JP2023007140A - Vacuum cleaner and battery for vacuum cleaner - Google Patents

Abstract

To provide a vacuum cleaner that enhances efficiency for cooling a battery.SOLUTION: A vacuum cleaner includes: a housing including a built-in electric blower; and a battery detachably attached to the housing so as to supply power to the electric blower. The vacuum cleaner uses pressure difference from atmospheric pressure generated inside the housing when the electric blower is driven to cause air to flow into the battery or a gap part between the housing and the battery.SELECTED DRAWING: Figure 4

Description

The present invention relates to vacuum cleaners and batteries for vacuum cleaners.

As a cordless vacuum cleaner with a built-in battery, for example, in Patent Document 1, an electric blower, a battery and a control unit are built in the outer shell of the main body, the battery is arranged in the exhaust air passage, and the exhaust air is generated during operation. A stick-type vacuum cleaner has been proposed in which the battery can be cooled by air currents in the road.

JP 2019-154486 A

The electric vacuum cleaner of Patent Document 1 has a cooling structure in which a battery is provided in the exhaust air passage in the main body. Not applicable to vacuum cleaners. In addition, in this cooling structure, the battery is cooled by the air warmed by the exhaust heat of the electric blower, so it cannot be said that the cooling efficiency is high.

SUMMARY OF THE INVENTION An object of the present invention is to provide an electric vacuum cleaner that takes the above circumstances into consideration.

The present invention comprises a housing containing an electric blower, and a battery detachably attached to the housing so as to supply power to the electric blower,
To provide a vacuum cleaner characterized in that an air current generated when the electric blower is driven is used to flow air into the inside of the battery or through a gap between the housing and the battery.

The present invention also provides a battery detachably attached to a housing containing an electric blower of an electric vacuum cleaner, comprising: a case detachable from the housing; a cell housed in the case; and a ventilation passage penetrating the case, and the cell can be cooled by flowing air through the ventilation passage using an airflow generated when the case is attached to the housing and the electric blower is driven. To provide a battery for a vacuum cleaner characterized by:

ADVANTAGE OF THE INVENTION According to this invention, the cooling efficiency of a battery can be improved.

BRIEF DESCRIPTION OF THE DRAWINGS It is the perspective view which looked at 1st Embodiment of the vacuum cleaner of this invention from the right rear. It is the perspective view which looked at the cleaner main body in the vacuum cleaner of 1st Embodiment from the right front. It is the perspective view which looked at the drive device of 1st Embodiment from the right front. FIG. 2 is a right cross-sectional view of the driving device of the first embodiment when a battery is attached; FIG. 2 is an internal structural diagram of the drive device of the first embodiment when the battery is not attached, viewed from the front right side; FIG. 3 is an internal structural diagram of the driving device of the first embodiment when the battery is not attached, viewed from the rear right side; FIG. 2 is an internal structural diagram of the drive device of the first embodiment when a battery is attached, viewed from the front right side; FIG. 2 is an internal structural diagram of the drive device of the first embodiment when a battery is mounted, viewed from the rear right side; FIG. 11 is an internal structural diagram of the drive device according to the second embodiment when a battery is attached, viewed from the right side; It is a right sectional view at the time of battery attachment of the drive device of 3rd Embodiment. It is an internal structure figure at the time of battery attachment which looked at the drive device of 4th Embodiment from the right side. It is an internal structure figure of the vacuum cleaner of 5th Embodiment. It is an internal structure figure of the vacuum cleaner of 7th Embodiment.

The present invention will be described in further detail below with reference to the drawings. It should be noted that the following description is illustrative in all respects and should not be construed as limiting the present invention.

(First embodiment)
FIG. 1 is a perspective view of the vacuum cleaner according to the first embodiment of the present invention as seen from the rear right side, and FIG. 2 is a perspective view of the vacuum cleaner main body of the vacuum cleaner of the first embodiment as seen from the front right side. . 3 is a perspective view of the drive device of the first embodiment as viewed from the front right side, and FIG. 4 is a right side cross-sectional view of the drive device of the first embodiment when a battery is mounted. In FIGS. 1 to 4, the arrows indicate the front, rear, left, right, up and down directions of the vacuum cleaner as seen from the user during use (cleaning), and the front, back, left, right, up and down directions are shown in the following description of the vacuum cleaner. based on Moreover, in FIG. 4, some illustration is abbreviate|omitted.

As shown in FIG. 1, the vacuum cleaner 1 of the first embodiment includes a cleaner main body 10, a suction port body 90, and an extension pipe 80 airtightly connecting the cleaner main body 10 and the suction port body 90. It is a stick-type vacuum cleaner with It should be noted that the suction port body 90 can be directly connected to the cleaner main body 10 without the extension pipe 80 and used as a handy type vacuum cleaner.
The cleaner body 10 includes a drive device 20, a dust collector 30 detachably attached to the drive device 20, and a battery 40 detachably attached to the drive device 20 as a power source.

As shown in FIGS. 1 to 4, the drive device 20 includes an electrical component storage portion 21 that stores the electric blower 50, a control board, and the like, a handle 22 connected to the rear end of the electrical component storage portion 21, and a handle 22 an operation switch portion 23 provided in the upper portion of the electrical component storage portion 21; a battery mounting portion 24 provided in the lower portion of the electrical component storage portion 21; 25 , and a dust collector mounting portion 26 provided along the lower edge of the pipe portion 25 and the front edge of the electric component housing portion 21 .

In this driving device 20 , the central axis of the dust collector 30 installed in the dust collector mounting portion 26 is parallel to the central axis of the pipe portion 25 . In this embodiment, the positional relationship between the dust collector mounting portion 26 and the pipe portion 25 is such that the pipe portion 25 is upward and the dust collector mounting portion 26 is downward. The positional relationship may be such that the device mounting portion 26 faces upward.

The electric component housing portion 21 has an air inlet 21a on the front edge and an exhaust port 21b on the right side. The air inlet 21a and the air outlet 21b communicate with each other through a ventilation passage in the electric component housing portion 21, and an electric blower 50 is provided in the ventilation passage. A hook-shaped leg portion 21c is provided below the air inlet 21a of the electrical component storage portion 21. As shown in FIG.

The battery mounting portion 24 is formed in a recessed shape that opens rearwardly and downwardly so that the battery 40 can be slid and detached. A terminal 24a (see FIG. 6) is provided. A connection opening 53b for a guide air passage 53, which will be described later, is provided in the deep portion of the battery mounting portion 24. As shown in FIG. This guide air passage 53 is provided for the purpose of causing air to flow inside the battery 40 by utilizing the pressure difference from the atmospheric pressure generated inside the housing 11 when the electric blower 50 is driven. Details of the battery 40 and the guide air passage 53 will be described later.

The pipe portion 25 has a connection port 25a connectable to the extension pipe 80 at its front end. The connection port 25a can be connected to a connection pipe portion 93 of the suction port body 90, which will be described later. Further, the pipe portion 25 has a storage space under the connection port 25a. In this storage space, a pair of clip-type terminals (not shown) that can be electrically and mechanically connected to a pair of pin-type terminals (not shown) possessed by the extension tube 80 or the suction port body 90 when connected thereto. is provided. The pair of clip-type terminals are electrically connected to the control circuit through conductive wires (not shown).

The dust collector mounting portion 26 has an outflow port 26a communicating with the connection port 25a at the rear lower end position of the pipe portion 25, and the dust collector 30 is engaged with the dust collector 30 at a position forward of the outflow port 26a at the lower end of the pipe portion 25. It has an engaging concave portion 26b that can be engaged with a convex portion (not shown). In addition, the dust collector mounting portion 26 has a locking rib 26c at the right front end position of the electric component housing portion 21, with which the locking lever 32a of the dust collector 30 is detachably locked. A portion of the dust collector mounting portion 26 on the side of the air inlet port 21a is formed into a shape into which the dust collector 30 is fitted when the dust collector 30 is mounted.

The operation switch unit 23 has, for example, a stop switch, a weak/strong switch for manual operation mode, and an automatic switch for automatic operation mode.
When the weak/strong switch is pressed when the driving device 20 is stopped or in the automatic operation mode, it switches to the manual weak operation mode with the minimum output, and when pressed in the manual weak operation mode, it switches to the manual strong operation mode with the maximum output. is.
The automatic switch is a switch that switches to an intermediate output automatic middle operation mode when pressed in the manual weak operation mode or the manual strong operation mode when the driving device 20 is stopped.

The dust collector 30 includes a dust container portion 31 and a filter unit 32 detachably attached to the dust container portion 31 .

As shown in FIG. 1, the suction port body 90 includes a suction port main body 91 having a suction port at the bottom, and a joint portion 92 provided on the suction port main body 91 so as to be rotatable about a first longitudinal axis. , the connecting pipe portion 93 provided to the joint portion 92 so as to be rotatable about the second horizontal axis, a rotating brush (not shown) housed in the inlet main body 91, a rotating brush driving motor, and It includes a motor drive circuit and the like, and the pair of pin-shaped terminals (not shown) provided on the outer surface of the connection pipe portion 93 . In the suction port body 90, the pair of pin-shaped terminals, the motor drive circuit, and the rotary brush drive motor are electrically connected by conductive wires (not shown).

As shown in FIG. 1, the extension pipe 80 includes a pipe body 81 having one end detachable from the pipe portion 25 of the driving device 20 and the other end detachable from the connection pipe portion 93 of the suction port body 90; and a cover member 82 covering the conductive cable (not shown). One end of the conductive cable is provided with the pair of pin-shaped terminals that can be electrically and mechanically connected to the pair of clip-shaped terminals of the driving device 20, and the other end of the conductive cable is provided with the suction port 90. A pair of clip-type terminals are provided that are electrically and mechanically connectable with the pair of pin-type terminals.

<Construction of battery and guide air passage>
As shown in FIGS. 1 to 4, the battery 40 includes a case 41 detachable from the housing 11 of the driving device 20, a plurality of cells 42 housed in the case 41, and an air passage 43 passing through the case 41. Prepare. A plurality of charge/discharge terminals (not shown) are provided on the front end side of the upper surface of the case 41, and a circuit board 44 is provided in the upper part of the case 41. The charge/discharge terminals and the cells 42 are not shown. It is electrically connected to the circuit board 44 by a lead wire.

In this embodiment, as shown in FIG. 4, in the space below the circuit board 44 in the case 41 of the battery 40, five cylindrical cells 42 are arranged in the upper and lower rows in the front-rear direction. The longitudinal direction of the cells 42 is the horizontal direction, and the gaps between the five cells 42 in the upper stage and the five cells 42 in the lower stage serve as ventilation paths 43 . A front surface of the case 41 is provided with a first ventilation port 43a of the ventilation path 43 opening forward, and a rear surface of the case 41 is provided with a second ventilation opening 43b of the ventilation path 43 opening downward. In addition, the plurality of cells 42 in the upper stage and the plurality of cells 42 in the lower stage are arranged so that one cell 42 in the lower stage is positioned in the space between the two cells 42 in the upper stage. As a result, the thickness of the entire battery 40 is reduced, and a part of each cell 42 protrudes into the ventilation passage 43, so that the air easily hits each cell 42 and the cooling efficiency is enhanced.

The first ventilation port 43 a is provided at a laterally intermediate position on the front surface of the case 41 , and the second ventilation port 43 b is provided at a laterally intermediate position on the rear surface of the case 41 . Further, the ventilation path 43 may have a width (width in the left-right direction) of the same extent as the first ventilation port 43a and the second ventilation port 43b in the case 41, but the length of the plurality of cells 42 They may have the same width.

FIG. 5 is an internal structure diagram of the drive device of the first embodiment when the battery is not installed, viewed from the right front, and FIG. 6 is an internal structure of the drive device of the first embodiment when the battery is not installed, viewed from the right rear. It is a diagram. 7 is a view of the internal structure of the drive device of the first embodiment when the battery is mounted, viewed from the front right side, and FIG. 8 is an internal structure of the drive device of the first embodiment when the battery is mounted, viewed from the rear right side. It is a diagram. 5 to 8, some of the parts are omitted in order to facilitate the explanation of the internal structure of the driving device 20. As shown in FIG.

As shown in FIGS. 4 to 8, the electric blower 50 is covered with an electric blower case 51 inside the housing 11 forming the electric component housing portion 21 of the drive device 20 . The electric blower case 51 has a lattice portion 51a (see FIGS. 5 and 7) provided in front of the fan portion 50a of the electric blower 50, and is located behind the fan portion 50a of the electric blower 50 and behind the motor portion 50b. It has an opening 51b (see FIGS. 6 and 8) provided on the side. A drive circuit board 52 for the motor portion 50b is provided behind the electric blower 50 in the electric blower case 51 (see FIGS. 4, 6 and 8).

Further, inside the housing 11 that constitutes the electric component housing portion 21 , the aforementioned guide air passage 53 that guides the airflow from the electric blower 50 to the battery 40 is provided. The guide air passage 53 is a bent cylindrical member, and has an opening 53a provided at one end (upstream in the airflow direction) and a connection opening 53b provided at the other end (downstream in the airflow direction). have.
As shown in FIGS. 3 and 4, the guide air passage 53 is provided at the air inlet port 21a side of the dust collector mounting portion 26, and the airtight sealing portion of the dust collector 30 is fitted therein. It is provided so as not to protrude forward from the surface.

One end of the guide air passage 53 is inserted into the electric blower case 51 through the opening 51b, and the opening 53a of the one end faces the fan portion 50a of the electric blower 50 at the rear position of the outer peripheral portion of the fan portion 50a. It is open. That is, the opening 53a is open at a position where the exhaust that does not pass through the motor portion 50b can be taken in directly from the fan portion 50a. With such a structure, it is possible to guide the exhaust gas, which has a lower temperature than the exhaust gas heated by passing through the motor portion 50 b of the electric blower, to the guide air passage 53 . As shown in FIG. 6, the mouth portion 53a has an arcuate opening at the rear position of the outer peripheral portion of the fan portion 50a. It is open. By doing so, a large amount of air flows into the guide air passage 53 . It should be noted that the opening range of the mouth portion 53a is not limited to a range of about 1/4 of the outer peripheral portion of the fan portion 50a, and may be larger or smaller than this.
The range from one end side to the other end side of the guide air passage 53 extends forward and downward through the side of the fan portion 50a of the electric blower 50, and the connection port portion 53b on the other end side is bent. It opens toward the battery mounting part 24 behind. The connection port portion 53b contacts or closely faces the first ventilation port 43a of the battery 40 mounted on the battery mounting portion 24 . At this time, when the connection port portion 53b and the first ventilation port 43a are connected while being in contact with each other, a seal ring may be provided around at least one of the connection port portion 53b and the first ventilation port 43a so that they contact each other. . In this embodiment, as long as air flows between the connection port portion 53b and the first ventilation port 43a, they are considered to be in a connected state even if they are not in contact with each other.

<Operation of the vacuum cleaner during operation>
As shown in FIGS. 1 to 3, when the operation switch portion 23 is operated to drive the electric blower 50, the pressure on the downstream side in the airflow direction at a position near the electric blower 50 in the housing 11 rises to positive pressure. , the pressure on the upstream side in the airflow direction in the vicinity of the electric blower 50 decreases to become a negative pressure, and an air flow (airflow) is generated due to the pressure difference from the atmospheric pressure. Due to this air flow, air containing dust on the floor surface is sucked into the suction port body 90, and the air containing dust flows through the extension pipe 80 into the pipe portion 25 of the drive device 20 of the cleaner body 10. Then, it flows into the dust collection container portion 31 from an inlet (not shown) of the dust collector 30 connected to the outlet 26a. The dust-laden air that has flowed into the dust container 31 swirls to centrifugally separate the relatively large first dust, which accumulates in the dust container 31, and the second dust that is smaller than the first dust. flows into the filter unit 32 and is captured by the filter body (not shown) of the filter unit 32 . The air from which the second dust has been removed passes through the filter main body, passes through the grid portion 51a of the electric blower case 51 from the air inlet 21a of the housing 11 of the driving device 20, and flows into the electric blower 50. Thus, the vacuum cleaner 1 of this embodiment is a vacuum cleaner having the cyclone dust collector 30 .

As shown in FIGS. 4 to 8, among the air that has flowed into the electric blower 50, the air that has passed through the vicinity of the rotation shaft of the fan portion 50a passes through the vicinity of the rotation shaft (motor core) of the motor portion 50b. Heat is easily transferred, but the heat of the motor portion 50b is not easily transferred to the air that has passed through the outer peripheral portion of the fan portion 50a.
According to this embodiment, part of the air that has passed through the outer peripheral portion of the fan portion 50a and before passing through the motor portion 50b (air that is not affected by the heat of the motor portion 50b) is passed through the mouth portion 53a as a guide air. It is taken into the path 53. In other words, the air that passes through the outer peripheral portion of the fan portion 50a and does not pass through the motor portion 50b is taken into the guide air passage 53 through the mouth portion 53a. This air can be introduced into the first ventilation port 43a of the battery 40 from the connection port 53b as cooling air A (see FIGS. 4 and 7). As a result, the cooling air cools the plurality of cells 42 in the battery 40, and the air warmed by the heat of the cells 42 is discharged to the outside through the second ventilation openings 43b. At this time, the air is exhausted downward from the second ventilation port 43b so that the user of the vacuum cleaner 1 is not directly exposed to the exhaust air.
On the other hand, the air that has not been taken into the guide air passage 53 is discharged to the outside from the exhaust port 21b of the housing 11 .

In this manner, the inside of the battery 40 can be cooled using the air that is not affected by the exhaust heat of the motor portion 50b of the electric blower 50 as cooling air, so the cooling efficiency of the battery 40 is improved. Regarding this point, in recent years, the capacity of batteries has been increased, and accordingly, the amount of heat generated by the batteries and circuits has increased. Conventionally, the battery is housed in the exhaust air passage between the electric blower and the exhaust port, and the exhaust air passing through the exhaust air passage cools the battery. Due to the rising temperature, it was difficult to cool sufficiently, and it was difficult to demonstrate the original performance due to the temperature limit. According to this embodiment, such a conventional problem can be improved.

Further, according to the present embodiment, in addition to the normal exhaust air from the exhaust port 21b of the driving device 20, the air after the battery has been cooled is exhausted from the battery 40. Therefore, the exhaust noise from the exhaust port 21b is reduced by dispersing the exhaust gas. Also, the momentum of the exhaust can be suppressed.
Further, according to the present embodiment, it is possible to use part of the exhaust air from the electric blower 50 for cooling the battery 40 and use the rest of the exhaust air for the blower. In this case, the air passage inside the housing 11 is switched to the blower mode. In the blower mode, for example, air taken in from the exhaust port 21 b turns to the upstream position of the electric blower 50 and passes through the electric blower 50 , and then the air path is arranged such that a part of the air is discharged from the pipe portion 25 . can be switched. Also in this case, part of the air from the fan portion 50a of the electric blower 50 passes through the guide air passage 53 and the battery 40 and is discharged to the outside. It should be noted that the battery cooling structure can be applied to the blower itself as well as to such a device that serves as both a vacuum cleaner and a blower. In this case, the exhaust port 21b becomes an intake port of the blower, and the air sucked from the intake port turns to the upstream side position of the electric blower 50 and passes through the electric blower 50 . After that, part of the air is exhausted from the pipe portion 25, and part of the air from the fan portion 50a of the electric blower 50 passes through the guide air passage 53 and the battery 40 and is exhausted to the outside.

(Second embodiment)
FIG. 9 is an internal structural diagram of the drive device according to the second embodiment when the battery is mounted, viewed from the right side. In addition, in FIG. 9, elements similar to those in FIG. 4 are given the same reference numerals.
In the first embodiment (see FIG. 4), the drive device 20 configured to cool the air from the fan portion 50a of the electric blower 50 through the battery 40 was exemplified, but the second embodiment shown in FIG. In the form, the driving device 20 is configured to cool the battery 40 by flowing air from the fan portion 50 a of the electric blower 50 into the gap S between the housing 11 and the battery 40 .
Other configurations in the second embodiment are generally similar to those in the first embodiment. In the following, the differences between the second embodiment and the first embodiment will be mainly described.

As shown in FIG. 9, in the case of the second embodiment, the configuration of the driving device 20 including the guide air passage 53 is the same as that of the first embodiment, but the battery 140 is configured as follows. That is, the battery 140 is provided with a groove portion 140 a extending in the front-rear direction in the upper surface of the battery 140 so that a gap portion S is formed between the battery 140 and the battery mounting portion 24 of the drive device 10 . Therefore, this battery 140 is not provided with the ventilation path 43 (see FIG. 4) unlike the battery 40 of the first embodiment.

A notch portion 140 b facing the connection port portion 53 b of the guide air passage 53 is provided on the front surface of the battery 140 mounted on the battery mounting portion 24 of the drive device 10 . The notch portion 140b is a notch that opens forward and upward and is connected to the groove portion 140a.
Therefore, the cooling air A discharged from the connection port 53b of the guide air passage 53 is discharged from the notch 140b of the battery 140 through the gap S to the rear outside. Battery 140 is thereby cooled.

(Third Embodiment)
FIG. 10 is a right cross-sectional view of the driving device according to the third embodiment when the battery is attached. In addition, in FIG. 9, elements similar to those in FIG. 4 are given substantially the same reference numerals.
In the first and second embodiments, the battery 40 (see FIG. 4) is cooled using the positive pressure in the housing 11 generated when the electric blower 50 is driven, in other words, the exhaust air passing through the fan section 50a. 10, the battery 40 may be cooled using the negative pressure in the housing 11 generated when the electric blower 50 is driven, in other words, the intake air sucked into the fan portion 50a. good.
Other configurations in the third embodiment are generally similar to those in the first embodiment. In the following, the differences between the third embodiment and the first embodiment will be mainly described.

As shown in FIG. 10 , in the case of the third embodiment, a guide air passage 153 that connects the upstream position of the electric blower 50 in the air flow direction and the battery 40 is provided in the housing 11 .
The guide air passage 153 has a mouth portion 153a that opens toward the fan portion 50a in front of the electric blower 50 and a connection port portion 153b that opens rearward at the back of the battery mounting portion 24 .
The battery 40 of the third embodiment has the same configuration as that of the first embodiment.

According to the third embodiment configured as described above, the air B in the guide air passage 153 is sucked by the electric blower 50 due to the negative pressure generated at the upstream position of the electric blower 50 during driving, and the exhaust port 21b is discharged. (See FIG. 1), and external air B flows from the second ventilation port 43b of the battery 40 through the ventilation passage 43 and the first ventilation port 43a into the guide air passage 153 from the connection port 153b. influx. Thus, the battery 40 can be cooled even if the flow of the air B passing through the battery 40 is reversed from that of the first embodiment.
In the case of the battery 40 of the third embodiment shown in FIG. 10, a filter may be provided in the second vent 43b in order to prevent dust from entering the battery 40 in the outside air.

(Fourth embodiment)
FIG. 11 is an internal structural diagram of the driving device according to the fourth embodiment when the battery is mounted, viewed from the right side. In FIG. 9, elements similar to those in FIGS. 4, 9, and 10 are given substantially the same reference numerals.
In the case of the fourth embodiment, the guide air passage 153 (see FIG. 10) is configured similarly to the third embodiment, and the battery 140 (see FIG. 9) is configured similarly to the second embodiment.

As shown in FIG. 11, according to the fourth embodiment, the air B in the guide air passage 153 is sucked by the electric blower 50 due to the negative pressure generated at the upstream position of the electric blower 50 during driving, and the exhaust port 21b (see FIG. 1), and external air B flows through the gap S between the battery 40 and the housing 11 and into the guide air passage 153 from the opening 153a. Thus, the battery 40 can be cooled even if the flow of the air B passing through the gap S is reversed from that of the second embodiment (see FIG. 9).

(Fifth embodiment)
FIG. 12 is an internal structural diagram of the vacuum cleaner of the fifth embodiment. In FIG. 12, elements similar to those in FIGS. 1 to 11 are given substantially the same reference numerals.
As shown in FIG. 12, the cordless vacuum cleaner of the fifth embodiment includes a canister-type vacuum cleaner main body 510. As shown in FIG.
In the case of this vacuum cleaner main body 510, a pipe portion 525 is provided in the front portion of the housing 511, a dust collector 530 is provided vertically in the front portion within the housing 511, and an electric blower is provided in the rear portion within the housing 511. 50 is provided vertically, and the same battery 40 as in the first embodiment is detachably attached to the battery attachment portion 524 provided at the rear end of the housing 511 .

The battery mounting portion 524 is oriented vertically so that the battery 40 can be slid vertically to be attached and detached. A mouth (not shown) is provided. Therefore, the first air vent 43 a of the battery 40 mounted in the battery mounting portion 524 is connected to the connection opening of the guide air passage 553 .
Further, an exhaust port 521b is provided at a position below the battery mounting portion 524 on the rear surface of the housing 511 .

The guide air passage 553 is provided between the peripheral portion of the fan portion 50 a of the electric blower 50 and the deep portion (bottom portion) of the battery mounting portion 524 . One end side of the guide air passage 553 is provided with an opening 553a for taking in the airflow from the fan portion 50a, and the other end side of the guide air passage 553 is opened toward the battery mounting portion 524 (upward). A connection port is provided.

According to this cleaner main body 510, when the electric blower 50 is driven, as indicated by arrow F in FIG. The removed air flows into electric blower 50 . A portion of the air A that has passed through the fan portion 50a of the electric blower 50 is sent into the battery 40 through the guide air passage 553, passes through the battery 40, and is discharged to the outside through the second ventilation port 43b. Other air Fx that has passed through the electric blower 50 is discharged to the outside from the exhaust port 521b.

Thus, even in a battery-driven canister-type vacuum cleaner body, the battery 40 can be efficiently cooled by the air A that is not affected by the exhaust heat of the motor portion 50b of the electric blower 50.

(Sixth embodiment)
In the case of the sixth embodiment, the battery 40 is cooled by allowing the air A from the guide air passage 553 in the fifth embodiment to pass through the gap provided between the battery 40 and the battery mounting portion 524 .

(Seventh embodiment)
FIG. 13 is an internal structural diagram of the vacuum cleaner of the seventh embodiment. In FIG. 13, elements similar to those in FIG. 12 are given substantially the same reference numerals.
As shown in FIG. 13, in the case of the seventh embodiment, the air B flowing through the battery 40 flows in the opposite direction to that in the fifth embodiment (see FIG. 12). In this case, a guide air passage 753 that connects the upstream position of the electric blower 50 in the airflow direction and the battery 40 is provided in the housing 511 .
The guide air passage 753 includes a mouth portion 753a that opens toward the fan portion 50a in front of the fan portion 50a of the electric blower 50, and a connection port portion (not shown) that opens upward at the back portion of the battery mounting portion 24. have
A battery 40 of the seventh embodiment has the same configuration as that of the first embodiment.

According to the seventh embodiment configured as described above, the air B in the guide air passage 753 is sucked by the electric blower 50 due to the negative pressure generated at the upstream position of the electric blower 50 during driving, and the exhaust port 21b is discharged. (see FIG. 1), and the external air B passes through the second ventilation port 43b of the battery 40, the ventilation passage 43 and the first ventilation port 43a, and the guide air passage from the connection port (not shown). flow into 753. Thus, the battery 40 can be cooled even if the flow of the air B passing through the battery 40 is reversed from that of the fifth embodiment.
In the case of the battery 40 of the seventh embodiment shown in FIG. 13, a filter may be provided in the second vent 43b in order to prevent dust from entering the battery 40 in the outside air.

(Eighth embodiment)
In the case of the eighth embodiment, the air B is passed through the gap provided between the battery 40 and the battery mounting portion 524 in the seventh embodiment to cool the battery 40, and the cooled air B is passed through the guide air passage 753. The electric blower 50 is made to suck.

(Other embodiments)
1. In the first to eighth embodiments, the vacuum cleaner main body including the driving device incorporating the electric blower, the dust collector and the battery detachably attached to the driving device, and the battery cooling structure was exemplified. If the main body is a canister type, it may not be equipped with a dust collector. In this case, a dust collecting device can be provided between the flexible hose and the extension pipe that connect the canister-type cleaner main body and the suction port (see, for example, Japanese Unexamined Patent Application Publication No. 2003-38397).
2. The battery cooling structures of the first to eighth embodiments can also be applied to self-propelled devices (for example, self-propelled vacuum cleaners) in which a battery is detachably attached to a housing that can travel on the floor surface. .

As mentioned above,
(1) A vacuum cleaner according to the present invention includes a housing containing an electric blower, and a battery detachably attached to the housing so as to supply power to the electric blower,
The airflow generated when the electric blower is driven is used to flow air into the interior of the battery or through a gap between the housing and the battery.

According to this configuration, when the electric blower is driven, the pressure on the downstream side in the airflow direction in the vicinity of the electric blower in the housing rises to become a positive pressure, and the pressure on the upstream side in the airflow direction in the vicinity of the electric blower decreases to become a negative pressure. Because of the pressure, an air flow (air current) is generated in the housing due to the pressure difference from the atmospheric pressure. This airflow can flow inside the removable battery or through a gap between the housing and the battery to cool the battery.

Moreover, the electric vacuum cleaner according to the present invention may be configured as follows, and these may be combined as appropriate.
(2) a guide air passage for guiding airflow from the electric blower to the battery is provided in the housing;
The airflow passing through the guide air passage may be discharged to the outside through the interior of the battery or the gap between the housing and the battery.
According to this configuration, the airflow (exhaust air) is introduced from the downstream side in the airflow direction in the vicinity of the electric blower into the guide airflow passage and passed through the interior of the battery or the gap between the housing and the battery, whereby the battery is cooled. Allow to cool.

(3) A guide air passage is provided in the housing for connecting an upstream position of the electric blower in an air flow direction and the battery, and
External air is drawn into the guide air passage through the inside of the battery or the gap between the housing and the battery by an air current drawn by the electric blower generated at the upstream position of the electric blower during operation. may be configured to flow into the
According to this configuration, an airflow is generated that is sucked by the electric blower due to the negative pressure generated at the upstream position of the electric blower when the electric blower is driven. As a result, the air inside the guide air passage is sucked, and the air inside the battery or the air in the gap between the housing and the battery is sucked toward the guide air passage, thereby Outside air is sucked into the gap between the battery and the battery to cool the battery.

(4) the housing has a battery mounting portion for detachably mounting the battery while sliding;
The guide air passage has a connection port at a deep portion in the battery mounting portion in the sliding direction of the battery,
The battery has an air passage inside thereof for passing an air flow,
The ventilation path has a first ventilation port in contact with or in close proximity to the connection port of the battery mounted in the battery mounting portion, and a second ventilation port opposite to the first ventilation port. There may be.
According to this configuration, it is possible to simply configure a cooling structure for cooling the battery by allowing the airflow (exhaust air) from the electric blower or the outside air to flow through the ventilation passage in the battery.

(5) the housing has a battery mounting portion for detachably mounting the battery while sliding;
The guide air passage has a connection port at a deep portion in the battery mounting portion in the sliding direction of the battery,
The clearance may be opened toward the connection opening at one end in the sliding direction and may be opened to the outside at the other end in the sliding direction.
According to this configuration, it is possible to simply configure a cooling structure that cools the battery by allowing the airflow (exhaust air) from the electric blower or the outside air to pass through the gap between the housing and the battery.

(6) The electric blower has a fan section and a motor section for rotating the fan section,
The airflow that has passed through the fan section but not the motor section is guided to the battery through the guide air passage, and the airflow that has passed through the fan section and the motor section is discharged to the outside from an exhaust port provided in the housing. You may
According to this configuration, the battery can be efficiently cooled by the airflow that has passed through the fan section and has not been warmed by the exhaust heat of the motor section.

(7) It may further include a dust collector detachably attached to the housing, and a suction port connected to the housing directly or via a connection pipe.
According to this configuration, it is possible to obtain a handheld, stick or canister type cordless vacuum cleaner capable of cooling the detachable battery.

(8) Further, a battery for a vacuum cleaner according to the present invention is a battery detachably attached to a housing containing an electric blower of the vacuum cleaner, comprising: a case detachable from the housing; A cell housed in a case and a ventilation passage penetrating the case are provided, and air is blown into the ventilation passage by using an airflow generated when the case is attached to the housing and the electric blower is driven. It is characterized in that the cell can be cooled by flowing it.
According to this configuration, it is possible to obtain a detachable battery for a vacuum cleaner that can be efficiently cooled.

Preferred aspects of the present invention also include combinations of any of the above-described multiple aspects within a consistent range. For example, the cooling of the inside of the battery by the exhaust of the first embodiment and the cooling of the outer surface of the battery by the exhaust of the second embodiment may be combined, or the cooling of the inside of the battery by the intake of the third embodiment and the intake of the battery of the fourth embodiment may be combined. External cooling may be combined, battery internal cooling by exhaust in the fifth embodiment and battery external cooling by exhaust in the sixth embodiment may be combined, or battery internal cooling by intake air in the seventh embodiment may be combined. It may be combined with the cooling of the outer surface of the battery by intake air in the eighth embodiment.
In addition to the embodiments described above, various modifications of the present invention are possible. Those modifications should not be construed as not belonging to the scope of the present invention. The present invention should include all modifications within the scope of the claims, the meaning of equivalents, and the scope.

1: Electric vacuum cleaner 10, 510: Vacuum cleaner main body 11, 511: Housing 20, 120: Driving device 21: Electric component housing 21a: Air inlet 21b, 521b: Air outlet 21c: leg portion 22: handle 23: operation switch portion 24, 524: battery mounting portion 24a: power receiving terminal 25, 525: pipe portion 25a: connection port 26: dust collector mounting portion 26a: outflow port , 26b: engaging recess, 26c: locking rib, 30, 530: dust collector, 31: dust collecting container portion, 32: filter unit, 32a: locking lever, 40, 140: battery, 41: case, 42 : cell 43: ventilation path 43a: first ventilation port 43b: second ventilation port 44: circuit board 50: electric blower 50a: fan section 50b: motor section 51: electric blower case 51a: Lattice portion 51b: Opening 52: Drive circuit board 53, 153, 553, 753: Guide air passage 53a, 153a, 553a, 753a: Mouth 53b, 153b: Connection port 80: Extension pipe 81: Pipe body 82: Cover member 90: Suction port body 91: Suction port body 92: Joint portion 93: Connection pipe portion 140a: Groove portion A: Cooling air B: Air F, Fx: Arrows , S: clearance

Claims (8)

A housing containing an electric blower, and a battery detachably attached to the housing so as to supply power to the electric blower,
An electric vacuum cleaner, characterized in that an air current generated when the electric blower is driven is used to flow air into the interior of the battery or through a gap between the housing and the battery. A guide air passage is provided in the housing for guiding airflow from the electric blower to the battery,
The vacuum cleaner according to claim 1, wherein the airflow passing through the guide air passage is discharged to the outside through the interior of the battery or the gap between the housing and the battery. machine. A guide air passage is provided in the housing for connecting an upstream position in an air flow direction of the electric blower and the battery,
External air is drawn into the guide air passage through the inside of the battery or the gap between the housing and the battery by an air current drawn by the electric blower generated at the upstream position of the electric blower during operation. 2. The vacuum cleaner of claim 1, wherein the vacuum cleaner is configured to flow into. The housing has a battery mounting portion for detachably mounting the battery while sliding,
The guide air passage has a connection port at a deep portion in the battery mounting portion in the sliding direction of the battery,
The battery has an air passage inside thereof for passing an air flow,
The ventilation path has a first ventilation port that contacts or is adjacent to the connection port portion of the battery attached to the battery attachment portion, and a second ventilation port that is opposite to the first ventilation port. 4. The vacuum cleaner according to Item 2 or 3. The housing has a battery mounting portion for detachably mounting the battery while sliding,
The guide air passage has a connection port at a deep portion in the battery mounting portion in the sliding direction of the battery,
The electric vacuum cleaner according to claim 2 or 3, wherein said gap part opens toward said connection opening at one end in said sliding direction and opens to the outside at the other end in said sliding direction. The electric blower has a fan section and a motor section for rotating the fan section,
The airflow that has passed through the fan section but not the motor section is guided to the battery through the guide air passage, and the airflow that has passed through the fan section and the motor section is discharged to the outside from an exhaust port provided in the housing. Claim 2, Claim 4 depending on Claim 2, or Claim 5 depending on Claim 2. 7. The dust collecting device detachably attached to the housing, and a suction port body connected to the housing directly or via a connection pipe. vacuum cleaner. A battery detachably attached to a housing containing an electric blower of an electric vacuum cleaner, comprising a case detachable from the housing, cells housed in the case, and an air passage penetrating the case. wherein the cell can be cooled by flowing air through the ventilation passage using the airflow generated when the case is attached to the housing and the electric blower is driven. Battery for vacuum cleaner.

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