JP6643796B2 - Vacuum cleaner and its suction body - Google Patents

Description

  An embodiment of the present invention relates to a suction port of a vacuum cleaner having a motor that generates a driving force for driving a rotary cleaning body, and a vacuum cleaner having the same.

  Conventionally, as a floor brush as a suction port body used by being connected to an extension pipe of a vacuum cleaner or a vacuum cleaner body, a rotating brush, which is a rotary cleaning body, is rotated by a motor to scrape dust that has entered a carpet, There is a so-called power brush. The motor is housed in a motor chamber in the case body of the floor brush, and is configured to cool the motor by taking in outside air into the motor chamber using negative pressure generated by driving the electric blower.

  In recent years, a motor using a neodymium magnet may be employed in order to obtain a stronger rotational force. Neodymium magnets are liable to be thermally demagnetized, so it is required to cool the motor more efficiently.

JP 2014-87385 A JP 2000-245662 A JP-A-11-42184

  The problem to be solved by the present invention is to provide a suction port of a vacuum cleaner capable of cooling a motor more efficiently and a vacuum cleaner having the same.

The suction opening body of the vacuum cleaner of the embodiment includes a case body, a rotating body, a motor, a support, a suction opening, and a communication opening. The case body includes a suction chamber that has a suction port and forms an air passage for sucking air from the suction port, and a motor chamber that is separate from the suction chamber. The rotating body is rotatably arranged on the case body. The motor is arranged in a motor room. Further, the motor has one end side opening and the other end side opening communicating with each other at one end side and the other end side in the axial direction, respectively, and generates a driving force for driving the rotating body. The support is formed of a member having elasticity and is attached to the periphery of the motor at a position between the one end opening and the other end opening to elastically support the motor with respect to the motor chamber. The support is pressed against the motor chamber to airtightly partition the motor chamber into one side and the other side that is wider in the axial direction of the motor than the one side. The suction opening is provided in the case body, and communicates one side of the motor chamber partitioned by the support with the outside of the case body. The communication opening is provided in the case body over a region in the axial direction of the motor, and communicates the other side of the motor chamber partitioned by the support with the suction chamber . The opening area of the suction opening is smaller than the opening area of the communication opening. The volume of one side of the motor chamber defined by the support and communicating with the suction opening is smaller than the volume of the other side of the motor chamber communicating with the communication opening .

FIG. 2 shows a suction port body of the vacuum cleaner of one embodiment, (a) is a perspective view showing a part of a case body seen through, and (b) is a cross-sectional view of the case body at a position of a motor chamber. (a) is a perspective view showing a lower part of the motor chamber of the case body, and (b) is a perspective view showing an upper part of the motor chamber of the case body. FIG. 3 is a plan view showing a part of the suction port body. FIG. 2 is a perspective view showing a part of the case body from the front. It is a perspective view which shows the vacuum cleaner provided with the suction port body same as the above.

  Hereinafter, a configuration of an embodiment will be described with reference to FIGS. 1 to 5.

  In FIG. 5, reference numeral 11 denotes a so-called canister type vacuum cleaner. The vacuum cleaner 11 includes a vacuum cleaner main body 12 and a pipe as an air path forming body detachably connected to the vacuum cleaner main body 12. And a part 13.

  The cleaner main body 12 is capable of turning and traveling on the floor as a surface to be cleaned, the electric blower 15, a main body control unit (not shown) for controlling the operation of the electric blower 15, and the electric blower 15 and the main body control. In addition to accommodating a power supply unit such as a secondary battery or a cord reel device for supplying power to the unit and the like, a dust collecting unit 18 communicating with the suction side of the electric blower 15 is provided. In addition, a main body suction port 19 is formed in the front part of the cleaner body 12 so as to communicate with the dust collecting part 18 and to be connected to the base end of the pipe part 13. In this embodiment, for example, a cyclone-separated dust collector is used as the dust collector 18, but an arbitrary dust collector such as a paper pack or a filter may be used.

  The pipe portion 13 includes a hose body 21, an extension pipe 22 made of, for example, a synthetic resin detachable from the hose body 21, and a floor brush 24 as a suction port body detachable from the extension pipe 22. Have.

  The hose body 21 has a flexible hose portion 25, a connection pipe portion 26 provided on the base end side (downstream side) of the hose portion 25 and connected to the main body suction port 19, and a distal end side of the hose portion 25. (At the upstream side).

  The proximal end side (downstream side) of the extension tube 22 is detachably connected to the hand operation unit 27. Further, a grip portion 28 to be gripped by a user is formed on the hand operation portion 27 so as to protrude toward the base end side.A setting button for setting an operation mode of the electric blower 15 and the like is provided on the grip portion 28. 29 are located.

  As shown in FIGS. 1 to 4, the floor brush 24 absorbs dust on the floor surface by running on the floor surface. Hereinafter, the front-rear direction and the left-right direction (both sides, width direction) are based on the traveling direction of the floor brush 24, and the vertical direction is the anti-gravity direction when the floor brush 24 is placed on a flat floor surface. And the direction of gravity. The floor brush 24 has a longitudinally extending case body 31 extending in the left-right direction, that is, a horizontally long case body 31, and is rotatably connected to a rear portion of the case body 31 and is detachably attached to a distal end side (upstream side) of the extension tube 22. And a connection pipe 32 to be connected.

  The case body 31 is divided into a plurality of case bodies formed of, for example, a synthetic resin, and in the present embodiment, for example, a lower case 35 forming a lower portion and a lower side of a rear portion, and an upper portion of the lower case 35 are formed. An upper case 36 that covers the upper part and the upper part of the rear part; a plate-shaped front cover 37 that pivotally supports the upper end at the front end of the upper case 36 to form the front part; A buffer bumper 38 is arranged between the case 36 and both sides of the front part. In addition, the case body 31 includes a suction chamber 41 located at a front portion and extending in a longitudinal direction in the left and right direction, a motor chamber 42 adjacent to one rear side of the suction chamber 41, and a suction chamber 41 and a motor chamber 42. A drive chamber 43 adjacent to one side of the suction chamber 41 and a control chamber 44 adjacent to the other rear side of the suction chamber 41 are partitioned.

  At the front end of the lower case 35, a suction port 46 that opens the lower part and the front part of the suction chamber 41 is cut out. At the rear of the lower case 35, a projection 47 to which the front end of the connection pipe 32 is attached is provided to project rearward.

  In the present embodiment, the upper case 36 constitutes, for example, a front upper case 36a which is a first upper case body constituting an upper part of the suction chamber 41, and upper parts of the motor chamber 42, the drive chamber 43 and the control chamber 44. And a rear upper case 36b as a second upper case body.

  The rear and upper portions of the suction chamber 41 are defined by a partition wall portion 51 rising upward from the rear of the suction port 46 in the lower case 35 and the upper case 36 (front upper case 36a). Is opened, and the front part is partitioned by the front cover 37. In the suction chamber 41 (the case body 31), a rotating brush 52 as a rotating cleaning body as a rotating body is rotatably arranged.

  The rotating brush 52 scrapes dust that has entered a floor surface such as a carpet by rotation. The rotating brush 52 is disposed so as to have an axial direction along the left-right direction which is the longitudinal direction of the suction chamber 41, and both ends are pivotally connected to the case body 31 with one end inserted into the drive chamber 43. Supported. The rotating brush 52 has a plurality of cleaning members (not shown) such as brush bristles made of synthetic resin or a blade made of soft synthetic resin in the circumferential direction of the outer peripheral surface. It is arranged to be spirally twisted from one end to the other end.

  The motor chamber 42 is located on one side of the connection pipe 32 (projection 47), and is divided into upper, lower, left, right and front and rear by an upper case 36 (rear upper case 36b) and a lower case 35. The front of the motor chamber 42 is adjacent to the suction chamber 41 via the partition 51. That is, the partition wall 51 is interposed between the suction chamber 41 and the motor chamber 42. Further, a motor 54 for generating a driving force for rotationally driving the rotary brush 52 is housed in the motor chamber 42, and the motor 54 is provided with a plurality of holding ribs as holding sections provided in the motor chamber 42. Held by 56. The motor chamber 42 communicates with the outside of the case body 31 through a suction opening 58 provided on one side of the rear portion of the case body 31, and sucks through a communication opening 59 provided in the case body 31 (partition wall 51). It communicates with the room 41.

  The motor 54 is, for example, a commutator-type motor that operates by being supplied with power from the power supply unit of the cleaner body 12 (FIG. 5) via the tube unit 13 (FIG. 5). The motor 54 includes a substantially cylindrical motor case 61 made of metal such as aluminum having excellent heat dissipation, and a rotor (not shown) integrated with a commutator (not shown) inside the motor case 61. In addition, a stator constituted by, for example, a neodymium magnet is arranged. The rotating shaft 62, which is an output shaft integrated with the rotor, is led out from one end of the motor case 61 to the outside. Further, a pair of carbon brushes are pressed against a commutator located on the opposite side of the rotation shaft 62 of the rotor, and these carbon brushes are housed at the other end side in the motor case 61. Further, the motor 54 has an upstream opening 64 as a plurality of one-side openings at one end of the motor case 61, and a downstream side as a plurality of other-side openings at the other end of the motor case 61. The opening 65 is open. Further, a support member 67 (one end side) is attached to one end of the motor 54, a support member 68 is attached to the other end (the other end), and a support 69 is attached between both ends. The motor 54 is supported by the support members 67, 68 and the support 69, and the support member 67, 68 and the support 69 are held by the holding rib 56. Is held and fixed. The motor 54 is housed in the motor chamber 42 along the longitudinal direction of the case body 31 in the axial direction, and the rotating shaft 62 is inserted into the drive chamber 43. Also, lead wires (not shown) are electrically connected to the motor 54 to a carbon brush or the like, and these lead wires are connected to the control room 44 side through the lower part of the connection pipe 32.

  The upstream opening 64 has a plurality of openings at positions near one end of the one end surface and the outer peripheral surface of the motor 54 (motor case 61), which are separated from each other in the circumferential direction. These upstream openings 64 are opened in a longitudinal slit shape along the circumferential direction of the motor 54 (motor case 61).

  A plurality of downstream openings 65 are provided at positions closer to the other end of the outer peripheral surface of the motor 54 (motor case 61) and are separated from each other in the circumferential direction. The downstream opening 65 is opened at a position facing the carbon brush in the motor case 61.

  Further, the upstream opening 64 and the downstream opening 65 communicate with each other via the inside of the motor 54 (motor case 61). The total opening area of the upstream opening 64 is set to be larger than the total opening area of the downstream opening 65. That is, in the present embodiment, the area obtained by adding the opening areas of all the upstream openings 64 is larger than the area obtained by adding the opening areas of all the downstream openings 65.

  The support member 67 is formed in an annular shape with an elastic synthetic resin such as rubber, for example, and is fixed to one end surface of the motor case 61 around the rotation shaft 62.

  The support member 68 is formed in a substantially cylindrical shape having a bottom with, for example, an elastic synthetic resin such as rubber, and is attached to the other end of the motor case 61 so as to cover it.

  The support 69 is formed of a flexible and elastic member such as a sponge. That is, the support 69 is formed of a member softer than the support members 67 and 68. Further, the support 69 is provided between the upstream opening 64 and the downstream opening 65 and at a position near the upstream opening 64, that is, at a position near one end of the motor 54 (motor case 61). It is wound and fixed around the outer periphery (periphery) of 54 (motor case 61), and has an annular shape. Further, the support 69 basically has no air permeability, and partitions the motor chamber 42 into one side and the other side by being pressed against the holding rib 56. That is, the support 69 is provided in the motor chamber 42 with an upstream motor chamber 71 as a first motor chamber where one end of the motor 54 is located, and a downstream motor chamber as a second motor chamber where the other end of the motor 54 is located. The chamber 72 is partitioned at least at a position outside the motor 54 (motor case 61) in the motor chamber 42 so as not to communicate with each other.

  The support members 67 and 68 and the support body 69 absorb vibrations generated by driving the motor 54 and do not transmit the vibrations to the case body 31. That is, the support members 67, 68 and the support 69 insulate the case body 31 and the motor 54 from each other.

  In the present embodiment, the upstream motor chamber 71 communicates with the suction opening 58 and the upstream opening 64 of the motor 54, and the air sucked into the inside through the suction opening 58 is supplied from the upstream opening 64 of the motor 54 to the motor 54. An air passage that sucks into the inside of the motor case (motor case 61) is formed.

  In the present embodiment, the downstream motor chamber 72 is in communication with the downstream opening 65 and the communication opening 59 of the motor 54, and the air exhausted from the downstream opening 65 of the motor 54 is transmitted from the communication opening 59 to the suction chamber 41. To form an air passage for discharging.

  The capacity of the upstream motor chamber 71 is formed to be smaller than the capacity of the downstream motor chamber 72. That is, the inside of the upstream motor chamber 71 is a space narrower than the inside of the downstream motor chamber 72. Specifically, the size of the upstream motor chamber 71 is set to be smaller in the left-right direction, which is the longitudinal direction, than the downstream motor chamber 72. In other words, the support 69 is attached to a position near one end of the motor 54 (motor case 61) and is held by the holding rib 56, so that the motor chamber 42 and the upstream motor chamber 71 are relatively narrow. It is divided into a relatively wide downstream motor chamber 72 (FIG. 3).

  The holding ribs 56 are provided along the front-back direction, and a plurality of the holding ribs 56 are arranged apart from each other in the left-right direction. These holding ribs 56 are provided from a lower holding rib 75 as a lower holding portion protruding upward from the lower case 35 (the bottom surface of the lower case 35), and from the upper case 36 (the top surface of the rear upper case 36b). An upper holding rib 76 as an upper holding portion protruding downward is configured to hold the support members 67, 68 and the support body 69 from above and below.

  The lower holding rib 75 has an upper portion that supports the motor 54 (the supporting members 67, 68 and the supporting body 69) cut out in a substantially semicircular shape along the outer shape of the motor 54 (the motor case 61) (FIG. 2). (a)).

  The upper holding rib 76 has a lower portion facing the motor 54 (the support members 67, 68 and the support 69) cut out in a substantially semicircular shape along the outer shape of the motor 54 (the motor case 61) (FIG. 2). (b)).

  Accordingly, the holding ribs 56 form the substantially arc-shaped holes 78 along the outer shape of the motor 54 (motor case 61) by the lower holding ribs 75 and the upper holding ribs 76 being vertically opposed and closely contacting each other. It is provided at the center (FIG. 1 (b)).

  In the present embodiment, the holding rib 56 includes a first holding rib 56a located on one side, a second holding rib 56b located on the other side, and a first holding rib 56a and a second holding rib 56b. A third holding rib 56c located near the first holding rib 56a is set therebetween, the first holding rib 56a holds the support member 67 airtight, and the second holding rib 56b holds the support member 68 airtight. The third holding ribs 56c hold the support 69 airtight.

  The suction opening 58 communicates the upstream motor chamber 71, which is one side of the motor chamber 42 defined by the support 69, with the outside of the case body 31 (FIG. 1A). The suction opening 58 is formed, for example, on one side of the rear part of the case body 31 so as to be long in the vertical direction. In the present embodiment, a plurality of suction openings 58 are opened apart from each other in the left-right direction that is the longitudinal direction of the case body 31. The downstream side of the suction opening 58, that is, the inside of the case body 31 (the motor chamber 42 (upstream motor chamber 71) side) is covered by an upstream filter 81 as a first filter.

  The communication opening 59 communicates the suction chamber 41 with the downstream motor chamber 72, which is the other side of the motor chamber 42 defined by the support 69. The communication opening 59 is formed, for example, on one side of the lower case 35 (the partition wall 51) of the case body 31 so as to be longitudinally open along the vertical direction. In the present embodiment, a plurality of communication openings 59 are opened apart from each other in the left-right direction that is the longitudinal direction of the case body 31. Further, the upstream side (the motor chamber 42 (downstream motor chamber 72) side) of the communication opening 59 is covered by a downstream filter (not shown) which is a second filter. Then, the total opening area of the communication opening 59 is larger than the total opening area of the suction opening 58, in other words, the total opening area of the suction opening 58 is smaller than the total opening area of the communication opening 59. It is set as follows. That is, in the present embodiment, the area obtained by adding the opening areas of all the communication openings 59 is larger than the area obtained by adding the opening areas of all the suction openings 58.

  The drive chamber 43 is formed in a longitudinal shape along the front-rear direction. One end of the rotating brush 52 and the rotating shaft 62 of the motor 54 are inserted into the driving chamber 43, respectively. The drive chamber 43 houses a transmission unit 83 that connects one end of the rotary brush 52 and the rotary shaft 62 of the motor 54 to transmit the driving force (rotational force) of the motor 54 to the rotary brush 52. ing.

  The transmission means 83 includes, for example, a gear 85 attached to the rotating shaft of the motor 54, and a timing belt 86 wound around the gear 85 and one end of the rotating brush 52. Accordingly, the rotary brush 52 is driven to rotate in the same direction, for example.

  The control room 44 is located on the other side of the connection pipe 32 (the protruding portion 47), and is divided into upper, lower, left, right, front and rear by an upper case 36 (rear upper case 36b) and a lower case 35. That is, the control room 44 is located on the side opposite to the motor room 42 with respect to the connection pipe 32. The front of the control chamber 44 is adjacent to the suction chamber 41 via the partition wall 51. That is, the partition wall 51 is interposed between the suction chamber 41 and the control chamber 44. Further, in the control room 44, a motor control means 88 for controlling the drive of the motor 54 and a grounding detection means (not shown) for detecting the grounding of the floor brush 24 with the floor surface are respectively housed. . The control chamber 44 communicates with the outside of the case body 31 through a control chamber suction opening (not shown) provided on the other rear side of the case body 31 and is connected to the case body 31 (the partition wall 51). It communicates with the suction chamber 41 through a control chamber communication opening 92 provided.

  The motor control unit 88 is supplied with power from a power supply unit of the cleaner body 12 (FIG. 5) via the tube unit 13 (FIG. 5). Further, the motor control means 88 includes, in addition to a lead wire (not shown) electrically connected to the motor 54, the inside of the connection pipe 32 (the outside of the air passage in the connection pipe 32) and the inside of the extension pipe 22 (the inside of the extension pipe 22). The setting button 29 (FIG. 5) and the lead wire electrically connected to the motor chamber 42 side (motor 54) are electrically connected through the extension pipe 22 (outside the air passage in the extension pipe 22). The motor control means 88 turns on and off the drive of the motor 54 in accordance with the setting made by operating the setting button 29 (FIG. 5) of the hand operation section 27, and the floor brush 24 is grounded to the floor by the ground detection means. When it is detected that the motor 54 is not (separated from the floor), the motor 54 is controlled to stop.

  The downstream side of the control room suction opening, that is, the inside of the case body 31 (the control room 44) is covered with a control room upstream side filter (not shown) which is a third filter.

  The upstream side of the control chamber communication opening 92 (the motor chamber 42 (downstream motor chamber 72) side) is covered by a control chamber downstream filter (not shown) that is a fourth filter.

  On the other hand, the connection pipe 32 has a cylindrical first rotating pipe 95 rotatably supported in a direction around an axis (direction around an axis) with respect to the case body 31, and an axial direction of the first rotating pipe 95. The first rotation pipe 95 has a front end (upstream side) rotatably supported by a rotation axis in a direction intersecting (orthogonal to) the rotation axis, and the first rotation pipe 95 has a rotation axis. A rear end side (downstream side) is provided with a cylindrical second rotating pipe 96 that is detachably connected to and connected to. The first rotary pipe 95 is located on the projecting portion 47 of the case body 31 and communicates with the suction chamber 41 (suction port 46) via a separate air path body 97.

  The air path body 97 is formed in a substantially cylindrical shape that expands toward the front end side with, for example, a synthetic resin or the like. 36 (rear upper case 36b), and is vertically sandwiched and faces the suction chamber 41.

  Next, the operation of the embodiment will be described.

  When assembling the floor brush 24, as a general rule, the motor control means 88 and the motor 54 are attached to the lower case 35, and the rotating brush 52 is attached, and the rotating shaft 62 of the motor 54 and one end of the rotating brush 52 are attached. Are connected by the transmission means 83, the bumper 38 is placed on the lower case 35, the upper case 36 with the front cover 37 attached thereto is covered from above on the lower case 35, and the lower case 35 and the upper case are Secure with 36.

  The assembling of the motor 54 will be described in more detail. A support member 67 is attached to one end of the motor case 61, a support member 68 is attached to the other end, and the outer periphery of the motor case 61 is provided between the support members 67 and 68. After the support 69 is wound and the support members 67, 68 and the support 69 are arranged so as to fit on the respective lower holding ribs 75 protruding from the lower case 35, the upper case 36 (the rear upper case 36b) is covered. Thus, the support members 67 and 68 and the support 69 are sandwiched between each upper holding rib 76 and each lower holding rib 75 protruding from the upper case 36 (the rear upper case 36b). As a result, the support members 67 and 68 and the support 69 are pressed against the lower holding rib 75 and the upper holding rib 76, respectively. In particular, the support 69 is crushed by the lower holding rib 75 and the upper holding rib 76, and The gap between the upper and lower holding ribs 75 and 76 is closed to form a motor chamber 42 partitioned into an upstream motor chamber 71 and a downstream motor chamber 72. That is, in the motor chamber 42, the upstream motor chamber 71 is defined by the lower case 35 and the upper case 36 (the rear upper case 36b) between the first holding rib 56a and the third holding rib 56c, and The downstream motor chamber 72 is defined by the lower case 35 and the upper case 36 (rear upper case 36b) between the rib 56b and the third holding rib 56c.

  Then, as shown in FIGS. 1 to 5, at the time of cleaning, first, the user communicates and connects the hose body 21 to the main body suction port 19 of the cleaner main body 12 via the connection pipe part 26, The extension tube 22 and the floor brush 24 are sequentially connected to a hand operation unit 27 on the distal end side of the hose body 21. Therefore, the suction chamber 41 (suction port 46) of the floor brush 24 communicates with the suction side of the electric blower 15.

  Next, the floor brush 24 is placed on the floor, and the user holding the grip unit 28 operates a predetermined setting button 29 in a state where power can be supplied from the power supply unit to the main unit control unit and the electric blower 15; The main controller controls the input of the electric blower 15 in accordance with the operation mode set by the setting button 29, and the electric blower 15 is driven.

  Further, by moving the floor brush 24 back and forth on the floor, the user sucks dust and air from the suction port 46 on the tip side of the floor brush 24 by the action of the negative pressure generated by driving the electric blower 15. . At this time, the user operates the extension tube 22 with the grip portion 28 of the hand operation portion 27 according to the angle and the height of the gap between the gap for inserting the floor brush 24 and the standing position of the user. By the rotation of the first rotary pipe 95 and the second rotary pipe 96, the floor brush 24 is inserted into a gap or the like while changing the angle with respect to the extension pipe 22 while maintaining the ground contact with the floor surface.

  Further, the user appropriately rotates the rotating brush 52 according to the type of the floor surface. At this time, when the user operates the predetermined setting button 29, the motor 54, which is supplied with power from the cleaner body 12 via the wiring, is driven by the motor control means 88 in accordance with the operation of the setting button 29, and The rotating brush 52 is rotated at a high speed through the gear 85 and the timing belt 86 of the transmission means 83 connected to the rotating shaft 62 of the motor 54, and assists cleaning such as scraping out dust on the floor surface and polishing the floor surface. .

  Further, when the suction port 46 (suction chamber 41) becomes a negative pressure, a negative pressure acts on the motor chamber 42 and the control chamber 44 via the communication opening 59 and the control chamber communication opening 92, and the suction opening 58 After the air is sucked from the control room suction opening through the upstream filter 81 and the control room upstream filter, and cools the motor 54 and the motor control means 88, the downstream filter and the communication port 59 and the control room communication opening 92 The air is sucked into the suction chamber 41 via the downstream filter of the control chamber. More specifically, in the motor chamber 42, the air sucked into the upstream motor chamber 71 from the suction opening 58 flows from the upstream opening 64 of the motor 54 opening into the upstream motor chamber 71 to the motor 54 (motor case 61). ), Flows through the inside of the motor 54 (motor case 61) from one end to the other end, and cools the inside of the motor 54 (motor case 61). The exhaust gas is exhausted to the outside of the motor case 61 into the downstream motor chamber 72, and is exhausted to the suction chamber 41 from the communication opening 59 communicating with the downstream motor chamber 72.

  Then, the air sucked into the suction chamber 41 of the floor brush 24 becomes a suction wind, and carries the dust from the main body suction port 19 to the dust collection unit 18 via the extension pipe 22 and the hose body 21. Collect dust at.

  Thereafter, the suction air from which the dust has been removed is sucked into the electric blower 15 and passes through the electric blower 15 to become an exhaust air, and the exhaust air (not shown) provided at a rear portion of the cleaner main body 12 or the like. Exhaust to the outside of 12.

  When cleaning is completed and the vacuum cleaner 11 is stored, the main body control unit stops the electric blower 15 by operating the setting button 29. At this time, when the rotating brush 52 is operating, the motor control means 88 also stops the motor 54.

  In the embodiment described above, a support 69 is attached around the motor 54 at a position between the upstream opening 64 and the downstream opening 65, and the motor 54 is supported with respect to the motor chamber 42. The chamber 42 is partitioned into one side (upstream motor chamber 71) and the other side (downstream motor chamber 72), and the upstream motor chamber 71 and the outside of the case body 31 communicate with each other through the suction opening 58. The motor chamber 72 and the suction chamber 41 communicate with each other through the communication opening 59. For this reason, all the air sucked from the outside into the upstream motor chamber 71 of the motor chamber 42 through the suction opening 58 by the negative pressure of the suction chamber 41 is introduced into the motor 54 (motor case 61) from the upstream opening 64. By flowing and exhausting from the downstream opening 65 to the downstream motor chamber 72, compared to the case of simply flowing air to the outer surface of the motor 54 or flowing only a part of the air to the inside of the motor 54, The motor 54 can be cooled more efficiently.

  Further, since the upstream motor chamber 71 and the downstream motor chamber 72 do not communicate with each other outside the motor 54 (motor case 61) in the motor chamber 42, heat exchange is performed through the motor 54 (motor case 61). After the warmed air is exhausted from the downstream opening 65 to the downstream motor chamber 72, the air does not circulate from the outside of the motor 54 to the upstream motor chamber 71 in the motor chamber 42. In other words, cold air is always sucked, so that the cooling efficiency of the motor 54 can be further improved.

  In addition, since the support 69 vibrates and insulates the motor 54 and the case body 31, the case body 31 does not vibrate due to the vibration of the motor 54, and the floor brush 24 with good silence can be obtained. . In other words, since the motor chamber 42 is partitioned into the upstream motor chamber 71 and the downstream motor chamber 72 by using the support 69 that provides vibration isolation between the motor 54 and the case body 31, the upstream motor A member for partitioning the chamber 71 from the downstream motor chamber 72 is not required separately, and there is no increase in cost and weight of the floor brush 24 due to an increase in parts.

  Further, since the support 69 is wound around the motor 54 (motor case 61), the lower case 35 is simply assembled with the upper case 36 (rear upper case 36b), and the lower holding rib 75 and the upper holding rib 76 Thus, the motor chamber 42 can be easily divided into the upstream motor chamber 71 and the downstream motor chamber 72 by sandwiching the support 69 from above and below. That is, a dedicated man-hour for partitioning the motor room 42 into the upstream motor room 71 and the downstream motor room 72 is not required, and an increase in man-hour costs is not caused.

  In addition, the motor 54 has an upstream opening 64 for sucking air on the side of the rotating shaft 62 on which there is no carbon brush, and a downstream opening 65 for discharging air on the side of the commutator on which there is a carbon brush. Since the carbon powder is formed, the carbon powder generated from the carbon brush due to sliding contact with the commutator is directly discharged from the downstream opening 65 without diffusing into the motor 54. Can be prevented.

  Furthermore, by making the opening area of the suction opening 58 smaller than the opening area of the communication opening 59, the wind speed on the suction side that sucks air into the motor 54 is relatively improved, and the cooling efficiency can be further improved.

  Further, by making the volume of the upstream motor chamber 71 smaller than the volume of the downstream motor chamber 72, air sucked into the upstream motor chamber 71 from the suction opening 58 is prevented from stagnating in the upstream motor chamber 71. Can be suppressed. Therefore, the air sucked into the upstream motor chamber 71 is sucked into the motor 54 in a cold state from the upstream opening 64 without being heated by the heat of the motor 54, so that the cooling efficiency can be further improved.

  In particular, in the case of the motor 54 using a neodymium magnet, demagnetization due to overheating is likely to occur, so by improving the cooling efficiency of the motor 54 as described above, the rotating brush 52 can be rotated more strongly using the neodymium magnet. It is possible to easily realize the motor 54 in which the driving force to be obtained is lighter and smaller, and the power down due to the thermal demagnetization hardly occurs.

  In the above-described embodiment, the motor 54 has the upstream opening 64 on the rotating shaft 62 side and the downstream opening 65 on the commutator (carbon brush) side. In this case, the same operation is achieved by arranging the motor 54 such that the side where the upstream opening 64 is located is the upstream motor chamber 71 and the side where the downstream opening 65 is located is the downstream motor chamber 72. The effect can be achieved.

  Further, the motor 54 drives the rotary brush 52 to rotate, but may also rotate a rotary body such as a traveling wheel rotatably provided on the case body 31, for example.

  Further, the vacuum cleaner 11 is not limited to the canister type, but also corresponds to, for example, a so-called upright type in which a connecting pipe 32 of a floor brush 24 is connected to a lower part of a vertically long cleaner body 12. Can be used.

  While one embodiment of the present invention has been described, this embodiment is provided by way of example and is not intended to limit the scope of the invention. The new embodiment can be implemented in other various forms, and various omissions, replacements, and changes can be made without departing from the spirit of the invention. This embodiment and its modifications are included in the scope and gist of the invention, and are also included in the invention described in the claims and their equivalents.

11 Vacuum cleaner
12 Vacuum cleaner body
15 Electric blower
24 Floor brush as suction body
31 Case body
41 Suction chamber
42 Motor room
46 Suction port
52 Rotating brush as rotating body
54 motor
58 Suction opening
59 Communication opening
64 Upstream opening as one end opening
65 Downstream opening as the other end opening
69 support

Claims (2)

A suction chamber having a suction port and forming an air passage for sucking air from the suction port, and a case body including the suction chamber and a separate motor chamber;
A rotating body rotatably arranged on the case body,
A motor arranged in the motor chamber, including one end opening and the other end opening communicating with each other at one end and the other end in the axial direction, and a motor that generates a driving force for driving the rotating body,
The motor is formed by a member having elasticity and attached around the motor at a position between the one end side opening and the other end side opening to elastically support the motor with respect to the motor chamber. A support that airtightly partitions the motor chamber into one side and the other side that is wider than the one side in the axial direction of the motor by being pressed against the chamber;
A suction opening provided in the case body and communicating one side of the motor chamber partitioned by the support and the outside of the case body,
A communication opening is provided in the case body over a region in the axial direction of the motor and communicates with the other side of the motor chamber partitioned by the support and the suction chamber ,
The opening area of the suction opening is smaller than the opening area of the communication opening,
A suction port of the vacuum cleaner , wherein a volume of one side of the motor chamber which is partitioned by the support and communicates with the suction opening is smaller than a volume of another side of the motor chamber which communicates with the communication opening. Body . A vacuum cleaner body with an electric blower,
Vacuum cleaner suction chamber is characterized by comprising a suction port body according to claim 1 Symbol mounting to the suction side communicates with the electric blower.

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