JP7526488B2 - Suction port body of vacuum cleaner, and vacuum cleaner - Google Patents

Description

The present invention relates to a suction mouth body of a vacuum cleaner and a vacuum cleaner equipped with the same.

Conventionally, there is known a vacuum cleaner capable of sucking up dust on a cleaning surface, as disclosed in, for example, the following Patent Document 1. The vacuum cleaner disclosed in Patent Document 1 employs a suction port body with a suction opening formed on the underside and a roughly cylindrical electric motor disposed inside. In addition, the suction port body disclosed in Patent Document 1 has a cooling vent hole formed on the side, and a ventilation passage for passing cooling air introduced from the cooling vent hole is formed to the side of the flat portion formed on the side so that the cross section perpendicular to the axis of the electric motor has a roughly oval shape.

Japanese Patent Application Publication No. 9-47395

However, when holes are provided on the side, as in the suction mouth body disclosed in Patent Document 1, for example, the side is often cleaned by running it along a wall surface. In that case, if the hole on the side is blocked by the wall surface, it is not possible to take in cooling air, which may result in the electric motor not being able to be effectively cooled.

Therefore, the present invention aims to provide a vacuum cleaner suction inlet body that can effectively cool the motor, and a vacuum cleaner equipped with the same.

The suction port body of a vacuum cleaner in an embodiment of the present invention comprises a case body having a suction port, a rotating cleaning body rotatably mounted on the case body, a motor mounted inside the case body and generating a driving force for driving the rotating cleaning body, and a drive transmission mechanism for transmitting the driving force of the motor to the rotating cleaning body, the drive transmission mechanism having an output pulley mounted on the rotating shaft of the motor, a driven pulley detachably connected to the rotating cleaning body via an attachment part, and a belt stretched between the output pulley and the driven pulley, the case body having a notch facing the driven pulley on one side in the axial direction of the rotating cleaning body, and a first cover part for closing the notch.

The present invention provides a vacuum cleaner suction inlet body that can effectively cool a motor, and a vacuum cleaner equipped with the same.

1 is a perspective view showing a vacuum cleaner and a suction mouth body according to an embodiment of the present invention as viewed from the front side. FIG. 2 is a cross-sectional view of the vacuum cleaner shown in FIG. 1 . 1 is a plan view showing a state in which an upper case body of an air inlet body according to an embodiment of the present invention has been removed. 1 is a perspective view showing a suction port body according to an embodiment of the present invention as viewed from the bottom side. FIG. 1 is a perspective view showing a state in which an upper case body of an air inlet body according to an embodiment of the present invention has been removed; 1 is a perspective view showing a state in which an upper case body and a tube portion of a suction port body according to an embodiment of the present invention have been removed; 1 is an exploded perspective view showing a state in which an upper case body and a pipe portion of a suction port body according to an embodiment of the present invention are removed and a motor chamber is disassembled. FIG. 2 is an enlarged plan view of a main portion of the suction port body according to one embodiment of the present invention with the upper case body and the housing member removed. FIG. 1 is an exploded perspective view showing an enlarged view of a main portion with an upper case body of an air inlet body according to an embodiment of the present invention removed and a motor chamber disassembled; FIG. 1A is an exploded oblique view showing the mounting structure of the cleaning body relative to the mounting portion and the cleaning body drive mechanism as viewed from a first direction, and FIG. 1B is an exploded oblique view showing the mounting structure of the cleaning body relative to the mounting portion and the cleaning body drive mechanism as viewed from a different direction than FIG. FIG. 13 is a bottom view showing a suction port body according to modified example 3. 13 is an enlarged oblique view of a main portion of a suction port body in a state in which a communication portion and a first opening portion according to modified example 3 are provided, as viewed from the bottom side. FIG. FIG. 13 is an exploded perspective view showing a configuration according to Modification 7.

The following is a detailed description of a vacuum cleaner 1 according to one embodiment of the present invention, with reference to the drawings. In the following description, the overall configuration of the vacuum cleaner 1 is first briefly described, and then the suction port body 50 provided as the suction head of the vacuum cleaner 1 is described in detail. In the following description, unless otherwise specified, the positional relationships in the front-to-rear, up-down, width directions, etc. are described based on the vacuum cleaner 1 being set upright as shown in FIG. 1.

<Overall configuration of the vacuum cleaner 1>
FIG. 1 is a perspective view showing an upright state (storage state) of a vacuum cleaner 1 according to an embodiment. The vacuum cleaner 1 is a relatively small and lightweight vacuum cleaner (e.g., a futon cleaner) called a handy cleaner. As shown in FIG. 1, the vacuum cleaner 1 has a main body 10 and a suction port body 50. The main body 10 is formed in a substantially cylindrical shape. The vacuum cleaner 1 is configured such that a handle portion 30 is integrally provided on one end side of the main body 10, and a suction port body 50 is rotatably connected to the other end side of the main body 10. When cleaning objects to be cleaned such as futons, rugs, and carpets, or surfaces to be cleaned such as flooring (hereinafter, these are collectively referred to as "objects to be cleaned"), the vacuum cleaner 1 can be used by gripping the handle portion 30, tilting the main body 10 at an arbitrary angle, and moving the suction port body 50 in the forward and backward directions.

Figure 2 is a cross-sectional view of the vacuum cleaner 1 according to the embodiment. Below, the internal configuration of the vacuum cleaner 1 according to the embodiment will be described with reference to Figure 2.

The main body 10 comprises a substantially cylindrical main body housing 10a. A U-shaped handle portion 30 is integrally formed on the upper portion of the main body housing 10a. An air intake port 11b is formed in the approximate center of the lower end of the main body housing 10a, and a cylindrical duct cover 11 is extended downward.

Inside the duct cover 11, a dust sensor 11a for detecting dust is provided. The dust sensor 11a is composed of a light-emitting element and a light-receiving element, and light emitted from the light-emitting element passes through the duct cover 11 and is received by the light-receiving element on the opposite side. The passage of dust can be detected by determining whether or not light is received. The position of the dust sensor 11a is not limited to the inside of the duct cover 11, but may be anywhere that dust passes through.

The motor chamber 15c houses the fan motor 15, which is an electric blower. The fan motor 15 includes a suction fan 15a and a suction motor 15b, and is housed inside the housing 15d. The housing 15d is configured so that it can be separated into the suction fan 15a side and the suction motor 15b side. A ring-shaped sound-absorbing material 14 is provided to cover the upper and side surfaces of the suction fan 15a side, and is covered by the housing 15d on the suction fan 15a side. On the outer side of the sound-absorbing material 14, a number of grooves are formed in a ring shape that extend in the axial direction and do not contact the inner side of the housing 15d on the suction fan 15a side. When the suction motor 15b drives the suction fan 15a, negative pressure is generated inside the vacuum cleaner 1, and dust is sucked in. The fan motor 15 is driven by PWM control, but other control methods may be adopted depending on the type of the fan motor 15.

A circular nonwoven fabric filter 17 is provided above the fan motor 15. The top of the nonwoven fabric filter 17 is closed by a filter cap 18, and an exhaust flow path 19 is provided that runs from the side of the nonwoven fabric filter 17 through the rear side of the main housing 10a to the exhaust port 23 at the bottom.

The opening of the main housing 10a formed below the fan motor 15 is closed by a cone-shaped dust filter 13. The dust filter 13 is a mesh filter insert molded into a resin frame, and separates air from dust (description of the mesh filter is omitted). The dust filter 13 may be a known filter such as a HEPA (High Efficiency Particulate Air) filter.

A dust cup 22 is attached in front of the dust collection filter 13. The dust cup 22 collects dust and other particles sucked in from the suction port body 50. By operating the release part B (see Figure 1) provided on the side of the dust cup 22, the dust cup 22 can be removed from the main body 10 and the dust accumulated inside can be discarded.

The handle section 30 is provided with operation buttons 31 that the user operates with his/her fingertips, and a display section 32 that shows the results of the operation.

A power cord 33 is pulled out from the handle 30 and is designed to be connected to a power outlet. If a rechargeable battery pack is attached inside the main body housing 10a, it can be used as a cordless cleaner powered by the battery pack.

The suction mouth body 50 is configured by assembling components such as a rotating cleaning unit 80 and a beating unit 90 to a case body 60. The suction mouth body 50 can suck up dust by turning on the vacuum cleaner 1.

The electric vacuum cleaner 1 is generally configured as described above. The electric vacuum cleaner 1 has a characteristic structure in each part, such as the suction mouth body 50. A more detailed explanation is provided below.

<<Configuration of the suction port body 50>>
As shown in FIG. 3 and other figures, the suction mouth body 50 includes a case body 60, a rotary cleaning unit 80, and a beating unit 90. The suction mouth body 50 is formed by incorporating the rotary cleaning unit 80 and the beating unit 90 into the case body 60 to form an integrated unit. The suction mouth body 50 can perform an operation of scraping out or scraping off dust from the object to be cleaned by the rotary cleaning unit 80. The suction mouth body 50 can also perform an operation of applying vibrations or the like to the object to be cleaned by the beating unit 90 to make the dust float to the surface side of the object to be cleaned. The suction mouth body 50 can suck up the dust collected by the operation of the rotary cleaning unit 80 and the beating unit 90. The beating unit 90 is not limited to cleaning the object to be cleaned, and may be operated when cleaning the surface side to be cleaned, such as flooring.

The case body 60 is a case with a space inside. As shown in FIG. 2, the case body 60 has an upper case body 60a and a lower case body 60b, and can be separated into upper and lower parts. The suction port body 50 is attached to the main body 10 in a basic position in which the left-right direction of the case body 60 is the longitudinal direction and the front-rear direction is the lateral direction of the case body 60, and is used by attaching it to the main body 10. As shown in FIGS. 3 to 7, the case body 60 has a suction chamber 62, a rotating cleaning body chamber 64, a motor chamber 66, a hammering unit housing section 68, a tube section 70, a first opening 72, and a second opening 74.

The suction chamber 62 is a part that forms a space that can suck in dust. The suction chamber 62 is located on the rear side (back side) of the case body 60 and is provided so as to extend in the left-right direction (longitudinal direction). The suction chamber 62 is provided with a suction port 62a, which is connected to the rotating cleaning body chamber 64 described in detail later. As shown in FIG. 5, the case body 60 has a communication part 65 that communicates with the suction chamber 62. Since the suction port 62a is located at the end of the communication part 65, it can also be expressed that the communication part 65 has the suction port 62a. The communication part 65 is designed to be rotatably fitted with a cylindrical horizontal tube part 70a that constitutes the tube part 70 described in detail later, with its axis direction facing the left-right direction (longitudinal direction) of the case body 60. In this embodiment, it has a curved surface 65a that curves to fit the circumferential surface of the horizontal tube section 70a, and supports 65b, 65b are provided at both ends to support the rotating shaft 72a of the horizontal tube section 70a.

As shown in Figures 3 to 7, the rotating cleaning body chamber 64 is a space formed to extend in the left-right direction (longitudinal direction) of the case body 60 forward (adjacent to the short side of the case body 60) relative to the suction chamber 62 (suction port 62a). The rotating cleaning body chamber 64 communicates with the communication section 65 via the suction port 62a.

The rotary cleaning body chamber 64 is a space for accommodating the rotary cleaning body 82 that constitutes the rotary cleaning section 80, which will be described in detail later. The main part of the rotary cleaning body chamber 64 is constituted by the lower case body 60b of the case body 60. As shown in FIG. 4, the rotary cleaning body chamber 64 is open to the outside at the bottom side. For example, the rotary cleaning body chamber 64 may be opened in a substantially entire rectangular shape at the bottom, or the opening area may be partitioned by a frame 64a formed in a lattice shape, as in this embodiment. By providing something like a frame 64a, it is possible to prevent the object to be cleaned from being sucked into the rotary cleaning body chamber 64, even if the object to be cleaned is something like a futon.

The rotary cleaning body chamber 64 allows the rotary cleaning body 82 to rotate inside. As shown in Figures 5 to 7, the rotary cleaning body chamber 64 is curved in an approximately arc shape to fit the outer periphery of the rotary cleaning body 82. In the lower case body 60b, the portion forming the rotary cleaning body chamber 64 is shaped to bulge in an arc shape toward the internal space of the case body 60. The rotary cleaning body chamber 64 incorporates a first bearing portion 64b at one longitudinal end for rotatably supporting one end of the rotary cleaning body 82. Meanwhile, as shown in Figure 7, a notch 64c is provided at the other longitudinal end of the rotary cleaning body chamber 64.

The notch 64c is formed by cutting out a portion (the top portion in this embodiment) of the peripheral surface 64d that constitutes the rotating cleaning body chamber 64. As shown in Figures 3 and 7, the notch 64c can be closed by the cleaning body side cover part 66d of the housing member 66b, which will be described in detail later. The notch 64c is provided to allow the driven side pulley 84d, which will be described in detail later, to be incorporated into the lower case body 60b, and the end of the driven side pulley 84d is exposed to the rotating cleaning body chamber 64.

As shown in FIG. 7 and other figures, the rotary cleaning body chamber 64 has an opening 64e on the circumferential surface 64d. The opening 64e is provided in a portion that is covered by the motor side cover portion 66c of the housing member 66b, which will be described in detail later. Therefore, the opening 64e functions as a second opening 74 for communicating the motor chamber 66, which is formed using the housing member 66b, with the rotary cleaning body chamber 64. A filter 64f is provided in the opening 64e. This filter 64f is for preventing dust from entering the motor chamber 66 side from the rotary cleaning body chamber 64. Even if dust adheres to the filter 64f from the rotary cleaning body chamber 64 side, the dust adhered to the filter 64f can be removed and cleaned by rotating the rotary cleaning body 82 in the rotary cleaning body chamber 64.

As shown in FIG. 8, a step engagement portion 64i is provided at the end of the rotating cleaning body chamber 64. The step engagement portion 64i is a portion that engages with the end of the rotating cleaning body 82, which will be described in detail later.

As shown in Figures 3 and 7, the motor chamber 66 is a space inside the case body 60 that houses the first motor 84a that serves as the drive source for the rotary cleaning body 82. The motor chamber 66 is provided on the forward side of the rotary cleaning body chamber 64. In other words, the motor chamber 66 is provided in the short direction of the case body 60, on the opposite side of the rotary cleaning body chamber 64 from the suction chamber 62. The motor chamber 66 is located away from the longitudinal center of the case body 60 toward the notch 64c of the rotary cleaning body chamber 64 described above.

The motor chamber 66 can accommodate the first motor 84a in a position in which the axial direction faces the longitudinal direction (left-right direction) of the case body 60. As shown in FIG. 7, the motor chamber 66 is formed by covering and fixing the housing member 66b from above to the motor arrangement portion 66a formed on the lower case body 60b side, which can be fitted over approximately half the circumference of the first motor 84a. As shown by the dashed line in FIG. 3, when the first motor 84a is accommodated in the motor chamber 66, the bulging portion 84f, which bulges outward in the radial direction at the axial middle portion of the first motor 84a, is in contact with the inner circumferential surface of the motor chamber 66 over approximately the entire circumference. As a result, the inside of the motor chamber 66 is divided into two regions, one on one side and the other on the axial direction, with the contact portion between the bulging portion 84f and the inner circumferential surface as a boundary. Specifically, the interior of the motor chamber 66 is divided into a first region 66x formed at the center of the longitudinal direction of the case body 60, and a second region 66y located on the outer side in the longitudinal direction.

The housing member 66b includes a motor side cover portion 66c and a cleaning body side cover portion 66d. The motor side cover portion 66c is attached to cover the motor arrangement portion 66a, thereby covering the first motor 84a.

As shown in FIG. 7 and the like, the motor side cover part 66c is provided with an inlet side opening 66e and an outlet side opening 66f. The inlet side opening 66e is formed by an opening provided on the side of the side forming the motor chamber 66 that faces the center in the longitudinal direction (left-right direction) of the case body 60. The outlet side opening 66f is formed by an opening portion formed at the lower end of the portion that bulges toward the side where the rotary cleaning body chamber 64 is provided (the rear side of the case body 60) on the second region 66y side formed inside the motor chamber 66 described above when the motor side cover part 66c is placed over the motor arrangement part 66a and attached. The outlet side opening 66f is located at a position corresponding to the opening 64e of the rotary cleaning body chamber 64 described above. Therefore, when the motor side cover part 66c is attached to the motor arrangement part 66a, the outlet side opening 66f and the opening 64e are connected to each other. As a result, the motor chamber 66 and the rotary cleaning body chamber 64 are in a state of communication. It is preferable that the discharge side opening 66f and the opening 64e are connected to communicate with each other, but they may also be spaced apart and face each other.

The cleaning body side cover part 66d is a part that covers the notch 64c provided at the end of the above-mentioned rotating cleaning body chamber 64, thereby closing the rotating cleaning body chamber 64. The cleaning body side cover part 66d is integrated with the above-mentioned motor side cover part 66c.

The motor side cover part 66c and the cleaning body side cover part 66d can be provided as separate bodies, but by forming them integrally as the housing member 66b as in this embodiment, the number of parts can be minimized. In addition, in order to obtain other effects, in this embodiment, the housing member 66b is also provided with a structure for maintaining a constant axial distance between the first motor 84a housed in the motor chamber 66 and the rotating cleaning body 82 housed in the rotating cleaning body chamber 64.

Specifically, as shown in FIG. 9 and the like, a rotating shaft support hole 66g for taking out the rotating shaft 84e of the first motor 84a is formed on the end surface forming the motor chamber 66 by mounting the housing member 66b. The rotating shaft support hole 66g is an approximately circular hole formed by matching the arc-shaped (approximately semicircular in this embodiment) notches formed on the motor arrangement section 66a side and the motor side cover section 66c side of the housing member 66b. In addition, the end surface forming the rotating cleaning body chamber 64 is provided with a cleaning body support hole 66h into which the groove 82f provided at the end of the rotating cleaning body 82 fits. The cleaning body support hole 66h is an approximately circular hole formed by matching the arc-shaped (approximately semicircular in this embodiment) notches formed on the lower case body 60b side and the cleaning body side cover section 66d side of the housing member 66b. Because the housing member 66b is an integral part of the motor side cover part 66c and the cleaning body side cover part 66d, the distance between the rotating shaft support hole 66g and the cleaning body support hole 66h can be kept approximately constant. Therefore, the axial distance between the first motor 84a and the rotating cleaning body 82 housed in the rotating cleaning body chamber 64 can be kept constant.

As shown in Figures 3 and 7, the hammering unit housing 68 is a space that houses the drive source of the hammering unit 90, which will be described later in detail. The hammering unit housing 68 is provided on the front side of the rotary cleaning body chamber 64, similar to the motor chamber 66 described above. That is, the hammering unit housing 68 is provided in the short direction of the case body 60, at a position opposite the suction chamber 62 with respect to the rotary cleaning body chamber 64. The hammering unit housing 68 is disposed in approximately the center of the case body 60 in the longitudinal direction. Therefore, the hammering unit housing 68 is disposed on the front side of the case body 60 so as to be aligned with the motor chamber 66 in the left-right width direction of the case body 60.

As shown in FIG. 5, the tube section 70 is a tubular section rotatably connected to the case body 60 at the communication section 65. The tube section 70 has a horizontal tube section 70a and a vertical tube section 70b. The horizontal tube section 70a is a tubular section closed at both ends. The horizontal tube section 70a is provided with a rotation shaft 72a that protrudes axially outward from the closed portions at both ends at the axial center position. In addition, an opening is provided on the periphery of the horizontal tube section 70a. The vertical tube section 70b is a tubular section connected to the periphery of the horizontal tube section 70a at approximately the center of the axial direction of the horizontal tube section 70a. One end side of the vertical tube section 70b (the upper end side in this embodiment) is a free end and can be connected to the main body 10 side of the vacuum cleaner 1. In addition, the other end side of the vertical tube section 70b is connected to the horizontal tube section 70a.

The horizontal tube section 70a is arranged in the portion where the curved surface 65a of the communication section 65 formed on the lower case body 60b side is formed, and the rotation shaft 72a is fitted into the support sections 65b, 65b. Then, the upper case body 60a is placed over the lower case body 60b to be integrated, so that the tube section 70 is supported rotatably around the rotation shaft 72a. In addition, an arc-shaped recess 65c is provided in the lower case body 60b at a position that is rearward (back side) of the portion where the curved surface 65a is formed and corresponds to approximately the center of the case body 60 in the left-right direction. The curvature of the recess 65c corresponds to the curvature of the outer surface of the vertical tube section 70b. Therefore, the recess 65c can support the vertical tube section 70b when the vertical tube section 70b is tilted 90 degrees.

The case body 60 has an opening that connects the inside to the outside. The opening is provided at a predetermined position (a position different from the side of the case body 60) excluding the side of the case body 60, and is shown as a first opening 72 in Figures 3 and 5, for example. In this embodiment, the gap between the tube portion 70 and the lower case body 60b is provided as the first opening 72. The rear side of the first opening 72 is open due to the recess 65c, making it easier for air to flow in.

The second opening 74 is an opening that connects the inside of the case body 60 to the rotary cleaning body chamber 64. As described above, in this embodiment, the opening 64e provided on the peripheral surface 64d of the rotary cleaning body chamber 64 is the second opening 74. The second opening 74 (opening 64e) is connected to a ventilated motor chamber internal flow path formed inside the motor chamber 66 inside the case body 60, thereby connecting the inside of the case body 60 to the rotary cleaning body chamber 64.

As shown in FIG. 10, the rotary cleaning unit 80 includes a rotary cleaning body 82 and a drive transmission mechanism 84. The rotary cleaning unit 80 transmits power to the rotary cleaning body 82 via the drive transmission mechanism 84 to rotate the rotary cleaning body 82 and scrape out or remove dust adhering to the object to be cleaned.

As shown in Figures 4 and 9, the rotating cleaning body 82 is housed inside the above-mentioned rotating cleaning body chamber 64 so that it can rotate. Specifically, the rotating cleaning body 82 has a cleaning body main body 82a extending in the axial direction and a first attachment body 82x of the attachment portion 82b. The rotating cleaning body 82 is housed inside the rotating cleaning body chamber 64 in a position in which the axial direction faces the longitudinal direction (left-right direction) of the case body 60, and is supported so as to be freely rotatable via the attachment portion 82b.

The rotating cleaning body 82 has a brush attachment portion 82c on the outside of the cleaning body main body 82a formed in a cylindrical shape, and a groove portion 82d between the brush attachment portions 82c, 82c adjacent in the circumferential direction. The brush attachment portion 82c and the groove portion 82d can each be, for example, provided substantially linearly in the axial direction of the cleaning body main body 82a, but in this embodiment, they are provided in a spiral shape on the outer periphery of the cleaning body main body 82a, centered on the axial center position of the cleaning body main body 82a. The brush attachment portion 82c is rail-shaped, and can hold the brush 82h by clamping it in a state where it protrudes toward the outside of the cleaning body main body 82a.

The mounting portion 82b is a portion used to mount the rotating cleaning body 82 to the case body 60. The mounting portion 82b is provided on one longitudinal side and the other longitudinal side of the cleaning body main body 82a. The mounting portion 82b includes a first mounting body 82x and a second mounting body 82y. The first mounting body 82x is fixed to an end of the cleaning body main body 82a. The second mounting body 82y is provided on the driven pulley 84d (described later) and is disposed on the case body 60 (lower case 60b) side. The first mounting body 82x and the second mounting body 82y are connectable and separable in the axial direction.

The first mounting body 82x has a mounting recess 82e and a first flange portion 82i. The mounting recess 82e is formed in a concave shape on the end surface of the mounting portion 82b. The mounting recess 82e may have any shape, but in this embodiment, it is cross-shaped. The mounting recess 82e is a portion into which the mounting protrusion 82j of the second mounting body 82y described below can be fitted and engaged. The first flange portion 82i is provided at the end of the first mounting body 82x (the end on the second mounting body 82y side) so as to bulge radially outward. In addition, the first flange portion 82i is supported by the stepped engagement portion 64i described above so as to cover it from the axial outside.

The second mounting body 82y has a mounting protrusion 82j and a second flange portion 82k. The mounting protrusion 82j protrudes in the axial direction at the end of the second mounting body 82y and is engageable with the above-mentioned mounting recess 82e. The mounting protrusion 82j may have any shape, but in this embodiment, it has a cross shape similar to the mounting recess 82e. The second flange portion 82k is provided so as to bulge radially outward at the end of the second mounting body 82y (the end on the first mounting body 82x side).

As shown in FIG. 8, the second mounting body 82y has a groove 82f formed therein, and the groove 82f is provided in the middle of the mounting portion 82b (second mounting body 82y). Specifically, the groove 82f is located between the first flange portion 82i and the second flange portion 82k. The groove 82f is provided around substantially the entire circumference of the mounting portion 82b (second mounting body 82y).

8, the groove 82f is located further toward the axial end of the rotary cleaning body 82 than the second flange portion 82k, and the groove 82f of the second mounting body 82y is supported by the cleaning body support hole 66h. The mounting protrusion 82j is located closer to the rotary cleaning body chamber 64 than the cleaning body support hole 66h, and is exposed to the rotary cleaning body chamber 64. Specifically, the radial side of the mounting protrusion 82j faces the notch 64c of the rotary cleaning body chamber 64.

As shown in FIG. 10, one of the two longitudinal ends of the rotating cleaning body 82 is connected to a drive transmission mechanism 84 so as to transmit power. Therefore, the rotating cleaning body 82 can be driven by receiving power output from the drive transmission mechanism 84. The drive transmission mechanism 84 includes a first motor 84a, a power transmission body 84b, an output pulley 84c, a driven pulley 84d, etc.

The first motor 84a generates a driving force for driving the rotary cleaning body 82. The first motor 84a is composed of a motor and the like provided in the case body 60. The first motor 84a is housed in the motor chamber 66 described above with its axial direction facing the longitudinal direction (left-right direction) of the case body 60. As described above, the first motor 84a has a bulging portion 84f that bulges outward in the radial direction at the middle of the axial direction. When the first motor 84a is housed in the motor chamber 66, the bulging portion 84f is in contact with the inner peripheral surface of the motor chamber 66. As a result, the inside of the motor chamber 66 is divided into a first region 66x formed on the longitudinal center side of the case body 60 and a second region 66y on the longitudinal outer side. The first motor 84a has a first ventilation opening 84g and a second ventilation opening 84h in each of the portion housed on the first region 66x side and the portion housed on the second region 66y side. This allows the first motor 84a to, for example, exhaust air taken into the interior of the first motor 84a through the first ventilation opening 84g through the second ventilation opening 84h.

The power transmission body 84b is composed of a toothed endless belt. The output side pulley 84c is a toothed pulley attached to the rotating shaft 84e of the motor constituting the first motor 84a. The driven side pulley 84d is integrally provided on the second mounting body 82y of the mounting part 82b to which the rotating cleaning body 82 is connected. The drive transmission mechanism 84 is configured such that the power transmission body 84b is a power transmission body 84b made of an endless belt that is wound between the output side pulley 84c and the driven side pulley 84d. Therefore, by operating the first motor 84a, the rotational power can be transmitted to the mounting part 82b side, and the rotating cleaning body 82 can be rotated in the suction space of the case body 60. The driven side pulley 84d is rotatably attached to a shaft part (not shown), and a bearing member 63a is provided that is attached to the shaft part so that a part of it is included in the driven side pulley 84d and fixed to the lower case body 60b. The driven pulley 84d may be rotatable relative to the shaft, or the driven pulley 84d and the shaft may be rotatable relative to the bearing member 63a. In addition, a bearing member 63b is provided at the end of the first motor 84a, which supports the rotating shaft 84e so that it can rotate and is fixed to the lower case body 60b.

As shown in FIG. 3, the beating unit 90 is provided with a second motor 94a in addition to the first motor 84a described above. As shown in FIG. 4, the beating unit 90 is provided with a beating member 94b and the like in addition to the second motor 94a. The beating unit 90 transmits vibrations generated by operating the second motor 94a to the object to be cleaned (e.g., a futon, etc.) via the beating member 94b, and performs the operation of beating the surface of the object to be cleaned. The beating unit 90 is provided on the front side of the rotating cleaning body chamber 64. The beating unit 90 is also provided adjacent to the motor chamber 66 equipped with the first motor 84a, and is provided in approximately the center of the case body 60 in the longitudinal direction (left-right direction).

The second motor 94a is housed in the motor case 94c. The second motor 94a is housed inside the motor case 94c with its rotation shaft facing the longitudinal direction of the case body 60. The rotation shaft of the second motor 94a is connected to a disk 94g inside the motor case 94c. The rotation shaft of the second motor 94a is connected to a position (eccentric position) that is off the center of the disk 94g. The second motor 94a is also arranged so as not to move vertically in the lower case body 60b. As a result, the second motor 94a is arranged so that the outer peripheral surface of the disk abuts against the top surface of the motor case 94c inside the motor case 94c. The motor case 94c is also movable vertically. Therefore, the second motor 94a is operated to rotate the disk connected to the rotation shaft eccentrically, thereby vibrating the motor case 94c in the vertical direction.

The striking member 94b is provided so as to be exposed on the bottom surface of the case body 60. Specifically, the bottom surface of the case body 60 is provided with a striking part housing portion 68 consisting of a recess on the front side having a depth equivalent to or greater than the thickness of the striking member 94b. The striking member 94b is disposed within the striking part housing portion 68 so as to extend in the longitudinal direction (left-right direction) of the case body 60.

As shown in FIG. 4, the hitting member 94b has a symmetrical shape when viewed from above, like two futon beater handles joined together. The hitting member 94b is made wider towards the ends, and many openings 94d are formed. The central part of the hitting member 94b is made into a support part 94f. The area near the support part 94f functions like the handle of a futon beater. Therefore, the hitting member 94b is configured to be able to exert a large hitting force at the end of the hitting member 94b by moving it up and down near the support part 94f.

The striking unit 90 is configured by connecting the above-mentioned motor case 94c to the support portion 94f of the striking member 94b or in the vicinity thereof. Therefore, the striking unit 90 can transmit the vertical vibrations generated by operating the second motor 94a to activate the striking member 94b to exert a striking force, thereby obtaining the effect of lifting dust to the surface side of the object to be cleaned.

<<Regarding the airflow generated in the suction port body 50>>
As described above, the suction port body 50 includes the first opening 72, the second opening 74, etc., in addition to the tube portion 70 through which the sucked dust passes. The suction port body 50 generates an airflow passing through the inside of the case body 60 via the first opening 72 and the second opening 74, and can suppress heat generation from the first motor 84a and the second motor 94a built into the case body 60, and can discharge the heat generated by these motors to the outside of the case body 60. The airflow formed in the suction port body 50 will be described in more detail below.

As shown by the arrow in FIG. 3, the suction port body 50 has a first opening 72 consisting of a gap formed between the tube portion 70 and the lower case body 60b on the rear side (back side). The suction port body 50 also has a second opening 74 consisting of an opening 64e formed in the part forming the rotary cleaning body chamber 64. Here, the rotary cleaning body chamber 64 is located forward of the suction chamber 62 and communicates with the suction chamber 62. The communication portion 65 is also a space that communicates with the tube portion 70. Therefore, when the electric vacuum cleaner 1 is operated, negative pressure generated by the flow of air sucked by the fan motor 15 acts on the tube portion 70, the communication portion 65, the suction port 62a, the suction chamber 62, and the rotary cleaning body chamber 64 (second opening 74). Therefore, when the electric vacuum cleaner 1 is operated, an air flow is formed in the suction port body 50 that extends roughly from the first opening 72 to the second opening 74.

Here, the suction port body 50 has a housing member 66b forming a motor chamber 66 in which the first motor 84a is housed inside the case body 60. The housing member 66b also has an inlet side opening 66e that opens toward the striking section 90 side where the second motor 94a is present, and an outlet side opening 66f formed to communicate with the second opening 74. Here, the inside of the housing member 66b is divided into two areas, a first area 66x and a second area 66y, by the bulging portion 84f of the first motor 84a. However, a first ventilation opening 84g and a second ventilation opening 84h are provided on the peripheral surface of the first motor 84a, and ventilation is possible through a route that bypasses the inside of the first motor 84a through these openings. Therefore, in the housing member 66b, the airflow that flows into the first region 66x from the inlet side opening 66e can pass through a path that bypasses the inside of the first motor 84a via the first ventilation opening 84g and the second ventilation opening 84h, and reach the second region 66y. Also, in the housing member 66b, the airflow that reaches the second region 66y can reach the rotating cleaning body chamber 64 via the outlet side opening 66f and the second opening 74.

As described above, inside the suction port body 50, a flow path through which airflow can pass is formed inside the motor chamber 66. In addition, the motor chamber 66 is connected to the rotating cleaning body chamber 64, where negative pressure from the fan motor 15 acts, via the discharge side opening 66f and the second opening 74. Therefore, inside the suction port body 50, the airflow introduced from the first opening 72 flows from the beater section 90 side (second motor section 94a) toward the motor chamber 66, passes through the inlet side opening 66e and the discharge side opening 66f provided on the side of the motor chamber 66, and flows into the rotating cleaning body chamber 64 from the second opening 74.

<About modified versions>
Hereinafter, modified examples of the vacuum cleaner 1 and the suction mouth body 50 of the above-described embodiment will be described. In the following description, the same components as those shown in the above-described embodiment will be described using the same reference numerals and description will be omitted.

<Modification 1>
The suction port body 50 illustrated in the above embodiment includes, in addition to the first motor 84a, the second motor 94a for driving the beating unit 90, and is configured to be capable of cooling and suppressing temperature rise not only for the first motor 84a but also for the second motor 94a, but other configurations are also possible, for example. Specifically, the suction port body 50 may not include the beating unit 90 or the second motor 94a for driving it.

In this case, the number of heat sources inside the case body 60 is reduced, and the internal configuration of the case body 60 is simplified, so that the cooling effect and the temperature rise suppression effect of the first motor 84a can be further improved. In this case, the motor arrangement part 66a is provided on the rear side of the suction chamber 62, and the first motor 84a is arranged, and the shape of the housing member 66b is changed accordingly. That is, the shape of the motor side cover part 66c and the cleaning body side cover part 66d may be changed so that the front-back relationship is reversed in accordance with the change in the arrangement of the first motor 84a. More specifically, the motor side cover part 66c is arranged to straddle the upper part of the suction chamber 62, and the cleaning body side cover part 66d is arranged to straddle the upper part of the suction chamber 62 to close the notch 64c. This can be realized by providing the second opening 74 on the suction chamber 62 side of the rotating cleaning body chamber 64 and the discharge side opening 66f on the rotating cleaning body chamber 64 side of the motor side cover part 66c.
<Modification 2>
In the first modification, a motor placement section 66a is provided on the rear side of the suction chamber 62, a first motor 84a is disposed, and the rotary cleaning body chamber 64 and the housing member 66b are communicated with each other. The difference between the second modification and the first modification is that the suction chamber 62 and the housing member 66b are communicated with each other, instead of the rotary cleaning body chamber 64 and the housing member 66b being communicated with each other. Specifically, instead of providing the second opening 74 in the rotary cleaning body chamber 64, a hole is provided in the suction chamber 62, and the hole is communicated with the discharge side opening 66f on the second region 66y side of the motor side cover part 66c, and the cleaning body side cover part 66d is configured to straddle the upper part of the suction chamber 62 and close the notch 64c. Here, the shape and size of the hole provided in the suction chamber 62 may be appropriately adjusted. Then, instead of the first opening 72, a first opening may be provided on the rear side of the lower case 60b, and the inlet side opening 66e of the motor side cover portion 66c may be provided at a position on the first region 66x side opposite the first opening.

<Modification 3>
In the above-described embodiment, an example has been shown in which the first opening 72 is formed between the tube portion 70 and the case body 60, but an opening may be formed in another portion in addition to or instead of the first opening 72. Specifically, for example, as shown in the upper left region of Fig. 11, the suction port body 50 of the vacuum cleaner 1 may be provided with one or more (multiple in this modification) openings 100 in the bottom surface of the case body so as to communicate between the inside and the outside of the case body, instead of or in addition to the first opening 72.

When an opening 100 is provided near the first motor 84a as shown in FIG. 11, the airflow introduced from the opening 100 is expected to flow from the first motor 84a to the beating section 90 side, enter the motor chamber 66 from the inlet side opening 66e, and enter the rotary cleaning body chamber 64 from the outlet side opening 66f, as shown by the arrow in the figure. In addition, the airflow that flows into the rotary cleaning body chamber 64 is expected to flow through the suction chamber 62, the communication section 65, and the tube section 70, and is sucked into the main body 10 side. By forming such an airflow, it is expected to have effects such as suppressing the rise in the internal atmospheric temperature of the case body 60, cooling effects such as the first motor 84a and the second motor 94a of the beating section 90, and suppressing temperature rise.

In addition, when the above-mentioned opening 100 or the like is provided, other configurations may be added to more reliably introduce airflow into the case body 60 through the opening 100. Specifically, for example, as shown in FIG. 12, a guide groove 110 may be formed to function as a passage that guides air from the outer periphery side (the front side in this embodiment) of the case body 60 toward the area where the opening 100 is formed (the tapping part housing part 68 in this embodiment). With such a configuration, airflow is guided by the guide groove 110 on the bottom surface (bottom part) of the suction port body 50 and is formed to flow toward the opening 100 facing the guide groove 110, making it possible to more reliably introduce airflow into the case body 60 through the opening 100. In addition, the guide groove 110 is open on the bottom side of the case body 60 here, but instead of the guide groove 110, an opening with a closed bottom side of the case body 60 may be formed and communicated with the opening 100. In addition, a filter may be provided on this opening and the opening 100 to prevent dust from entering.

<Modification 4>
In the above embodiment, an example is shown in which the filter 64f is provided at the opening 64e provided in the rotary cleaning body chamber 64, where the filter 64f is provided at a position where the brush 82h of the rotary cleaning body 82 comes into contact, so that the filter 64f can be cleaned by the rotary cleaning body 82, but other configurations are also possible. For example, the filter 64f may be one in which the state of contact with the rotary cleaning body 82 changes depending on the rotational position of the rotary cleaning body 82, such as by changing the protruding amount of the multiple brushes 82h of the rotary cleaning body 82 so that the filter 64f switches between a contact state and a non-contact state depending on the rotational position. Also, the filter 64f may be configured to come into contact with the rotary cleaning body 82 regardless of the rotational position of the rotary cleaning body 82.

In addition, in the above embodiment, an example was shown in which the filter 64f was provided at the opening 64e provided in the rotary cleaning body chamber 64, but the filter 64f may be provided at the portion where the housing member 66b and the rotary cleaning body chamber 64 communicate with each other. For example, the filter 64f may be provided at the discharge side opening 66f on the housing member 66b side. In such a configuration, cleaning of the filter 64f using the rotation of the rotary cleaning body 82 may be more difficult than in the above embodiment, but it would be even better to add another configuration that makes the filter 64f cleanable.

<Modification 5>
In the above embodiment, an example was shown in which the internal space of the motor chamber 66 was divided into a first region 66x and a second region 66y by the bulge 84f provided in the axial middle portion of the first motor 84a, but the motor chamber 66 does not have to be configured in this way and may be a space that is connected over substantially the entirety. In addition, in a configuration in which the inside of the motor chamber 66 is not divided into the first region 66x and the second region 66y, the position at which the inlet side opening 66e is provided is not limited to the axial surface of the motor side cover portion 66c, and it may be provided at any appropriate position that allows communication with the rotary cleaning body chamber 64.

<Modification 6>
In the above embodiment, the suction port body 50 is configured to have the rotary cleaning body chamber 64 (accommodation chamber) and the suction chamber 62 (accommodation chamber) provided separately, but the present invention is not limited to this. Specifically, the suction port body 50 may be configured to provide the rotary cleaning body 82 in the suction chamber 62 (accommodation chamber) having the suction port 62a without distinguishing between the rotary cleaning body chamber 64 and the suction chamber 62. With this configuration, it is no longer necessary to provide two spaces, the rotary cleaning body chamber 64 and the suction chamber 62, separately in the case body 60, and the configuration of the case body 60 can be simplified accordingly.

<Modification 7>
In the above embodiment, as illustrated in Fig. 9, the lower case body 60b is covered with the housing member 66b to cover the first motor 84a arranged in advance in the motor arrangement portion 66a and to support the rotary shaft 84e of the first motor 84a and the second mounting body 82y forming the mounting portion 82b of the rotary cleaning body 82. However, other configurations can be adopted for the structure of this portion as well. For example, as illustrated in Fig. 13, a drive unit 120 in which the first motor 84a and the second mounting body 82y (drive transmission mechanism 84) are unitized may be provided, and the drive unit 120 may be incorporated into the lower case body 60b to enable the first motor 84a and the second mounting body 82y (drive transmission mechanism 84) to be mounted. Although not illustrated, a stopper member is provided at each of the shaft ends of the first motor 84a and the second mounting body 82y to prevent the output side pulley 84c and the driven side pulley 84d from coming off from their respective shaft portions. With such a configuration, the rotating cleaning body 82 can be installed in the drive unit 120 by inserting and connecting the rotating cleaning body 82 to the second mounting body 82y of the drive unit 120 incorporated in the lower case body 60b, as shown by the arrow in the figure.
The driving unit 120 has a motor side cover part 120c and a cleaning element side cover part 120d, and the cleaning element side cover part 120d closes the notch 64c, which is the same as the above-mentioned embodiment. The motor side cover part 120c of the driving unit 120 has a rotating shaft support hole 66g (not shown), and the cleaning element side cover part 120d has a cleaning element support hole 66h (not shown) that supports the groove 82f of the driven pulley 84d. Although not shown, the driving unit 120 may be configured as an upper unit case and a lower unit case so that the rotating shaft support hole 66g and the cleaning element support hole 66h are separated into upper and lower parts. Alternatively, a slit may be provided in the motor side cover part 120c to guide the rotating shaft 84e of the first motor 84a to the rotating shaft support hole 66g, and a slit may be provided in the cleaning element side cover part 120d to guide the driven pulley 84d to the cleaning element support hole 66h.

The above-described configuration allows the first motor 84a, the mounting portion 82b, etc. to be unitized and assembled integrally into the lower case body 60b, improving the efficiency of the assembly work of the suction port body 50.

Although each of the modified examples has been described above, it is naturally conceivable that each of the modified examples can be combined with each other so as not to cause technical discrepancies. In particular, in modified example 7, the inlet side opening 66e, the outlet side opening 66f, and the filter 64f are not essential components, but the inlet side opening 66e, the outlet side opening 66f, and the filter 64f may be provided on the motor side cover part 120c, as in the above-mentioned embodiment.

<Overview of the structure and effects>
Based on the embodiment and modified examples of the vacuum cleaner 1 and suction mouth body 50 described above, the relationship between the configurations of the vacuum cleaner 1 and the suction mouth body 50 and the effects obtained thereby will be summarized below.

(a-1) As shown in the above embodiment, the suction port body 50 of the vacuum cleaner 1 has a case body 60 with a space inside and a rotating cleaning body 82 rotatably mounted on the case body 60, and the case body 60 is characterized by having a suction chamber 62 with a suction port 62a capable of sucking in dust, a rotating cleaning body chamber 64 that opens to the outside in front of the suction port 62a and in which the rotating cleaning body 82 is arranged, a first motor 84a that is arranged inside the space in a direction that intersects with the axial direction of the rotating cleaning body 82 relative to the rotating cleaning body chamber 64 and generates a driving force for driving the rotating cleaning body 82, a first opening 72 that is provided at a position other than the side of the case body 60 (other than the side of the case body 60) and that connects the inside of the case body 60 to the outside, and a second opening 74 that connects the inside of the case body 60 to the rotating cleaning body chamber 64.

As described in (a-1) above, the suction port body 50 of the vacuum cleaner 1 has a first opening 72 that communicates between the inside and outside of the case body 60 in which the first motor 84a is housed, and a second opening 74 that communicates between the inside of the case body 60 and the rotary cleaning body chamber 64. The rotary cleaning body chamber 64 is open to the outside in front of the suction port 62a. The suction chamber 62, the rotary cleaning body chamber 64, and the first motor 84a are arranged in the front-rear direction of the case body 60 (a direction intersecting the axial direction of the rotary cleaning body 82). Therefore, when the vacuum cleaner 1 is operated with the suction port 62a facing the object to be cleaned to generate suction force, an airflow is generated that flows into the inside of the case body 60 from the first opening 72, passes through the rotary cleaning body chamber 64, and reaches the suction chamber 62. Therefore, with the suction port body 50 of the vacuum cleaner 1 described above, it is possible to effectively cool the first motor 84a inside the case body 60 and prevent the temperature from rising.

(a-2) As shown in the above embodiment, the suction port body 50 of the vacuum cleaner 1 shown in (a-1) above is rotatably connected to the case body 60 rearward of the suction port 62a and has a tube portion 70 that communicates with the suction chamber 62, and the first opening 72 is preferably provided between the tube portion 70 and the case body 60.

By adopting the configuration as described above in (a-2), it is possible to allow the airflow introduced into the suction port body 50 from the first opening 72 provided between the tube portion 70 and the case body 60 to flow smoothly from the rear to the front inside the case body 60. This can reduce the internal atmospheric temperature of the case body 60 and improve the cooling effect and temperature rise suppression effect of the first motor 84a built into the case body 60.

(a-3) As a modified example described above, in the suction port body 50 of the vacuum cleaner 1 shown in (a-1) above, the first opening may be provided so as to open at the bottom surface of the case body 60.

By using the configuration described above in (a-4), the airflow introduced into the main body case from the first opening can effectively cool the first motor 84a, etc., and prevent the temperature from rising.

(a-4) As shown in the above embodiment, the suction port body 50 of the electric vacuum cleaner 1 shown in any of (a-1) to (a-3) above has a motor chamber 66 in which the first motor 84a is housed inside the case body 60, and the motor chamber 66 preferably includes an inlet side opening 66e that opens in a direction away from the position facing the rotary cleaning body chamber 64, and a discharge side opening 66f that is provided as a second opening 74 and opens toward the rotary cleaning body chamber 64.

By configuring as described above in (a-4), the suction port body 50 increases the likelihood that the airflow introduced into the case body 60 will flow through a path that passes through the motor chamber 66 and reaches the rotating cleaning body chamber 64, thereby improving the cooling effect of the first motor 84a and the effect of suppressing temperature rise.

(a-5) As shown in the above embodiment, the suction port body 50 of the vacuum cleaner 1 shown in any of (a-1) to (a-4) above may have a rotating cleaning body 82 that includes a cleaning body main body 82a (shaft portion) and a brush 82h (cleaning body) that protrudes in a direction intersecting the axial direction of the cleaning body main body 82a, and a filter 64f that abuts against the brush 82h is provided in the second opening 74.

Because of the configuration described above in (a-5), in the suction port body 50, the rotating cleaning body 82 that rotates in the rotating cleaning body chamber 64 can also be used to clean the filter 64f. In addition, because the rotating cleaning body 82 operates on almost every occasion when the vacuum cleaner 1 is used, the filter 64f is always kept clean.

(a-6) As shown in the above embodiment, the suction port body 50 of the vacuum cleaner 1 shown in any of (a-1) to (a-4) above is provided with a second motor 94a provided inside the case body 60 separately from the first motor 84a, and a beating section 90 provided forward of the rotary cleaning body chamber 64 and transmitting the vibrations of the second motor 94a to the object to be cleaned, and the second motor 94a is preferably provided side by side with the rotary cleaning body chamber 64 inside the space in a direction intersecting the axial direction of the rotary cleaning body 82.

According to the configuration as described above in (a-6), the suction port body 50 can be configured to be more compact in the front-rear direction than when the first motor 84a and the second motor 94a are arranged in front and behind the rotary cleaning body chamber 64 inside the case body 60. In addition, by arranging the first motor 84a and the second motor 94a side by side in the longitudinal direction on the front side of the case body 60, it becomes possible to cool the first motor 84a and the second motor 94a together by the airflow that reaches the front side from the rear side.

(a-7) As a modified example, as described above, the suction port body 50 of the vacuum cleaner 1 shown in (a-3) above may include a second motor 94a provided inside the case body 60 separately from the first motor 84a, a beating unit 90 provided forward of the rotating cleaning body chamber 64 and transmitting the vibrations of the second motor 94a to the object to be cleaned, and a beating unit housing 68 in which the beating unit 90 is housed and in which a first opening 100 is provided.

With the configuration described above in (a-7), the airflow introduced into the inside of the case body 60 from the first opening 72 provided in the striking unit housing 68 is expected to have a cooling effect and a temperature rise suppression effect on the first motor 84a and the second motor 94a.

(a-8) As a modified example described above, the suction port body 50 of the vacuum cleaner 1 shown in (a-7) above has an opening (first opening 100) that is provided on the front side of the case body 60 and opens toward the bottom surface of the case body 60, and the beating part housing section 68 preferably connects the inside and outside of the case body 60 via the opening (first opening 100).

The configuration described above in (a-8) allows airflow to be introduced into the case body 60 through the opening (first opening 100), providing the effect of cooling the first motor 84a and the second motor 94a and suppressing temperature increases.

(b) As shown in the above embodiment, the suction port body 50 of the vacuum cleaner 1 has a case body 60 having a space inside, and a rotating cleaning body 82 rotatably mounted on the case body 60, and the case body 60 has a suction chamber 62 having a suction port 62a capable of sucking in dust, a rotating cleaning body chamber 64 that is open to the outside forward of the suction port 62a and in which the rotating cleaning body 82 is arranged, and the rotating cleaning body 82 is arranged inside the space so as to be aligned with the rotating cleaning body chamber 64 in a direction that intersects with the axial direction of the rotating cleaning body 82. The rotating cleaning body 82 includes a first motor 84a that generates a driving force for driving the rotating cleaning body 82, a first opening 72 that connects the inside and outside of the case body 60, and a second opening 74 that connects the inside of the case body 60 and the rotating cleaning body chamber 64. The rotating cleaning body 82 includes a cleaning body main body 82a and a brush 82h that protrudes in a direction intersecting the axial direction of the cleaning body main body 82a, and a filter 64f that abuts against the brush 82h is provided in the second opening 74.

The suction port body 50 of the vacuum cleaner 1 of this embodiment is configured as described above in (b), so that an airflow can be introduced into the case body 60 through the first opening 72 and discharged to the outside through the second opening 74. The suction port body 50 can use this airflow to effectively cool the first motor 84a and prevent it from heating up.

As described above, the rotating cleaning body 82 that rotates in the rotating cleaning body chamber 64 can come into contact with the filter 64f provided in the second opening 74. Therefore, with the configuration described in (b) above, the rotating cleaning body 82 can also be used to clean the filter 64f. In addition, since the rotating cleaning body 82 operates on almost every occasion when the vacuum cleaner 1 is used, the filter 64f can be kept clean at all times.

(c) As shown in the above embodiment, the suction port body 50 of the vacuum cleaner 1 has a case body 60 having a space inside, and a rotating cleaning body 82 rotatably mounted on the case body 60, and the case body 60 has a suction chamber 62 having a suction port 62a capable of sucking in dust, a rotating cleaning body chamber 64 that is open to the outside forward of the suction port 62a and in which the rotating cleaning body 82 is arranged, and a driving force for driving the rotating cleaning body 82, which is arranged inside the space so as to be aligned with the rotating cleaning body chamber 64 in a direction intersecting the axial direction of the rotating cleaning body 82. It is characterized by having a first motor 84a that generates a vibration, a second motor 94a that is provided separately from the first motor 84a and is arranged inside a space formed inside the case body 60 so as to be aligned with the first motor 84a in the axial direction of the rotating cleaning body 82, a beating section 90 that is provided in front of the rotating cleaning body chamber 64 and transmits the vibration of the second motor 94a to the object to be cleaned, a first opening 72 that connects the inside and outside of the case body 60, and a second opening 74 that connects the rotating cleaning body chamber 64 and the inside of the case body 60.

The suction port body 50 of the vacuum cleaner 1 of this embodiment is configured as described above in (c), so that an airflow can be formed inside the case body 60, which flows in through the first opening 72 and is exhausted to the outside from the second opening 74. The suction port body 50 can effectively cool the first motor 84a and the second motor 94a and prevent the temperature from rising by the airflow formed inside the case body 60.

As described in (c) above, the suction port body 50 has the first motor 84a provided for driving the rotary cleaning body 82 and the second motor 94a provided for driving the beating section 90 arranged along the axial direction of the rotary cleaning body. Because of this arrangement, the suction port body 50 has a compact configuration in the front-rear direction compared to when the first motor 84a and the second motor 94a are arranged in front and behind the rotary cleaning body chamber 64 inside the case body 60. In addition, by arranging the first motor 84a and the second motor 94a side by side in the longitudinal direction on the front side of the case body 60, it is possible to cool the first motor 84a and the second motor 94a together by the airflow that reaches the front side from the rear side.

(d) The suction port body 50 of the electric vacuum cleaner 1 illustrated as a modified example has a case body 60 having a space inside and a rotating cleaning body 82 rotatably mounted on the case body 60, the case body 60 having a suction chamber 62 having a suction port 62a capable of sucking in dust, a rotating cleaning body chamber 64 that opens to the outside in front of the suction port 62a and in which the rotating cleaning body 82 is arranged, a first motor 84a that is arranged inside the space in a direction that intersects with the axial direction of the rotating cleaning body 82 relative to the rotating cleaning body chamber 64 and generates a driving force for driving the rotating cleaning body 82, a first opening 72 that connects the inside of the case body 60 to the outside, and a second opening 74 that connects the rotating cleaning body chamber 64 to the inside of the case body 60, the first opening 72 being arranged to open forward of the rotating cleaning body chamber 64 and toward the bottom surface (bottom) of the case body.

The suction port body 50 configured as described in (d) above can form an airflow inside the case body 60 that flows between the opening 100 that is provided to open on the bottom surface (bottom) and the second opening 74. Therefore, according to the above-mentioned configuration, the airflow formed inside the case body 60 can effectively cool the first motor 84a and suppress the temperature rise.

(e) As shown in the above embodiment, the suction port body 50 of the vacuum cleaner 1 of this embodiment includes a case body 60 having a suction port 62a, a rotating cleaning body 82 rotatably mounted on the case body 60, a storage chamber mounted on the case body 60 in which the rotating cleaning body 82 is disposed, a first motor 84a mounted inside the case body 60 and generating a driving force to drive the rotating cleaning body 82, and a cover portion (housing member 66b) that constitutes part of the storage chamber and is separate from the storage chamber, and the cover portion radially covers the end of the rotating cleaning body 82 and holds it rotatably.

Because of the configuration described in (e) above, the cover portion can be used not only as a member forming the storage chamber, but also as a member for holding the end of the rotating cleaning body 82 in position with high precision.

In addition, because of this configuration, the rise in the internal atmospheric temperature of the suction port body 50 can be suppressed, and the cooling effect and temperature rise suppression effect of the first motor 84a arranged inside the suction port body 50 can be obtained.

In the above embodiment and modified examples, the vacuum cleaner 1 and the suction mouth body 50 are exemplified as being used for cleaning futons and the like, but the present invention is not limited to this, and the same configuration can be applied to, for example, so-called canister-type vacuum cleaners and stick-type vacuum cleaners. In addition, for example, if the vacuum cleaner 1 and the suction mouth body 50 are to be used for purposes other than cleaning futons and the like, it is possible to omit the beating portion 90, or to not provide a frame 64a or the like formed in a lattice shape or the like at the opening of the rotating cleaning body chamber 64.

The suction mouth body 50 illustrated in the above embodiment and modified examples is exemplified as being rotatable only in the front-rear direction, i.e., swivelable only around the axis of the horizontal tube section 70a that constitutes the tube section 70. However, for example, the tube section may be made up of a first pipe with a rotation axis in the front-rear direction and a second pipe with a rotation axis in the left-right direction, and the first pipe and the second pipe may be connected to each other to make it swivelable in the left-right direction in addition to the front-rear direction, or the tube section may have a universal joint structure to make it swivelable all around.

(1-1) The suction port body of a vacuum cleaner according to the first aspect of this embodiment comprises a case body having a space inside and a suction port capable of sucking in dust, and a rotating cleaning body rotatably mounted on the case body, the case body being open to the outside in front of the suction port, a storage chamber in which the rotating cleaning body is disposed, a motor arranged inside the space in a direction intersecting the axial direction of the rotating cleaning body relative to the storage chamber, and generating a driving force for driving the rotating cleaning body, a first opening provided at a position other than the side of the case body, connecting the inside of the case body with the outside, and a second opening connecting the inside of the case body with the storage chamber.

(1-2) The suction port body of the above-mentioned vacuum cleaner is preferably rotatably connected to the case body rearward of the suction port, has a tube portion communicating with the storage chamber, and the first opening is preferably provided between the tube portion and the case body.

(1-3) It is preferable that the first opening of the suction port body of the above-mentioned vacuum cleaner is provided so as to open at the bottom of the case body.

(1-4) The suction mouth body of the above-mentioned vacuum cleaner preferably has a motor chamber in which the motor is housed inside the case body, and the motor chamber preferably includes an inlet side opening that opens in a direction away from a position facing the housing chamber, and a discharge side opening that is provided as the second opening and opens toward the housing chamber.

(1-5) In the suction mouth body of the above-mentioned vacuum cleaner, the rotating cleaning body preferably includes a shaft portion and a cleaning body that protrudes in a direction intersecting the axial direction of the shaft portion, and a filter that abuts against the cleaning body is preferably provided in the second opening.

(1-6) The suction mouth body of the above-mentioned vacuum cleaner preferably includes a motor provided as a first motor, a second motor provided inside the case body separately from the first motor, and a beating section provided forward of the storage chamber and transmitting vibrations of the second motor to an object to be cleaned, and the second motor is preferably provided next to the storage chamber inside the space in a direction intersecting the axial direction of the rotary cleaning body.

(1-7) The suction mouth body of the above-mentioned vacuum cleaner may preferably include a motor provided as a first motor, a second motor provided inside the case body separately from the first motor, a beating unit provided forward of the storage chamber and transmitting vibrations of the second motor to an object to be cleaned, and a beating unit storage section in which the beating unit is stored and in which the first opening is provided.

(1-8) The suction mouth of the above-mentioned vacuum cleaner may have an opening at the front side of the case body that opens toward the object to be cleaned, and the beating part housing may communicate between the inside and outside of the case body via the opening.

(2) A cleaning device comprising a case body having a space therein and an inlet port capable of sucking in dust, and a rotating cleaning body rotatably mounted on the case body, the case body being open to the outside in front of the inlet port, a storage chamber in which the rotating cleaning body is disposed, a motor arranged inside the space in a direction intersecting the axial direction of the rotating cleaning body relative to the rotating cleaning body chamber, generating a driving force for driving the rotating cleaning body, a first opening connecting the inside of the case body to the outside, and a second opening connecting the inside of the case body to the rotating cleaning body chamber, the rotating cleaning body including a shaft portion and a cleaning body protruding in a direction intersecting the axial direction of the shaft portion, and a filter in contact with the cleaning body being provided in the second opening.

(3) The suction port body of the vacuum cleaner according to the third aspect of this embodiment has a case body having a space inside and a suction port capable of sucking in dust, and a rotating cleaning body rotatably arranged on the case body, the case body being open to the outside in front of the suction port, a storage chamber in which the rotating cleaning body is arranged, a first motor arranged inside the space so as to be aligned with the storage chamber in a direction intersecting the axial direction of the rotating cleaning body and generating a driving force for driving the rotating cleaning body, a second motor arranged separately from the first motor and arranged inside the space so as to be aligned with the first motor in a direction along the axial direction of the rotating cleaning body, a striking section arranged forward of the storage chamber and transmitting vibrations of the second motor to an object to be cleaned, a first opening communicating the inside and outside of the case body, and a second opening communicating the inside of the storage chamber and the inside of the case body.

(4) The suction port body of the vacuum cleaner according to the fourth aspect of this embodiment comprises a case body having a space inside and a suction port capable of sucking in dust, and a rotating cleaning body rotatably arranged on the case body, the case body being open to the outside in front of the suction port, a storage chamber in which the rotating cleaning body is arranged, a motor arranged inside the space in a direction intersecting the axial direction of the rotating cleaning body relative to the storage chamber, generating a driving force for driving the rotating cleaning body, a first opening that connects the inside and outside of the case body, and a second opening that connects the storage chamber and the inside of the case body, the first opening being arranged to open forward of the storage chamber and toward the object to be cleaned.

(5) The suction port body of a vacuum cleaner in a fifth aspect of this embodiment comprises a case body having a suction port, a rotating cleaning body rotatably mounted on the case body, a storage chamber provided in the case body in which the rotating cleaning body is disposed, a motor provided inside the case body for generating a driving force to drive the rotating cleaning body, and a cover portion that forms part of the storage chamber and is separate from the storage chamber, wherein the cover portion radially covers an end of the rotating cleaning body and holds it rotatably.
(6) The suction port body of the vacuum cleaner in the sixth aspect of this embodiment is characterized in that it includes a case body having a suction port, a rotating cleaning body rotatably mounted on the case body, a storage chamber mounted on the case body in which the rotating cleaning body is disposed, a motor mounted inside the case body and generating a driving force to drive the rotating cleaning body, an output side pulley mounted on the motor, a driven side pulley connected to the rotating cleaning body, and a belt rotatably stretched between the output side pulley and the driven side pulley, and is equipped with a drive transmission mechanism that transmits the driving force from the motor to the rotating cleaning body, and a support member that supports the output shaft of the motor and the driven side pulley as a single unit.

The present invention is not limited to the configurations described in the above-mentioned embodiments, and design changes, etc. can be made as appropriate within the scope of the technical ideas of the present invention. The components of the above-mentioned embodiments and variations may be arbitrarily selected and combined. Any component of each embodiment or variation may be arbitrarily combined with any component described in the means for solving the invention, the mode for carrying out the invention, etc., or any component that embodies any component described in the means for solving the invention, the mode for carrying out the invention, etc. We intend to obtain rights to these as well in this application or in divisional applications based on this application.

This invention can be used effectively in vacuum cleaners in general.

1: Vacuum cleaner 50: Suction port body 60: Case body 62: Suction chamber 62a: Suction port 64: Rotary cleaning body chamber 64f: Filter 66: Motor chamber 66b: Housing member 66e: Inlet side opening 66f: Discharge side opening 68: Beating part accommodating part 70: Tube part 72: First opening 74: Second opening 82: Rotary cleaning body 82a: Cleaning body main body 82h: Brush 84a: First motor 90: Beating part 94a: Second motor

Claims (7)

a case body having an internal space and an inlet port capable of sucking in dust;
A rotating cleaning body that is rotatably provided in the case body and is disposed in an accommodation chamber that is a space extending in a longitudinal direction of the case body ;
a motor provided inside the case body and configured to generate a driving force for driving the rotary cleaning body;
a drive transmission mechanism that transmits a drive force of the motor to the rotary cleaning body;
a first cover portion that constitutes a part of a top side of a peripheral surface that constitutes the storage chamber, the bottom side of the case body being open to the outside, and that is separate from the case body;
The drive transmission mechanism includes:
an output pulley provided on a rotating shaft of the motor;
a driven pulley detachably connected to the rotary cleaning body via an attachment portion;
a belt that is stretched between the output pulley and the driven pulley,
The case body is
A first opening is provided at a position different from a side of the case body and allows the inside and outside of the case body to communicate with each other;
A second opening that communicates the inside of the case body with the storage chamber;
a notch on one side in the axial direction of the rotary cleaning body, the notch facing the radial side of the mounting portion of the driven pulley and having a shape formed by cutting out a part of a top side of the peripheral surface constituting the accommodation chamber,
The suction port body of a vacuum cleaner, wherein the first cover portion covers the notch when the driven pulley is disposed in the case body. The suction port body of the vacuum cleaner according to claim 1, characterized in that the case body and the first cover part form a first support hole that supports the driven pulley. The suction mouth body of the vacuum cleaner according to claim 1, characterized in that the first cover portion has a first support hole that supports the driven pulley. A second cover portion that covers the motor is provided.
4. The suction head body of the vacuum cleaner according to claim 2 or 3, wherein the case body and the second cover portion form a motor chamber in which the motor is housed, and also form a second support hole that supports the rotating shaft. A second cover portion that covers the motor is provided.
4. The suction head body of the vacuum cleaner according to claim 2, wherein the second cover portion forms a motor chamber in which the motor is housed, and has a second support hole that supports the rotary shaft. The suction mouth of the vacuum cleaner according to claim 4 or 5, characterized in that the first cover part is integral with the second cover part. A vacuum cleaner comprising a suction mouth body according to any one of claims 1 to 6.

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