JP2019073995A5 - - Google Patents

Description

Vacuum pump

The present invention relates to a vacuum pump for evacuating the inside of a pipe.

Conventionally, there are vacuum pumps for various purposes. The vacuum pump disclosed in Japanese Patent Application Laid-Open No. 2008-18098 is a vacuum pump that evacuates the piping of the refrigerant of the air conditioner, and the secondary battery that is the power source of the electric motor that drives the pump is detachably attached. It has a possible battery mount. As a result, the vacuum pump is formed so that a secondary battery, that is, a battery can be used without taking power from a commercial power source.

JP-A-2008-18098

The work of evacuation performed by the above-mentioned vacuum pump is to fill the inside of the air conditioner pipe with a refrigerant, so that the inside of the pipe is evacuated. Creating a vacuum cannot be done abruptly, but takes some time.
Here, for example, when one or two air conditioners are installed in a facility such as a single-family house, the length of the piping can be shortened, so that the above vacuum pump can be evacuated with a sufficient margin with one battery. It can be carried out.
However, for example, a facility such as a building is larger than a facility such as the above-mentioned single-family house, and when an air conditioner is attached to the facility, the length of the piping is relatively long, so that the work time for evacuation becomes long. .. Therefore, the battery may run out during the work. In response to this problem of running out of battery during work, if the battery is simply enlarged or increased in capacity, the battery dedicated to the vacuum pump will not be versatile, and it will be heavy and inconvenient to carry, which may make it difficult to use. ..

Therefore, an object to be solved by the present invention is to provide a vacuum pump capable of stable continuous operation for a long time by using a commercially available general-purpose battery.

The vacuum pump according to claim 1 is a vacuum pump for evacuating.
The vacuum pump is the pump body and
The motor that drives the pump body and
A power supply unit that supplies power to the motor and has multiple batteries ,
Consists of
To the power supply unit that electrically connects the selected battery and the motor among the plurality of batteries.
When the remaining battery level of one of the above batteries becomes less than a predetermined threshold value
From the battery of the one, it provided a switching control means for controlling said remaining battery capacity is switched to sufficient other of said battery,
The switching control means, in response to the battery remaining amount of the battery, characterized by being configured to sequentially switch the electrical connection of the said motor battery.

In the invention of claim 1, the vacuum pump according to claim 2 is provided with a battery remaining amount detecting means for detecting the remaining battery level of the battery in the power supply unit.
The battery remaining amount of one of the batteries detected by the battery remaining amount detecting means is compared with the threshold value by the switching control means.
When the remaining battery level of one of the batteries is less than the threshold value,
The switching control means is configured to automatically switch to another battery having a sufficient remaining battery level.

The vacuum pump according to claim 3 has, in the invention according to claim 2, that the battery remaining amount detecting means has a plurality of battery remaining amount detecting circuits facing each of the plurality of the batteries. It is a feature.

The vacuum pump according to claim 4 is provided with a battery holder in which a plurality of the batteries can be detachably attached to the power supply unit in the invention according to claim 3.
The battery holder is characterized by having the switching control means and the battery remaining amount detecting means.

In the invention of claim 4, the vacuum pump according to claim 5 has a holder-side interface portion and a battery-side interface portion formed so as to be capable of bidirectional communication with each other at positions where the battery holder and the battery face each other. Provide,
The battery remaining amount detecting means detects the battery remaining amount of the battery based on the measurement data relating to the impedance of the battery transmitted from the holder side interface part to the battery side interface part. And.

The vacuum pump according to claim 6 is characterized in that, in the invention according to claim 4, the battery holder has a plurality of slots into which a plurality of the batteries are mounted so as to face each other.

In the invention of claim 4, the vacuum pump according to claim 7 is provided with a plurality of switches in which a plurality of the batteries are electrically connected to the motor, respectively, in the battery holder.
The switching control means controls on / off of each switch according to the battery remaining amount of the battery detected by the battery remaining amount detecting means.
It is characterized in that it is configured to sequentially switch the electrical connection between the motor and the battery.

The vacuum pump according to claim 8 has, in the invention according to claim 1, the power supply unit having a notification unit capable of notifying the operating status of any one of the pump body, the motor, and the power supply unit. It is characterized by being.

The vacuum pump according to claim 9 is the invention according to claim 8, wherein the notification unit includes a visual notification means for visually notifying the operation status and an auditory notification for audibly notifying the operation status. It is characterized by having either one or both of the notification means.

The vacuum pump according to claim 10 is characterized in that, in the invention according to claim 9, the visual notification means has an LED lamp that lights up in a predetermined lighting color or blinks in a predetermined blinking pattern. And.

The vacuum pump according to claim 11 is characterized in that, in the invention according to claim 9, the auditory notification means has a speaker capable of outputting a predetermined alarm sound or voice guidance.

According to the present invention, among a plurality of batteries that supply power to the motor that drives the pump body of the vacuum pump, a battery of one battery is connected to a power supply unit that electrically connects one selected battery and the motor. When the remaining amount becomes less than a predetermined threshold value, a switching control means for controlling switching from the one battery to another battery having a sufficient remaining battery amount is provided, and the switching control means is the remaining battery level of the battery. It was configured to sequentially switch the electrical connection between the motor and the battery according to the situation .
As a result, the vacuum pump can be stably and continuously operated for a long time.

Further, preferably, the power supply unit is provided with a battery holder to which a plurality of batteries can be detachably attached via a slot, and the battery holder is provided with a switching control means and a remaining battery level for detecting the remaining battery level of the battery. A detecting means is provided, and the remaining battery level of one battery detected by the remaining battery level detecting means is compared with the threshold value by the switching control means, and the remaining battery level of one battery is less than the threshold value. At that time, the switching control means is configured to automatically switch to another battery having a sufficient remaining battery power.
As a result, a commercially available general-purpose battery can be detachably attached to the battery holder via the slot, and the vacuum pump can be stably and continuously operated for a long time by the plurality of general-purpose batteries.
Here, preferably, the battery remaining amount detecting means may be a plurality of battery remaining amount detecting circuits facing each of the plurality of batteries, and bidirectional communication with each other at a position where the battery holder and the battery face each other. A possible holder-side interface section and a battery-side interface section are formed, and the battery remaining amount detecting means of the battery remains in the battery based on the measurement data related to the battery impedance transmitted from the holder-side interface section to the battery-side interface section. The amount may be detected.

Preferably, the battery holder is provided with a plurality of switches for electrically connecting the plurality of batteries to the motor, and the switching control means of each switch is provided according to the remaining battery level of the battery detected by the battery level detecting means. It was configured to control on / off and sequentially switch the electrical connection between the motor and the battery.
As a result, the battery of the vacuum pump can be easily switched with a simple configuration, so that the vacuum pump can be stably operated continuously for a long period of time.

More preferably, the power supply unit is provided with a notification unit capable of notifying the operating status of any one of the pump body, the motor, and the power supply unit, and the notification unit is an LED that lights up in a predetermined lighting color or blinks in a predetermined blinking pattern. Either a visual notification means having a lamp and visually notifying the operation status, or an auditory notification means having a speaker capable of outputting a predetermined alarm sound or voice guidance and aurally notifying the operation status. Has one or both.
As a result, the operating status of the vacuum pump can be visually or audibly notified to the user, and the user can know the pump body, the motor abnormality, the battery switching timing, and the remaining battery level of the battery at an early stage. The vacuum pump can be operated stably and continuously for a long time.

It is a perspective view which shows the outline of the structure of the vacuum pump which concerns on this Example. It is a perspective view which shows the outline of the battery mounting position of the vacuum pump which concerns on this Example. It is a perspective view which shows the outline of the battery attachment / detachment state of the vacuum pump which concerns on this Example. It is a block diagram which shows the outline of the structure of the battery switching part of the vacuum pump which concerns on this Example. It is explanatory drawing which shows the battery exchange method of the power-source part of the vacuum pump which concerns on this Example.

Examples of the vacuum pump according to the present invention will be described with reference to the accompanying drawings. 1 and 2 are perspective views showing an outline of the configuration of the vacuum pump according to the present embodiment.

As shown in FIG. 1, the vacuum pump 10 includes a pump main body 11, a motor 12, and a power supply unit 13 including a plurality of batteries.
As shown in FIG. 3, the power supply unit 13 has a battery holder 13a in which a plurality of batteries are detachably formed. When the power of the vacuum pump 10 is turned on, one of the batteries included in the power supply unit 13 is connected to the motor 12 and is formed so as to supply power to the motor 12.
In this embodiment, the battery holder 13a has two batteries 14 and 15 formed in a substantially rectangular parallelepiped shape as shown in FIGS. 1 to 3. The batteries are hereinafter referred to as a first battery 14 and a second battery 15. The first battery is detachably attached to the first slot 16 and the second battery 15 is detachably attached to the second slot 17. When the power of the vacuum pump 10 is turned on, the first battery 14 is preferentially used first, and then the second battery 15 is used. The method of switching from the first battery 14 to the second battery 15 will be described later.
In this embodiment, the battery holder 13a has the first slot 16 and the second slot 17, but the present invention is not limited to these, and for example, when the vacuum pump 10 is enlarged, there is a margin in space. If there is, you may add more slots so that you can install more batteries.

The first battery 14 and the second battery 15 are commercially available general-purpose batteries. A general-purpose battery is a battery sold at home improvement stores and the like, and is widely used as a power source for rechargeable power tools such as dust collectors, blowers, impacts, drills, and chainsaws. Therefore, the general-purpose battery can be easily obtained, and the power source can be easily diverted between the power tools by accommodating the general-purpose battery between the power tools that use the general-purpose battery. As a result, when the battery runs out during the evacuation work by the vacuum pump 10 and there is no spare battery, the battery attached to another power tool can be diverted. Further, since the battery of the electric tool already owned can be diverted by the vacuum pump 10, the cost can be suppressed.

Further, the battery holder 13a has a battery switching unit 20. The battery switching unit 20 is formed so that the first battery 14 attached to the first slot 16 and the second battery 15 attached to the second slot 17 can be switched according to predetermined conditions. As a result, the battery related to the power supply supplied to the motor 12 can be freely switched.
As shown in FIG. 4, the battery switching unit 20 notifies the switch unit 21, the control unit 22 that controls the switch unit 21, the usage status of the first battery 14 or the second battery 15, and the remaining battery level. It has 23.

The switch unit 21 has a first switch 25 that connects the first battery 14 and the motor 12, and a second switch 26 that connects the second battery 15 and the motor 12.
The first switch 25 and the second switch 26 are mechanical switches such as relays that physically open and close circuits, and electrons using elements such as transistors and field effect transistors (FETs). Switch may be used.
Further, preferably, the backflow prevention circuits 25a and 26a may be provided in the first switch 25 and the second switch 26, respectively. As a result, the backflow of current from the first slot 16 side to the second battery 15 and from the second slot 17 side to the first battery 14 is prevented, and the entire circuit including the first switch 25 or the second switch 26 is affected. Can be protected.
The switch unit 21 operates according to the signal input from the control unit 22. Specifically, the first switch 25 or the second switch 26 is closed to open the on signal connecting the batteries 14 and 15 and the motor 12, or the first switch 25 or the second switch 26 is opened to display the batteries 14 and 15. An off signal for disconnecting the motor 12 is input.
Further, the switch unit 21 has an overcurrent detection circuit 27 capable of detecting an overcurrent flowing with respect to the load of the motor 12 and a power switch 35 of the vacuum pump 10. When the power switch 35 is turned on, the first battery 14 is preferentially selected as the power source for the motor 12.

As described above, the control unit 22 is formed so as to output an on signal or an off signal to the switch unit 21 to control the switch unit 22.
Control unit 22, a first battery remaining amount detecting circuit 28 for detecting the remaining battery capacity of the first battery 14, and a second battery remaining amount detecting circuit 29 for detecting the remaining battery capacity of the second battery 15 It has a battery remaining amount detecting means .
The first battery remaining amount detection circuit 28 and the second battery remaining amount detection circuit 29 are connected to the + terminals of the first slot 16 or the second slot 17, respectively. The remaining battery remaining amount detection circuits 28 and 29 are formed so that the remaining amount of the batteries 14 and 15 can be detected by measuring the voltage of the + terminal of the first battery 14 or the second battery 15. Data related to the remaining battery levels of the detected batteries 14 and 15 are input to the control unit 22.
Further, as shown in FIG. 4, the battery remaining amount detecting means may use a bidirectional communication function performed between the holder side interface unit 40a and the battery side interface unit 40b. The battery remaining amount detecting method of the battery remaining amount detecting means do I'm in both communication function will be described later.
The control unit 22 has a switching control means 30 that selects a first slot 16 or a second slot 17 according to the detected remaining battery level and controls switching between the first battery 14 and the second battery 15. ing.

The switching control means 30 detects the remaining battery level when the first battery level detecting circuit 28 or the second battery level detecting circuit 29 detects the remaining battery level of the first battery 14 or the second battery 15. Is formed to compare with a predetermined threshold.
Here, for example, when it is detected that the remaining battery level of the first battery 14 is less than a predetermined threshold value, a signal prompting the replacement of the first battery 14 is output to the notification unit 23.
At this time, if a second battery 15 having a sufficient remaining battery level is already installed on the second slot 17 side, control for automatically switching from the first battery 14 to the second battery 15 is performed. As a result, the motor 12 can be continuously operated, and the vacuum pump 10 can be stably and continuously operated for a long time.
On the other hand, if the remaining battery level of the second battery 15 is less than a predetermined threshold value and is not replaced, or if the second slot 17 is empty, the second battery 15 on the second slot 17 side is charged. A signal is issued to the notification unit 23 to warn that the battery has not been replaced.

Further, the switching control means 30 causes the overcurrent to flow from the batteries 14 and 15 to the motor 12, and when the overcurrent is detected by the overcurrent detection circuit 27, the first battery 14 or the first battery 14 or the first battery causes the overcurrent. 2 It is formed so as to output an off signal for disconnecting the connection between the battery 15 and the motor 12 to the first switch 25 or the second switch 26.
At this time, the switching control means 30 outputs an off signal to, for example, the first switch 25 while being connected, and at the same time outputs an on signal to the other second switch 26 which has been opened, so that the first battery 14 Is formed to switch from to the second battery 15. As a result, when an abnormality is detected, the batteries 14 and 15 can be quickly switched to protect the circuits, devices, and the like inside the motor 12 and the battery holder 13a.
Further, if the overcurrent is still detected by the overcurrent detection circuit 27 after switching the batteries 14 and 15, the switching control means 30 uses the first battery 14 or the second battery 15 that is the cause of the overcurrent. An off signal for disconnecting both of the above and the motor 12 is output to both the first switch 25 and the second switch 26, and an abnormality detection signal indicating that an abnormality / failure due to an overcurrent has occurred is output. , Is formed so as to output to the notification unit 23.
As a result, the control unit 22 completely disconnects both the batteries 14 and 15 and the motor 12, and stops the operation of the vacuum pump 10. Therefore, it is possible to protect the entire equipment including the circuits and devices of the motor 12 and the switch unit 21, and the moving parts of the vacuum pump 10.

The notification unit 23 is configured to display the operating status of any one of the vacuum pump 10, the motor 12, and the control unit 22 .
The notification unit 23 has a first LED lamp 36a and a second LED lamp 36b, and has a visual notification means for visually notifying the operation status and a speaker 37 capable of outputting an alarm sound or voice guidance, and displays the operation status. It is composed of an auditory notification means for auditory notification. As a result, the notification unit 23 can urge the user to replace the battery at an early stage, warn of an abnormality / failure, and notify the user.
The first LED lamp 36a indicates that the first battery 14 is attached to the first slot 16, and the motor 12 is operating using the first battery 14, for example, by changing the blinking pattern or the lighting color. Therefore, it is possible to notify that the remaining battery level of the first battery 14 is not sufficient.
Similarly, the second LED lamp 36b is used to indicate that the second battery 15 is attached to the second slot 17 or to warn the remaining battery level of the second battery 15.
Further, the LED lamps 36a and 36b serve as alarm lamps indicating that an abnormality or failure occurring in each of the batteries 14 and 15 or the battery holder 13a is detected by changing the blinking pattern or the lighting color of the LED lamps 36a and 36b. Can be used.
The type of lamp is not limited to this, and the number of lamps may be increased or decreased according to the content and purpose of notification such as indicating on / off of the power switch 35 of the vacuum pump 10, and visually. Instead of the LED lamp , the notification means uses, for example, a display such as a liquid crystal monitor to display each information such as on / off of the power switch 35 or the remaining battery level of the batteries 14 and 15. You may.
The speaker 37 is formed so that an alarm sound or voice guidance for notifying that the remaining amount of the batteries 14 and 15 has become low or that an abnormality / failure has occurred in the vacuum pump 10 can be output. As a result, in addition to the notification by the LED lamps 36a and 36b, the notification can be performed by sound, and the user can be further urged to promptly replace the batteries 14 and 15.
Not limited to the notification unit 23 according to this embodiment, when the batteries 14 and 15 have a display window indicating the remaining battery level, the batteries 14 and 15 are placed in the battery holder 13a so that the display window can be visually recognized. It may be configured to be attached to. At this time, the remaining battery levels can be easily checked on the batteries 14 and 15 sides, and the remaining battery levels can be checked on the power supply unit 13 side with the first LED lamp 36a and the second LED lamp 36b. it can. As a result, for example, when the power consumption is significantly different between the batteries 14 and 15 and the power supply unit 13, abnormalities such as abnormal discharge or overcurrent of the batteries 14 and 15 can be detected at an early stage. The batteries 14 and 15 can be easily double-checked.

Further, as shown in FIG. 4, preferably, the battery switching unit 20 may be provided with the holder-side interface unit 40a. Then, it is preferable that the battery side is provided with the battery side interface portion 40b arranged to face the holder side interface portion 40a. The holder-side interface portion 40a and the battery-side interface portion 40b are formed so that bidirectional communication is possible.
Here, some of the general-purpose batteries used in this embodiment have a measuring means for measuring the impedance of the battery cells constituting the battery. The measuring means makes it possible to measure the remaining amount of the battery based on the characteristic that the impedance becomes higher as the battery is used and the energy capacity of the battery decreases accordingly.
In the measuring means, the impedance is measured from the relationship between the discharge characteristic at no load before being connected to the motor 12 and the discharge characteristic when actually connected to the motor 12. The causes of high impedance are those due to the use of batteries, those that gradually increase over a long period of time such as deterioration over time, those that suddenly change in resistivity due to changes in operating temperature and environmental temperature, or those that are temporary due to overcurrent. There is something that suddenly rises.
The measuring means is formed so as to transmit the measurement data obtained by periodically measuring the impedance to the power supply unit 13 side via the battery side interface unit 40b. Then, on the power supply unit 13 side, the measurement data received via the holder side interface unit 40a is stored in the memory provided in the control unit 22 , and the original measurement data and the updated measurement data are usually compared. It can be determined whether the impedance has increased due to the use or deterioration over time, or whether the impedance has temporarily increased due to a sudden change in the resistance or an overcurrent.
Further, based on the impedance measurement data, the power supply unit 13 side outputs a discharge instruction for overcurrent or a battery save instruction for the battery remaining amount detecting means, and operates based on the discharge end voltage estimated from the measurement data. The possible time and the like are output to the notification unit 23. In this way, the power supply unit 13 side is formed so that the usage / operating status of the batteries 14 and 15 can be accurately grasped and precise control can be performed based on the measurement data on the batteries 14 and 15 sides. ..

The motor 12 is formed so as to be electrically connectable to the power supply unit 13. The motor 12 has a motor housing 45 and a rotor (not shown) housed in the motor housing 45. The rotation shaft of the rotor is extended toward the pump body 11. As a result, the motor 12 and the pump body 11 are mechanically connected. The power supply of the motor 12 is supplied from the first battery 14 or the second battery 15 of the power supply unit 13. As a result, the vacuum pump 10 can operate without taking power from a commercial power source. Therefore, since the vacuum pump 10 can be made cordless, it can be freely moved and installed, and since a commercial power source is not used, it is not necessary to impose a burden on the owner of the commercial power source. .. Furthermore, the vacuum pump 10 can be used even in a place where there is no commercial power source nearby, such as on the roof of a building.

The pump main body 11 has a casing 50 having an intake port 51 and an exhaust stack 52, and a rotor (not shown) housed in the casing 50.
The casing 50 is filled with a predetermined amount of oil (not shown). The intake port 51 is formed so as to be connectable to the end of the pipe that is the work target of evacuation. The anti-casing side of the exhaust stack 52 is open to the atmosphere. Further, the intake port 51 has a solenoid valve 53.
In the rotor, the rotor shaft is mechanically directly connected to the motor shaft of the motor 12. The rotor has at least one, preferably two or more vanes. The vane is formed so as to be able to move forward and backward along the radial direction of the rotor, and the tip of the vane is formed so as to press the inner wall of the casing 50 by a spring housed inside the vane. As a result, a space surrounded by the side surface of the vane and the inner wall of the casing 50 is formed. The space becomes a semi-vacuum state as the rotor rotates, and air in the pipe is taken in from the intake port 51. The taken-in air is compressed as the rotor rotates and is discharged from the exhaust stack 52 to the atmosphere. As a result, by connecting the open end of the pipe to the intake port 51 and driving the pump body 11, the air inside the pipe taken in from the intake port 51 is discharged from the exhaust pipe 52, and the inside of the pipe is exhausted. Can be evacuated. Here, if an abnormality or failure occurs in either the pump main body 11, the motor 12, or the power supply unit 13, the operating vacuum pump 10 is formed to stop. At this time, the solenoid valve 53 is closed. As a result, the space between the intake port 51 and the inside of the pump is cut off, and it is possible to prevent air from flowing back to the piping during the evacuation operation.
Although this embodiment describes the vacuum pump 10, the pump body 11 is not limited to this. That is, any pump that can be operated by the motor 12 can be appropriately selected according to the application. This pump can be used in places where continuous operation is required for a relatively long time and it is difficult to secure a commercial 100V power supply, such as a drainage pump used in a flooded area during a disaster. The pump configured as in this embodiment can be operated for a long time by switching the power supply, and a high effect can be expected.

The vacuum pump 10 having the above configuration operates as described below. The operation of the battery switching unit 20 of the vacuum pump 10 will be mainly described below with reference to the attached drawings. FIG. 5 is an explanatory diagram showing an outline of a method of switching a battery attached to a power supply unit.

Here, it is assumed that the battery holder 13a provided in the power supply unit 13 of the vacuum pump 10 is equipped with a battery having a sufficient remaining battery capacity in both the first slot 16 and the second slot 17. Further, the battery attached to the first slot 16 is the first battery 14, the battery attached to the second slot 17 is the second battery 15, and the spare battery is the third battery 14a and the fourth battery 15a. Further, the first slot 16 is set to be used preferentially over the second slot 17. As a result, when the power of the vacuum pump 10 is turned on, the first battery 14 attached to the first slot 16 is used first.

When the user turns on the power switch 35 of the vacuum pump 10, as shown in FIG. 4, the first switch 25 is closed, power is supplied from the first battery 14 to the motor 12, and the first LED lamp 36a of the notification unit 23 is turned on. Lights in a predetermined lighting color.
On the other hand, the second LED lamp 36b related to the second slot 17 to which the second battery 15 is attached is turned off or turned off when the power switch 35 is turned on and the first battery 14 is used, or the first LED lamp 36a. It lights up with a predetermined lighting color different from that of the above, or blinks with a predetermined blinking pattern. This emphasizes that the first battery 14 is used as the power source for the motor 12, and the user can easily determine whether the first slot 16 or the second slot 17 is used.
The motor 12 is operated by the power supply supplied from the first battery 14, the motor 12 drives the pump body 11, the air inside the pipe is sucked from the intake port 51 and exhausted from the exhaust pipe 52, and the inside of the pipe is exhausted. It is evacuated. At this time, the notification unit 23 notifies that the first LED lamp 36a on the first battery 14 side is lit in a predetermined lighting color or blinks in a predetermined blinking pattern, and the first battery 14 side is in use.

If the battery level of the first battery 14 is sufficient, the first switch 25 remains closed.
Then, when the first battery remaining amount detection circuit 28 detects that the remaining battery level of the first battery 14 is less than a predetermined threshold value, first, the first LED lamp 36a is turned off or with a predetermined lighting color. Along with lighting or blinking in a predetermined blinking pattern, an alarm sound is emitted from the speaker 37, and the notification unit 23 notifies that the remaining battery level of the first battery 14 is low. After that, when it is detected that the battery consumption further progresses and the remaining battery level of the first battery 14 becomes less than a predetermined threshold value related to the remaining battery level at which the operation of the motor 12 cannot be maintained, the switching control means. Reference numeral 30 denotes a process of outputting an off signal to the first switch 25 and at the same time outputting an on signal to the second switch 26.
As a result, the power supply is switched from the first battery 14 to the second battery 15, and the power is supplied from the second battery 15 to the motor 12.
It should be noted that the threshold value is set in two stages as described above, the warning of low battery level is given in the first stage, and the battery switching is performed in the second stage. Not limited to the processing method, a single threshold value is set. , Battery low warning and battery switching are processed at the same time, or multiple thresholds are set, battery low warning is given in multiple stages with different patterns, and battery switching is performed at the final stage. It may be processed as follows.
Along with the above switching process, in the notification unit 23, the second LED lamp 36b on the second battery 15 side lights up in a predetermined lighting color or blinks in a predetermined blinking pattern, and the second battery 15 side is in use. Shown. As a result, it is notified that the first battery 14 has been switched to the second battery 15.
At this time, the first LED lamp 36a, which is turned off in the first step, may be turned on with a predetermined lighting color different from that of the second LED lamp 36b, or may blink in a predetermined blinking pattern. As a result, the user can be strongly urged to replace the first battery 14 in the first slot 16 with the spare third battery 14a at an early stage.

Then, as shown in FIG. 5, while the second battery 15 is in use, the first battery 14 is removed from the first slot 16 and replaced with a spare third battery 14a. Further, preferably, the removed first battery 14 may be attached to the charger to charge the second battery 15 while the second battery 15 is in use. By keeping the next battery on standby in this way, when the remaining battery level of the second battery 15 becomes less than a predetermined threshold value, the power supply can be smoothly switched from the second battery 15 to the third battery 14a. Can be done. Then, after the power is switched from the second battery 15 to the third battery 14a, the second battery 15 is removed and replaced with a spare fourth battery 15a in the second slot 17 while the third battery 14a is being used. To.
By replacing the battery and switching the power supply in this way, the motor 12 can continuously operate the pump body 11 for a long time, and even in a facility having a long piping facility, the vacuuming work has a sufficient margin. It can be performed.
Further, when the batteries 14, 14a, 15, 15a are switched, the LED lamps 36a, 36b and the speaker 37 are used to appeal to the user's visual and auditory senses, and the remaining battery power is low. I tried to encourage the exchange of. As a result, a battery having a low battery level can be replaced with a battery having a sufficient battery level, so that continuous operation can be performed for a long time.

Further, the vacuum pump 10 according to the present embodiment uses a relatively small general-purpose battery on the market instead of using a large battery having a large battery capacity. General-purpose batteries are easily available and can be used for other power tools, so the amount of batteries brought to the work site can be reduced, and by using batteries alternately, one battery is in use. In addition, it is possible to easily charge the other battery or prepare a new battery. Therefore, it is possible to flexibly respond at the work site, and as a result, the work time can be shortened and the work can be performed efficiently.
Further, at present, the above-mentioned general-purpose battery has different standards depending on the power tool manufacturer. Therefore, when the vacuum pump 10 according to this embodiment is used, the general-purpose battery that can be used in the vacuum pump 10 and other power tools are used. It is preferable to have a general-purpose battery to be used. Therefore, the power tool maker that provides the general-purpose battery used in the vacuum pump 10 according to the present embodiment can enclose the user.

10 ... Vacuum pump,
11 ... Pump body, 12 ... Motor, 13 ... Power supply, 13a ... Battery holder,
14 ... 1st battery, 14a ... 3rd battery, 15 ... 2nd battery, 15a ... 4th battery, 16 ... 1st slot, 17 ... 2nd slot,
20 ... Battery switching unit,
21 ... Switch unit, 22 ... Control unit, 23 ... Notification unit,
25 ... 1st switch, 26 ... 2nd switch, 25a, 26a ... Backflow prevention circuit, 27 ... Overcurrent detection circuit,
28 ... 1st battery remaining amount detection circuit, 29 ... 2nd battery remaining amount detection circuit,
30 ... Switching control means,
35 ... Power switch,
36a ... 1st LED lamp, 36b ... 2nd LED lamp, 37 ... Speaker,
40a ... Holder side interface part, 40b ... Battery side interface part,
45 ... Motor housing,
50 ... casing, 51 ... intake port, 52 ... exhaust stack, 53 ... solenoid valve.

Claims (11)

A vacuum pump for evacuating
The vacuum pump is the pump body and
The motor that drives the pump body and
A power supply unit that supplies power to the motor and has multiple batteries ,
Consists of
To the power supply unit that electrically connects the selected battery and the motor among the plurality of batteries.
When the remaining battery level of one of the above batteries becomes less than a predetermined threshold value
From the battery of the one, it provided a switching control means for controlling said remaining battery capacity is switched to sufficient other of said battery,
A vacuum pump in which the switching control means, in response to the battery remaining amount of the battery, characterized by being configured to sequentially switch the electrical connection of the said motor battery. The power supply unit is provided with a battery remaining amount detecting means for detecting the remaining battery level of the battery.
The battery remaining amount of one of the batteries detected by the battery remaining amount detecting means is compared with the threshold value by the switching control means.
When the remaining battery level of one of the batteries is less than the threshold value,
The vacuum pump according to claim 1, wherein the switching control means is configured to automatically switch to another battery having a sufficient remaining battery level. The vacuum pump according to claim 2, wherein the battery remaining amount detecting means has a plurality of battery remaining amount detecting circuits facing each of the plurality of batteries. A battery holder to which a plurality of the batteries can be detachably attached is provided in the power supply unit.
The vacuum pump according to claim 1 or 2, wherein the battery holder has the switching control means and the battery remaining amount detecting means. A holder-side interface portion and a battery-side interface portion formed so as to enable bidirectional communication with each other are provided at positions where the battery holder and the battery face each other.
The battery remaining amount detecting means detects the battery remaining amount of the battery based on the measurement data relating to the impedance of the battery transmitted from the holder side interface part to the battery side interface part. The vacuum pump according to claim 4. The vacuum pump according to claim 4, wherein the battery holder has a plurality of slots into which the plurality of batteries are mounted so as to face each other. The battery holder is provided with a plurality of switches for electrically connecting the plurality of the batteries to the motor.
The switching control means controls on / off of each switch according to the battery remaining amount of the battery detected by the battery remaining amount detecting means.
The vacuum pump according to claim 4, wherein the electric connection between the motor and the battery is sequentially switched. The vacuum pump according to claim 1, wherein the power supply unit has a notification unit capable of notifying the operating status of any one of the pump body, the motor, and the power supply unit. The notification unit is characterized in that it has either or both of a visual notification means for visually notifying the operation status and an auditory notification means for aurally notifying the operation status. Item 8. The vacuum pump according to Item 8. The vacuum pump according to claim 9, wherein the visual notification means has an LED lamp that lights up in a predetermined lighting color or blinks in a predetermined blinking pattern. The vacuum pump according to claim 9, wherein the auditory notification means has a speaker capable of outputting a predetermined alarm sound or voice guidance.