JP2020118073A - Air compressor - Google Patents

Abstract

To prevent an abnormal motion of an air compressor when stability in installing the air compressor is low, as the compressor is easily oscillated by transmission of vibration of a compression mechanism in a case when the air compressor is disposed on an installation surface of low stability, or in a case when the stability is low in being carried, and the air compressor is preferably stopped to prevent the abnormal motion and to disable supply of compressed air, in a case when the air compressor is oscillated.SOLUTION: A stationary type air compressor 1 includes a compressed air generator 20 for generating compressed air, a tank 4 for storing the compressed air, a leg portion 3 for installation, a controller 40 for controlling start/stop of a function as the air compressor 1, and a vibration sensor 45 detecting vibration of the air compressor 1. The controller 40 stops the function as the air compressor 1 in a case when the vibration sensor 45 detects a vibration value out of the vibration value of a prescribed range.SELECTED DRAWING: Figure 2

Description

The present invention is, for example, an air compressor for supplying compressed air to tools such as a compressed air driven nailer and an air tacker, and is a stationary air compressor installed and used on an installation surface such as a floor or a workbench. Regarding compressors.

The air compressor described in Patent Document 1 includes an electric motor and a compression mechanism that generates compressed air. The compression mechanism includes a crank connected to the motor shaft of the electric motor, and a piston connected to the crank and capable of reciprocating in the cylinder. Compressed air is generated by starting the electric motor and reciprocating the piston in the cylinder via the crank. The generated compressed air is stored in a tank provided in the air compressor, and is supplied from the tank to tools such as a compressed air driven nailer and an air tacker. This type of air compressor is used by being installed on the installation surface such as a floor or a workbench.

When the air compressor is activated, the reciprocating motion of the piston causes vibration mainly from the compression mechanism. Citation 2 describes an air compressor that diagnoses a failure of the air compressor by comparing the vibration when the air compressor is functioning normally and the vibration detected by the detection means.

Japanese Patent Laid-Open No. 2012-112282 Patent No. 4455968

The vibration generated in the compression mechanism is transmitted to the legs supporting the tank and the air compressor. When the air compressor is placed on a highly stable installation surface, it is difficult for the air compressor to sway even when vibration is transmitted to the tank or legs. However, when the air compressor installation is not stable, such as when the air compressor is placed on an installation surface with low stability, or when the air compressor is carried around (when the installation surface is unstable or If the posture of the air compressor is unstable, or if the air compressor is in a suspended state where no air compressor is installed, etc.), it will occur in the compression mechanism even if it is functioning normally as an air compressor. The air compressor easily shakes due to the transmission of vibration. When the air compressor shakes, stop the air compressor and disable the compressed air supply to prevent abnormal or inadvertent operation of the air compressor or the external air tool to which the compressed air is supplied. Is desirable.

An object of the present invention is to prevent abnormal or careless operation of the air compressor when the installation stability of the air compressor is low.

According to one feature of the present disclosure, an air compressor is a stationary type, a compression mechanism that generates compressed air, a tank that stores the compressed air generated by the compression mechanism, a leg for installation, and the air. It has a controller that controls the start and stop of the function of the compressor. The air compressor includes a vibration detection unit that detects vibration of the air compressor. The controller stops the function as the air compressor when the vibration value detected by the vibration detecting means deviates from the vibration value in the predetermined range. Here, the function as an air compressor includes a function of supplying power from a battery or an AC power source, a function of generating compressed air in a compression mechanism, a function of storing the generated compressed air in a tank, or a compressed air stored in the tank. Includes a series of functions from the power supply to the compressed air being supplied to the external air tool, such as the supply function to send the compressed air to the external air tool. As a result, the function of the air compressor can be stopped. Further, the vibration value in the predetermined range includes not only the magnitude (absolute value) of the vibration value but also the number of times the vibration value is detected, the frequency, and the like.

Therefore, the threshold value of the vibration value is set to be larger than the vibration value detected by the vibration detection means when the air compressor is placed on a highly stable installation surface, for example. As a result, when the vibration value detected by the vibration detecting means becomes larger than the threshold value, that is, when the vibration value deviates from the vibration value in the predetermined range, it is determined that the stability of the air compressor is low, and the function as the air compressor is determined. It can be stopped. Therefore, it is possible to prevent abnormal or careless operation of the air compressor. Further, when the stability of the air compressor is high, the function as the air compressor can be continued. The vibration value threshold value may be set smaller than the vibration value detected by the vibration detecting means when the air compressor is placed on an installation surface having low stability or is carried.

According to another feature of the present disclosure, the controller stops the function as the air compressor when the amplitude of the vibration detected by the vibration detecting means deviates from the amplitude value in the predetermined range.

Therefore, the threshold value of the vibration amplitude is set to be larger than the amplitude detected by the vibration detecting means when the air compressor is placed on a highly stable installation surface, for example. As a result, when the amplitude of the vibration detected by the vibration detecting means becomes larger than the threshold value, that is, when the amplitude is out of the predetermined range, it is determined that the stability of the air compressor is low, and the function as the air compressor is determined. It can be stopped. Therefore, it is possible to prevent abnormal operation such as swaying of the air compressor.

According to another feature of the disclosure, the vibration detection means is provided on the tank or the leg.

Therefore, when the stability of the air compressor is low, the vibration detecting means is installed in the tank or the leg portion in which the vibration is apt to cause an abnormal operation such as shaking of the air compressor. This makes it easy to prevent abnormal operation of the air compressor.

According to another feature of the present disclosure, an air compressor is a stationary type, and includes a compression mechanism that generates compressed air, a tank that stores the compressed air generated by the compression mechanism, a leg for installation, and the air. It has a controller that controls the start and stop of the function of the compressor. The air compressor includes an inclination detection unit that detects the inclination of the air compressor with respect to the installation surface. The controller stops the function as the air compressor based on the tilt angle detected by the tilt detecting means.

Therefore, based on the tilt angle detected by the tilt detecting means, when the controller determines that the stability of the air compressor is low, for example, when the installation surface of the air compressor is unstable or when the air compressor sways, Stops the function as an air compressor. As a result, it is possible to prevent abnormalities or inadvertent operation of the air compressor. Also, if the controller determines that the stability of the air compressor is high, for example, if the detected tilt angle is sufficiently small and the installation surface of the air compressor is stable, the function as the air compressor should be continued. You can

According to another feature of the present disclosure, the controller stops the function as the air compressor when the tilt angle detected by the tilt detecting means is out of the predetermined angle range. Here, the predetermined angle range includes not only the magnitude (absolute value) of the tilt angle, but also the number of times the tilt angle is detected, the frequency, and the like.

Therefore, for example, the threshold value of the tilt angle is set to be larger than the tilt angle detected by the tilt detecting means when the air compressor is placed on a highly stable installation surface. As a result, when the tilt angle detected by the tilt detection unit becomes larger than the threshold value, that is, when the tilt angle deviates from the tilt angle within the predetermined range, it is determined that the stability of the air compressor is low, and the function as the air compressor is determined. It can be stopped. Therefore, it is possible to prevent the air compressor from sliding and swaying on the installation surface having a relatively large inclination angle, and it is possible to prevent abnormal operation of the air compressor.

According to another feature of the present disclosure, the controller stops the function as the air compressor when the change amount of the tilt angle detected by the tilt detection means is out of the predetermined angle range.

Therefore, the threshold value of the swing amplitude (the amount of change in the tilt angle) is set to be larger than the swing amplitude detected by the tilt detecting means when the air compressor is placed on a highly stable installation surface. As a result, when the sway amplitude detected by the inclination detecting means becomes larger than the threshold value, that is, when the sway amplitude deviates from the sway amplitude within a predetermined range, it is determined that the stability of the air compressor is low, and the function as the air compressor is determined. It can be stopped. Therefore, it is possible to prevent abnormal operation such as swaying of the air compressor.

According to another feature of the present disclosure, the tilt detecting means is a gyro sensor, and the tilt detecting means is provided on a substrate included in the controller.

Therefore, it is possible to enhance the assembling property when electrically connecting the tilt detecting means (gyro sensor) to the controller.

According to another feature of the disclosure, the air compressor is powered by a DC power source.

Therefore, by attaching a DC power source such as a rechargeable battery that can be repeatedly charged to the air compressor to supply power, the air compressor can be used even when the work place is away from the AC power source.

It is the whole air compressor perspective view concerning the present invention. It is the perspective view which removed the housing of the air compressor which concerns on 1st Embodiment. It is a right side view of the air compressor which concerns on 1st Embodiment, and is a one part longitudinal cross-sectional view. It is a block diagram which shows typically control of the air compressor which concerns on 1st Embodiment. It is a flow chart which shows the flow which stops the function as an air compressor based on the detection of the vibration sensor concerning a 1st embodiment. It is a perspective view which removed the housing of the air compressor which concerns on 2nd Embodiment. It is a right view of the air compressor which concerns on 2nd Embodiment, and is a one part longitudinal cross-sectional view. It is a block diagram which shows typically control of the air compressor which concerns on 2nd Embodiment. It is a flowchart which shows the flow which stops the function as an air compressor based on the detection of the attitude sensor which concerns on 2nd Embodiment.

Next, a first embodiment of the present invention will be described based on FIGS. As shown in FIGS. 1 to 3, a stationary air compressor 1 includes a housing 2 that covers the entire body and one horizontally elongated tank 4 that can store compressed air. On the lower surface side of the tank 4, a pair of left and right installation leg portions 3 is provided at both ends in the longitudinal direction of the tank 4, and a total of four leg portions 3 are provided. When the air compressor 1 is installed on the installation surface F such as a floor or a workbench, the air compressor is supported by the four legs 3. A discharge port 34 communicating with the tank 4 is provided above the tank 4. An air hose can be connected to the discharge port 34. Compressed air can be supplied from the tank 4 to a tool driven by compressed air, such as a nailing machine, via the connected air hose. In the following description, the vertical direction is defined by the posture in which the air compressor 1 is installed with the leg portion 3 on the lower side. Further, with the ejection port 34 as the front side, the front, rear, left, and right directions are defined on the basis of the time when viewed from the user located on the front side.

As shown in FIGS. 2 and 3, the air compressor 1 includes a compressed air generator (compression mechanism) 20 above the tank 4. The compressed air generation unit 20 includes an electric motor 16 that is a drive source and a piston 24 that compresses the drawn outside air. The electric motor 16 is housed in the motor housing 15 with the motor shaft 16a extending forward. A drive gear 16b and a cooling fan 16c are integrally attached to the motor shaft 16a. A driven gear 18b of a reduction unit 18 housed in a gear housing 17 meshes with the drive gear 16b. The driven gear 18b is provided integrally with the output shaft 18a that is rotatably supported by the gear housing 17. The front part of the output shaft 18a enters into the crank housing 21, and the crank disk 22 is attached to the front part. The crank disk 22 is provided with a crank shaft 22a that is eccentric with respect to the output shaft 18a. A base end portion of a crank rod 23 is supported by the crank shaft 22a so as to be relatively rotatable. A piston 24 is attached to the tip of the crank rod 23. A cylinder 25 extending vertically is hermetically attached to the upper portion of the crank housing 21. The piston 24 is supported in the cylinder 25 so as to be capable of reciprocating in an airtight manner. The upper piston chamber above the cylinder 25 communicates with the ventilation pipe 26. The ventilation pipe 26 communicates with the inside of the tank 4.

When the electric motor 16 is activated, the rotational output of the electric motor 16 is decelerated by the engagement of the drive gear 16b and the driven gear 18b. The decelerated rotation output rotates the crank disk 22 via the output shaft 18a. When the crank disk 22 rotates, the crankshaft 22a revolves around the output shaft 18a. As a result, the crank rod 23 moves up and down, and the piston 24 reciprocates up and down in the cylinder 25. By the reciprocating movement of the piston 24, the outside air is supplied to the piston upper chamber of the cylinder 25 to generate compressed air. The generated compressed air is supplied into the tank 4 via the ventilation pipe 26.

As shown in FIGS. 2 and 3, a compressed air supply unit 30 is provided at the front of the air compressor 1. The compressed air supply unit 30 includes a pressure adjusting unit 31, a pressure adjusting dial 32, a meter 33, and a discharge port 34. The pressure adjusting dial 32 and the meter 33 are exposed at the upper part. The pressure adjusting dial 32 is supported so that the user can rotate it. The discharge port 34 projects forward from the front end of the housing 2. The pressure adjusting unit 31 is provided in the middle of the path where the inside of the tank 4 and the discharge port 34 communicate with each other. When the pressure adjusting dial 32 is rotated, the pressure adjusting unit 31 can reduce the pressure of the compressed air in the tank 4 and supply the compressed air to the discharge port 34. The pressure of the compressed air reduced by the pressure adjusting unit 31 is displayed on the meter 33.

As shown in FIGS. 2 and 3, at the rear portion of the air compressor 1, a battery mounting portion 12 to which a battery 13 that supplies power to the electric motor 16 can be attached and detached is provided. The battery 13 can be repeatedly used by removing it from the battery mounting portion 12 and charging it with a separately prepared charger. The battery 13 can be reused as a DC power source with other rechargeable electric tools such as a screw tightener and an electric drill. The power supply from the battery 13 attached to the battery attachment portion 12 to the electric motor 16 is controlled by the power supply controller 10 and the controller 40.

As shown in FIGS. 1 and 2, the power supply control unit 10 controls power supply from the battery 13 to various electric material components such as the electric motor 16, the controller 40, and an electromagnetic valve 36 described later. The power supply control unit 10 includes a push button 11 that can be pushed from the outside of the housing 2. By pressing the push button 11 when the power supply from the battery 13 is in the off state, the power supply is switched to the on state. When the power supply from the battery 13 is on, the push button 11 is pressed to switch the power supply to the off state.

As shown in FIGS. 2 and 3, the air compressor 1 contains a controller 40. As shown in FIG. 4, the controller 40 is configured by housing a controller board 40b in a shallow box-shaped rectangular controller case 40a. The controller board 40b includes a microcomputer (microprocessor) 41 that controls the electric motor 16 and the like, an FET circuit 42 that switches the current of the electric motor 16 based on a control signal received from the microcomputer 41, and the like. As shown in FIG. 3, the controller 40 is arranged beside the cooling fan 16c. The cooling fan 16c is rotated by the rotation of the motor shaft 16a, and cooling air is generated. The cooling air cools the controller 40 located downstream of the cooling fan 16c while cooling the electric motor.

As shown in FIGS. 2 and 3, a pressure sensor 5 is provided on the side of the tank 4. The pressure sensor 5 detects whether the pressure in the tank 4 has reached a set pressure and is in a full state or less than the set pressure. When it is detected that the pressure in the tank 4 has reached the set pressure, the controller 40 stops the electric motor 16 and enters the standby state. When it is detected that the pressure in the tank 4 is less than the set pressure, the controller 40 restarts the electric motor 16 or continues the starting state.

As shown in FIGS. 1 and 2, a drain cock 6 for draining water and a drain discharge port 6a are provided on the lower side of the tank 4. The drain discharge port 6a communicates with the inside of the tank 4 and opens slightly downward. The drain cock 6 opens and closes the drain outlet 6a by rotating. When the air compressor 1 is used, it is used with the drain cock 6 closed. When the drain cock 6 is opened, the drain (water) and the compressed air accumulated in the tank 4 are discharged from the drain discharge port 6a according to the opening amount.

As shown in FIGS. 2 and 3, a compressed air discharge means 35 is provided at the front part of the tank 4. The compressed air discharge means 35 includes an electromagnetic valve 36 and a discharge pipe 37. The discharge pipe 37 communicates with the inside of the tank 4 via the electromagnetic valve 36. The electromagnetic valve 36 is electrically connected to the battery 13 and the controller 40, and is opened and closed by electric power supplied from the battery 13 under the control of the controller 40. When the electromagnetic valve 36 is closed, the compressed air in the tank 4 is not discharged from the discharge pipe 37. When the electromagnetic valve 36 is open, the compressed air in the tank 4 is discharged from the discharge pipe 37.

As shown in FIGS. 1 and 2, a handle 7 is provided above the air compressor 1. The handle 7 has a loop shape protruding upward from the upper surface of the housing 2. The handle 7 is a grip portion when a user carries the air compressor 1. A support shaft 7b is inserted in each of the front and rear bases of the handle 7 so as to extend in the left-right direction. The handle 7 is supported by the housing 2 by a support shaft 7b.

As shown in FIG. 3, one front belt mounting portion 7a and one rear belt mounting portion 7a are provided. The belt mounting portion 7a is formed with a recessed portion that opens upward and a column portion that extends in the left-right direction inside the recessed portion and that has both ends supported by the handle 7. A shoulder belt 8 having annular portions at both ends can be attached to the belt attaching portion 7a. The user can carry the air compressor 1 by hanging the shoulder belt 8 on the shoulder in a state in which the shoulder belt 8 is mounted between the pair of front and rear belt mounting portions 7a.

As shown in FIGS. 2 and 3, the vibration sensor (vibration detection means) 45 is attached to the side portion of the tank 4. As shown in FIG. 4, the vibration sensor 45 is electrically connected to the controller 40. The vibration sensor 45 detects an amplitude A at which the vibration sensor 45 vibrates. The vibration detected by the vibration sensor 45 is due to, for example, the vibration due to the reciprocating movement of the piston 24 being propagated to the tank 4. Alternatively, the vibration detected by the vibration sensor 45 is, for example, shaking of the compressor 1 when the user holds the handle 7 and carries the compressor 1. The vibration sensor 45 is not limited to the tank 4, but when the installation of the air compressor 1 is unstable (when the installation surface F is unstable, or the attitude of the installed air compressor 1 is unstable, or the air compressor 1 is not stable). It may be provided at a place where vibration is particularly likely to occur when the equipment is suspended without being installed. The vibration sensor 45 may be attached to the leg portion 3, for example.

The controller 40 performs vibration detection and operation control according to the flow shown in FIG. When the power supply controller 10 is turned on in step (hereinafter abbreviated as ST) 01, first, the measurement time T and the count number C are initialized (ST02). After waiting for a predetermined time, for example, 10 milliseconds (ST03), the vibration sensor 45 acquires the amplitude A (ST04). Next, it is determined whether the amplitude A detected by the vibration sensor 45 is larger or smaller than the amplitude threshold At (ST05). The amplitude threshold At is based on, for example, the amplitude A detected by the vibration sensor 45 when the air compressor 1 is placed on the installation surface F having high stability such that the mounted air compressor 1 does not shake. It is set in advance.

Next, the controller 40 measures the number of times the amplitude A equal to or larger than the threshold value At is detected within the predetermined time Tt. The detection by the vibration sensor 45 is performed at intervals of a predetermined time waiting in ST03. When the amplitude A equal to or larger than the threshold value At is detected within the predetermined time Tt, the count number C is incremented by 1 (ST06). When the amplitude A is smaller than the threshold value At, the count number C is not increased.

Next, it is determined whether or not the measurement time T is within a predetermined time Tt (ST07). When the measurement time T exceeds the predetermined time Tt, the flow is returned to ST02. When the measurement time T is within the predetermined time Tt, it is next determined whether or not the count number C is equal to or more than the threshold value Ct (ST08). When the count C becomes equal to or more than the threshold value Ct within a predetermined time Tt, for example, 2 seconds, the controller 40 immediately stops the function as the air compressor 1 and disables the air compressor 1 ( ST09). The threshold value Ct may be 1, and in that case, the controller 40 immediately stops the function as the air compressor 1 when the count C increases by 1 within the predetermined time Tt (ST06). .. If the count C does not exceed the threshold value Ct within the predetermined time Tt, the flow is returned to ST03 and the function as the air compressor 1 is continued without stopping.

The air compressor 1 has one or more configurations that stop the function of the air compressor 1. Here, the function as the air compressor 1 includes a function of supplying power from the battery 13 to the electric motor 16 via the power supply control unit 10, a function of the controller 40 controlling the electric motor 16, and a driving of the electric motor 16. The function of generating compressed air in the compressed air generator 20, the function of storing the generated compressed air in the tank 4, and the function of storing the compressed air in the tank 4 to an external air tool via the compressed air supply unit 30. It includes a series of functions such as a supply function of sending power from the battery 13 and supplying compressed air to an external air tool, and by stopping a part or one of these functions, The function of the air compressor 1 can be stopped.

One of the configurations for stopping the function of the air compressor 1 is a configuration for stopping the rotation of the electric motor 16. As shown in FIG. 4, the electric motor 16 is electrically connected to the controller 40. As shown in FIG. 5, when the vibration sensor 45 detects the amplitude A equal to or larger than the threshold value At at the frequency of exceeding the threshold value Ct within the predetermined time Tt, the controller 40 stops the electric motor 16. As a result, the vertical reciprocating movement of the piston 24 shown in FIG. 3 is stopped, and the generation of compressed air in the compressed air generating unit 20 is stopped.

One of the configurations for stopping the function of the air compressor 1 is a configuration for cutting off the power supply from the battery 13 to the electric motor 16. As shown in FIG. 4, the power supply controller 10 is electrically connected to the controller 40. As shown in FIG. 5, when the vibration sensor 45 detects the amplitude A equal to or larger than the threshold value At at the frequency of exceeding the threshold value Ct within the predetermined time Tt, the controller 40 transfers the battery 13 to the electric motor 16. While the power supply is cut off, the supply state of the power control unit 10 is switched to the off state. As a result, the rotation of the electric motor 16 and the vertical reciprocating motion of the piston 24 shown in FIG. 3 are stopped, and the generation of compressed air in the compressed air generating unit 20 is stopped. Generation of compressed air is restarted by pressing the push button 11 again to restart the compressed air generation unit 20. When the vibration sensor 45 detects the amplitude A equal to or larger than the threshold value At with a frequency exceeding the threshold value Ct within the predetermined time Tt, that is, when the air compressor 1 is apt to sway and the unstable installation state is not resolved. The power supply from the battery 13 to the electric motor 16 is cut off again.

One of the configurations for stopping the function of the air compressor 1 is a configuration in which the electromagnetic valve 36 is opened to discharge the compressed air in the tank 4 from the exhaust pipe 37 to the atmosphere. As shown in FIG. 4, the electromagnetic valve 36 is electrically connected to the controller 40 and the battery 13. As shown in FIG. 5, when the vibration sensor 45 detects the amplitude A equal to or larger than the threshold value At with the frequency exceeding the threshold value Ct within the predetermined time Tt, the controller 40 shifts from the battery 13 to the electromagnetic valve 36. Power is supplied, which causes the solenoid valve 36 to open. Therefore, the compressed air in the tank 4 shown in FIG. 2 is not supplied to the compressed air supply unit 30, but is discharged to the atmosphere from the discharge pipe 37. When the number of times that the vibration sensor 45 detects the amplitude A equal to or larger than the threshold value At is smaller than the threshold value Ct within the predetermined time Tt, the controller 40 does not supply the electric power from the battery 13 to the electromagnetic valve 36. The electromagnetic valve 36 remains closed, and the operating state of the air compressor 1 is continued.

As shown in FIG. 5, the notification means 43 informs the user that the vibration sensor 45 has detected the amplitude A equal to or larger than the threshold value At within a predetermined time Tt, that is, the frequency A exceeds the threshold value Ct, that is, the air compressor 1. Is informed that the air compressor is swaying and the installation state is unstable, and that the function of the air compressor 1 is stopped. The notification means 43 shown in FIG. 4 is, for example, a buzzer incorporated in the controller 40. When the vibration sensor 45 detects the amplitude A that is equal to or larger than the threshold value At with the frequency that exceeds the threshold value Ct within the predetermined time Tt, the notification means 43 generates a sound. As a result, the air compressor 1 is liable to sway such as being placed on the installation surface F with low stability or being carried, and the installation state is unstable, and the function as the air compressor 1 is stopped. Can be notified to the user.

According to the air compressor 1 described above, the controller 40 determines the installation stability of the air compressor 1 based on the amplitude A of the vibration detected by the vibration sensor 45, and detects the amplitude A equal to or greater than the threshold value At. The function of the air compressor 1 is stopped. Therefore, the amplitude threshold At is set to be larger than the amplitude A detected by the vibration sensor when the air compressor 1 is placed on the installation surface F having high stability such as a fixed workbench or a hard ground. .. Accordingly, when the amplitude A detected by the vibration sensor 45 becomes larger than the threshold value At, it is determined that the installation stability of the air compressor 1 is low, and the function of the air compressor 1 can be stopped. Therefore, it is possible to prevent abnormal or careless operation such as the air compressor 1 swinging. When the installation stability of the air compressor 1 is high, the function of the air compressor 1 can be continued.

Further, according to the air compressor 1, the vibration sensor 45 is provided in the tank 4. Therefore, when the stability of the installation of the air compressor 1 is low, the vibration sensor 45 is installed in the tank 4 or the leg portion 3 in which an abnormal operation such as the vibration of the air compressor 1 is likely to occur due to the transmission of vibration. This makes it easy to prevent abnormal operation of the air compressor 1.

Further, according to the air compressor 1, power is supplied from the battery 13 which is a DC power source. The battery 13 can be repeatedly charged and can be attached to and detached from the battery attaching portion 12. Therefore, the air compressor 1 can be used even when the work place is away from the AC power source, for example.

Next, a second embodiment of the present invention will be described based on FIGS. The stationary air compressor 50 of the second embodiment includes an attitude sensor (inclination detection means) 51 called a gyro sensor, instead of the vibration sensor 45 of the air compressor 1 of the first embodiment. In the following description, only the configuration different from the air compressor 1 of the first embodiment will be described in detail.

As shown in FIGS. 6 to 8, the attitude sensor 51 is housed in the controller case 40a of the controller 40 and provided on the controller board 40b. The attitude sensor 51 is electrically connected to the microcomputer 41 of the controller 40. The attitude sensor 51 detects the tilt angle B of the attitude sensor 51 with reference to the direction of gravity.

As shown in the flowchart of FIG. 9, the controller 40 turns on the power supply control unit 10 (ST21), initializes the measurement time T and the count number C (ST22) (at the start of the measurement), and then detects the attitude sensor 51. The tilt angle initial value B0 detected by is acquired (ST23). The controller 40 determines whether the acquired tilt angle initial value B0 is larger or smaller than the threshold value Bt of the tilt angle initial value (ST24). The threshold value Bt of the initial value of the tilt angle is set in advance, for example, on the basis of the installation surface F having a relatively small tilt angle such that the mounted air compressor 50 does not slide or rock. When the tilt angle initial value B0 is equal to or more than the threshold value Bt of the tilt angle initial value, the controller 40 immediately stops the function as the air compressor 50 and disables the air compressor 50 (ST32). When the tilt angle initial value B0 is smaller than the threshold value Bt of the tilt angle initial value, the function of the air compressor 1 is continued without stopping, and after a predetermined time, for example, 10 milliseconds standby (ST25), the posture sensor 51 is operated. Then, the process proceeds to the step (ST26, 27) of acquiring the swing amplitude D of.

Next, the controller 40 acquires the tilt angle B detected by the attitude sensor 51 (ST26), and based on the difference between the tilt angle B and the previously acquired tilt angle initial value B0, the swing amplitude of the attitude sensor 51 (the tilt angle The change amount D is acquired (ST27). The controller 40 determines whether the swing amplitude D is larger or smaller than the swing amplitude threshold Dt (ST28). The shake amplitude threshold value Dt is, for example, the shake amplitude D detected by the attitude sensor 51 when the air compressor 50 is placed on the installation surface F having high stability such that the mounted air compressor 50 does not slide or shake. Is preset based on

Next, the controller 40 measures the number of times that the swing amplitude D equal to or larger than the threshold value Dt is detected within the predetermined time Tt. The detection by the attitude sensor 51 is performed at predetermined time intervals waiting in ST25. When the swing amplitude D equal to or larger than the threshold value Dt is detected within the predetermined time Tt, the count number C is incremented by 1 (ST29). When the swing amplitude D is smaller than the threshold value Dt, the count number C is not increased. Next, it is determined whether or not the measurement time T is within a predetermined time Tt (ST30). When the measurement time T is within the predetermined time Tt and the count C becomes equal to or more than the threshold value Ct within the predetermined time Tt, for example, 2 seconds (ST31), the controller 40 functions as the air compressor 50. The air compressor 50 is immediately stopped and the air compressor 50 is disabled (ST32). The threshold value Ct may be 1, and in that case, the controller 40 immediately stops the function as the air compressor 50 when the count C increases by 1 within the predetermined time Tt (ST29). .. When the count time C does not exceed the threshold value Ct and the predetermined time Tt has elapsed, the flow is returned to ST22, the measurement time T and the count time C are initialized, and the function as the air compressor 1 is stopped. Continue without. After that, in the flow, a new tilt angle initial value B0 is newly acquired (ST23), and the step of comparing the tilt angle initial value B0 and the threshold value Bt (ST24) is executed again.

The air compressor 50 has one or more configurations that stop the function of the air compressor 50. Similar to the function as the air compressor 1 according to the first embodiment, the function as the air compressor 50 includes a series of functions until the power is supplied from the battery 13 and the compressed air is supplied to the external air tool. The function as the air compressor 50 can be stopped by stopping a part or one of these functions. The configuration for stopping the function of the air compressor 50 is the same as the configuration included in the air compressor 1 according to the first embodiment.

According to the air compressor 50 described above, the controller 40 determines the installation stability of the air compressor 50 based on the inclination angle B of the inclination detected by the attitude sensor 51 (ST24), and determines that the inclination angle is equal to or greater than the threshold value Bt. Based on this, the function of the air compressor 50 is stopped (ST32). In particular, the inclination angle initial value B0 acquired at the beginning of the measurement time is compared with the inclination angle initial value threshold value Bt (ST24), and the function of the air compressor 50 is stopped. Therefore, when the air compressor 50 is placed on a highly stable installation surface F such as a workbench whose upper surface is substantially horizontal or a roof with a small inclination angle, the inclination sensor threshold Bt is set as the attitude sensor 51. Is set to be larger than the tilt angle B detected by. As a result, when the initial angle value B0 detected by the attitude sensor 45 becomes larger than the threshold value Bt, that is, when the installation surface F is an inclined surface having a relatively large inclination angle of the threshold value Bt or more, the air compressor. It is determined that the stability of the installation of 50 is low, and the function as the air compressor 50 is stopped. As a result, it is possible to prevent the air compressor 50 from sliding or swinging on an inclined surface with low installation stability, and it is possible to prevent abnormal operation of the air compressor 50. When the installation stability of the air compressor 50 is high, the function of the air compressor 50 can be continued.

Further, according to the air compressor 50, the controller 40 determines the stability of the installation of the air compressor 50 by the swing amplitude D of the inclination detected by the attitude sensor 51 (ST28), and based on the swing amplitude of the threshold value Dt or more. Then, the function as the air compressor 50 is stopped (ST32). Therefore, the threshold value Dt of the swing amplitude is set to be larger than the swing amplitude D detected by the attitude sensor 51 when the air compressor 50 is placed on the installation surface F having high stability. Accordingly, when the swing amplitude D detected by the attitude sensor 45 becomes larger than the threshold value Dt, it is determined that the installation stability of the air compressor 50 is low, and the function of the air compressor 50 can be stopped. Therefore, it is possible to prevent abnormal operations such as the air compressor 50 swinging. The abnormal operation of the air compressor 50 can be prevented. When the installation stability of the air compressor 50 is high, the function of the air compressor 50 can be continued.

In the above-described embodiment, the threshold value Dt of the swing amplitude D and the threshold value C of the count number C are set independently, but a plurality of threshold values Dt and threshold values Ct are provided and associated with each other. Then, the threshold value Ct may be set according to the value of the threshold value Dt. For example, the threshold value Ct is set to 3 for the threshold value Dt of 2°, and the threshold value Ct is set to 2 for the threshold value Dt of 3°. At this time, when the swing amplitude D of 3° or more is detected twice within the predetermined time Tt, the controller 40 functions as the air compressor 50 even if the swing amplitude D of 2° or more is detected less than three times. To stop. Further, when the swing amplitude D of 2° or more and less than 3° is detected twice within the predetermined time Tt, the swing amplitude D of 3° or more is detected less than twice, so the function as the air compressor 50 continues. To do.

Further, according to the air compressor 50, the attitude sensor 51 is a gyro sensor, and is provided on the controller board 40b included in the controller 40. Therefore, it is possible to improve the assemblability when electrically connecting the attitude sensor 51 to the controller 40.

Various modifications can be added to the air compressors 1 and 50 of the first and second embodiments described above. For example, the plurality of configurations for stopping the functions of the air compressors 1 and 50 described above can be used alone or in combination. The present invention is also applied to the case where the number of tanks 4 and the number of legs 3 provided are different from those of the air compressors 1 and 50, and the case where the positional relationship between the tank 4 and the compressed air generator 20 and the like is different from that of the air compressors 1 and 50. be able to. Instead of the detachable battery 13 and the battery mounting portion 12, a built-in battery may be provided. The notification means 43 may be, for example, a light source that visually notifies instead of a buzzer or the like that notifies by sound.

For example, the vibration sensor 45 may detect the acceleration of vibration and determine the stability of the installation of the air compressor 1 from the acceleration of vibration. Instead of the posture sensor 51, for example, an acceleration sensor that detects an acceleration that changes the swing amplitude may be used to determine the stability of the installation of the air compressor 50 from the acceleration that changes the swing amplitude. The installation location of the vibration sensor 45, the attitude sensor 51, or the controller 40 equipped with the attitude sensor 51 is not limited to the illustrated location, but may be changed as appropriate as long as the location is easy to shake when the installation stability of the air compressor 1 is low. It may be, for example, below the tank 4. The series of configurations from the detection of the vibration sensor 45 and the attitude sensor 51 to the stop of the functions of the air compressors 1 and 50 are not limited to the case where the installation stability of the air compressors 1 and 50 is low. , 50 can also be used as a means for determining abnormal vibration due to a failure or the like, and abnormal operation of the air compressors 1, 50 due to the failure or the like can be prevented.

1... Air compressor (first embodiment)
2... Housing 3... Legs 4... Tank 5... Pressure sensor 6... Drain cock, 6a... Drain discharge port 7... Handle, 7a... Belt mounting part, 7b... Spindle 8... Shoulder belt 10... Power control part 11... Push Button 12... Battery mounting portion 13... Battery 15... Motor housing 16... Electric motor, 16a... Motor shaft, 16b... Drive gear, 16c... Cooling fan 17... Gear housing 18... Reduction gear part, 18a... Output shaft, 18b... Follower gear 20... Compressed air generator (compression mechanism)
21... Crank housing 22... Crank disk, 22a... Crank shaft 23... Crank rod 24... Piston 25... Cylinder 26... Vent pipe 30... Compressed air supply section 31... Pressure adjusting section 32... Pressure adjusting dial 33... Meter 34... Exhaust Outlet 35... Compressed air discharging means 36... Electromagnetic valve 37... Discharge pipe 40... Controller, 40a... Controller case, 40b... Controller board (board)
41... Microcomputer (microprocessor), 42... FET circuit, 43... Notification means 45... Vibration sensor (vibration detection means)
50... Air compressor (second embodiment)
51... Attitude sensor (inclination detecting means)
F...Installation surface

Claims (8)

A stationary type that includes a compression mechanism that generates compressed air, a tank that stores the compressed air generated by the compression mechanism, a leg for installation, and a controller that controls the start and stop of the function of the air compressor. An air compressor,
A vibration detecting means for detecting the vibration of the air compressor,
An air compressor, wherein the controller stops the function as the air compressor when the vibration value detected by the vibration detecting means deviates from a vibration value within a predetermined range. The air compressor according to claim 1, wherein
An air compressor in which the controller stops the function as the air compressor when the amplitude of the vibration detected by the vibration detecting means deviates from an amplitude value within a predetermined range. The air compressor according to claim 1 or 2, wherein
The vibration detecting means is an air compressor provided in the tank or the leg portion. A stationary type that includes a compression mechanism that generates compressed air, a tank that stores the compressed air generated by the compression mechanism, a leg for installation, and a controller that controls the start and stop of the function of the air compressor. An air compressor,
Equipped with inclination detection means for detecting the inclination of the air compressor with respect to the installation surface,
The controller is an air compressor that stops the function as the air compressor based on the tilt angle detected by the tilt detecting means. The air compressor according to claim 4,
The controller is an air compressor that stops the function as the air compressor when the tilt angle detected by the tilt detecting means is out of a predetermined angle range. The air compressor according to claim 4 or 5, wherein
An air compressor, wherein the controller stops the function as the air compressor when the amount of change in the tilt angle detected by the tilt detecting means is out of a predetermined angle range. The air compressor according to any one of claims 4 to 6,
The said inclination detection means is a gyro sensor, The air compressor which provided this inclination detection means in the board|substrate with which the said controller is equipped. The air compressor according to any one of claims 1 to 7,
An air compressor powered by a DC power supply.

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