JP2021142205A - Vacuum cleaner - Google Patents

Abstract

To provide a vacuum cleaner capable of suppressing deterioration in convenience even when deterioration in an insulation resistance value by electrochemical migration occurs in a printed board in a switch.SOLUTION: A vacuum cleaner includes: an electric blower driven by the power stored in a secondary battery for generating suction negative pressure in a suction air passage; a first electric passage 35 to which a voltage is applied by the power stored in the secondary battery; switches 26a and 26b provided to the first electric passage 35 for receiving operation input by switching power supply and power shutdown of the first electric passage 35; a switch 51 for power shutdown provided to the first electric passage 35 connecting the secondary battery and the switches 26a and 26b for switching power supply and power shutdown of the first electric passage 35 according to a predetermined event; and a body control unit 21 for changing an operation state of the electric blower when power is supplied to the first electric passage 35 by the switches 26a and 26b.SELECTED DRAWING: Figure 2

Description

An embodiment of the present invention relates to a vacuum cleaner.

There is known an electric vacuum cleaner that repeatedly switches the input of an electric blower on and off each time the operation switch is short-circuited. The operation switch is a switch that accepts a push-down operation, and is, for example, a tactile switch (tact switch) or a membrane switch.

Japanese Unexamined Patent Publication No. 2007-268081

By the way, a printed circuit board is used for the tact switch and the membrane switch. On a printed circuit board, a phenomenon may occur in which a metal used as a wiring or an electrode moves on an insulating material. This phenomenon is called electrochemical migration or ion migration. In a printed circuit board that has undergone electrochemical migration, the insulation resistance value between the electrodes may decrease.

If the insulation resistance between the electrodes on the printed circuit board inside the switch decreases, the switch may short-circuit irregularly without the intention of the user. If the switch is short-circuited irregularly, the electric blower suddenly starts operation, the electric blower suddenly stops operation, or the operation output of the electric blower suddenly changes, which is inconvenient. For example, in a vacuum cleaner provided with a secondary battery as a power source for the electric blower, the electric blower may suddenly start operation and the battery may run out. Such an unintended battery exhaustion impairs the convenience of the vacuum cleaner.

Therefore, an object of the present invention is to propose an electric vacuum cleaner capable of suppressing a decrease in convenience even when a decrease in insulation resistance value occurs due to electrochemical migration on a printed circuit board in a switch.

In order to solve the above problems, the electric vacuum cleaner according to the embodiment of the present invention is driven by a suction air passage, a secondary battery, and electric power stored in the secondary battery, and generates a suction negative pressure in the suction air passage. An electric blower to be operated, an electric circuit to which a voltage is applied by the electric power stored in the secondary battery, a first switch provided in the electric circuit to switch between energization and interruption of energization of the electric path to receive an operation input, and the above two. A second switch provided in the electric circuit connecting the next battery and the first switch to switch between energization and de-energization of the electric path according to a predetermined event, and the electric power when the electric path is energized by the first switch. It is equipped with a control unit that changes the operating state of the blower.

The perspective view of the vacuum cleaner which concerns on embodiment of this invention. The block diagram of the input detection circuit and the charge path connection detection circuit of the vacuum cleaner which concerns on embodiment of this invention. The block diagram of another example of the input detection circuit of the vacuum cleaner which concerns on embodiment of this invention.

Embodiments of the suction port body and the vacuum cleaner according to the present invention will be described with reference to FIGS. 1 to 3.

FIG. 1 is a perspective view of the vacuum cleaner according to the embodiment of the present invention.

As shown in FIG. 1, the vacuum cleaner 1 according to the present embodiment is, for example, a stick type. The vacuum cleaner 1 has a vacuum cleaner main body 12 which has a handle 11 and can be operated by hand, and a vacuum cleaner main body 12 Detachable secondary battery 13 (also called storage battery, rechargeable battery, and rechargeable battery), extension tube 15 connected to the vacuum cleaner body 12, and suction port 16 connected to the extension tube 15. It has.

The vacuum cleaner 1 may be a canister type, an upright type, or a handy type. The vacuum cleaner 1 may be a cordless type having a secondary battery 13 as a power source, or a wired type that obtains electric power from a commercial AC power source via a power cord.

The vacuum cleaner main body 12 includes a main body case 17 having a handle 11, an electric blower 18 housed in the main body case 17 to generate a suction negative pressure, and a dust separation / dust collecting unit 19 detachably provided in the main body case 17. It mainly includes a main body control unit 21 that controls the electric blower 18.

The vacuum cleaner main body 12 drives the electric blower 18 by the electric power stored in the secondary battery 13, and causes the negative pressure generated by the drive of the electric blower 18 to act on the extension pipe 15. The vacuum cleaner 1 sucks dust-containing air (hereinafter, referred to as “dust-containing air”) from the floor surface through the suction port body 16 and the extension pipe 15, separates the dust from the dust-containing air, and after the separation. Dust is collected and accumulated, and the separated air is exhausted.

The main body case 17 includes a cylindrical front half portion 17a arranged on the extension line of the extension pipe 15 in a side view, and a rear portion 17b that bends from the front half portion 17a and gradually separates from the extension line of the extension pipe 15. ing. A dust separation / dust collection unit 19 is provided above the front half portion 17a of the main body case 17. The latter half 17b of the main body case 17 extends rearward in a used state (FIG. 2) in which the suction port body 16 is arranged on the floor.

A main body connection port 23 is provided on the front portion of the main body case 17.

The main body connection port 23 is a joint to which the extension pipe 15 can be attached and detached. The main body connection port 23 projects toward the front from the cylindrical front half portion 17a of the main body case 17. The main body connection port 23 is a fluid inlet of the vacuum cleaner main body 12, and fluidly connects the extension pipe 15 and the dust separation / dust collection unit 19. By removing the extension pipe 15 from the vacuum cleaner main body 12, the main body connection port 23 also functions as a suction port when the vacuum cleaner main body 12 is used alone. That is, when the extension pipe 15 is removed from the vacuum cleaner main body 12, the dust separation / dust collection unit 19 is a suction air passage from the electric blower 18 to the main body connection port 23. When the extension pipe 15 is attached to the vacuum cleaner main body 12, the suction port body 16, the extension pipe 15, and the dust separation / dust collecting unit 19 are suction air passages from the electric blower 18 to the suction port 27.

The handle 11 is integrally provided with the main body case 17. The handle 11 is a portion that the user grips by hand in order to clean the floor surface with the vacuum cleaner 1. The handle 11 is arched from the vicinity of the rear end portion of the dust separation / dust collecting portion 19 to the rear end portion of the main body case 17. Further, the handles 11 are arranged so as to intersect with each other on the extension line of the extension pipe 15 center line.

In the vicinity of the handle 11, an input unit 26 is provided so as to be arranged within a range in which the user holding the handle 11 can move his / her fingers.

The input unit 26 includes a main switch 26a that receives an operation start operation and an operation stop operation of the electric blower 18, and an operation mode changeover switch 26b that accepts an operation mode selection operation of the electric blower 18. The main switch 26a and the operation mode changeover switch 26b are electrically connected to the main body control unit 21. The input unit 26 may include a brush switch that accepts a start operation and a stop operation of supplying electric power to the suction port body 16.

The user of the vacuum cleaner 1 can operate the input unit 26 to start or stop the electric blower 18. When the main body control unit 21 receives an operation signal from the main switch 26a while the electric blower 18 is stopped, the main body control unit 21 starts the electric blower 18. When the main body control unit 21 receives an operation signal from the main switch 26a while the electric blower 18 is operating, the main body control unit 21 stops the electric blower 18.

The user of the vacuum cleaner 1 can selectively select the operation mode of the electric blower 18 by operating the input unit 26. Each time the main body control unit 21 receives an operation signal from the operation mode changeover switch 26b, the main body control unit 21 switches the operation mode in the order of strong → medium → weak → strong → medium → weak → .... The input unit 26 may individually include a strong operation switch (not shown), a medium operation switch (not shown), and a weak operation switch (not shown) instead of the operation mode changeover switch 26b.

The dust separation / dust collecting unit 19 is arranged on the upper surface side of the vacuum cleaner main body 12 and can be attached to and detached from the vacuum cleaner main body 12. The dust separation / dust collection unit 19 separates dust from the dust-containing air flowing into the vacuum cleaner main body 12, collects and accumulates the dust, and sends clean air from which the dust has been removed to the electric blower 18. The dust separation / dust collection unit 19 may be a centrifugal separation method in which the dust and air are centrifugally separated by utilizing the difference in mass between the dust and the air sucked by the electric vacuum cleaner 1, or the dust-containing air may be separated from the dust. It may be a filtration separation method having a filter for filtering out.

The electric blower 18 is driven by the electric power stored in the secondary battery 13. The electric blower 18 sucks air from the suction air passage to generate a negative pressure (suction negative pressure).

The main body control unit 21 includes a microprocessor and a storage device that stores various arithmetic programs and parameters executed by the microprocessor. The storage device stores various settings (arguments) related to a plurality of preset operation modes. The plurality of operating modes are associated with the output of the electric blower 18. Different input values (input value of the electric blower 18 and current target value flowing through the electric blower 18) are set in each operation mode. Each operation mode is associated with an operation input received by the input unit 26. The main body control unit 21 selectively selects an arbitrary operation mode corresponding to the operation input to the input unit 26 from a plurality of preset operation modes. Further, the main body control unit 21 reads the selected operation mode setting from the storage unit, and operates the electric blower 18 according to the read operation mode setting.

The secondary battery 13 stores the electric power consumed by the electric blower 18 and the main body control unit 21. The secondary battery 13 may be fixed to the main body case 17 or may be detachable from the main body case 17. In other words, the vacuum cleaner 1 may or may not be used by appropriately exchanging a plurality of secondary batteries 13. When the charge rate of the secondary battery 13 detachably attached to the vacuum cleaner 1 drops, the secondary battery 13 is replaced with a charged secondary battery 13 to replace the secondary battery 13 with the charged secondary battery 13. Can continue to operate. The vacuum cleaner main body 12 is provided with a charging connector 25 for detachably connecting a charger for charging the secondary battery 13. The charging connector 25 is, for example, a socket. The plug of the charging device is detachably inserted into the socket. When the plug is inserted into the socket, the secondary battery 13 is charged.

The extension pipe 15 and the suction port 16 suck dust on the floor surface together with air by the negative pressure acting from the electric blower 18 and guide the dust to the vacuum cleaner main body 12.

The extension pipe 15 is fluidly connected to the suction side of the electric blower 18 via the main body connection port 23 of the main body case 17 and the dust separation / dust collection unit 19. The extension pipe 15 has a length that substantially reaches the floor surface in a state where the user holds the handle 11 of the vacuum cleaner main body 12. At one end of the extension pipe 15, a joint structure that can be attached to and detached from the main body connection port 23 of the vacuum cleaner main body 12 is provided. At the other end of the extension pipe 15, a joint structure is provided so that the suction port body 16 of the vacuum cleaner body 12 can be attached and detached. The extension tube 15 may or may not be stretchable.

The suction port body 16 is movable or slidable on a floor surface such as a wooden floor or a carpet, and has a suction port 27 on a bottom surface facing the floor surface in a running state or a sliding state. Further, the suction port body 16 includes a rotatable rotary cleaning body 28 arranged at the suction port 27 and an electric motor 29 as a drive source for driving the rotary cleaning body 28. One end of the suction port body 16 is provided with a detachable joint structure at the other end of the extension pipe 15. The suction port body 16 is fluidly connected to the suction side of the electric blower 18 via an extension pipe 15.

The vacuum cleaner 1 starts the electric blower 18 when the main switch 26a is operated. For example, in the vacuum cleaner 1, when the main switch 26a is operated while the electric blower 18 is stopped, the electric blower 18 is first started in the strong operation mode. The vacuum cleaner 1 changes the operation mode of the electric blower 18 to the medium operation mode when the operation mode changeover switch 26b is operated, and weakly operates the operation mode of the electric blower 18 when the operation mode changeover switch 26b is operated again. Change to the mode and repeat the same. The strong operation mode, the medium operation mode, and the weak operation mode are a plurality of preset operation modes. The input value of the electric blower 18 in the strong operation mode is the largest, and the input value of the electric blower 18 in the weak operation mode is the smallest. The started electric blower 18 sucks air from the dust separation / dust collection unit 19 and makes the inside of the dust separation / dust collection unit 19 a negative pressure.

The negative pressure in the dust separation / dust collecting unit 19 sequentially passes through the main body connection port 23, the extension pipe 15, and the suction port body 16 and acts on the suction port 27. The vacuum cleaner 1 cleans the surface to be cleaned by sucking dust on the surface to be cleaned together with air by the negative pressure acting on the suction port 27. The dust separation / dust collection unit 19 separates and accumulates dust from the dust-containing air sucked into the vacuum cleaner 1, while sending the air separated from the dust-containing air to the electric blower 18. The electric blower 18 exhausts the air sucked from the dust separation / dust collection unit 19 to the outside of the vacuum cleaner main body 12.

Next, the input detection circuit received by the input unit 26 of the vacuum cleaner 1 will be described in detail.

FIG. 2 is a configuration diagram of an input detection circuit and a charging path connection detection circuit of the vacuum cleaner according to the embodiment of the present invention.

As shown in FIG. 2, in the vacuum cleaner 1 according to the present embodiment, an input detection circuit 31 for detecting an operation input received by an input unit 26 and a charging device for the secondary battery 13 are connected to the secondary battery 13. It is provided with a charging path connection detection circuit 32 that detects whether or not the battery is present.

The input detection circuit 31 is connected to the secondary battery 13 via, for example, a control power supply unit that outputs a control voltage of 5 volts. The power supply for control is a voltage regulator. That is, a voltage is applied to the first electric circuit 35 of the input detection circuit 31 by the electric power stored in the secondary battery 13. The control power supply unit can also output the control voltage by the electric power supplied from the charging device via the charging connector 25. In other words, a voltage is also applied to the first electric circuit 35 of the input detection circuit 31 by the electric power supplied from the charging device via the charging connector 25.

The input detection circuit 31 includes a first pull-up resistor 36, a first protection resistor 37, and a resistance voltage divider circuit 38 including a main switch 26a and an operation mode changeover switch 26b.

The first pull-up resistor 36 is provided in the first electric circuit 35 that connects the control power supply unit and the resistance voltage dividing circuit 38.

The first protection resistor 37 is provided in the first electric circuit 35 connecting the input detection circuit 31 and the main body control unit 21.

The resistance voltage dividing circuit 38 includes a plurality of resistors 39a and 39b connected in series to the switches 26a and 26b, respectively. The resistor 39a is provided in the first electric circuit 35 connecting the first pull-up resistor 36 and the main switch 26a. The resistor 39b is provided in the first electric circuit 35 connecting the first pull-up resistor 36 and the operation mode changeover switch 26b. The combination of the resistor 39a and the main switch 26a and the combination of the resistor 39b and the operation mode changeover switch 26b are connected in parallel.

The resistance voltage dividing circuit 38 changes the voltage dividing value of the output voltage of the control power supply unit in response to the operation of the main switch 26a and the operation mode changeover switch 26b. The voltage dividing value of the output voltage of the control power supply unit changed by the resistance voltage dividing circuit 38 is an operation signal received by the main body control unit 21. The main body control unit 21 changes the operating state of the electric blower 18 when the first electric path 35 is energized by the switches 26a and 26b. That is, the main body control unit 21 starts or stops the electric blower 18 when the first electric path 35 is energized by the main switch 26a. The main body control unit 21 switches the operation mode of the electric blower 18 when the first electric path 35 is energized by the operation mode changeover switch 26b.

The switches 26a and 26b (first switch) are provided in the first electric circuit 35 to switch between energization and interruption of energization of the first electric path 35 to receive an operation input. The switches 26a and 26b are momentary switches. The switches 26a and 26b are preferably tactile switches or membrane switches that give a click feeling when pushed down. When the switches 26a and 26b are pushed down, they close to energize the first electric circuit 35, and when the pushing force is lost, they open to shut off the energization of the first electric circuit 35.

Further, the charging path connection detection circuit 32 is connected to the secondary battery 13 via the control power supply unit, similarly to the input detection circuit 31. That is, a voltage is applied to the second electric circuit 45 of the charging path connection detection circuit 32 by the electric power stored in the secondary battery 13.

The charging path connection detection circuit 32 includes a second pull-up resistor 46, a second protection resistor 47, and a plug-in detection switch 48.

The second pull-up resistor 46 is provided in the second electric circuit 45 that connects the control power supply unit and the plug-in detection switch 48.

The second protection resistor 47 is provided in the second electric circuit 45 that connects the charging path connection detection circuit 32 and the main body control unit 21.

When the charging device is connected to the secondary battery 13, the plug-in detection switch 48 (third switch) opens to cut off the energization of the second electric circuit 45, and the charging device is removed from the secondary battery 13. If so, it is closed and the second electric circuit 45 is energized. The plug-in detection switch 48 opens when pushed into the plug of the charging device inserted into the charging connector 25 of the secondary battery 13, and closes when the plug of the charging device is pulled out from the charging connector 25 of the secondary battery 13.

The input detection circuit 31 is provided in the first electric circuit 35 connecting the secondary battery 13 and the switches 26a and 26b, and is used for power cutoff for switching between energization and cutoff of the energization of the first electric circuit 35 according to a predetermined event. A switch 51 (second switch) is provided.

The power cutoff switch 51 is a switching element, for example, a PNP type transistor. The power cutoff switch 51 is provided in the first electric circuit 35 that connects the control power supply unit and the first pull-up resistor 36 of the input detection circuit 31. The emitter of the power cutoff switch 51 is connected to the control power supply unit. The base of the power cutoff switch 51 is connected to a second electric circuit 45 that connects the second pull-up resistor 46 of the charging path connection detection circuit 32 and the plug-in detection switch 48. The collector of the power cutoff switch 51 is connected to the first pull-up resistor 36 of the input detection circuit 31.

When the plug of the charging device is pulled out from the charging connector 25 of the secondary battery 13, the plug-in detection switch 48 closes. Then, the base current flows from the emitter of the power cutoff switch 51 toward the base, and the collector current flows from the emitter of the power cutoff switch 51 toward the collector. That is, the power cutoff switch 51 is closed and a voltage is applied to the resistance voltage dividing circuit 38 of the input detection circuit 31. In this state, the input unit 26 can detect the operation input to the switches 26a and 26b. Therefore, the main body control unit 21 operates the electric blower 18 in response to the operation input to the input unit 26.

On the other hand, when the plug of the charging device is inserted into the charging connector 25 of the secondary battery 13, the plug-in detection switch 48 opens. Then, the base current of the power cutoff switch 51 is cut off, and the collector current of the power cutoff switch 51 is cut off. That is, the power cutoff switch 51 is opened and no voltage is applied to the resistance voltage dividing circuit 38 of the input detection circuit 31. In this state, the input unit 26 does not detect the operation input to the switches 26a and 26b. Therefore, the main body control unit 21 invalidates the operation input to the input unit 26.

In other words, the power cutoff switch 51 switches between energization and cutoff of the first electric path 35 according to the event of whether or not the plug of the charging device is inserted into the charging connector 25 of the secondary battery 13. When the plug of the charging device is inserted into the charging connector 25 of the secondary battery 13, the power cutoff switch 51 opens to shut off the energization of the first electric circuit 35, and the charging connector of the secondary battery 13 is cut off. If the plug of the charging device is not inserted in 25, it is closed and the first electric path 35 is energized. In the input detection circuit 31 that operates in this way, even if the printed circuit board in the switches 26a and 26b undergoes electrolytic chemical migration and the switches 26a and 26b are irregularly short-circuited regardless of the user's intention. , When the plug of the charging device is inserted into the charging connector 25 of the secondary battery 13, the electric blower 18 suddenly starts the operation, the electric blower 18 suddenly stops the operation, or the electric blower It is possible to prevent the operating output of 18 from changing unexpectedly. When the plug of the charging device is inserted into the charging connector 25 of the secondary battery 13, the secondary battery 13 is in either the charging state or the standby state after the charging is completed.

Next, another example of the input detection circuit 31 of the vacuum cleaner 1 according to the embodiment of the present invention will be described. In the input detection circuit 31A described in another example, the same components as those of the input detection circuit 31 are designated by the same reference numerals, and duplicate description will be omitted.

FIG. 3 is a block diagram of another example of the input detection circuit of the vacuum cleaner according to the embodiment of the present invention.

As shown in FIG. 3, the power cutoff switch 51 of the input detection circuit 31A according to the present embodiment replaces the event of whether or not the plug of the charging device is inserted into the charging connector 25 of the secondary battery 13. , The energization of the first electric circuit 35 and the interruption of the energization are switched according to the event of whether or not the charging voltage is applied to the secondary battery 13.

The secondary battery 13 has a charging circuit 61 that transmits a signal notifying the application of the charging voltage to the main body control unit 21 when the charging voltage is applied from the charging device. When the charging voltage is no longer applied from the charging device, the charging circuit 61 stops transmitting a signal notifying the main body control unit 21 that the charging voltage is applied. The main body control unit 21 determines whether or not a charging voltage is applied to the secondary battery 13 based on the presence or absence of this signal.

The base of the power cutoff switch 51 is connected to the main body control unit 21. The main body control unit 21 turns on and off the base current based on whether or not the charging voltage of the secondary battery 13 is applied. The main body control unit 21 is connected to a charging circuit 61 that can detect whether or not charging of the secondary battery 13 is completed by detecting the charging voltage of the secondary battery 13.

When the secondary battery 13 is being charged and the charging voltage is applied to the secondary battery 13, the main body control unit 21 cuts off the base current, the secondary battery 13 is fully charged, and the secondary battery 13 is fully charged. When the charging voltage to the battery 13 is not applied, a base current is passed. In other words, when the main body control unit 21 has not detected the completion of charging of the secondary battery 13, the power cutoff switch 51 is opened to connect the secondary battery 13 and the switches 26a and 26b to the first electric circuit 35. When the energization is cut off and the completion of charging of the secondary battery 13 is detected, the power cutoff switch 51 is closed and the first electric circuit 35 connecting the secondary battery 13 and the switches 26a and 26b is energized.

Therefore, when the secondary battery 13 is fully charged and the charging voltage to the secondary battery 13 is not applied, the base current flows from the emitter of the power cutoff switch 51 toward the base, and the power is cut off. A collector current flows from the emitter of the switch 51 toward the collector. That is, the power cutoff switch 51 is closed and a voltage is applied to the resistance voltage dividing circuit 38 of the input detection circuit 31A. In this state, the input unit 26 can detect the operation input to the switches 26a and 26b. Therefore, the main body control unit 21 operates the electric blower 18 in response to the operation input to the input unit 26.

On the other hand, when the secondary battery 13 is being charged and a charging voltage is applied to the secondary battery 13, the base current of the power cutoff switch 51 is cut off, and the collector current of the power cutoff switch 51 is cut off. Is blocked. That is, the power cutoff switch 51 is opened and no voltage is applied to the resistance voltage dividing circuit 38 of the input detection circuit 31A. In this state, the input unit 26 does not detect the operation input to the switches 26a and 26b. Therefore, the main body control unit 21 invalidates the operation input to the input unit 26.

In other words, the power cutoff switch 51 switches between energization of the first electric path 35 and cutoff of the energization according to the event of whether or not the secondary battery 13 is charged. The power cutoff switch 51 opens when the secondary battery 13 is charged to shut off the energization of the first electric circuit 35, and closes when the secondary battery 13 is not charged. Energize 35. In the input detection circuit 31A that operates in this way, even if electrochemical migration occurs on the printed circuit board in the switches 26a and 26b and the switches 26a and 26b are irregularly short-circuited regardless of the intention of the user. When the secondary battery 13 is being charged, the electric blower 18 suddenly starts operation, the electric blower 18 suddenly stops operation, or the operation output of the electric blower 18 suddenly changes. You can prevent that.

The "predetermined event" for opening and closing the power cutoff switch 51 is the first event of whether or not the plug of the charging device is inserted into the charging connector 25 of the secondary battery 13, and the charging of the secondary battery 13. It is not limited to the second event of whether or not a voltage is applied. For example, the "predetermined event" is a third event of whether or not the vacuum cleaner 1 is housed in the storage table, and a fourth event of whether or not the handle 11 of the vacuum cleaner body 12 is gripped by the user. As described above, it may be an event related to the usage mode of the vacuum cleaner 1.

When the third event is applied to the event of opening and closing the power cutoff switch 51, the vacuum cleaner 1 includes, for example, a sensor or a switch capable of detecting that the vacuum cleaner main body 12 is connected to the storage stand. Is preferable.

When the vacuum cleaner main body 12 is separated from the storage stand, a base current flows from the emitter of the power cutoff switch 51 toward the base, and a collector current flows from the emitter of the power cutoff switch 51 toward the collector. .. That is, the power cutoff switch 51 is closed and a voltage is applied to the resistance voltage dividing circuits 38 of the input detection circuits 31 and 31A. In this state, the input unit 26 can detect the operation input to the switches 26a and 26b. Therefore, the main body control unit 21 operates the electric blower 18 in response to the operation input to the input unit 26.

On the other hand, when the vacuum cleaner main body 12 is housed in the storage stand, the base current of the power cutoff switch 51 is cut off, and the collector current of the power cutoff switch 51 is cut off. That is, the power cutoff switch 51 is opened and no voltage is applied to the resistance voltage dividing circuit 38 of the input detection circuit 31A. In this state, the input unit 26 does not detect the operation input to the switches 26a and 26b. Therefore, the main body control unit 21 invalidates the operation input to the input unit 26.

When the fourth event is applied to the event of opening and closing the power cutoff switch 51, the vacuum cleaner 1 is provided with, for example, a sensor or a switch capable of detecting whether or not the handle 11 is gripped. Is preferable.

When the handle 11 is gripped, the base current flows from the emitter of the power cutoff switch 51 toward the base, and the collector current flows from the emitter of the power cutoff switch 51 toward the collector. That is, the power cutoff switch 51 is closed and a voltage is applied to the resistance voltage dividing circuits 38 of the input detection circuits 31 and 31A. In this state, the input unit 26 can detect the operation input to the switches 26a and 26b. Therefore, the main body control unit 21 operates the electric blower 18 in response to the operation input to the input unit 26.

On the other hand, when the handle 11 is not gripped, the base current of the power cutoff switch 51 is cut off, and the collector current of the power cutoff switch 51 is cut off. That is, the power cutoff switch 51 is opened and no voltage is applied to the resistance voltage dividing circuit 38 of the input detection circuit 31A. In this state, the input unit 26 does not detect the operation input to the switches 26a and 26b. Therefore, the main body control unit 21 invalidates the operation input to the input unit 26.

The switches 26a and 26b whose voltage application state changes according to a "predetermined event" by the power cutoff switch 51 may include at least one of the switches 26a and 26b. It is preferable that at least the main switch 26a is included.

Further, the "predetermined event" for turning on / off the power cutoff switch 51 may include at least one of the first event to the fourth event. The "predetermined event" that turns on / off the power cutoff switch 51 may be a condition that is satisfied by a logical product that combines these plurality of events or a condition that is satisfied by a logical sum.

As described above, the vacuum cleaner 1 according to the present embodiment is provided in the first electric path 35 connecting the secondary battery 13 and the switches 26a and 26b, and energizes and energizes the first electric path 35 according to a predetermined event. The power cutoff switch 51 for switching between the cutoff and the cutoff is provided. Therefore, the vacuum cleaner 1 can switch between enabling and disabling the operation input to the switches 26a and 26b depending on whether or not a predetermined event has occurred. Therefore, in the vacuum cleaner 1, even when the insulation resistance value of the printed circuit boards in the switches 26a and 26b is lowered due to electrolytic chemical migration, the electric blower suddenly starts operation or the electric blower unexpectedly starts operation. It is possible to suppress a decrease in convenience caused by suddenly stopping the operation or suddenly changing the operation output of the electric blower.

Further, the vacuum cleaner 1 according to the present embodiment includes charging the secondary battery 13 and waiting after the charging of the secondary battery 13 is completed as predetermined events. Therefore, in the vacuum cleaner 1, even if the main switch 26a is unexpectedly short-circuited due to, for example, electrochemical migration, the power of the secondary battery 13 is being charged while the secondary battery 13 is being charged or while the secondary battery 13 is on standby. Do not waste.

Further, the vacuum cleaner 1 according to the present embodiment includes tactile switches as switches 26a and 26b. Since a tactile switch generally has a built-in printed circuit board, irregular short circuits due to electrolytic chemical migration are likely to become apparent. However, since the vacuum cleaner 1 can appropriately switch between enabling and disabling the switches 26a and 26b according to a predetermined event, the cost due to the adoption of an inexpensive tactile switch having insufficient electromigration resistance Easy to reduce.

Further, the vacuum cleaner 1 according to the present embodiment includes input detection circuits 31 and 31A in which a voltage is also applied by electric power supplied from the charging device via the charging connector 25. Therefore, the vacuum cleaner 1 can reliably switch between enabling and disabling the switches 26a and 26b according to a predetermined event even when the charging rate of the secondary battery 13 being charged is insufficient. can.

Further, the vacuum cleaner 1 according to the present embodiment switches between enabling and disabling the main switch 26a according to a predetermined event. Therefore, even if the main switch 26a is unexpectedly short-circuited due to electrochemical migration, the vacuum cleaner 1 can use the power of the secondary battery 13 while charging the secondary battery 13 or while waiting after charging is completed. Don't waste it.

Further, the vacuum cleaner 1 according to the present embodiment switches between enabling and disabling the main switch 26a according to a predetermined event. Therefore, in the vacuum cleaner 1, even if the operation mode changeover switch 26b is unexpectedly short-circuited due to electrochemical migration, when the vacuum cleaner 1 is restarted, the previous operation mode selected by the user is unexpectedly short-circuited. It can be easily prevented from switching to.

Further, in the electric vacuum cleaner 1 according to the present embodiment, when the plug-in detection switch 48 is closed, the power cutoff switch 51 is closed to energize the first electric circuit 35 connecting the secondary battery 13 and the switches 26a and 26b, and plug the plug. When the in-detection switch 48 is opened, the power cutoff switch 51 is opened to cut off the energization of the first electric circuit 35 connecting the secondary battery 13 and the switches 26a and 26b. Therefore, the vacuum cleaner 1 can easily detect a "predetermined event" by plugging and unplugging the charging device, and can reliably switch between enabling and disabling the switches 26a and 26b.

Further, when the electric vacuum cleaner 1 according to the present embodiment detects the completion of charging of the secondary battery 13, the power cutoff switch 51 is closed to connect the secondary battery 13 and the switches 26a and 26b. When the electric path 35 is energized and the completion of charging of the secondary battery 13 is not detected, the power cutoff switch 51 is opened to cut off the energization of the first electric path 35 connecting the secondary battery 13 and the switches 26a and 26b. do. Therefore, the vacuum cleaner 1 can easily detect a "predetermined event" by the charging voltage of the secondary battery 13 and reliably switch between enabling and disabling the switches 26a and 26b.

Therefore, according to the vacuum cleaner 1 according to the present embodiment, even if the printed circuit board in the switches 26a and 26b has a decrease in insulation resistance due to electrochemical migration, the decrease in convenience can be suppressed.

Although some embodiments of the present invention have been described, these embodiments are presented as examples and are not intended to limit the scope of the invention. These novel embodiments can be implemented in various other embodiments, and various omissions, replacements, and changes can be made without departing from the gist of the invention. These embodiments and modifications thereof are included in the scope and gist of the invention, and are also included in the scope of the invention described in the claims and the equivalent scope thereof.

1 ... Electric vacuum cleaner, 11 ... Handle, 12 ... Vacuum cleaner body, 13 ... Secondary battery, 15 ... Extension tube, 16 ... Suction port, 17 ... Body case, 17a ... First half, 17b ... Second half, 18 ... Electric blower, 19 ... Dust separation and dust collection unit, 21 ... Main unit control unit, 23 ... Main unit connection port, 25 ... Charging connector, 26a ... Main switch, 26b ... Operation mode changeover switch, 27 ... Suction port, 26 ... Input unit , 28 ... rotary cleaner, 29 ... electric motor, 31, 31A ... input detection circuit, 32 ... charging path connection detection circuit, 35 ... first electric circuit, 36 ... first pull-up resistor, 37 ... first protection resistor, 38 ... Resistor voltage dividing circuit, 39a, 39b ... Resistance, 45 ... Second electric circuit, 46 ... Second pull-up resistance, 47 ... Second protection resistance, 48 ... Plug-in detection switch, 51 ... Power cutoff switch, 61 ... Charging circuit ..

Claims (8)

The suction air passage and
With a rechargeable battery
An electric blower that is driven by the electric power stored in the secondary battery and generates a suction negative pressure in the suction air passage.
An electric circuit to which a voltage is applied by the electric power stored in the secondary battery, and
A first switch provided in the electric circuit to receive an operation input by switching between energization and interruption of the electric circuit.
A second switch provided in the electric circuit connecting the secondary battery and the first switch to switch between energization and disconnection of the electric circuit according to a predetermined event.
A vacuum cleaner including a control unit that changes the operating state of the electric blower when the electric circuit is energized by the first switch. The predetermined event includes charging of the secondary battery and waiting after charging of the secondary battery is completed.
The second switch opens during charging of the secondary battery to cut off the energization of the electric circuit connecting the secondary battery and the first switch, and opens during standby after charging of the secondary battery is completed. The electric vacuum cleaner according to claim 1, wherein the electric circuit connecting the secondary battery and the first switch is cut off. The vacuum cleaner according to claim 1 or 2, wherein the first switch is a tactile switch. A connector for detachably connecting a charging device for charging the secondary battery is provided.
The vacuum cleaner according to any one of claims 1 to 3, wherein a voltage is also applied to the electric circuit by electric power supplied from the charging device via the connector. The vacuum cleaner according to any one of claims 1 to 4, wherein the first switch accepts an operation start operation and an operation stop operation of the electric blower. The vacuum cleaner according to any one of claims 1 to 5, wherein the first switch accepts an operation of switching the operation mode of the electric blower. A connector that detachably connects the charging device that charges the secondary battery,
A third switch that opens when the charging device is connected to the connector and closes when the charging device is removed from the connector.
When the third switch is closed, the second switch is closed to energize the electric circuit connecting the secondary battery and the first switch, and when the third switch is opened, the second switch is opened and the secondary battery is opened. The electric vacuum cleaner according to any one of claims 1 to 3, 5, and 6, which shuts off the energization of the electric circuit connecting the first switch and the first switch. A connector for detachably connecting a charging device for charging the secondary battery is provided.
When the completion of charging of the secondary battery is detected, the secondary switch is closed, the electric circuit connecting the secondary battery and the primary switch is energized, and the charging of the secondary battery is not completed. In the case of detection, according to any one of claims 1 to 3, 5, and 6, the second switch is opened to cut off the energization of the electric circuit connecting the secondary battery and the first switch. Electric vacuum cleaner.

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