it is considered that the compressor body 3 needs to be switched to the compression stop. For this reason, it moves to step 16 and CPU15 stops the electric motor 2 using the inverter circuit 12. FIG. Thereby, the compressor main body 3 stops the operation and switches to the compression stop. When step 16 is completed, the process proceeds to step 22 and returns.

  Moreover, when it determines with "NO" in step 14, the electric motor 2 has stopped and the compressor main body 3 has stopped discharge of compressed air. Therefore, the process proceeds to step 17 to determine whether or not the power supply voltage V is in a low voltage state. When “NO” is determined in step 17, the frequency at which the power supply voltage V becomes equal to or lower than the determination voltage value VL is low, and it is considered to be in a normal state. Therefore, the process proceeds to step 18 to determine whether or not the pressure P is higher than the lower limit pressure value Pmin as the restart pressure (P> Pmin). When it is determined as “YES” in step 18, it is considered that the pressure P is higher than the lower limit pressure value Pmin and it is not necessary to replenish the tank 5 with compressed air. For this reason, it moves to step 22 and returns as it is.

  On the other hand, when it is determined as “NO” in step 18, it is considered that the pressure P in the tank 5 falls below the lower limit pressure value Pmin, and the compressed air in the tank 5 is insufficient. Therefore, the process proceeds to step 19, and the CPU 15 starts up the electric motor 2 using the inverter circuit 12. Thereby, the compressor body 3 starts the compression operation. When step 19 is completed, the routine goes to step 22 and returns.

  Further, when “YES” is determined in step 17, the frequency at which the power supply voltage V becomes equal to or lower than the determination voltage value VL is higher than a predetermined frequency, for example, about 5% of the whole, and in a low voltage state. It is believed that there is. For this reason, it transfers to step 20 and it is determined whether the pressure P in the tank 5 is higher than the low voltage lower limit pressure value PminH.

  Here, the low voltage lower limit pressure value PminH is such that when the power supply voltage V is in a low voltage state, the pressure P of the tank 5 is held in advance higher than the lower limit pressure value Pmin, and the electric motor 2 is started. The timing to do is shifted. For this reason, the lower limit pressure value PminH for low voltage is set to a value higher than the lower limit pressure value Pmin (PminH> Pmin) and stored in the storage device 16.

  In order to secure a sufficient time until the power supply voltage V returns to the normal state, the low voltage lower limit pressure value PminH is as low as possible within the range lower than the upper limit pressure value Pmax and higher than the lower limit pressure value Pmin. It is preferable to set a high value. On the other hand, in order to extend the stop time of the electric motor 2 and reduce the power consumption of the air compressor 21, the low voltage lower limit pressure value PminH is lower than the upper limit pressure value Pmax and higher than the lower limit pressure value Pmin. It is preferable to set the value as low as possible in the range. For this reason, the low voltage lower limit pressure value PminH is set to an appropriate value in consideration of these two points of interest.

  When it is determined as “YES” in step 20, it is considered that the pressure P is higher than the low voltage lower limit pressure value PminH, and it is not necessary to replenish the tank 5 with compressed air. For this reason, it moves to step 22 and returns as it is.

  On the other hand, when “NO” is determined in step 20, the pressure P in the tank 5 has decreased to the lower limit pressure value PminH for low voltage or lower, so the routine proceeds to step 21 where the power supply voltage V is determined in advance. It is determined whether or not it is higher than a predetermined lower limit voltage value V1 (V> V1).

  At this time, the lower limit voltage value V1 is set to about 80V, for example. The lower limit voltage value V1 may be the same value as the lower limit voltage value V0 used in the first embodiment, or may be a different value. Further, the lower limit voltage value V1 may be the same value as the determination voltage value VL for determining whether or not the low voltage state is set, or may be a different value.

  And when it determines with "YES" at step 21, it is thought that the power supply voltage V is holding | maintaining the value which can start the electric motor 2 normally. Therefore, the process proceeds to step 19, and the CPU 15 starts up the electric motor 2 using the inverter circuit 12. Thereby, the compressor body 3 starts the compression operation. When step 19 is completed, the routine goes to step 22 and returns.

  On the other hand, when it is determined as “NO” in step 21, it is considered that the power supply voltage V has decreased to a value lower than the predetermined lower limit voltage value V1, and has decreased to a value at which the electric motor 2 cannot be normally started. Therefore, in order to wait for the activation of the electric motor 2 until the power supply voltage V becomes higher than the lower limit voltage value V1, the routine proceeds to step 22 and returns.

  Thus, the second embodiment can provide the same effects as those of the first embodiment. In the second embodiment, when the power supply voltage V detected by the voltage detection circuit 14 is in a low voltage state, the control device 10 increases the lower limit pressure value Pmin to the low voltage lower limit pressure value PminH. Therefore, as shown in FIG. 7, when the power supply voltage V is in a low voltage state, the lower limit pressure value Pmin is increased so that the pressure P in the tank 5 is higher than the original restart pressure. Can be maintained. As a result, while the pressure P in the tank 5 decreases from the low voltage lower limit pressure value PminH to the lower limit pressure value Pmin that is the original restart pressure, the air pressure is adjusted to the timing when the power supply voltage V is kept sufficiently high. The compression device 21 can be activated. As a result, when the power supply voltage V is low, it is possible to avoid the start of the air compressor 21 and wait until the power supply voltage V becomes high.

  In addition, since the pressure P in the tank 5 is maintained at a value higher than the original lower limit pressure value Pmin, the frequency at which the pressure P in the tank 5 decreases below the lower limit pressure value Pmin can be reduced. As a result, even when the difference between the lower limit pressure value Pmin and the actually used pressure is small or when the amount of compressed air used is large, the pressure P in the tank 5 is suppressed from decreasing and connected to the tank 5. The workability of pneumatic equipment can be improved.

  In the second embodiment, the low voltage lower limit pressure value PminH is a predetermined value determined in advance. However, the present invention is not limited to this, and the low voltage lower limit pressure value PminH may be a variable according to the use environment of the air compressor 21 or may be a function according to the power supply voltage V. For example, the low voltage lower limit pressure value PminH may be lowered when the power supply voltage V is high, and the low voltage lower limit pressure value PminH may be increased when the power supply voltage V is low.

  In the second embodiment, when the power supply voltage V is normal, the electric motor 2 is started when the pressure P in the tank 5 drops below the lower limit pressure value Pmin regardless of the measured value of the power supply voltage V. The configuration. However, the present invention is not limited to this, and by combining the first and second embodiments, even if the power supply voltage V is normal and the pressure P drops below the lower limit pressure value Pmin, the power supply voltage V When the measured value is equal to or lower than the lower limit voltage value V0, the electric motor 2 may be prevented from starting.

  Next, FIG. 8 shows a third embodiment, which is characterized in that the upper limit pressure value is lowered when the power supply voltage is in a low voltage state. In the third embodiment, the same components as those in the first embodiment are denoted by the same reference numerals, and the description thereof is omitted.

  The air compressor 31 according to the third embodiment is configured by the electric motor 2, the compressor body 3, the tank 5, the pressure sensor 9, the control device 10 and the like, similarly to the air compressor 1 according to the first embodiment. Has been. However, in the third embodiment, the control device 10 performs the pressure opening / closing control shown in FIG. 8 and decreases the upper limit pressure value Pmax when the power supply voltage V is in a low voltage state in which the power supply voltage V tends to decrease. Whether or not the power supply voltage V is in the low voltage state is determined using, for example, the histogram 22 shown in FIG. 6 as in the second embodiment.

  Therefore, the pressure switching control according to the third embodiment will be described with reference to FIG.

  First, when the control device 10 is driven, the CPU 15 reads the pressure opening / closing control program shown in FIG. And according to this program, CPU15 performs the following processes for every predetermined sampling period (for example, 10-20 ms).

  First, in step 31, the pressure P in the tank 5 is measured using the detection signal from the pressure sensor 9. Next, at step 32, the power supply voltage V is measured using the detection signal from the voltage detection circuit 14. Next, in step 33, as the power supply voltage state statistical processing, the histogram 22 shown in FIG. 6 is created using the measured power supply voltage V.

  In the following step 34, it is determined whether or not the compressor body 3 is in a compression operation, that is, whether or not the electric motor 2 is driven. When it is determined “YES” in step 34, the electric motor 2 is driven and the compressor body 3 is performing the compression operation. Therefore, the process proceeds to step 35 to determine whether or not the power supply voltage V is in a low voltage state. When it is determined “NO” in step 35, the frequency at which the power supply voltage V becomes equal to or lower than the determination voltage value VL is low, and it is considered to be in a normal state. Therefore, the process proceeds to step 36 to determine whether or not the pressure P in the tank 5 is lower than the upper limit pressure value Pmax as the stop pressure (P <Pmax).

  And when it determines with "YES" at step 36, it is thought that the pressure P has not reached the upper limit pressure value Pmax and it is not necessary to stop the compression operation. Therefore, the current operation state is maintained, and the process proceeds to step 42 and returns.

  On the other hand, when “NO” is determined in step 36, the pressure P in the tank 5 is higher than the upper limit pressure value Pmax, and it is considered that the compressor body 3 needs to be switched to the compression stop. For this reason, it moves to step 37 and CPU15 stops the electric motor 2 using the inverter circuit 12. FIG. Thereby, the compressor main body 3 stops the operation and switches to the compression stop. When step 37 is completed, the routine proceeds to step 42 and returns.

  Further, when “YES” is determined in step 35, the frequency at which the power supply voltage V becomes equal to or lower than the determination voltage value VL is higher than a predetermined frequency of about 5%, for example, and is considered to be in a low voltage state. For this reason, the process proceeds to step 38 to determine whether or not the power supply voltage V is higher than a predetermined lower limit voltage value V2 (V> V2).

  At this time, the lower limit voltage value V2 is set to about 80V, for example. The lower limit voltage value V2 may be the same as or different from the lower limit voltage values V0 and V1 used in the first and second embodiments. Further, the lower limit voltage value V2 may be the same value as the determination voltage value VL for determining whether or not the low voltage state is set, or may be a different value.

  When it is determined “YES” in step 38, it is considered that the power supply voltage V holds a value that allows the electric motor 2 to start normally, and therefore, the processing after step 36 is executed.

  On the other hand, if “NO” is determined in step 38, the power supply voltage V drops below the predetermined lower limit voltage value V 2, and when the pressure P rises to near the upper limit pressure value Pmax, the electric motor 2 is driven to a value that cannot be continued. It is thought that it is decreasing. Therefore, the process proceeds to step 39 to determine whether or not the pressure P in the tank 5 is lower than the low voltage upper limit pressure value PmaxL (P <PmaxL).

  Here, the low voltage upper limit pressure value PmaxL reduces the load by suppressing the pressure P of the tank 5 from rising to the vicinity of the upper limit pressure value Pmax when the power supply voltage V enters a low voltage state. It is. For this reason, the low voltage upper limit pressure value PmaxL is set to a value (PmaxL <Pmax) lower than the upper limit pressure value Pmax and stored in the storage device 16.

  In order to reduce the load on the air compressor 31 as much as possible, the low voltage upper limit pressure value PmaxL is set to the lowest possible value within a range lower than the upper limit pressure value Pmax and higher than the lower limit pressure value Pmin. Is preferred. On the other hand, in order to widen the allowable range of the pressure P and reduce the restart frequency of the electric motor 2, the low voltage upper limit pressure value PmaxL is lower than the upper limit pressure value Pmax and higher than the lower limit pressure value Pmin. It is preferable to set the value as high as possible. For this reason, the low voltage upper limit pressure value PmaxL is set to an appropriate value in consideration of these two points of interest.

  And when it determines with "YES" at step 39, it is thought that the pressure P has not reached the low voltage upper limit pressure value PmaxL, and it is not necessary to stop the compression operation. Therefore, the current operation state is maintained, and the process proceeds to step 42 and returns.

  On the other hand, when “NO” is determined in step 39, the pressure P in the tank 5 is higher than the low voltage upper limit pressure value PmaxL, and it is considered necessary to switch the compressor body 3 to the compression stop. . For this reason, it moves to step 37 and CPU15 stops the electric motor 2 using the inverter circuit 12. FIG. When step 37 is completed, the routine proceeds to step 42 and returns.

  Moreover, when it determines with "NO" at step 34, the electric motor 2 has stopped and the compressor main body 3 has stopped discharge of compressed air. For this reason, it moves to step 40 and it is determined whether the pressure P is higher than the lower limit pressure value Pmin as the restart pressure (P> Pmin). When it is determined as “YES” in Step 40, it is considered that the pressure P is higher than the lower limit pressure value Pmin and it is not necessary to replenish the tank 5 with compressed air. For this reason, it moves to step 42 and returns as it is.

  On the other hand, when it is determined as “NO” in step 40, it is considered that the pressure P in the tank 5 drops below the lower limit pressure value Pmin and the compressed air in the tank 5 is insufficient. For this reason, it moves to step 41 and CPU15 starts the electric motor 2 using the inverter circuit 12. FIG. Thereby, the compressor body 3 starts the compression operation. When step 41 is completed, the routine proceeds to step 42 and returns.

  The air compressor 31 according to the third embodiment has the above-described configuration. Next, the operation of reducing the upper limit pressure value Pmax will be described with reference to FIGS. 8 to 10.

  First, as a comparative example, the case where the upper limit pressure value Pmax is fixed will be described with reference to FIG. FIG. 9 shows temporal changes in the pressure P and the power supply voltage V in the tank when the air compressor according to the comparative example is used.

  The air compressor of the comparative example performs pressure opening / closing control in a state where the upper limit pressure value Pmax is fixed. For this reason, when the power supply voltage V is low and the pressure P approaches the upper limit pressure value Pmax, the reaction force of the compressed air increases as the pressure in the tank increases. The output may be smaller than the reaction force of compressed air. In this case, the electric motor may be locked or stepped out, and the air compressor may unintentionally stop abnormally before the pressure P reaches the upper limit pressure value Pmax.

  On the other hand, in the third embodiment, when the power supply voltage V is in the low voltage state, as shown in FIG. 10, the upper limit pressure value Pmax is lowered to the low voltage upper limit pressure value PmaxL. For this reason, when the power supply voltage V is low, the pressure P does not rise to the vicinity of the upper limit pressure value Pmax, and the load can be reduced. As a result, it is possible to prevent a state where the air compressor 31 stops unintentionally.

  Thus, the third embodiment can provide the same operational effects as those of the first embodiment. In the third embodiment, when the power supply voltage V detected by the voltage detection circuit 14 is in the low voltage state, the control device 10 reduces the upper limit pressure value Pmax to the low voltage upper limit pressure value PmaxL. For this reason, when the power supply voltage V is in a low voltage state, the upper limit pressure value Pmax can be lowered, and the electric motor 2 can be stopped at the pressure P in the tank 5 with a margin in the output of the electric motor 2. . As a result, it is possible to prevent a state where the electric compressor 2 is locked or stepped out at a low voltage and the air compressor 31 stops unintentionally.

  In the third embodiment, the low voltage upper limit pressure value PmaxL is a predetermined value determined in advance. However, the present invention is not limited to this, and the low voltage upper limit pressure value PmaxL may be a variable according to the use environment of the air compressor 31 or may be a function according to the power supply voltage V. For example, when the power supply voltage V is high, the low voltage upper limit pressure value PmaxL may be increased, and when the power supply voltage V is low, the low voltage upper limit pressure value PmaxL may be decreased.

  In the third embodiment, the electric motor 2 is activated when the pressure P in the tank 5 falls below the lower limit pressure value Pmin regardless of the measured value of the power supply voltage V. However, the present invention is not limited to this, and the configuration of the first embodiment or the second embodiment may be combined with the third embodiment, and all the first to third embodiments may be combined. It is good also as composition which combines.

  In each of the embodiments, the electric motor 2 is an inverter control type. However, for example, an electric motor that directly supplies an AC voltage of a power source may be used. In this case, while measuring the alternating voltage of a power supply as a power supply voltage, the supply and stop of the electric power from a power supply to an electric motor may be controlled, for example with an electromagnetic switch.

  Further, in each of the above embodiments, the air compressors 1, 21, and 31 have been described as examples of the gas compressors. However, the present invention can be widely applied to compressors that compress other gases such as nitrogen. .

  As described in each of the above embodiments, according to the invention of claim 1, the control means is at least one of the upper limit pressure value and the lower limit pressure value according to the voltage value detected by the voltage detection means. Change one. For this reason, even when a power supply voltage falls, a restart pressure and a stop pressure can be changed according to a power supply voltage, and the start and stop timing can be changed. As a result, when the power supply voltage is low and the power supplied from the power supply is low, the start-up and operation of the compression device can be avoided, and the operation timing can be adjusted when the power supply voltage is high and stable. It is possible to prevent in advance starting or abnormal stopping during operation.

  According to the invention of claim 2, the control means reduces the lower limit pressure value when the voltage detected by the voltage detection means is equal to or lower than the predetermined lower limit voltage value. For this reason, when the power supply voltage is low, the lower limit pressure value can be lowered to shift the start timing, and the compression apparatus can be started at a timing when the power supply voltage is high, avoiding start-up at a low voltage. it can. Further, since the load can be reduced by lowering the lower limit pressure value, the compression device can be started even with a relatively low power supply voltage.

  According to the invention of claim 3, the control means increases the lower limit pressure value when the voltage detected by the voltage detection means is in a low voltage state in which the voltage tends to decrease. For this reason, when the power supply voltage is in a low voltage state, the lower limit pressure value can be increased to maintain the pressure in the tank at a value higher than the original restart pressure. As a result, the compressor can be started in accordance with the timing when the power supply voltage is high while the pressure in the tank drops from the lower limit pressure value at which the pressure has increased to the original restart pressure. As a result, when the power supply voltage is low, it is possible to avoid starting the compressor and wait until the power supply voltage becomes high. In addition, since the pressure in the tank is maintained at a higher value than the original restart pressure, the frequency with which the pressure in the tank decreases below the original restart pressure can be reduced. Thereby, the pressure fall in a tank can be suppressed and the workability | operativity of the pneumatic equipment connected to the tank can be improved.

  According to the invention of claim 4, the control means reduces the upper limit pressure value when the voltage detected by the voltage detection means is in a low voltage state in which the voltage tends to decrease. For this reason, when the power supply voltage is in a low voltage state, the upper limit pressure value can be reduced, and the electric motor can be stopped at a pressure in the tank with a margin in the output of the electric motor. As a result, it is possible to prevent a state in which the electric motor is locked or stepped out at a low voltage and the compressor is stopped unintentionally.

1, 21, 31 Air compressor 2 Electric motor 3 Compressor body 5 Tank 9 Pressure sensor (pressure detection means)
10 Control device (control means)
14 Voltage detection circuit (voltage detection means)
15 Arithmetic processing unit (CPU)
16 Storage device PS Power supply

Claims (2)

A compressor body that sucks and compresses gas, an electric motor that drives the compressor body, voltage detection means that detects a power supply voltage of the electric motor, and a tank that stores compressed gas generated by the compressor body A pressure detecting means for detecting the pressure of the tank; and when the pressure detected by the pressure detecting means falls below a predetermined lower limit pressure value, the power supply to the electric motor is turned on, and a predetermined upper limit pressure is set. In the gas compression device comprising the control means for turning off the power supply to the electric motor when the value is equal to or greater than the value,
The control means changes at least one of the upper limit pressure value and the lower limit pressure value according to the voltage value detected by the voltage detection means ,
Wherein if the voltage detected by said voltage detecting means is in a low voltage condition that decline, gas compression apparatus, characterized in Rukoto raising the lower limit pressure value. Wherein if the voltage detected by said voltage detecting means is in a low voltage condition that decreasing trend, the gas compression device according to claim 1, characterized in that lowering the upper limit pressure value.

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