JP6582823B2 - air compressor - Google Patents

Description

  The present invention relates to an air compressor, and more particularly to a portable air compressor used at a construction work site or the like.

  A portable air compressor used at a construction work site or the like is used as an air source for nailing work or the like, and is often used in a place where the power supply environment is relatively bad. Specifically, a temporary power source is usually installed at a construction work site or the like, and an extension cord is connected to the temporary power source, and a plurality of electric tools may be used at the same time by hook wiring or the like. For this reason, the input voltage becomes unstable, and the opportunity to use it at AC 100 V or less increases.

  When the air compressor is used in a low voltage state of AC 100 V or less, the number of revolutions of the electric motor is reduced and the time for filling the tank with the compressed air is increased. Accordingly, the operation time of the electric motor becomes longer and the cooling performance is lowered. When the cooling performance deteriorates, there is a concern that the temperature of electronic components such as FETs (switching elements) mounted on the control board will rise, and the control circuit will be damaged early.

  For example, Patent Document 1 discloses an electric tool that is connected by a voltage drop, breaker breakage, or the like when the stability of supplied power, such as a temporary power supply or a power supply by a generator, is lower than that of a normal commercial power supply. In particular, it is described that restarting devices such as air compressors can often occur.

Japanese Unexamined Patent Publication No. 2015-145047

  By the way, in recent construction work sites and the like, various electric tools are brought into the site in order to shorten the construction period. In spite of this, the power supply environment is mostly AC100V (30A), which is the same as that of ordinary households. Therefore, the problems as described above can frequently occur.

  In the air compressor described in Patent Document 1 described above, even when the power supply environment is bad (when the voltage is low), the operation of operating the motor of the air compressor is performed. Therefore, since the control board can become high temperature, the life of the air compressor is reduced in the long run. In addition, since the worker notices that the power supply environment is bad after starting the work, it is necessary to stop the work and review the operating environment of the air compressor after that, which may lead to a significant reduction in work efficiency. There is.

  The objective of this invention is providing the air compressor which can grasp | ascertain and alert | report the power supply environment before the operation | movement of an air compressor.

An aspect of the present invention is an air compressor including an electric motor, a compression mechanism driven by the electric motor, and a tank that stores air compressed by the compression mechanism, and the electric motor includes a power supply unit for supplying a driving current, and the control to that control section a rotation of the electric motor, the electric power supply from the outside to the power supply unit, automatically detecting voltage input voltage input to the power supply unit a detection unit, the input voltage detected by the voltage detecting section, possess a Table radical 113 that displays the status is second voltage higher than the low and the third voltage than the first voltage to the outside, the The control unit performs drive time limit control for limiting the drive time of the air compressor within a predetermined time when the input voltage is the third voltage, and as the drive time elapses, Change the display contents That.

  In another aspect of the present invention, one end of a power cord is connected to the power source, a plug that is plugged into an outlet is provided at the other end of the power cord, and the voltage detector is connected to the outlet of the plug. The input voltage is automatically detected by plugging in.

In another aspect of the present invention, before Symbol Table radical 113 displays a predetermined notification content in accordance with the magnitude of the input voltage detected by the voltage detecting unit.

In another aspect of the present invention, notification content before Symbol Table radical 113 is at least either of the flashing light emitting diodes having different lighting and speed of the light-emitting diodes having different colors.

In another aspect of the present invention, a pressure sensor is provided for detecting the pressure in the tank, before Symbol control section, when the input voltage is the first voltage and the second voltage, the detection value of the pressure sensor Is increased to the first pressure set value, the electric motor is stopped, and when the detected value of the pressure sensor is decreased to the second pressure set value, the electric motor is driven, and when the input voltage is the third voltage, When the detected value of the pressure sensor rises to a third pressure set value that is at least smaller than the first pressure set value, the electric motor is stopped.

In another aspect of the present invention, before Symbol control section, when the input voltage is of the third voltage, when the detection value of the pressure sensor is reduced to the fourth pressure set value smaller than the second pressure set value The electric motor is driven.

In another aspect of the present invention, the drive time of the air compressor is the drive time of the electric motor .

In another aspect of the present invention, before Symbol Table radical 113 is a light emitting diode, before Symbol control section, the faster the flashing cycle of the light emitting diode in accordance with the driving time elapses.

  According to the present invention, a voltage detection unit that automatically detects an input voltage input to the power supply unit by supplying power from the outside to the power supply unit, and the input voltage detected by the voltage detection unit is less than the first voltage. And a voltage display unit for displaying the state of the second voltage that is lower than the third voltage to the outside, so that the power supply environment can be grasped and reported before the operation of the air compressor.

It is a perspective view which shows an air compressor. It is a horizontal sectional view of an air compressor. It is a top view which shows the operation panel of an air compressor. It is a block diagram which shows the electric system of an air compressor. It is a 1st flowchart figure which shows the control content of an air compressor. It is a 2nd flowchart figure which shows the control content of an air compressor. It is a 3rd flowchart figure which shows the control content of an air compressor. It is a timing chart figure which shows the control content of an air compressor.

  Hereinafter, an embodiment of the present invention will be described in detail with reference to the drawings.

  1 is a perspective view showing the air compressor, FIG. 2 is a horizontal sectional view of the air compressor, FIG. 3 is a plan view showing an operation panel of the air compressor, and FIG. 4 is an electric system of the air compressor. Each block diagram is shown.

  An air compressor (air compressor) 10 shown in FIG. 1 is a portable air compressor that can be easily carried by an operator at a construction work site or the like. The air compressor 10 is used as a compressed air supply source that supplies compressed air to an air tool that drives nails and screws into wood or the like by the pressure of the compressed air.

  As shown in FIG. 1, the air compressor 10 includes a base 12 including a skeleton such as a frame and two air tanks (tanks) 11 a and 11 b that are connected to the skeleton and are parallel to each other. Legs 13 are attached to the lower surfaces of both end portions of each of the air tanks 11 a and 11 b, and the air compressor 10 is placed at a desired installation location by the four leg portions 13. Handles 14 are provided at both ends of the base 12 so that an operator can carry the air compressor 10 by holding the handles 14.

  Mounted on the base 12 are the electric motor 20 shown in FIG. 2 and a compression mechanism 30 that is driven by the electric motor 20 to generate compressed air. The electric motor 20 and the compression mechanism 30 are covered with a plastic cover 15 (see FIG. 1). The compression mechanism 30 includes a crankcase 40, and a first cylinder 50a and a second cylinder 50b that are arranged to face each other.

  The electric motor 20 includes a cylindrical stator (stator) 21, a rotor (rotor) 22 that is rotatably provided on the radial inner side of the stator 21, and a rotary shaft 23 that is fixed to the rotation center of the rotor 22. In addition, a position sensor 24 (see FIG. 4) made of a Hall element or the like for detecting the rotational position of the rotor 22 is provided. The electric motor 20 is a brushless motor and is disposed outside the crankcase 40. The electric motor 20 is fixed to a first case portion 41 a that forms the crankcase 40 and is integrated with the crankcase 40.

  The rotating shaft 23 penetrates the rotor 22 and protrudes on both sides in the axial direction of the rotor 22. The first protrusion 23 a that protrudes to one side in the axial direction of the rotor 22 passes through the crankcase 40 and is rotatably supported by a bearing provided in the crankcase 40. Specifically, the first protrusion 23a of the rotating shaft 23 passes through the first case portion 41a and the second case portion 41b that forms the crankcase 40 facing the first case portion 41a. And the 1st protrusion part 23a is rotatably supported by the bearing provided in each of the 1st, 2nd case parts 41a and 41b.

  A control board 60 on which a calculation unit 66 (see FIG. 4) for controlling the rotation of the electric motor 20 is arranged on the opposite side of the crankcase 40 from the electric motor 20 side. In addition to the arithmetic unit 66, the control board 60 includes a drive unit 61 having a switching element such as an FET, a power source unit 62 to which one end of a power cord 63 is electrically connected, and the like. Here, the power supply unit 62 supplies a drive current to the electric motor 20. A plurality of other electronic components are also mounted on the control board 60. These electronic components (see FIG. 4) will be described later.

  The control board 60 is disposed so as to face the second case portion 41b from the axial direction of the rotary shaft 23, and is fixed to one air tank 11b. A cooling fan 64 is disposed between the control board 60 and the crankcase 40, and the control board 60 is cooled by an air flow (cooling air) generated by the cooling fan 64. The cooling fan 64 is fixed to an end portion of the first projecting portion 23a projecting from the second case portion 41b, and thereby rotates integrally with the rotating shaft 23 to generate cooling air.

  A first cylinder 50a and a second cylinder 50b are fixed to both sides of the crankcase 40 along the direction orthogonal to the rotation shaft 23. The first and second cylinders 50 a and 50 b are disposed (opposed) at positions different from each other by 180 degrees with respect to the rotation direction of the rotation shaft 23. A first piston 51a is reciprocally accommodated inside the first cylinder 50a, and a second piston 51b is reciprocally accommodated inside the second cylinder 50b. That is, the air compressor 10 according to the present embodiment is a reciprocating type air compressor.

  In order to convert the rotary motion of the rotary shaft 23 into the reciprocating motion of the first piston 51a, one end of the first connecting rod 52a is pin-coupled to the first piston 51a, and the other end of the first connecting rod 52a is 1 is rotatably coupled to an eccentric cam mounted on the protruding portion 23a. That is, the first connecting rod 52a straddles between the crankcase 40 and the first cylinder 50a, and connects the first protrusion 23a and the first piston 51a.

  Further, in order to convert the rotational motion of the rotary shaft 23 into the reciprocating motion of the second piston 51b, one end of the second connecting rod 52b is pin-coupled to the second piston 51b, and the other end of the second connecting rod 52b is The first projecting portion 23a is rotatably coupled to another eccentric cam. That is, the second connecting rod 52b straddles between the crankcase 40 and the second cylinder 50b and connects the first projecting portion 23a and the second piston 51b.

  Then, by driving the electric motor 20, the rotary shaft 23 is rotated, and the rotary motion of the rotary shaft 23 is caused by the motion conversion mechanism including the pair of eccentric cams and the first and second connecting rods 52a and 52b. The second pistons 51a and 51b are converted into reciprocating motions in the first and second cylinders 50a and 50b.

  Here, each cam crest (not shown) provided in the pair of eccentric cams protrudes radially outward and in the same direction of the first protrusion 23a. That is, under the state shown in FIG. 2, each cam mountain protrudes to the left in the drawing. Thus, as shown in FIG. 2, when the first piston 51a moves in a direction to compress the upper chamber of the first cylinder 50a, the second piston 51b moves in a direction to expand the upper chamber of the second cylinder 50b. To do. On the contrary, when the second piston 51b moves in the direction of compressing the upper chamber of the second cylinder 50b, the first piston 51a moves in the direction of expanding the upper chamber of the first cylinder 50a. The upper chamber of each cylinder 50a, 50b is a space on the opposite side of each piston 52a, 52b from the connecting rod 52a, 52b side in each cylinder 50a, 50b.

  Buffer chambers 54a and 54b are respectively provided inside cylinder heads 53a and 53b provided in the respective cylinders 50a and 50b. A check valve is provided between the upper chamber of each cylinder 50a, 50b and each buffer chamber 54a, 54b. When the first piston 51a moves in the direction of compressing the upper chamber of the first cylinder 50a and the pressure of the air in the upper chamber becomes higher than a predetermined pressure, the upper chamber of the first cylinder 50a and the buffer chamber 54a A check valve in between is opened. Then, the air compressed by the first piston 51a is pumped to the upper chamber of the second cylinder 50b via the first pipe 55 that communicates the buffer chamber 54a and the second cylinder 50b. In addition, the 1st piping 55 in this Embodiment is a metal pipe.

  Thereafter, when the second piston 51b moves in the direction of compressing the upper chamber of the second cylinder 50b and the pressure of the air in the upper chamber becomes higher than a predetermined pressure, the upper chamber of the second cylinder 50b and the buffer chamber 54b A check valve in between is opened. Then, the air compressed by the second piston 51b is pumped and stored in the other air tank 11a via a second pipe (not shown) that communicates the buffer chamber 54b and the other air tank 11a. .

  The pair of air tanks 11 a and 11 b communicate with each other via the third pipe 56. Thereby, the internal pressure of a pair of air tank 11a, 11b is kept at the same pressure. In addition, the 2nd piping and the 3rd piping 56 in this Embodiment are metal pipes.

  Here, as shown in FIG. 2, outside air is introduced into the upper chamber of the first cylinder 50a. That is, the first piston 51a compresses the outside air, and the second piston 51b further compresses the outside air (air) compressed by the first piston 51a. In other words, the first piston 51a is a first-stage low-pressure piston, and the second piston 51b is a second-stage high-pressure piston. The first cylinder 50a is a first-stage low-pressure cylinder, and the second cylinder 50b is a second-stage high-pressure cylinder. Thus, the air compressor 10 according to the present embodiment compresses air in two stages. Specifically, compressed air of about 1.0 [Mpa] is generated by the first piston 51a, and compressed air of about 4.0 to 4.5 [MPa] is generated by the second piston 51b.

  As shown in FIG. 1, couplers 16a and 16b, which are outlets for compressed air, are provided above the ends of the pair of air tanks 11a and 11b. Further, pressure reducing valves 17a and 17b for adjusting the pressure of the compressed air taken out are provided between the air tanks 11a and 11b and the couplers 16a and 16b, respectively. The pressure of the compressed air adjusted by these pressure reducing valves 17a and 17b is measured and displayed by pressure gauges 18a and 18b installed in the vicinity of the pressure reducing valves 17a and 17b, respectively.

  As shown in FIG. 2, the other air tank 11a is provided with a safety valve 19a that automatically opens when the pressure in the pair of air tanks 11a and 11b becomes higher than a predetermined pressure. On the other hand, one air tank 11b is provided with a drain device 19b, and when this drain device 19b is operated, compressed air and moisture in each air tank 11a, 11b are discharged.

  Further, as shown in FIG. 1, an operation panel 80 is provided on the upper surface of the cover 15 and between the pressure reducing valves 17a and 17b. As shown in FIG. 3, the operation panel 80 has seven first display portions 82a for displaying the operation switch 81a and the mode switch 81b operated by the operator, the operation state and the operation state of the air compressor 10, and the like. -82g, and a second display portion 83 that is formed from two 7-segment displays and can display numbers, alphabets, and the like.

  Here, during the operation of the air compressor 10, a load current is generated in the electric motor 20 which is a drive source of the pistons 51a and 51b. Therefore, the temperature of the electric motor 20 rises due to Joule heat accompanying the load current. Moreover, the temperature of each cylinder 50a, 50b and each piston 51a, 52b itself rises with the compression heat which generate | occur | produces at the compression process of each piston 51a, 51b. Furthermore, as the temperature of the electric motor 20 and the cylinders 50a and 50b rises, the temperature of the crankcase 40 in contact with them also rises.

  Therefore, as shown in FIG. 2, a cooling fan 57 is installed on the opposite side of the electric motor 20 from the crankcase 40 side. Thereby, the electric motor 20, the compression mechanism 30 and the like are cooled, the early wear of the movable part is suppressed, and the life of the air compressor 10 can be extended.

  The cooling fan 57 is fixed to the end of the second protrusion 23b of the rotating shaft 23 that protrudes in the direction opposite to the direction in which the first protrusion 23a protrudes from the rotor 22 of the electric motor 20. That is, the cooling fan 57 rotates integrally with the rotating shaft 23. Thus, in the present embodiment, the cooling fan 64 is provided at one end of the rotating shaft 23, and the cooling fan 57 is provided at the other end of the rotating shaft 23.

  As shown in FIG. 3, the operation panel 80 includes a panel body 80 a formed in a substantially V shape following the shape of the upper surface of the cover 15 (see FIG. 1) of the air compressor 10. The panel main body 80a is formed in a plate shape by a resin material such as plastic, and includes a pair of engaging claws 80b and a screw fixing portion 80c provided on the side opposite to the side where each engaging claw 80b is provided. . That is, the panel body 80a is fixed to the cover 15 with only one fixing screw.

  As shown in FIGS. 3 and 4, the operation switch 81a and the mode switch 81b, the seven first display portions 82a to 82g, and the second display portion 83 are electrically connected to the back surface of the panel body 80a. The operation panel substrate 84 is fixed. A part of the panel main body 80a is transparent, whereby the states of the first display units 82a to 82g and the second display unit 83 can be confirmed from the outside.

  The operation switch 81a is a main switch that turns on / off the operation of the air compressor 10, and the mode switch 81b is a changeover switch that switches the operation mode (normal mode / silent mode, etc.) of the air compressor 10. Here, the shaded portions in FIG. 3 are portions where light emitting diodes (LEDs) are arranged, and these shaded portions are lit or blinked in various colors.

  As shown in FIG. 4, the control board 60 is electrically connected to the operation panel board 84. A drive unit 61 that supplies a drive current to the electric motor 20 is mounted on the control board 60, and the drive unit 61 is provided with a plurality of FETs (not shown). A power supply unit 62 is connected to the drive unit 61, and one end of a power cord 63 is connected to the power supply unit 62. The power source unit 62 converts AC power from an AC power source 65 such as a temporary power source into DC power, and supplies optimal power to the drive unit 61 and other electronic components. Here, AC power from the AC power source 65 is supplied to the power source unit 62 by inserting a plug 63 a provided at the other end of the power cord 63 into the outlet 65 a.

  The control board 60 is equipped with a calculation unit (CPU) 66 that executes various calculation processes based on various input signals and the like. The arithmetic unit 66 is operated by the electric power from the power source unit 62 to switch the plurality of FETs provided in the driving unit 61. As a result, a drive current having a predetermined magnitude is supplied to the electric motor 20, and the electric motor 20 is rotationally driven in a predetermined rotation direction and rotation speed.

  In addition, a motor current detection unit 67 is provided between the calculation unit 66 and the drive unit 61, and the motor current detection unit 67 detects the drive current flowing through the electric motor 20 and sends the result to the calculation unit 66. Sending out (feedback). Thereby, the calculating part 66 can grasp | ascertain the load condition from the outside with respect to the electric motor 20, for example, and can control to protect the electric motor 20 from burning etc., when a load is large.

  A power supply current detection unit 68 and a voltage detection unit 69 are provided between the power supply unit 62 and the calculation unit 66. The power supply current detection unit 68 detects the current of the power supply unit 62 and sends the result to the calculation unit 66. The voltage detection unit 69 detects a voltage (input voltage) input from the AC power supply 65 to the power supply unit 62 and sends the result to the calculation unit 66. As described above, the calculation unit 66 constantly monitors the state of the input voltage that enters the power supply unit 62 from the AC power supply 65 such as a temporary power supply.

  Here, the voltage detector 69 automatically plugs the plug 63 a of the power cord 63 into the outlet 65 a of the AC power supply 65 by an operator, and automatically supplies the power supply 62 to the power supply 62 from the AC power supply 65 by supplying external power. The incoming input voltage is detected. Then, the automatically detected state of the input voltage (information such as the magnitude of the voltage) is sent to the calculation unit 66, and the calculation unit 66 selects one of the first display units 82a to 82g based on this information. At least one is lit or blinked to notify (display) the state of the input voltage to the worker (external). That is, at least one of the seven first display portions 82a to 82g constitutes a voltage display portion in the present invention, and this voltage display portion indicates the state of the input voltage detected by the voltage detection portion 69. The plug 63a is automatically displayed when the plug 63a is inserted into the outlet 65a. The voltage detection unit 69 is not limited to detecting the magnitude (large or small value) of the voltage entering the power supply unit 62, but may be a change in voltage waveform.

  An EEPROM (nonvolatile memory) 70 is connected to the calculation unit 66. In the EEPROM 70, operation log data of the air compressor 10 (operation mode change history, rotation speed history of the electric motor 20, etc.) is recorded. Then, at the time of maintenance of the air compressor 10, the consumable parts can be exchanged by reading the operation log data from the EEPROM 70.

  Further, the position sensor 24 for detecting the rotational position of the rotor 22 (see FIG. 2) forming the electric motor 20 is connected to the calculation unit 66. Accordingly, the calculation unit 66 operates the drive unit 61 at an optimal timing according to the detection value (position signal of the rotor 22, that is, a feedback signal) from the position sensor 24, and efficiently drives the electric motor 20 to rotate. be able to.

  Furthermore, a pressure sensor 71 that detects internal pressures of the two air tanks 11a and 11b is connected to the calculation unit 66. Although not shown in FIG. 2, the pressure sensor 71 is provided in the middle of the third pipe 56, for example. Thereby, the pressure in each air tank 11a, 11b made into the mutually same pressure via the 3rd piping 56 is detectable. Then, based on the magnitude of the detected value from the pressure sensor 71 (pressure signal in each air tank 11a, 11b), the calculation unit 66 stops or restarts (drives) the electric motor 20 from rotation. To do. That is, the calculation part 66 comprises the motor control part in this invention.

  A threshold value storage unit 66a is provided inside the calculation unit 66, and the threshold value storage unit 66a has a first pressure setting to be compared with a detection value from the pressure sensor 71 as shown in FIG. The value P1, the second pressure set value P2, the third pressure set value P3, and the fourth pressure set value P4 are stored in advance.

  Here, the first pressure set value P1 is, for example, 4.35 [Mpa], and the second pressure set value P2 is, for example, 3.50 [Mpa]. These first pressure set value P1 and second pressure set value P2 form a set pressure range (A) in which the pressure in each air tank 11a, 11b is “high pressure side”. The third pressure set value P3 is, for example, 3.20 [Mpa], and the fourth pressure set value P4 is, for example, 2.30 [Mpa]. The third pressure set value P3 and the fourth pressure set value P4 form a set pressure range (B) in which the pressure in each air tank 11a, 11b is “low pressure side”. That is, the magnitude relationship between the pressure setting values P1 to P4 is P1> P2> P3> P4. However, the magnitude relationship between the pressure set values P1 to P4 is not limited to the above, and may be a relationship in which the set pressure range (A) and the set pressure range (B) partially overlap each other. Specifically, the relationship of P1> P3> P2> P4 may be satisfied.

  Then, in the calculation unit 66, the state of the input voltage detected by the voltage detection unit 69 is “normal voltage (first voltage: range of AC 100 to 81 V, for example)” and “driveable voltage (second voltage: AC 80 to 71 V, for example). The electric motor 20 is set so that the pressure in each air tank 11a, 11b falls within the set pressure range (A) in order to set the pressure in each air tank 11a, 11b to “high pressure side”. Drive to rotate. That is, the first pressure set value P1 is a stop pressure value for stopping the electric motor 20 at the normal voltage and the driveable voltage, and the second pressure set value P2 is the electric drive at the normal voltage and the driveable voltage. This is a restart pressure value for restarting the motor 20. The “normal voltage” at which the air compressor 10 can operate normally may be from AC110V.

  On the other hand, when the state of the input voltage detected by the voltage detector 69 is the “difficult driving voltage (third voltage: range of AC 70 to 65 V, for example)”, the calculation unit 66 sets the air tanks 11a and 11b. The electric motor 20 is driven to rotate so that the pressure in each of the air tanks 11a and 11b falls within the set pressure range (B) (the shaded portion in FIG. 8) so that the internal pressure becomes the “low pressure side”. In other words, the third pressure set value P3 is a stop pressure value that stops the electric motor 20 at the time of difficult driving voltage (low voltage), and the fourth pressure set value P4 is electric at the time of difficult driving voltage (low voltage). This is a restart pressure value for restarting the motor 20.

  As a result, the operating time of the electric motor 20 becomes longer when the input voltage is in a “difficult to drive voltage” state where the voltage is low and the rotational speed of the electric motor 20 is lower than normal. It is possible to prevent the cooling performance of the air compressor 10 from being lowered. In this case, although the pressure in each air tank 11a, 11b is low in the set pressure range (B), the air tool can be used continuously to some extent. Therefore, the work efficiency is not significantly reduced.

  As shown in FIG. 4, a timer unit 66 b is provided inside the calculation unit 66. The timer unit 66b regulates the continued rotational driving of the electric motor 20 when the input voltage is in the “driving difficulty voltage” state. Specifically, as described above, if the air compressor 10 is continuously operated in a low voltage environment, the life of the air compressor 10 is reduced. Therefore, when the input voltage is in the “driving difficulty voltage” state, the timer unit 66b starts (activates) counting, whereby the calculation unit 66 sets the driving time of the electric motor 20 within a predetermined time (for example, within 60 seconds). ). That is, the arithmetic unit 66 performs drive time limit control when the input voltage is in the “drive difficult voltage” state. Therefore, overheating of the air compressor 10 is prevented, and it is possible to prevent the air compressor 10 from becoming inoperable or shortening its life.

  Then, the calculation unit 66 lights or blinks at least one of the seven first display units 82a to 82g during the execution of the drive time limit control as described above, and as the drive time elapses. Then, a process of changing the display content (notification content) of the voltage display unit (first display units 82a to 82g) is performed. Details of this processing will be described later.

  As shown in FIG. 4, operation switch 81 a and mode switch 81 b, seven first display units 82 a to 82 g, and second display unit 83 are electrically connected to calculation unit 66. Yes. Thereby, the calculating part 66 controls the rotational drive of the electric motor 20 according to operation of the operation switch 81a and the mode switch 81b by an operator, and the 1st display part 82a-82g and the 1st display part 82a-82g and the state of the air compressor 10 itself. 2 Display on the display unit 83.

  Next, operation | movement of the air compressor 10 formed as mentioned above is demonstrated in detail using drawing.

  FIG. 5 is a first flowchart showing the control contents of the air compressor, FIG. 6 is a second flowchart showing the control contents of the air compressor, and FIG. 7 is a third flowchart showing the control contents of the air compressor. FIG. 8 is a flow chart, and FIG. 8 is a timing chart showing the control content of the air compressor.

  As shown in FIG. 5, first, an operator inserts the plug 63a of the power cord 63 into the outlet 65a of the AC power supply 65, whereby the control of the air compressor 10 is started (step S1). At this time, the air compressor 10 is not in an operating state, and the rotation drive of the electric motor 20 is stopped.

  In the subsequent step S2, the calculation unit 66 determines whether or not the input voltage input from the AC power supply 65 to the power supply unit 62 is in the range of AC100 to 81V (normal voltage). If it is determined in step S2 that the input voltage is in the range of AC 100 to 81V (yes), the process proceeds to step S3. In step S3, the first display unit (LED) 82a among the seven first display units 82a to 82g is lit in green, and then the process proceeds to step S10 shown in FIG. Thereby, the operator can recognize that it is “a normal voltage having a sufficient magnitude” for operating the air compressor 10 by viewing the first display portion 82a.

  If it is determined in step S2 that the input voltage is smaller (no) than the range of AC 100 to 81V (normal voltage), the process proceeds to step S4. In step S4, the arithmetic unit 66 determines whether or not the input voltage is in the range of AC 80 to 71V (driveable voltage). Here, the drivable voltage is a voltage that allows the air compressor 10 to operate substantially normally, although the operating efficiency of the air compressor 10 decreases compared to the normal voltage. If it is determined in step S4 that the input voltage is in the range of AC 80 to 71 V (yes), the process proceeds to step S5. In step S5, the first display portion 82a is lit in yellow, and then the process proceeds to step S10 shown in FIG. Thereby, the operator can recognize that it is the “driveable voltage” that is lower than the normal voltage but can operate the air compressor 10 by viewing the first display portion 82a. If the air compressor 10 indicates that the input voltage is in the range of AC 80 to 71 V (driveable voltage), for example, the operator can prevent the voltage supplied to the air compressor 10 from dropping. Measures can be taken to continue the operation of the air compressor 10 by refraining from using these tools.

  If it is determined in step S4 that the input voltage is smaller (no) than the range of AC 80 to 71 V (driveable voltage), the process proceeds to step S6. In step S <b> 6, the calculation unit 66 determines whether or not the input voltage is in the range of AC 70 to 65 V (driving difficulty voltage). If it is determined in step S6 that the input voltage is in the range of AC 70 to 65 V (yes), the process proceeds to step S7. In step S7, the first display section 82a is flashed in red at a cycle of once / second (low-speed flashing), and then the process proceeds to step S10 shown in FIG. Thereby, the operator can recognize that the air compressor 10 is “a difficult driving voltage that can be operated with restrictions” by visually observing the first display portion 82a. Based on this, the operator can use the air compressor 10 within a predetermined time (short time) or review the use environment of the air compressor 10 (stop using other power tools, etc.).

  If it is determined in step S6 that the input voltage is smaller than AC65V (no), the process proceeds to step S8 assuming that the input voltage is the “undriveable voltage”. In step S <b> 8, the calculation unit 66 causes “low voltage error display” in which the operation of the electric motor 20 is impossible, for example, by blinking all seven first display units 82 a to 82 g in red at high speed. . And it progresses to step S9 and control of the air compressor 10 is complete | finished. Here, the “low voltage error display” is not limited to the above, and an error code (for example, “E1” or the like) indicating that the input voltage is an inoperable voltage is displayed on the second display unit 83. Also good.

  As described above, in the air compressor 10 according to the present embodiment, the calculation unit 66 causes the first display unit 82a to have the notification content determined in advance according to the magnitude of the input voltage detected by the voltage detection unit 69. That is, the notification contents shown in step S3, step S5 and step S7 in FIG. 5 are displayed.

  As shown in FIG. 6, in step S10, the calculation unit 66 determines whether or not the operation switch 81a is turned on by the operator. If it is determined in step S10 that the operation switch 81a is turned on by the operator (yes), the process proceeds to step S11. On the other hand, if it is determined in step S10 that the operation switch 81a is not turned on (no), the process of step S10 is repeated.

  In subsequent step S11, the calculation unit 66 determines again whether or not the input voltage is in the range of AC 100 to 81V (normal voltage). If it is determined in step S11 that the input voltage is in the range of AC 100 to 81V (yes), the process proceeds to step S12. In step S12, the first display unit (LED) 82a is lit in green, and then the process proceeds to step S15.

  If it is determined in step S11 that the input voltage is smaller (no) than the range of AC 100 to 81V (normal voltage), the process proceeds to step S13. In step S <b> 13, the calculation unit 66 determines again whether or not the input voltage is in the range of AC 80 to 71 V (driveable voltage). If it is determined in step S13 that the input voltage is in the range of AC 80 to 71 V (yes), the process proceeds to step S14. In step S14, the first display portion 82a is lit in yellow, and then the process proceeds to step S15. On the other hand, if it is determined in step S13 that the input voltage is smaller (no) than the range of AC 80 to 71 V (driveable voltage), the process proceeds to step S18 shown in FIG.

  In step S15, the calculation unit 66 determines whether or not the pressure in the pair of air tanks 11a and 11b is within the set pressure range (A) shown in FIG. If it is determined in step S15 that the pressure in each of the air tanks 11a and 11b is within the set pressure range (A) (yes), the process proceeds to step S16. In continuing step S16, the calculating part 66 maintains the state which stopped the rotational drive of the electric motor 20, and returns to step S10 after that.

  On the other hand, if it is determined in step S15 that the pressure in each air tank 11a, 11b is not within the set pressure range (A) (no), the process proceeds to step S17. In continuing step S17, the calculating part 66 rotationally drives the electric motor 20, and returns to step S10 after that.

  Here, the operation of the calculation unit 66 in steps S15 to S17 will be described in detail. As shown in the solid line graph of FIG. 8, when the input voltage is a normal voltage (a range of AC100 to 71V) and a driveable voltage (a range of AC80 to 71V), the calculation unit 66 has a first detection value of the pressure sensor 71. When the pressure reaches the pressure set value P1, the electric motor 20 is stopped. Thereby, the pressure in each air tank 11a, 11b does not become 4.35 [Mpa] or more. Then, when the use of the pneumatic tool is started at the work start point TP1, the compressed air in each air tank 11a, 11b is gradually consumed, and the pressure in each air tank 11a, 11b decreases. Thereafter, when the detection value of the pressure sensor 71 decreases to the second pressure set value P2, the calculation unit 66 restarts (drives) the electric motor 20. As a result, when the input voltage is a normal voltage and a drivable voltage, the pressure in each air tank 11a, 11b is within the set pressure range (A).

  As shown in FIG. 7, in step S <b> 18, the calculation unit 66 determines again whether or not the input voltage is in the range of AC 70 to 65 V (driving difficulty voltage). If it is determined in step S18 that the input voltage is in the range of AC 70 to 65 V (yes), the process proceeds to step S19. On the other hand, if it is determined in step S18 that the input voltage is smaller than AC65V (no), it is determined that the input voltage is the “undriveable voltage” and the process proceeds to step S20. In step S20, the calculating part 66 performs the same process as step S8 of FIG. 5, and control of the air compressor 10 is complete | finished in subsequent step S21.

  In step S19, the calculation unit 66 performs a process of switching from the set pressure range (A) to the set pressure range (B) based on the drive difficulty voltage (AC 70 to 65V range) where the input voltage is a low voltage. Determine whether it has been done. If it is determined in step S19 that the process of switching to the set pressure range (B) has already been performed (yes), the process proceeds to step S22. On the other hand, if it is determined in step S19 that the process for switching to the set pressure range (B) has not yet been performed (no), the process proceeds to step S23. In step S23, the calculation part 66 performs a process of switching from the set pressure range (A) to the set pressure range (B). Thereafter, the process returns to step S15 in FIG. 6 and is controlled so that the pressure in each of the air tanks 11a and 11b falls within the set pressure range (B).

  In step S <b> 22, the calculation unit 66 determines whether or not the electric motor 20 is being rotationally driven (during operation). If it is determined in step S22 that the electric motor 20 is being operated (yes), the process proceeds to step S24. On the other hand, if it is determined in step S22 that the electric motor 20 is not operating (no), the process returns to step S15 in FIG.

  In step S24, the calculation unit 66 operates the timer unit 66b to start counting by the timer unit 66b. In subsequent step S25, the calculation unit 66 determines whether or not the count value Tn by the timer unit 66b is larger than Ta (30 seconds). If it is determined in step S25 that the count value Tn is greater than Ta (yes), the process proceeds to step S26. On the other hand, if it is determined in step S25 that the count value Tn is equal to or less than Ta (no), the process returns to step S15 in FIG.

  In step S26, this time, the calculation unit 66 determines whether or not the count value Tn by the timer unit 66b is larger than Tb (50 seconds). If it is determined in step S26 that the count value Tn is greater than Tb (yes), the process proceeds to step S27. On the other hand, if it is determined in step S26 that the count value Tn is equal to or less than Tb (no), the process proceeds to step S28.

  In step S27, the first display portion 82a is flashed in red at a cycle of 5 times / second (high-speed flashing), and then the process proceeds to step S29. In step S28, the first display unit 82a is flashed in red and at a cycle of 3 times / second (medium-speed flashing), and then the process proceeds to step S29.

  In step S29, the calculation unit 66 further determines whether or not the count value Tn by the timer unit 66b has reached a predetermined time Tc (60 seconds). If it is determined in step S29 that the count value Tn has reached Tc (yes), the process proceeds to step S30. On the other hand, if it is determined in step S29 that the count value Tn has not reached Tc (no), the process returns to step S26. In step S <b> 30, the calculation unit 66 stops the rotational drive of the electric motor 20. As a result, the continuous driving time of the electric motor 20 is set within a predetermined time (60 seconds), and overheating of the entire air compressor 10 due to the long-time rotation driving of the electric motor 20 at a difficult driving voltage is prevented. The

  As described above, in step S24 to step S30, the calculation unit 66 drives the electric motor 20 so that the driving time is limited to a predetermined time (60 seconds) when the input voltage is a driving difficulty voltage (AC 70 to 65 V range). Perform time limit control. Then, when the drive time limit control is performed, the calculation unit 66 changes the display content (notification content) of the first display unit 82a as the drive time elapses (30 seconds / 50 seconds have elapsed). The remaining operation time of the air compressor 10 is notified to the person. However, the predetermined time (60 seconds) and the time for changing the display contents (30 seconds / 50 seconds) can be arbitrarily set according to the specifications (heat resistance, etc.) of the air compressor 10.

  Here, the contents of the drive time limit control by the calculation unit 66 will be described in detail. As shown in the broken line graph of FIG. 8, when the input voltage is a driving difficulty voltage (AC 70 to 65 V), the calculation unit 66 increases the electric motor 20 when the detection value of the pressure sensor 71 increases to the third pressure set value P3. Stop. Thereby, the pressure rise in each air tank 11a, 11b is suppressed, and it does not become 3.20 [Mpa] or more. Then, when the use of the pneumatic tool is started at the work start point TP2, the compressed air in each air tank 11a, 11b is gradually consumed, and the pressure in each air tank 11a, 11b decreases. Thereafter, when the detection value of the pressure sensor 71 decreases to the fourth pressure set value P4, the calculation unit 66 restarts (drives) the electric motor 20. As a result, when the input voltage is a driving difficulty voltage, the pressure in each of the air tanks 11a and 11b is within the set pressure range (B).

  However, when the set pressure range (B) is set, the input voltage is a drive difficulty voltage (AC 70 to 65 V range), and therefore, the rotational drive of the electric motor 20 has the following time restrictions. Added. Specifically, as shown in FIG. 8, the use of the air tool is started at time t1 (work start point TP2), and the pressure in each air tank 11a, 11b is set to the fourth pressure setting at time t2. When the value decreases to the value P4, the calculation unit 66 restarts (drives) the electric motor 20.

  Thereafter, the time until time t3 (Ta in step S25) is 30 seconds. Until that time, the state in step S7 in FIG. 5 is maintained by the calculation unit 66, and the first display unit 82a The display content is “flashing red once / second”, and this is continuously notified to the operator.

  Thereafter, until 30 seconds elapse at time t3 and until time t4 (50 seconds at Tb in step S26) elapses, the calculation unit 66 changes the display content of the first display unit 82a to “red flashing 3 times / This is continuously reported to the worker as "second".

  Next, until 50 seconds have elapsed at time t4 and until time t5 (60 seconds at Tc (predetermined time) in step S29) has elapsed, the calculation unit 66 changes the display content of the first display unit 82a to “red”. This will continue to be reported to the operator as “blinking 5 times / second”.

  Note that the calculation unit 66 can cause the second display unit 83 to count down the remaining drive time of the electric motor 20 together with the display content (flashing red) of the first display unit 82a.

  As described in detail above, according to the air compressor 10 according to the present embodiment, when the operator inserts the plug 63a of the power cord 63 into the outlet 65a and power is supplied to the power source 62 from the outside, The voltage detection unit 69 automatically detects the input voltage input to the power supply unit 62, and the input voltage detected by the voltage detection unit 69 is lower than the normal voltage (AC 100 to 81V range) and is difficult to drive. The first display unit 82a displays a state in which the driveable voltage (AC80 to 71V range) is higher than (AC70 to 65V range). Therefore, the power supply environment can be grasped and notified before the operation of the air compressor 10, and the work efficiency can be greatly improved.

  In addition, according to the air compressor 10 in the present embodiment, the calculation unit 66 causes the first display unit 82a to display the notification content (predetermined according to the magnitude of the input voltage detected by the voltage detection unit 69) ( 5 (see step S3, step S5, and step S7 in FIG. 5), the control logic of the calculation unit 66 is not complicated.

  Furthermore, according to the air compressor 10 according to the present embodiment, the notification content of the first display unit 82a is the lighting of a light emitting diode (LED) having a different color or the blinking of a light emitting diode having a different speed. Therefore, the state (input voltage state) of the air compressor 10 can be made more conspicuous for the worker.

  Further, according to the air compressor 10 according to the present embodiment, when the input voltage is a driving difficulty voltage lower than the normal voltage and the drivable voltage, the pressure in each air tank 11a, 11b is set to “low pressure side”. Therefore, the electric motor 20 is driven to rotate so that the pressure in each air tank 11a, 11b falls within the set pressure range (B). As a result, the pneumatic tool can be used continuously to some extent, and as a result, work efficiency does not need to be significantly reduced.

  Furthermore, according to the air compressor 10 according to the present embodiment, when the input voltage is a driving difficulty voltage lower than the normal voltage and the drivable voltage, the driving time of the electric motor 20 is within a predetermined time (60 seconds). Since the driving time limit control is limited, it is possible to prevent the air compressor 10 from being burned due to overheating while the air compressor 10 is continuously driven.

  Further, according to the air compressor 10 according to the present embodiment, the calculation unit 66 changes the display content of the first display unit 82a as the drive time elapses when the drive time limit control is performed. Based on the above, the operator can use the air compressor 10 within a predetermined time or review the use environment of the air compressor 10. In this case, the calculation unit 66 gradually increases the blinking cycle of the first display unit 82a (light emitting diode), so that the operator can more easily grasp the remaining drive time of the air compressor 10.

  It goes without saying that the present invention is not limited to the above-described embodiment, and various modifications can be made without departing from the scope of the invention. For example, the air compressor 10 according to the above embodiment is a multistage air compressor including two cylinders and pistons, but the cylinder and piston may be one set or three or more sets.

DESCRIPTION OF SYMBOLS 10 Air compressor 11a, 11b Air tank 12 Base 13 Leg 14 Handle 15 Cover 16a, 16b Coupler 17a, 17b Pressure reducing valve 18a, 18a Pressure gauge 19a Safety valve 19b Drain device 20 Electric motor 21 Stator 22 Rotor 23 Rotating shaft 23a First 1 projecting portion 23b second projecting portion 24 position sensor 30 compression mechanism 40 crank case 41a first case portion 41b second case portion 50a first cylinder 50b second cylinder 51a first piston 51b second piston 52a first connecting rod 52b first Two connecting rods 53a, 53b Cylinder heads 54a, 54b Buffer chamber 55 First piping 56 Third piping 57 Cooling fan 60 Control board 61 Drive unit 62 Power source 63 Power cord 63a Plug 64 Cooling fan 65 AC power supply 65a outlet 66 arithmetic unit (motor control unit)
66a Threshold value storage unit 66b Timer unit 67 Motor current detection unit 68 Power supply current detection unit 69 Voltage detection unit 70 EEPROM
71 Pressure sensor 80 Operation panel 80a Panel main body 80b Engaging claw 80c Screw fixing part 81a Operation switch 81b Mode switch 82a First display part (voltage display part, light emitting diode)
82b to 82g First display section 83 Second display section 84 Operation panel substrate P1 First pressure set value P2 Second pressure set value P3 Third pressure set value P4 Fourth pressure set value

Claims (8)

An electric motor;
A compression mechanism driven by the electric motor;
A tank for storing air compressed by the compression mechanism;
An air compressor comprising:
A power supply for supplying a drive current to the electric motor;
The control to that control section a rotation of the electric motor,
A voltage detection unit that automatically detects an input voltage input to the power supply unit by supplying power from the outside to the power supply unit;
The input voltage detected by the voltage detecting section, and table radical 113 that displays the status is second voltage higher than the low and the third voltage than the first voltage to the outside,
I have a,
When the input voltage is the third voltage, the control unit performs a driving time limit control that limits a driving time of the air compressor within a predetermined time, and displays the display unit as the driving time elapses. contents of Ru by changing the, air compressor. One end of a power cord is connected to the power source,
A plug to be plugged into an outlet is provided at the other end of the power cord,
The voltage detection unit automatically detects the input voltage by inserting the plug into the outlet.
The air compressor according to claim 1. Before Symbol Table radical 113 displays a predetermined notification content in accordance with the magnitude of the input voltage detected by the voltage detecting section,
The air compressor according to claim 1 or 2. Notification content before Symbol Table radical 113 is at least either of the flashing light emitting diodes having different lighting and speed of the light-emitting diodes having different colors,
The air compressor according to claim 3. A pressure sensor for detecting the pressure in the tank is provided;
Before Symbol control section is,
When the input voltage is the first voltage and the second voltage, if the detected value of the pressure sensor rises to the first pressure set value, the electric motor is stopped, and the detected value of the pressure sensor reaches the second pressure set value. When lowered, the electric motor is driven,
When the input voltage is the third voltage, the electric motor is stopped when a detected value of the pressure sensor rises to a third pressure set value smaller than at least the first pressure set value;
The air compressor according to any one of claims 1 to 4. Before Symbol control section is,
When the input voltage is the third voltage, the electric motor is driven when the detected value of the pressure sensor decreases to a fourth pressure set value smaller than the second pressure set value;
The air compressor according to claim 5. The driving time of the air compressor is the driving time of the electric motor.
The air compressor according to claim 1. Before Symbol Table radical 113 is a light emitting diode,
Before SL control section, the faster the flashing cycle of the light emitting diode according to the drive time has elapsed,
The air compressor according to claim 1 .

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