JP2022143026A - vacuum cleaner system - Google Patents

Abstract

To provide a vacuum cleaner system capable of cleaning a rotary brush of a suction tool by using sufficient suction force by an electric blower when a vacuum cleaner is placed on a stand without requiring arrangement of a high-capacity power supply circuit in the stand.SOLUTION: A vacuum cleaner system includes a vacuum cleaner and a stand. The stand includes: power supply means for supplying charging power of a secondary battery of the vacuum cleaner to the vacuum cleaner in a state where the vacuum cleaner is placed on the stand; and cleaning means arranged in a placement part on which a suction tool is placed so as to clean a rotary brush. The vacuum cleaner includes: detection means for detecting presence/absence of the supply of the charging power from the power supply means; and control means for performing a rotary brush cleaning operation to operate a brush motor and an electric blower by supplying driving power from the secondary battery when the power supply means starts the supply of the charging power.SELECTED DRAWING: Figure 7

Description

The present disclosure relates to a vacuum cleaner system.

A post for supporting the vacuum cleaner in an upright position, a pedestal for supporting the post, and a mount provided on one end side of the pedestal for placing the suction tool of the vacuum cleaner on the upper side. 2. Description of the Related Art There is known a vacuum cleaner stand comprising a placing section and cleaning means for cleaning a rotating brush provided in the placing section and facing an opening formed in the bottom surface of a suction tool, and having a charging means. (See Patent Document 1, for example). Patent Document 1 describes that power consumption of the battery due to cleaning of the rotating brush is suppressed by rotating the rotating brush when the vacuum cleaner is placed on the vacuum cleaner stand and the battery is being charged. It is

JP 2018-149162 A

As described above, Patent Document 1 suggests rotating the rotating brush with the electric power for charging the battery supplied from the vacuum cleaner stand in order to suppress the power consumption of the battery due to the cleaning of the rotating brush. . However, the current required to obtain sufficient suction power by the electric blower is much higher than the current required to charge the battery. If the electric blower is driven by charging power supplied from the stand, sufficient suction force cannot be obtained. Alternatively, if the power supplied from the stand side is used to obtain a sufficient suction force by the electric blower, the stand must be provided with a large-capacity power supply circuit.

The present disclosure has been made to solve such problems. Its purpose is to allow the electric blower to generate sufficient suction power when the vacuum cleaner is placed on the stand so that the stand does not need to have a larger power supply circuit than is necessary to charge the battery. To provide a vacuum cleaner system capable of cleaning a rotating brush of a tool.

An electric vacuum cleaner system according to the present disclosure includes an electric vacuum cleaner and a stand on which the electric vacuum cleaner is placed. A suction tool having a rotating brush and a brush electric motor for rotating the rotating brush; an electric blower for generating an air flow sucked from the suction port; and supplying power for driving the brush electric motor and the electric blower. and a secondary battery, wherein the stand includes a support section for supporting the vacuum cleaner in an upright position, a pedestal section for supporting the support section, and a base section provided on the pedestal section, and the suction device is provided on an upper side of the stand. a mounting portion on which a tool is placed; power supply means for supplying power for charging the secondary battery to the vacuum cleaner while the vacuum cleaner is placed on the stand; cleaning means for cleaning the rotating brush, the electric vacuum cleaner comprising detection means for detecting whether or not the charging power is supplied from the power supply means; a control means for performing a rotary brush cleaning operation that supplies the drive power from the secondary battery to operate the brush motor and the electric blower when the supply of the charging power is started. .

According to the vacuum cleaner system according to the present disclosure, it is not necessary to equip the stand with a power supply circuit having a capacity larger than that required for charging the battery, and the electric blower is sufficient when the vacuum cleaner is placed on the stand. It is possible to clean the rotating brush of the suction tool by exerting a strong suction force.

Fig. 2 is a perspective view showing a state in which the electric vacuum cleaner according to Embodiment 1 is in use; Fig. 2 is an upper perspective view of a suction tool included in the electric vacuum cleaner according to Embodiment 1; Fig. 3 is a bottom perspective view of a suction tool included in the electric vacuum cleaner according to Embodiment 1; 1 is a perspective view of a stand according to Embodiment 1; FIG. FIG. 2 is an enlarged side view of a main part of the stand according to Embodiment 1; Fig. 2 is a perspective view of the vacuum cleaner placed on the stand of the vacuum cleaner system according to Embodiment 1; 2 is a block diagram showing the configuration of a control system of the vacuum cleaner system according to Embodiment 1; FIG. FIG. 4 is a flow chart showing an operation example of a charge connection detection unit included in the vacuum cleaner according to Embodiment 1; 2 is a block diagram showing the internal configuration of a microcomputer of the vacuum cleaner system according to Embodiment 1; FIG. FIG. 4 is a flow chart showing an operation example of the vacuum cleaner system according to Embodiment 1; FIG. 4 is a flow chart showing an operation example of the vacuum cleaner system according to Embodiment 1; FIG. 4 is a flow chart showing an operation example of the vacuum cleaner system according to Embodiment 1; FIG. 4 is a flow chart showing an operation example of the vacuum cleaner system according to Embodiment 1;

A form for implementing a vacuum cleaner system according to the present disclosure will be described with reference to the accompanying drawings. In each figure, the same or corresponding parts are denoted by the same reference numerals, and overlapping descriptions are appropriately simplified or omitted. In the following description, for the sake of convenience, the positional relationship of each structure may be expressed based on the illustrated state. It should be noted that the present disclosure is not limited to the following embodiments, and any combination of the embodiments, any modification of the constituent elements of the embodiments, or each Any component of the embodiment can be omitted.

Embodiment 1.
Embodiment 1 of the present disclosure will be described with reference to FIGS. 1 to 13 . FIG. 1 is a perspective view showing the state of the vacuum cleaner in use. FIG. 2 is an upper perspective view of a suction tool provided in the vacuum cleaner. FIG. 3 is a bottom perspective view of a suction tool provided in the vacuum cleaner. FIG. 4 is a perspective view of the stand. FIG. 5 is an enlarged side view of the main part of the stand. FIG. 6 is a perspective view of the vacuum cleaner placed on the stand of the vacuum cleaner system. FIG. 7 is a block diagram showing the configuration of the control system of the vacuum cleaner system. FIG. 8 is a flow chart showing an operation example of a charge connection detection unit provided in the vacuum cleaner. FIG. 9 is a block diagram showing the internal configuration of the microcomputer of the vacuum cleaner system. 10 to 13 are flow charts showing an operation example of the vacuum cleaner system.

A vacuum cleaner system 100 according to this embodiment includes a vacuum cleaner 1 and a stand 20 . First, the configuration of the vacuum cleaner 1 will be described with reference to FIG. In the following description, dust and other debris may be collectively referred to simply as "dust." Also, air mixed with dust may be referred to as "dust-containing air". Air from which dust has been removed is sometimes called “clean air”.

The vacuum cleaner 1 is a cordless vertical vacuum cleaner. As shown in FIG. 1, the vacuum cleaner 1 includes a housing 2, an electric blower 3, a battery 4, a cylindrical portion 5, a dust collection portion 6, a handle 7, an extension pipe 9, and a suction tool 10. The electric blower 3 is housed inside the housing 2 . The electric blower 3 generates an airflow for sucking dust. A battery 4 serves as a power source for driving the electric blower 3 . Battery 4 is a rechargeable secondary battery.

The cylindrical portion 5 has a connection port 8 for sucking dust. The connection port 8 is an opening formed at one end of the tubular portion 5 . An air passage is formed inside the tubular portion 5 to guide the airflow of the dust-containing air that has passed through the connection port 8 to the dust collecting portion 6 . A packing (not shown) is provided at the opening edge of the connection port 8 to maintain airtightness when the extension pipe 9 is connected.

The dust collector 6 collects dust. The dust collector 6 separates dust from the dust-containing air sucked from the connection port 8 and collects the dust. The dust collector 6 in this embodiment comprises a cyclone separator. Instead of the dust collection unit 6 having the cyclone separator, for example, a dust collection unit that collects dust by filtering an airflow with a dust collection bag may be provided. The vacuum cleaner 1 has an exhaust port 12. - 特許庁The airflow from which dust has been removed by the dust collector 6 is discharged to the outside through the exhaust port 12 . The handle 7 is a part that is held by the user's hand during use. A user grips the vacuum cleaner 1 by gripping the handle 7 .

Hereinafter, when the vacuum cleaner 1 is upright, the direction in which the connection port 8 is positioned with respect to the handle 7 is defined as the "bottom" of the vacuum cleaner 1, and the opposite side is defined as the "top" of the vacuum cleaner 1. explain. Further, with the vacuum cleaner 1 standing upright, the battery 4, the cylindrical portion 5, and the extension tube 9 are arranged in a direction perpendicular to the direction connecting the top and bottom of the vacuum cleaner 1. ”, and the opposite side is referred to as the “front” of the vacuum cleaner 1 .

The handle 7 extends continuously from a position facing the rear end surface 11 of the upper housing 2 of the vacuum cleaner 1 toward the front side of the vacuum cleaner 1 . A space is formed between the handle 7 and the housing 2 . The fingers of the hand gripping the handle 7 can be inserted into this space.

A battery 4 is assembled on the rear side of the housing 2 . The battery 4 is adjacent to the electric blower 3 on the rear side of the vacuum cleaner 1. - 特許庁The battery 4 is removable from the housing 2 . The battery 4 is removed from the housing 2 by displacing the battery 4 downward from the vacuum cleaner 1 from the housing 2 . Also, the dust collector 6 is removable from the housing 2 . The dust collection part 6 is removed from the housing 2 by displacing the dust collection part 6 from the housing 2 in the upward direction of the electric vacuum cleaner 1 .

The extension pipe 9 is connected to the connection port 8 of the tubular portion 5 . The extension tube 9 is a straight and hollow tubular member. One end of the extension tube 9 is detachable from the connection port 8 of the tubular portion 5 . A suction tool 10 is connected to the other end of the extension pipe 9 .

Next, the configuration of the suction tool 10 of the vacuum cleaner 1 will be described with reference to FIGS. 2 and 3. FIG. The suction tool 10 has an outer shape formed by combining a lower case 41 and an upper case 42 . The external shape of the suction tool 10 presents a laterally long rectangular parallelepiped shape. A connection portion 13 is attached to one end side of the suction tool 10 via a joint portion 14 . The connecting portion 13 and the joint portion 14 are provided at the center of the suction tool 10 in the longitudinal direction.

A connecting portion 13 of the suction tool 10 is connected to the extension pipe 9 . The joint part 14 can change the orientation of the connection part 13 with respect to the suction tool 10 in the front-rear direction and the left-right direction within a preset angle range. That is, the extension pipe 9 connected to the connecting portion 13 can be tilted forward, backward, leftward, and rightward with respect to the suction tool 10 within a preset angle range. A user of the electric vacuum cleaner 1 performs cleaning while holding the handle 7 and tilting the housing 2, for example.

A suction chamber 44 having a horizontally long air passage is provided inside the suction tool 10 . A rotary brush 45 is rotatably accommodated in the suction chamber 44 . The rotating brush 45 has one end supported by a bearing 46 and the other end supported by a rotating brush holder 47 .

The rotating brush 45 is rotationally driven by a brush electric motor 48 incorporated in the suction tool 10 . The driving force of the brush electric motor 48 is transmitted to the rotating brush 45 via, for example, a belt, and rotates the rotating brush 45 in a preset direction. A bottom opening 43 of a suction chamber 44 is formed on the bottom surface of the suction tool 10 . The rotating brush 45 is provided inside the suction tool 10 so as to face the bottom opening 43 .

A suction port 49 is provided on the bottom surface of the suction tool 10 . The suction port 49 is arranged behind the bottom opening 43 on the bottom surface of the suction tool 10 . The suction port 49 communicates with the suction chamber 44 . The suction port 49 also communicates with the connecting portion 13 .

At the bottom of the suction tool 10 are provided wheels 50 supported by support members (not shown). This support member is attached to the suction tool 10 so as to be swingable. In addition, when the suction tool 10 is floating from the floor surface, the support member causes the wheels 50 to protrude toward the floor surface, and when the suction tool 10 is on the floor, the wheels 50 protrude from the suction tool 10 . is configured to be recessed inside the The suction tool 10 incorporates a switch (not shown) that is turned on when the wheel 50 is retracted. When this switch is turned on, the rotating brush 45 becomes drivable.

The electric blower 3 is driven according to the operation of an operation switch provided on the handle 7 . When the electric blower 3 is driven, a suction force acts inside the dust collecting portion 6, the cylindrical portion 5, and the extension pipe 9, and dust-containing air is sucked from the suction tool 10. - 特許庁That is, the airflow sucked from the suction port 49 is generated by the electric blower. At this time, the rotating brush 45 rotates, and the dust and the like that are picked up by the rotation of the rotating brush 45 are also sucked. As described above, the rotating brush 45 is rotationally driven by the brush electric motor 48 . The drive power for the brush motor 48 at this time is supplied from the battery 4 . That is, the battery 4 is a secondary battery that supplies drive power for the brush motor 48 and the electric blower 3 .

The dust-containing air sucked into the suction tool 10 passes through the extension pipe 9 and the cylindrical portion 5 and is taken into the dust collecting portion 6 . In the dust collector 6, dust is separated from the dust-containing air. Clean air discharged from the dust collector 6 passes through the electric blower 3 . The clean air that has passed through the electric blower 3 is discharged to the outside of the housing 2 through the exhaust port 12 .

Although illustration is omitted, the vacuum cleaner 1 can be used by removing the suction tool 10 and the extension pipe 9 . Since the lower end of the tubular portion 5 is located below the lower end of the dust collecting portion 6, when the suction tool 10 and the extension pipe 9 are removed from the vacuum cleaner 1, it protrudes downward from the housing 2. state. In this state, the vacuum cleaner 1 functions as a handy vacuum cleaner.

Next, the configuration of the stand 20 included in the vacuum cleaner system 100 will be described with reference to FIGS. 4 and 5. FIG. The stand 20 is for placing the electric vacuum cleaner 1 in an upright state. As shown in FIG. 4 , the stand 20 includes a pedestal portion 21 , a support portion 22 , a mounting portion 26 and an inclined portion 27 .

The base portion 21 has, for example, a square or rectangular shape when viewed from above. The pedestal portion 21 is formed so that its width in front view and rear view is the same as the longitudinal dimension of the suction tool 10 .

The pillar portion 22 is formed above the pedestal portion 21 . The pillar portion 22 is formed to stand vertically upward from the upper surface of the pedestal portion 21 . The strut portion 22 is a columnar member having the same thickness as the handle 7 . The axis of the pillar portion 22 is positioned at the center of the base portion 21 in the left-right direction. In other words, the support section 22 is positioned at the center of the stand 20 when viewed from the front and rear.

The mounting portion 26 is provided on one end side of the pedestal portion 21 . That is, the mounting portion 26 is provided so as to extend from one end of the pedestal portion 21 toward the side opposite to the support portion 22 . A bottom portion of the mounting portion 26 is in contact with the floor surface. The upper surface of the mounting portion 26 is arranged at a position lower than the upper surface of the pedestal portion 21 on which the strut portion 22 is provided by at least the thickness of the suction tool 10 .

The inclined portion 27 is provided on the opposite side of the mounting portion 26 to the pedestal portion 21 . A bottom portion of the inclined portion 27 is in contact with the floor surface. The inclined portion 27 is inclined so as to gradually become lower as the distance from the placing portion 26 increases. At the connecting portion between the inclined portion 27 and the mounting portion 26, the upper surface of the inclined portion 27 and the upper surface of the mounting portion 26 are smoothly continuous.

As shown in FIGS. 4 and 5, the pedestal portion 21 is provided with a projecting portion 28 . The projecting portion 28 is provided so as to protrude from the upper end portion of the side surface of the pedestal portion 21 on the mounting portion 26 side toward the mounting portion 26 side.

The strut portion 22 includes a handle support portion 23 , a dust collection portion support portion 24 and a connection port receiving portion 25 . The handle support portion 23 is provided at the upper end portion of the strut portion 22 . The dust collecting section support section 24 is fixed to a position in the middle of the support section 22 in the vertical direction. The dust collecting section support section 24 is arranged on the side of the support section 22 on which the mounting section 26 and the inclined section 27 are located. The dust collection part support part 24 has, for example, a cylindrical shape having the same diameter as that of the housing 2 and the dust collection part 6 . The connection port receiving portion 25 is arranged on the side of the dust collecting portion supporting portion 24 on which the mounting portion 26 and the inclined portion 27 are located.

As shown in FIGS. 4 and 5, the stand 20 has a rotary brush cleaning section 30. As shown in FIG. An upper surface of the mounting portion 26 and an upper surface of the inclined portion 27 are a mounting surface portion 29 . The rotary brush cleaning part 30 is attached to this attachment surface part 29 . The rotating brush cleaning section 30 is cleaning means for cleaning the rotating brush 45 of the suction tool 10 mounted on the mounting section 26, as will be described later. Note that the rotating brush cleaning section 30 on the inclined section 27 may not be provided.

The rotating brush cleaning section 30 includes a flocking section 31 . The flocked portion 31 is provided on the upper surface of the rotating brush cleaning portion 30 . The flocked portion 31 is made of, for example, short-haired inclined pile. The inclined pile of the flocked portion 31 of the mounting portion 26 protrudes from the upper surface of the rotary brush cleaning portion 30 and is inclined so as to face the side opposite to the base portion 21 . The inclined pile of the flocked portion 31 of the inclined portion 27 protrudes from the upper surface of the rotary brush cleaning portion 30 and is inclined so as to face the pedestal portion 21 side.

Next, the vacuum cleaner system 100 with the vacuum cleaner 1 placed on the stand 20 will be described with reference to FIG. The strut portion 22 configured as described above is for supporting the vacuum cleaner 1 in an upright state. Moreover, the pedestal portion 21 supports the support portion 22 . And the mounting part 26 is for mounting the suction tool 10 of the electric vacuum cleaner 1 on the upper side.

That is, as shown in the figure, the vacuum cleaner 1 is placed on the stand 20 with the front side of the vacuum cleaner 1 directed toward the support 22 of the stand 20 . The suction tool 10 is placed on the upper surface of the placing portion 26 while the vacuum cleaner 1 is placed on the stand 20 . Also, in this state, the handle 7 is placed on the upper surface of the handle support portion 23 . In this state, the dust collection section 6 is placed on the upper surface of the dust collection section support section 24 . Furthermore, in this state, the connection port receiving portion 25 supports a portion of the lower end side of the tubular portion 5 including the connection port 8 and a portion of the upper end side of the extension pipe 9 .

In this way, the post 22 is provided so as to be able to support the vacuum cleaner 1 with the front side of the suction tool 10 facing the base 21 . The rotating brush cleaning unit 30 is placed under the bottom opening 43 of the suction tool 10 in a state where the support 22 supports the vacuum cleaner 1 and the suction tool 10 is placed on the upper surface of the mounting part 26. It is provided in the position where it is arranged at least.

The stand 20 in the vacuum cleaner system 100 according to this embodiment is a charging stand that also serves as a charging device for the vacuum cleaner 1 . By placing the vacuum cleaner 1 on the stand 20 when not in use, the battery 4 of the vacuum cleaner 1 can be charged.

As shown in FIG. 7 , the stand 20 has a power plug 71 , a voltage converter 72 and a stand-side electrode 73 . The power plug 71 is connected to, for example, a commercial power outlet. The voltage converter 72 converts the AC voltage (for example, 100 V AC) of the commercial power supplied through the power plug 71 into any DC voltage (for example, 30 V DC). The DC voltage converted by the voltage converter 72 is output from the stand-side electrode 73 . The stand-side electrode 73 is provided on the handle support portion 23 of the stand 20 .

A cleaner-side electrode 62 is provided at the front lower end of the handle 7 on the vacuum cleaner 1 side. When the vacuum cleaner 1 is appropriately placed on the stand 20, the cleaner-side electrode 62 and the stand-side electrode 73 are electrically connected. Therefore, by properly placing the vacuum cleaner 1 on the stand 20 , the DC voltage output from the voltage converter 72 of the stand 20 is input to the cleaner-side electrode 62 of the vacuum cleaner 1 . This DC voltage is for charging the battery 4 of the vacuum cleaner 1 . In this way, the stand 20 has power supply means for supplying power for charging the battery 4 to the vacuum cleaner 1 while the vacuum cleaner 1 is placed on the stand 20 .

The vacuum cleaner 1 incorporates a control board 60 in addition to the electric blower 3 and the battery 4 described above. The control board 60 is provided with a microcomputer 61 , a voltage determination section 63 , a charging connection detection section 64 , a first current detector 65 , a second current detector 66 , a voltage detector 67 and a temperature detector 68 . The electric power discharged from the battery 4 is supplied not only to the electric blower 3 and the brush motor 48 but also to the microcomputer 61 .

The microcomputer 61 is a microcomputer. That is, the microcomputer 61 has a processor and memory. The microcomputer 61 executes a preset process by causing the processor to execute a program stored in the memory, and performs electric power including the suction operation of the electric blower 3, the operation of the brush motor 48, the charging and discharging of the battery 4, and the like. It controls the overall operation of the cleaner 1 .

A charging connection detection unit 64 is configured by the voltage determination unit 63 and the microcomputer 61 . The voltage determination unit 63 determines the voltage input to the cleaner-side electrode 62 . Based on the voltage X of the cleaner-side electrode 62, the charge connection detection unit 64 determines whether the vacuum cleaner 1 is connected to the stand 20, which is a charging stand. Detect whether power is supplied. The charging connection detection unit 64 is detection means for detecting whether charging power is supplied from the power supply means.

Two types of determination threshold values (threshold value A and threshold value B) are preset in the voltage determination unit 63 . Threshold A<threshold B. The voltage determination unit 63 compares the voltage X of the cleaner-side electrode 62 with the threshold A and the threshold B. FIG. Then, the microcomputer 61 determines the charging connection state of the vacuum cleaner 1 based on the comparison result of the voltage determining section 63 .

An example of the determination operation of the charge connection state of the vacuum cleaner 1 by the charge connection detection unit 64 as the detection means will be described with reference to the flowchart of FIG. 8 . First, in step S<b>1 , when power is supplied to the microcomputer 61 , the microcomputer 61 is activated, and the charge connection detector 64 is also activated.

In subsequent step S2, the voltage determination unit 63 compares the voltage X of the cleaner-side electrode 62 with the threshold A and the threshold B. FIG. If voltage X<threshold A, then the microcomputer 61 performs the process of step S3. In step S3, the microcomputer 61 determines that the vacuum cleaner 1 is not connected to the charging base (stand 20) and that charging power is not supplied from the power supply means. After step S3, the microcomputer 61 returns to step S2 to continue processing.

Also, if voltage X>threshold B in step S2, the microcomputer 61 then performs the process of step S4. In step S4, microcomputer 61 determines that vacuum cleaner 1 is connected to an abnormal charger. After step S4, the microcomputer 61 returns to step S2 to continue processing.

On the other hand, if threshold A<voltage X<threshold B in step S2, the microcomputer 61 next performs the process of step S5. In step S5, the microcomputer 61 determines that the vacuum cleaner 1 is connected to the charging base (stand 20) and that charging power is being supplied from the power supply means. After step S5, the voltage determination unit 63 next performs the process of step S6.

In step S6, the voltage determination unit 63 compares the voltage X of the cleaner-side electrode 62 with the threshold values A and B again. If voltage X>threshold B, microcomputer 61 returns to step S4 to continue processing. Further, if threshold A<voltage X<threshold B in step S6, the microcomputer 61 next performs the process of step S7. In step S7, the microcomputer 61 determines that the electric vacuum cleaner 1 is connected to the charging base (stand 20) and that charging power is being supplied from the power supply means. After step S7, the microcomputer 61 returns to step S5 to continue processing.

On the other hand, if voltage X<threshold A in step S6, then the microcomputer 61 performs the process of step S8. In step S8, the microcomputer 61 determines that the vacuum cleaner 1 has been removed from the charging base (stand 20), that is, the supply of charging power from the power supply means has been stopped. After step S8, the microcomputer 61 returns to step S2 to continue processing.

The first current detector 65 detects the current flowing through the brush motor 48 . A second current detector 66 detects the current flowing through the electric blower 3 . A voltage detector 67 detects the voltage output from the battery 4 . A temperature detector 68 detects the temperature of the electric blower 3 . The temperature detector 68 is arranged at a position separated from the electric blower 3 in the air passage inside the vacuum cleaner 1 by a certain distance.

As shown in FIG. 7 , the vacuum cleaner 1 has an operation section 15 . The operation unit 15 includes the operation switches described above. In addition, as shown in the figure, the vacuum cleaner 1 has a notification unit 69 . The notification unit 69 is for giving various notifications to the user of the vacuum cleaner 1 . The notification unit 69 includes, for example, a light emitting diode (LED), a speaker, a liquid crystal display, and the like.

In the vacuum cleaner 1 of the vacuum cleaner system 100 configured as described above, the microcomputer 61 controls the operation of the electric blower 3 and the brush motor 48, controls the charging and discharging of the battery 4, and performs notification by the notification unit 69. It is control means for controlling the operation. The microcomputer 61, which is a control means, performs these controls based on the operation contents of the operation unit 15, the charging connection detection unit 64, the first current detector 65, the second current detector 66, the voltage detector 67, and the temperature detection unit. Based on the detection result of the device 68.

As shown in FIG. 9, the microcomputer 61 includes an input/output section 61a, a peripheral circuit section 61b, a central processing section 61c, and a storage section 61d. The operation signal output from the operation unit 15, and the detection signals output from each of the charging connection detection unit 64, the first current detector 65, the second current detector 66, the voltage detector 67, and the temperature detector 68 are , is input to the microcomputer 61 via the input/output unit 61a. The central processing unit 61c is the processor described above. The storage unit 61d is the memory described above.

The central processing unit 61c reads and executes a program stored in the storage unit 61d, and performs arithmetic processing based on the operation signal and the detection signal acquired via the peripheral circuit unit 61b. As a result of this arithmetic processing, the control contents of the operations of the electric blower 3 and the brush motor 48, the charge/discharge of the battery 4, and the notification operation by the notification unit 69 are determined. The determined control content is output as a control signal from the input/output section 61a via the peripheral circuit section 61b. Then, according to the control signal output from the microcomputer 61, the operation of the electric blower 3 and the brush motor 48, charging and discharging of the battery 4, and notification operation by the notification unit 69 are performed.

In the vacuum cleaner 1 of the vacuum cleaner system 100 configured as described above, the rotary brush 45 rotates to scrape up dust and the like when the vacuum cleaner 1 is used, as described above. When dust or the like is scraped up by the rotation of the rotating brush 45, lint, fibrous material, hair, or the like is entangled and wound around the rotating brush 45. , lint, etc. may adhere to the tip of the cleaning body 33 and become clumps that cannot be removed.

In contrast, the stand 20 of the vacuum cleaner system 100 configured as described above can remove dust and the like attached to the rotating brush 45 . The removal of dust and the like attached to the rotating brush 45 by the stand 20 according to this embodiment will be described below.

For example, when the user finishes using the vacuum cleaner 1 and tries to place the vacuum cleaner 1 on the stand 20, the user first holds the handle 7 of the vacuum cleaner 1 and holds the suction tool 10. The front side of the suction tool 10 is directed to the stand 20, and the suction tool 10 is ridden on the inclined part 27 from the front side of the suction tool 10. - 特許庁Then, the suction tool 10 passes over the rotary brush cleaning part 30 on the upper surface of the inclined part 27 . When the rotating brush 45 of the suction tool 10 passes over the rotating brush cleaning portion 30 of the inclined portion 27, the rotating brush 45 and the flocked portion 31 of the rotating brush cleaning portion 30 come into contact with each other. Therefore, the flocked portion 31 removes dust and the like adhering to the rotating brush 45 .

Further, when the user pushes the vacuum cleaner 1 further, the suction tool 10 completely passes through the inclined portion 27 and is placed on the upper surface of the placing portion 26 . When the user stands the electric vacuum cleaner 1 forward from this state, the handle 7 is placed on the upper surface of the handle support portion 23 and the dust collection portion 6 is placed on the upper surface of the dust collection portion support portion 24 . A portion of the lower end side of the cylindrical portion 5 including the connection port 8 and a portion of the upper end side of the extension pipe 9 are supported by the connection port receiving portion 25, resulting in the state shown in FIG.

In the state shown in FIG. 6, the rotating brush cleaning section 30 of the mounting section 26 is arranged below the bottom opening 43 of the suction tool 10, as described above. Therefore, in this state, the rotating brush cleaning part 30 of the mounting part 26 is in contact with the rotating brush 45 this time. In the state shown in FIG. 6, the cleaner-side electrode 62 and the stand-side electrode 73 are electrically connected. Then, the charge connection detection unit 64 detects that the supply of the charging power described above from the power supply means described above has started.

In this embodiment, the microcomputer 61, which is the control means, causes the electric vacuum cleaner 1 to perform the rotating brush cleaning operation. The rotating brush cleaning operation is to operate the brush electric motor 48 and the electric blower 3 by supplying driving power from the battery 4 which is a secondary battery. It is desirable to stop charging the battery 4 during this rotating brush cleaning operation. However, the charging of the battery 4 and the rotating brush cleaning operation may be performed in parallel.

When the electric vacuum cleaner 1 performs the rotary brush cleaning operation in the state shown in FIG. Dust and the like can be removed. Furthermore, at this time, the removed dust and the like can be sucked from the suction port 49 .

While the electric current required for charging the battery 4 is about 2 A at most, the electric current required for driving the electric blower 3 to obtain a sufficient attractive force is 10 A or more. When the electric blower 3 is driven by the charging power supplied from the stand 20 side, sufficient suction power cannot be obtained, or the charging power supplied from the stand 20 side does not provide sufficient suction power by the electric blower 3. In order to achieve this, it is necessary to provide a large-capacity voltage conversion section 72 of the stand 20 corresponding to a current of 10 A or more. On the other hand, according to the vacuum cleaner system 100 according to this embodiment, the stand 20 does not need to be provided with power supply means having a larger capacity than that necessary for charging the battery 4, and the vacuum cleaner 1 can be installed in the stand 20. is placed, the electric blower 3 exerts a sufficient suction force to clean the rotating brush 45 of the suction tool 10.例文帳に追加

Here, the projecting portion 28 of the pedestal portion 21 is arranged above the upper surface of the suction tool 10 placed on the placing portion 26 . Therefore, when the suction tool 10 placed on the upper side of the mounting part 26 tries to move upward, that is, in a direction away from the mounting part 26, the suction tool 10 hits the projecting part 28 and is prevented from moving. That is, the protruding portion 28 constitutes movement restricting means for restricting movement of the suction tool 10 placed on the placing portion 26 in a direction away from the placing portion 26 .

When the rotating brush 45 rotates in a state where the rotating brush cleaning unit 30 is in contact with the rotating brush 45 from below, the rotating brush 45 moves away from the rotating brush cleaning unit 30 due to the resistance between the rotating brush 45 and the rotating brush cleaning unit 30 . It tries to move away from, that is, upwards. If the rotating brush 45 is separated from the rotating brush cleaning section 30, the effect of the rotating brush cleaning section 30 for removing dust and the like adhering to the rotating brush 45 is reduced.

On the other hand, in the stand 20 according to this embodiment, the movement of the suction tool 10 placed on the mounting portion 26 in the direction away from the mounting portion 26 is restricted by the protruding portion 28 as the movement restricting means. be. Therefore, when the rotating brush cleaning section 30 cleans the rotating brush 45 , the rotating brush 45 and the suction tool 10 are prevented from moving away from the rotating brush cleaning section 30 . Therefore, when the rotating brush cleaning unit 30 cleans the rotating brush 45, the rotating brush cleaning unit 30 and the rotating brush 45 can be kept in proper contact with each other. Therefore, the dust adhering to the rotating brush 45 can be stably removed.

As can be seen from the above description, the height from the mounting portion 26 to the projecting portion 28 is set so that the rotating brush cleaning portion 30 can maintain contact with the rotating brush 45 even when the suction tool 10 moves upward. adjusted. In other words, there may be a gap between the upper surface of the suction tool 10 placed on the placing portion 26 and the projecting portion 28 . However, even when the suction tool 10 moves upward until the upper surface of the suction tool 10 hits the protruding part 28, this gap is set to a distance that allows the rotating brush cleaning part 30 at the projecting position to keep in contact with the rotating brush 45. set.

In this embodiment, the microcomputer 61, which is control means, terminates the rotating brush cleaning operation when a preset rotating brush cleaning operation termination condition is satisfied during the rotating brush cleaning operation. As a condition for ending the rotating brush cleaning operation, for example, a certain period of time has elapsed after starting the rotating brush cleaning operation. In this case, the microcomputer 61, which is the control means, terminates the rotating brush cleaning operation when a predetermined time has elapsed since the rotating brush cleaning operation was started. This certain period of time is specifically set to, for example, 10 seconds. After completing the rotating brush cleaning operation, the microcomputer 61 starts charging the battery 4 with the charging power supplied from the stand 20 side. By doing so, the rotary brush cleaning operation started when the vacuum cleaner 1 is placed on the stand 20 is automatically terminated, and the battery 4 is charged, so that the vacuum cleaner 1 can be used from the next time onwards. be prepared.

Another example of the conditions for ending the cleaning operation of the rotating brush is that the voltage of the battery 4 drops below the reference voltage. In this case, the microcomputer 61, which is the control means, terminates the rotating brush cleaning operation when the voltage of the battery 4 drops below a preset first reference voltage during the rotating brush cleaning operation. After completing the rotating brush cleaning operation, the microcomputer 61 starts charging the battery 4 with the charging power supplied from the stand 20 side. The microcomputer 61 determines based on the detection signal of the voltage detector 67 whether the voltage of the battery 4 is equal to or lower than the first reference voltage.

On the other hand, when the vacuum cleaner 1 is detached from the stand 20 and performing a normal cleaning operation, the microcomputer 61 controls the electric blower 3 when the voltage of the battery 4 drops below the preset second reference voltage. to stop That is, when the voltage of the battery 4 drops below the second reference voltage while the electric blower 3 is operating in a state where charging power is not supplied from the power supply means of the stand 20, the microcomputer 61, which is the control means, Then, the electric blower 3 is stopped. Here, the second reference voltage is set to a value higher than the first reference voltage, which serves as a reference for stopping the rotating brush cleaning operation described above.

Since the electric vacuum cleaner 1 is placed on the stand 20 during the rotating brush cleaning operation, when the voltage of the battery 4 drops below the reference voltage, the rotating brush cleaning operation is stopped and charging of the battery 4 is immediately started. can. On the other hand, during a normal cleaning operation, the vacuum cleaner 1 is removed from the stand 20, so even if the voltage of the battery 4 drops below the reference voltage, the battery 4 cannot be charged immediately. Therefore, different discharge end voltages are set for the rotating brush cleaning operation and the normal cleaning operation, and the second reference voltage, which is the discharge end voltage for the normal cleaning operation, is set as the discharge end voltage for the rotating brush cleaning operation. By making it higher than the second reference voltage, it is possible to extend the drive time while suppressing overdischarge of the battery 4 .

The condition for ending the rotating brush cleaning operation may include the amount of dust sucked by the vacuum cleaner 1 during the rotating brush cleaning operation. In this case, the vacuum cleaner 1 has a dust sensor (not shown). The dust sensor is, for example, a sensor that detects the amount of dust or the like passing through the cylindrical portion 5 and collected by the dust collecting portion 6 . Based on the detection result of the dust sensor during the rotating brush cleaning operation, the microcomputer 61 performs the rotating brush cleaning operation when the amount of dust or the like collected by the rotating brush cleaning operation reaches a preset reference amount. terminate.

The microcomputer 61, which is a control means, terminates the rotating brush cleaning operation when no electric current is flowing to the brush electric motor 48 during the rotating brush cleaning operation. After finishing the rotating brush cleaning operation, the microcomputer 61 starts charging the battery 4 with charging power supplied from the stand 20 side. The microcomputer 61 determines based on the detection signal of the first current detector 65 whether current is flowing through the brush motor 48 . When no current is flowing to the brush motor 48, it can be determined that the vacuum cleaner 1 is placed on the stand 20 without the suction tool 10 attached to the vacuum cleaner 1. - 特許庁In such a case, even if only the electric blower 3 is operated, the rotating brush 45 of the suction tool 10 cannot be cleaned. Therefore, in such a case, by ending the rotary brush cleaning operation, it is possible to suppress wasteful operations and reduce the remaining amount of the battery 4 .

The conditions for ending the rotary brush cleaning operation may include detection of an abnormality in the vacuum cleaner 1 . In this case, the microcomputer 61, which is the control means, terminates the rotating brush cleaning operation when an abnormality of the electric vacuum cleaner 1 is detected during the rotating brush cleaning operation. Then, after finishing the rotating brush cleaning operation, the battery 4 is started to be charged with the charging power supplied from the stand 20 side. The microcomputer 61 detects an abnormality of the vacuum cleaner 1 in the following cases, for example.

When the first current detector 65 detects a current equal to or higher than a preset overcurrent reference value When the second current detector 66 detects a current equal to or higher than a preset overcurrent reference value Temperature When a high temperature equal to or higher than a preset reference temperature is detected by the detector 68

When such an abnormality of the electric vacuum cleaner 1 is detected, the cleaning operation of the rotating brush is promptly terminated, so that the electric blower 3 and the electric brush motor 48 are kept operating in an abnormal state to prevent damage caused by continuing to operate. , the occurrence of failures and the like can be suppressed.

In particular, when a current exceeding a preset overcurrent reference value is detected by the first current detector 65 , that is, when an overcurrent occurs in the brush motor 48 , a large amount of dust or the like accumulates on the rotating brush 45 . It is highly probable that the rotating brush 45 cannot rotate due to the adhesion of , and the brush electric motor 48 is locked. Therefore, in such a case, it is preferable that the microcomputer 61 causes the notification unit 69 to issue a notification to prompt the user to manually remove the dust and the like adhering to the rotating brush 45 . The notification unit 69 in this case is an example of notification means for notifying the user when an overcurrent occurs in the brush electric motor 48 during the rotating brush cleaning operation.

The rotary brush cleaning operation end condition may include that a specific operation is performed on the vacuum cleaner 1 . In this case, the microcomputer 61, which is the control means, terminates the rotating brush cleaning operation when the electric vacuum cleaner 1 is subjected to a preset stop operation during the rotating brush cleaning operation. After completing the rotating brush cleaning operation, the microcomputer 61 starts charging the battery 4 with the charging power supplied from the stand 20 side. The stop operation includes, for example, an operation to the power "off" switch of the operation unit 15, an operation to the operation "stop" switch of the operation unit 15, and the like. By doing so, when the user does not want the rotating brush cleaning operation, the rotating brush cleaning operation can be stopped, and convenience can be improved.

Further, when the electric vacuum cleaner 1 is placed on the stand 20 but is not in the rotating brush cleaning operation, the rotating brush cleaning operation may be performed by the user's operation. In this case, the microcomputer 61, which is the control means, is supplied with charging power from the power supply means of the stand 20, and when the rotating brush cleaning operation is not being performed, the preset start operation is started by the vacuum cleaner. When done, initiate a rotating brush cleaning operation. As the start operation, for example, an operation to the operation "start" switch of the operation unit 15 can be mentioned. In this way, after the rotating brush cleaning operation is performed once and then automatically stopped, when the user desires to perform the rotating brush cleaning operation again, the rotating brush cleaning operation can be performed, which is convenient. can be improved.

Furthermore, it may be possible to set in advance whether or not to perform the rotating brush cleaning operation when the vacuum cleaner 1 is placed on the stand 20 . That is, it may be possible to set whether or not to perform the rotating brush cleaning operation when the charging power supply is started from the power supply means of the stand 20 . In this case, for example, the user can set whether or not to perform the rotating brush cleaning operation when the vacuum cleaner 1 is placed on the stand 20 by operating the operation unit 15 . The setting information at this time is stored in the storage unit 61d of the microcomputer 61, for example. The operation unit 15 and the microcomputer 61 in such a configuration are an example of setting means capable of setting whether or not to perform the rotating brush cleaning operation when the supply of charging power from the power supply means of the stand 20 is started. . By providing such setting means, it is possible to further improve convenience.

Next, an example of the operation of the vacuum cleaner system 100 configured as described above will be described with reference to the flowcharts of FIGS. 10 to 13. FIG. First, with reference to FIG. 10, an example of the operation flow when the vacuum cleaner 1 is placed on the stand 20 and the rotary brush cleaning operation is not performed will be described. First, in step S10, when the charging connection detection unit 64 of the vacuum cleaner 1 detects that charging power has started to be supplied from the power supply means of the stand 20, in the following step S11, the microcomputer 61 detects that the stand The battery 4 is charged with the charging power supplied from the 20 side. After step S11, the microcomputer 61 next performs the process of step S12.

In step S12, the microcomputer 61 determines whether or not the voltage of the battery 4 detected by the voltage detector 67 is equal to or higher than a preset charging completion voltage. If the voltage of the battery 4 is less than the charging completion voltage, the microcomputer 61 returns to step S11 and continues processing. On the other hand, if the voltage of the battery 4 becomes equal to or higher than the charging completion voltage, the microcomputer 61 next performs the process of step S13. In step S<b>13 , the microcomputer 61 terminates charging of the battery 4 . When the process of step S13 is completed, the series of operations is finished.

Next, with reference to FIG. 11, an example of the operation flow when performing the rotary brush cleaning operation when the vacuum cleaner 1 is placed on the stand 20 will be described. First, in step S20, when the charging connection detection unit 64 of the vacuum cleaner 1 detects that charging power has started to be supplied from the power supply means of the stand 20, in the subsequent step S21, the microcomputer 61 The rotating brush cleaning operation of the vacuum cleaner 1 is started. That is, the microcomputer 61 supplies drive power from the battery 4 to operate the brush motor 48 and the electric blower 3 . After step S21, the microcomputer 61 next performs the process of step S22.

In step S22, the microcomputer 61 determines whether or not the above-described rotating brush cleaning operation end condition is satisfied. If the rotating brush cleaning operation end condition is not satisfied, the microcomputer 61 returns to the process of step S21 to continue the rotating brush cleaning operation. On the other hand, if the rotating brush cleaning operation end condition is satisfied, the microcomputer 61 next performs the process of step S23.

In step S<b>23 , the microcomputer 61 terminates the rotating brush cleaning operation of the vacuum cleaner 1 . That is, the microcomputer 61 stops the brush motor 48 and the electric blower 3 . In subsequent step S24, the microcomputer 61 charges the battery 4 with the charging power supplied from the stand 20 side. After step S24, the microcomputer 61 next performs the process of step S25.

In step S25, the microcomputer 61 determines whether or not the voltage of the battery 4 detected by the voltage detector 67 is equal to or higher than the aforementioned charge completion voltage. If the voltage of the battery 4 is less than the charging completion voltage, the microcomputer 61 returns to the process of step S24 to continue charging the battery 4. On the other hand, if the voltage of the battery 4 becomes equal to or higher than the charging completion voltage, the microcomputer 61 next performs the process of step S26. In step S26, the microcomputer 61 terminates charging of the battery 4. FIG. When the process of step S26 is completed, the series of operations is terminated.

Next, an example of the operation flow when an abnormality of the vacuum cleaner 1 is detected during the rotating brush cleaning operation will be described with reference to FIG. 12 . First, in step S30, when the charging connection detection unit 64 of the vacuum cleaner 1 detects that charging power has started to be supplied from the power supply means of the stand 20, in the subsequent step S31, the microcomputer 61 The rotating brush cleaning operation of the vacuum cleaner 1 is started. That is, the microcomputer 61 supplies drive power from the battery 4 to operate the brush motor 48 and the electric blower 3 . After step S31, the microcomputer 61 next performs the process of step S32.

In step S32, the microcomputer 61 determines whether or not the above-described rotating brush cleaning operation end condition is satisfied. If the rotating brush cleaning operation end condition is not satisfied, the microcomputer 61 returns to the process of step S31 to continue the rotating brush cleaning operation. On the other hand, if the rotating brush cleaning operation end condition is satisfied, the microcomputer 61 next performs the process of step S33.

In step S<b>33 , the microcomputer 61 terminates the rotating brush cleaning operation of the vacuum cleaner 1 . That is, the microcomputer 61 stops the brush motor 48 and the electric blower 3 . In subsequent step S34, the microcomputer 61 determines whether or not the condition for ending the rotating brush cleaning operation established in step S32 is an overcurrent caused by locking of the brush motor 48 or not. If the established rotating brush cleaning operation end condition is overcurrent due to locking of the brush motor 48, the microcomputer 61 then performs the process of step S35.

In step S35, the microcomputer 61 causes the notification section 69 to notify that the rotating brush 45 cannot be rotated. After step S35, the microcomputer 61 next performs the process of step S36. Further, if the rotating brush cleaning end condition established in step S34 is not an overcurrent due to locking of the brush motor 48, the microcomputer 61 proceeds to step S36 without performing step S35.

In step S36, the microcomputer 61 charges the battery 4 with the charging power supplied from the stand 20 side. After step S36, the microcomputer 61 next performs the process of step S37. In step S37, the microcomputer 61 determines whether or not the voltage of the battery 4 detected by the voltage detector 67 is equal to or higher than the charging completion voltage described above. If the voltage of the battery 4 is less than the charging completion voltage, the microcomputer 61 returns to the process of step S36 to continue charging the battery 4. On the other hand, if the voltage of the battery 4 becomes equal to or higher than the charging completion voltage, the microcomputer 61 next performs the process of step S38. In step S38, the microcomputer 61 terminates charging of the battery 4. FIG. When the process of step S38 is completed, the series of operations is terminated.

Next, an example of the operation flow when restarting the rotating brush cleaning operation after the rotating brush cleaning operation will be described with reference to FIG. 13 . First, in step S40, when the charge connection detection unit 64 of the vacuum cleaner 1 detects that the charging power supply has started from the power supply means of the stand 20, in the following step S41, the microcomputer 61 The rotating brush cleaning operation of the vacuum cleaner 1 is started. That is, the microcomputer 61 supplies drive power from the battery 4 to operate the brush motor 48 and the electric blower 3 . After step S41, the microcomputer 61 next performs the process of step S42.

In step S42, the microcomputer 61 determines whether or not the above-described rotating brush cleaning operation end condition is satisfied. If the rotating brush cleaning operation end condition is not satisfied, the microcomputer 61 returns to the process of step S41 to continue the rotating brush cleaning operation. On the other hand, if the rotating brush cleaning operation end condition is satisfied, the microcomputer 61 next performs the process of step S43.

In step S43, the microcomputer 61 terminates the rotating brush cleaning operation of the vacuum cleaner 1. FIG. That is, the microcomputer 61 stops the brush motor 48 and the electric blower 3 . In subsequent step S44, the microcomputer 61 charges the battery 4 with the charging power supplied from the stand 20 side. After step S44, the microcomputer 61 next performs the process of step S45.

In step S45, the microcomputer 61 determines whether or not the operation unit 15 has been operated to start. If the start operation has been performed, the microcomputer 61 next performs the process of step S46. In step S46, the microcomputer 61 suspends charging of the battery 4 once. After step S46, the microcomputer 61 returns to the process of step S41 and restarts the rotating brush cleaning operation.

On the other hand, if the start operation is not performed in step S45, the microcomputer 61 next performs the processing of step S47. In step S47, the microcomputer 61 determines whether or not the voltage of the battery 4 detected by the voltage detector 67 is equal to or higher than the aforementioned charge completion voltage. If the voltage of the battery 4 is less than the charging completion voltage, the microcomputer 61 returns to the process of step S44 to continue charging the battery 4. On the other hand, if the voltage of the battery 4 becomes equal to or higher than the charging completion voltage, the microcomputer 61 next performs the process of step S48. In step S48, the microcomputer 61 terminates charging of the battery 4. FIG. When the process of step S48 is completed, the series of operations is terminated.

1 Vacuum Cleaner 2 Housing 3 Electric Air Blower 4 Battery 5 Cylindrical Part 6 Dust Collection Part 7 Handle 8 Connection Port 9 Extension Pipe 10 Suction Tool 11 Rear End Face 12 Exhaust Port 13 Connection Part 14 Joint Part 15 Operation Part 20 Stand 21 Pedestal Part 22 Strut Part 23 Handle Supporting Part 24 Dust Collecting Part Supporting Part 25 Connection Port Receiving Part 26 Mounting Part 27 Inclined Part 28 Protruding Part 29 Mounting Surface Part 30 Rotating Brush Cleaning Part 31 Hair Planting Part 41 Lower Case 42 Upper Case 43 Bottom Opening 44 Suction chamber 45 Rotating brush 46 Bearing 47 Rotating brush holder 48 Electric motor for brush 49 Suction port 50 Wheel 60 Control board 61 Microcomputer 61a Input/output unit 61b Peripheral circuit unit 61c Central processing unit 61d Storage unit 62 Vacuum cleaner side electrode 63 Voltage Determination unit 64 charging connection detection unit 65 first current detector 66 second current detector 67 voltage detector 68 temperature detector 69 notification unit 71 power plug 72 voltage conversion unit 73 stand-side electrode 100 vacuum cleaner system

Claims (11)

a vacuum cleaner and
and a stand on which the vacuum cleaner is placed,
The vacuum cleaner is
a suction tool having a suction port formed on a bottom surface, and having a rotating brush facing the suction port and a brush electric motor for rotating the rotating brush;
an electric blower that generates an airflow sucked from the suction port;
a secondary battery that supplies drive power for the brush motor and the electric blower,
The stand is
a strut for supporting the vacuum cleaner in an upright position;
a pedestal for supporting the support;
a placing portion provided on the pedestal portion on which the suction tool is placed;
power supply means for supplying power for charging the secondary battery to the vacuum cleaner while the vacuum cleaner is placed on the stand;
cleaning means provided on the mounting portion for cleaning the rotating brush;
The vacuum cleaner is
detection means for detecting whether or not the charging power is supplied from the power supply means;
Control means for performing a rotating brush cleaning operation for supplying the drive power from the secondary battery to operate the brush motor and the electric blower when the charging power supply is started from the power supply means. and a vacuum cleaner system further comprising: 2. The electric vacuum cleaner system according to claim 1, wherein said control means terminates said rotating brush cleaning operation when a predetermined time has elapsed since said rotating brush cleaning operation was started. 3. The control means terminates the rotating brush cleaning operation when the voltage of the secondary battery drops below a preset first reference voltage during the rotating brush cleaning operation. A vacuum cleaner system as described. When the voltage of the secondary battery drops below a preset second reference voltage while the electric blower is operating in a state where the charging power is not supplied from the power supply means, Stopping the electric blower,
4. The vacuum cleaner system of claim 3, wherein said second reference voltage is greater than said first reference voltage. The electric vacuum cleaner according to any one of claims 1 to 4, wherein the control means terminates the rotating brush cleaning operation when current is not flowing to the brush electric motor during the rotating brush cleaning operation. machine system. The vacuum cleaner according to any one of claims 1 to 5, wherein the control means terminates the rotating brush cleaning operation when an abnormality of the vacuum cleaner is detected during the rotating brush cleaning operation. machine system. 7. The vacuum cleaner according to any one of claims 1 to 6, further comprising notification means for notifying a user when an overcurrent occurs in the brush motor during the rotating brush cleaning operation. machine system. The control device according to any one of claims 1 to 7, wherein the control means terminates the rotating brush cleaning operation when a preset stop operation is performed on the electric vacuum cleaner during the rotating brush cleaning operation. A vacuum cleaner system as described. The control means is supplied with the charging power from the power supply means, and
9. The electric appliance according to any one of claims 1 to 8, wherein the electric vacuum cleaner starts the rotating brush cleaning operation when a preset start operation is performed on the electric vacuum cleaner when the rotating brush cleaning operation is not in progress. cleaner system. 10. The apparatus according to any one of claims 1 to 9, further comprising setting means capable of setting whether or not to perform the rotating brush cleaning operation when supply of the charging power from the power supply means is started. A vacuum cleaner system as described. The control means is
stopping charging of the secondary battery with the charging power during the rotating brush cleaning operation;
The electric vacuum cleaner system according to any one of claims 1 to 10, wherein charging of the secondary battery with the charging power is started after the rotating brush cleaning operation is finished.

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