CN213655199U - Blower fan - Google Patents

Abstract

The utility model discloses an air blower. The blower can prevent the control substrate from being heated to a high temperature. The blower may include a housing, a motor, a centrifugal fan, and a control board. The housing may have a 1 st housing chamber and a 2 nd housing chamber communicating with each other through an opening therein. The motor may be disposed in the 1 st housing chamber, and a rotating shaft of the motor may be inserted through the opening. The centrifugal fan may be disposed in the 2 nd housing chamber and may be driven by a motor to rotate about the rotation shaft as a center axis. The control board may be disposed in the 1 st accommodation chamber and may control driving of the motor. The housing may further include a communication hole that communicates the 1 st housing chamber and the 2 nd housing chamber and is disposed separately from the opening.

Description

Blower fan

Technical Field

The technology disclosed herein relates to a blower.

Background

Patent document 1 discloses a blower. The blower includes a housing, a motor, a centrifugal fan, and a control board. The housing has a 1 st housing chamber and a 2 nd housing chamber which are connected to each other through an opening. The motor is disposed in the 1 st housing chamber, and the rotating shaft penetrates through the opening. The centrifugal fan is disposed in the 2 nd housing chamber and is driven by the motor to rotate about the rotation shaft as a center axis. The control substrate is disposed in the 1 st accommodation chamber and controls driving of the motor. The housing has an air inlet for communicating the outside of the housing with the 1 st accommodation chamber. When the centrifugal fan rotates, air flows from the air inlet to the 1 st housing chamber and flows through the opening to the 2 nd housing chamber. The control substrate is cooled by the air flowing in the 1 st accommodation chamber.

Documents of the prior art

Patent document

Patent document 1: japanese patent laid-open publication No. 2014-148951

SUMMERY OF THE UTILITY MODEL

Problem to be solved by utility model

In the above blower, when the pressure of the 2 nd housing chamber is higher than the pressure of the 1 st housing chamber, air is less likely to flow from the 1 st housing chamber to the 2 nd housing chamber, and air is less likely to flow from the outside to the 1 st housing chamber. As a result, the air is less likely to flow in the 1 st housing chamber. Therefore, the control board is not sufficiently cooled, and the control board may become high in temperature. In the present specification, a technique capable of suppressing the temperature of the control board from becoming high is disclosed.

Means for solving the problems

The present specification discloses a blower. The blower includes a housing, a motor, a centrifugal fan, and a control board. The housing has a 1 st housing chamber and a 2 nd housing chamber which are connected to each other through an opening. The motor is disposed in the 1 st housing chamber, and a rotating shaft of the motor penetrates through the opening. The centrifugal fan is disposed in the 2 nd housing chamber and is driven by the motor to rotate about the rotation shaft as a center axis. The control substrate is disposed in the 1 st accommodation chamber and controls driving of the motor. The housing further has a communication hole that communicates the 1 st housing chamber and the 2 nd housing chamber and is disposed separately from the opening.

In the above configuration, when the pressure of the 2 nd housing chamber is higher than the pressure of the 1 st housing chamber, air flows from the 2 nd housing chamber to the 1 st housing chamber through the communication hole and flows from the 1 st housing chamber to the 2 nd housing chamber through the opening. Therefore, even when the pressure of the 2 nd housing chamber is higher than the pressure of the 1 st housing chamber, air flows in the 1 st housing chamber, and the control board is sufficiently cooled by the air. As a result, the control board can be prevented from becoming high in temperature.

The communication hole may be arranged to overlap the centrifugal fan in the rotation axis direction.

The blower may further include a battery for supplying electric power to the motor.

The battery may be disposed close to the control board.

The blower may further include a heat radiation fin disposed in the 1 st housing chamber and guiding air flowing in the 1 st housing chamber, and the heat radiation fin may be disposed on the control board.

The blower may further include a cooling fan disposed between the opening and the centrifugal fan in the rotation axis direction, and the cooling fan may rotate together with the centrifugal fan.

The casing may have a discharge port for discharging the air sent by the centrifugal fan to the outside of the casing, and the blower may further have an air supply nozzle through which the air discharged from the discharge port flows, the air supply nozzle being a vertically long nozzle.

The control board may be disposed in a flow path through which air flows from the communication hole to the motor in the 1 st housing chamber.

The blower may further include a motor housing that houses the motor, the motor housing may include a motor inlet port that introduces air into the motor housing, and the control board may be disposed on an imaginary line connecting the communication hole and the motor inlet port.

Drawings

Fig. 1 is a perspective view of blower 2 in the blowing mode of embodiment 1.

Fig. 2 is a perspective view of the trigger member 24, the constant speed cruise valve (japanese: クルーズバルブ)26, and the sensor 32 of the blower 2 of embodiment 1.

Fig. 3 is a horizontal sectional view of blower 2 in the blowing mode of embodiment 1.

Fig. 4 is an enlarged view of the vicinity of the communication hole 84 of fig. 3.

Fig. 5 is a transverse sectional view of blower 2 in the blowing mode of embodiment 1.

Fig. 6 is a left side view of blower 2 with side case 8 removed in the blowing mode of embodiment 1.

Fig. 7 is a perspective view of blower 2 in the suction mode of embodiment 1.

Fig. 8 is a graph showing the relationship between the trigger depression amount and the motor rotation speed in the normal mode and the slow mode executed by control board 66 of blower 2 according to embodiment 1.

Fig. 9 is a graph showing the relationship between the trigger depression amount and the motor rotation speed in the normal mode and the slow mode executed by control board 66 of blower 2 according to embodiment 2.

Description of the reference numerals

2. A blower; 4. a housing; 6. a main housing; 8. a side housing; 20. an air suction port; 24. a trigger member; 26. a constant speed cruise valve; 42. a main power switch; 44. a display unit; 50. a fan housing chamber (2 nd housing chamber); 52. a motor storage chamber (1 st storage chamber); 54. an air suction port; 58. an outlet port; 59. an opening; 62. a motor; 62a, a rotating shaft; 64. a motor housing; 66. a control substrate; 67. a metal plate; 68. a heat dissipating fin; 70. a centrifugal fan; 72. a cooling fan; 78. a motor air suction port; 79. a motor discharge port; 82. an air supply nozzle; 84. a communicating hole; 92. a suction nozzle; B. a battery.

Detailed Description

In one or more embodiments, the blower may have a housing, a motor, a centrifugal fan, and a control board. The housing may have a 1 st housing chamber and a 2 nd housing chamber communicating with each other through an opening therein. The motor may be disposed in the 1 st housing chamber, and a rotating shaft of the motor may be inserted through the opening. The centrifugal fan may be disposed in the 2 nd housing chamber and may be driven by a motor to rotate about the rotation shaft as a center axis. The control board may be disposed in the 1 st accommodation chamber and may control driving of the motor. The housing may further include a communication hole that communicates the 1 st housing chamber and the 2 nd housing chamber and is disposed separately from the opening.

In the above configuration, when the pressure of the 2 nd housing chamber is higher than the pressure of the 1 st housing chamber, air flows from the 2 nd housing chamber to the 1 st housing chamber through the communication hole and flows from the 1 st housing chamber to the 2 nd housing chamber through the opening. Therefore, even when the pressure of the 2 nd housing chamber is higher than the pressure of the 1 st housing chamber, air flows in the 1 st housing chamber, and the control board is sufficiently cooled by the air. As a result, the control board can be prevented from becoming high in temperature.

In one or more embodiments, the communication hole may be disposed to overlap the centrifugal fan in the rotation axis direction.

In the above configuration, the centrifugal fan sends air radially outward. Therefore, by disposing the communication hole so as to overlap the centrifugal fan in the rotation axis direction, the air sent by the centrifugal fan can be prevented from flowing from the 2 nd housing chamber to the 1 st housing chamber through the communication hole. This can suppress a drop in the flow rate of the air blown out by the blower.

In one or more embodiments, the blower may further include a battery that supplies electric power to the motor.

In the above configuration, the blower can be used even in a work area where no external power supply is present.

In one or more embodiments, the battery may be disposed close to the control board.

In the above configuration, the length of the wiring connecting the battery and the control board can be shortened. This enables the wiring to be processed satisfactorily.

In one or more embodiments, the blower may further include a heat radiation fin that is disposed in the 1 st housing chamber and guides air flowing in the 1 st housing chamber. The heat radiation fins may be disposed on the control substrate.

In the above configuration, the air is guided by the heat radiation fins and flows on the control board. This enables the control board to be efficiently cooled. As a result, the control board can be prevented from becoming high in temperature.

In one or more embodiments, the blower may further include a cooling fan disposed between the opening and the centrifugal fan in the rotation axis direction. The cooling fan rotates together with the centrifugal fan.

In the above-described structure, when the cooling fan rotates, the pressure of the space in the vicinity of the cooling fan decreases. This enables air to efficiently flow from the 1 st housing chamber to the 2 nd housing chamber through the opening. Therefore, the flow rate of the air flowing through the 1 st housing chamber is increased, and the control board is efficiently cooled. As a result, the control board can be prevented from becoming high in temperature.

In one or more embodiments, the casing may have an outlet port for discharging the air sent by the centrifugal fan to the outside of the casing. The blower may further include an air supply nozzle through which air discharged from the discharge port flows. The air supply nozzle may be a vertically long nozzle.

In general, when a vertically long nozzle is used as the air blowing nozzle, the pressure in the 2 nd housing chamber is increased in a state where the centrifugal fan is rotated. Therefore, in a configuration in which the blower does not have the communication hole, when the pressure of the 2 nd housing chamber is higher than the pressure of the 1 st housing chamber, air may not easily flow from the 1 st housing chamber to the 2 nd housing chamber through the opening. As a result, the control board may not be sufficiently cooled and may become high in temperature. In the above configuration, since the communication hole communicates the 1 st housing chamber and the 2 nd housing chamber, even when a vertically long nozzle is used as the air blowing nozzle, sufficient air flows in the 1 st housing chamber, and the control board is sufficiently cooled. Therefore, the control board can be prevented from being heated to a high temperature.

In one or more embodiments, the control board may be disposed in a flow path through which air flows from the communication hole to the motor in the 1 st housing chamber.

In the above structure, air flows on the control substrate. This enables the control board to be efficiently cooled. As a result, the control board can be prevented from becoming high in temperature.

In one or more embodiments, the blower may further include a motor housing that houses the motor. The motor housing may have a motor inlet port for sucking air into the motor housing. The control board is arranged on an imaginary line connecting the communication hole and the motor suction port.

In the above configuration, the control board is disposed at the shortest distance between the communication hole and the motor intake port. Therefore, the control board can be efficiently cooled. As a result, the control board can be prevented from becoming high in temperature.

In one or more embodiments, the blower may include a motor, a centrifugal fan, a housing, a trigger member, and a control board. The centrifugal fan may be rotated about the rotation shaft as a center axis by the rotation of the motor. The casing may house the motor and the centrifugal fan, and guide air from the air inlet to the air outlet in accordance with rotation of the centrifugal fan. The trigger member may be pressed in by an operator. The control board may control driving of the motor. The control board may have a normal mode for adjusting the rotation speed of the motor in accordance with the pressed amount of the trigger member, and a relaxing mode for adjusting the rotation speed of the motor to a target rotation speed lower than the maximum rotation speed of the motor in a case where the pressed amount of the trigger member in the normal mode is the maximum amount.

In the above-described structure, the target rotation speed of the motor in the slow mode is lower than the maximum rotation speed of the motor in the normal mode. Therefore, the rotation speed of the centrifugal fan in the mild mode is lower than that in the normal mode. As a result, the suction force of the blower in the mild mode is smaller than that in the normal mode. Thus, in the relaxation mode, the attraction of small stones can be suppressed as compared with the normal mode. As a result, by setting the control board to the relaxation mode, the attraction of the pebbles can be stably suppressed.

In one or more embodiments, when the control board is in the relaxing mode, the rotation speed of the motor may be gradually increased to the target rotation speed as the pressed amount of the trigger member is increased to the maximum amount.

In the above configuration, the flow rate of the air sucked into the air inlet is changed according to the amount of depression of the trigger member. Therefore, the rotation speed of the motor, that is, the flow rate of the air sucked into the air inlet can be freely adjusted according to the state of the work area.

In one or more embodiments, when the control board is in the relaxing mode, the rotation speed of the motor may be constant at the target rotation speed regardless of the pressed amount of the trigger member.

In the above configuration, the rotation speed of the centrifugal fan is constant regardless of the pressed amount of the trigger member, and the suction force can be made constant. This allows the operator to easily perform the suction operation using the blower.

In one or more embodiments, the blower may further include a switch for switching between a normal mode and a relaxation mode of the control board.

In the above-described structure, the operator can switch the normal mode and the relaxing mode by a simple operation of pressing the switch.

In one or more embodiments, the switch may be a main power switch for switching between an on state in which the driving of the motor is permitted and an off state in which the driving of the motor is prohibited. In the case of a long press switch, the normal mode and the slow mode of the control board may be switched.

In the above-described configuration, the operator can perform the switching operation of the on state and the off state of the blower and the switching operation of the regular mode and the relaxation mode by using the main power switch. Therefore, it is not necessary to separately provide a changeover switch for switching the normal mode and the relaxing mode.

In one or more embodiments, the blower may further include a display unit capable of displaying that the control board is in the relaxation mode.

In the above configuration, the operator can easily confirm whether or not the control board is in the relaxing mode by the display content displayed on the display unit.

(embodiment 1)

Referring to fig. 1 to 8, a blower 2 according to embodiment 1 will be described. The blower 2 is a hand-held blower. The blower 2 has an air blowing mode and a suction mode. In the case where the blower 2 is used in the blowing mode, the blower 2 can blow up fallen leaves and the like on the ground. In the case where the blower 2 is used in the suction mode, the blower 2 can suck and collect fallen leaves and the like on the ground. Hereinafter, a direction in which the rotation shaft 62a of the motor 62 extends is referred to as a left-right direction, a direction orthogonal to the left-right direction is referred to as a front-rear direction, and a direction orthogonal to the left-right direction and the front-rear direction is referred to as an up-down direction.

Fig. 1 to 6 show the structure of the blower 2 used in the air blowing mode. The blower 2 has a housing 4, a plurality of (two in the present embodiment) batteries B, a main power switch 42, a display portion 44, a trigger member 24, a constant-speed cruise valve 26, and a sensor 32 (see fig. 2). The housing 4 has a main housing 6, side housings 8, a front connecting portion 10, a rear connecting portion 12, a main handle 14, and leg members 16. The main housing 6 is formed as a volute. The side case 8 is fixed to the left side surface of the main case 6 with screws. A plurality of air inlets 20 are formed in the front surface of the side casing 8. The air inlet 20 penetrates the side casing 8 in the thickness direction.

The front connection portion 10 extends upward from the front upper portion of the main casing 6. Rear connection portion 12 extends upward from the rear upper portion of main case 6. The main handle 14 extends from the rear upper portion of the front connecting portion 10 to the front upper portion of the rear connecting portion 12. That is, the front end of the main handle 14 is connected to the rear upper portion of the front connecting portion 10, and the rear end of the main handle 14 is connected to the front upper portion of the rear connecting portion 12. The main handle 14 is disposed above the main casing 6. The main handle 14 is held by an operator. The main handle 14 is made of a conductive material. The conductive material is, for example, a conductive elastomer. The leg members 16 are fixed to the lower portion of the main casing 6. In a state where the blower 2 is placed on the ground, only the leg members 16 are in contact with the ground. The leg member 16 has a secondary handle 18. When the blower 2 is placed on the floor, the sub-handle 18 is separated from the floor. Accordingly, when the operator picks up the blower 2 placed on the placement surface, the operator can hold the main handle 14 with one hand and the sub handle 18 with the other hand.

Two batteries B are detachably mounted to the front surface of the main casing 6. The two batteries B are electrically connected in series. In the modification, two batteries B may be electrically connected in parallel. Battery B is, for example, a lithium ion battery.

The main power switch 42 and the display portion 44 are disposed on the middle surface 40 formed by the side case 8 and the main case 6. The middle face 40 faces upward. The middle surface 40 is disposed below the left side of the main handle 14. The operator operates the main power switch 42 with a hand different from the hand holding the main handle 14. This can suppress erroneous operation of the main power switch 42 by the hand gripping the main handle 14. The main power switch 42 is a switch for switching the on state and the off state of the blower 2. When the blower 2 is in the off state, the drive of the motor 62 described later is prohibited. Thus, the motor 62 is not driven even if the trigger member 24 is pushed in. On the other hand, when the blower 2 is in the on state, the driving of the motor 62 is permitted. Thus, when the trigger member 24 is pushed in, the motor 62 is driven. The display unit 44 displays the state of the blower 2. In the present embodiment, the display unit 44 includes two display windows 44a and 44 b. When the blower 2 is in the on state, the display window 44a displays a content indicating that the blower 2 is in the on state. When the control board 66 to be described later is in the relaxing mode M2, the display window 44b displays a content indicating that the control board 66 to be described later is in the relaxing mode M2. The display unit 44 is, for example, an LED panel. In the modification, the display unit 44 may be configured to light up light.

The trigger member 24 and the constant speed cruise valve 26 are rotatably mounted to the main handle 14. As shown in fig. 2, the trigger member 24 has a trigger member operating portion 28 and a pressing portion 30. The trigger member operating portion 28 and the pressing portion 30 are integrally formed. The trigger member operation unit 28 is a unit that is pushed by the operator. The trigger member operation portion 28 rotates around a rotation shaft extending in the left-right direction as a center axis. The pressing portion 30 presses the switch 32a of the sensor 32 by the rotation of the trigger member operation portion 28. When the switch 32a of the sensor 32 is pressed when the blower 2 is in the on state, a motor 62 described later is driven. The amount of pressing of the switch 32a of the sensor 32 by the pressing portion 30 changes in accordance with the amount of pressing of the trigger member operation portion 28.

The constant-speed cruise valve 26 has a valve operating portion 34, an intermediate portion 36, and a stopper 38. The valve operating portion 34 is disposed outside the main handle 14 (see fig. 1). The valve operating portion 34 is operated by an operator. The valve operating portion 34 rotates around a rotation shaft extending in the left-right direction as a center axis. The valve operating portion 34 can be fixed at a desired rotational position. The intermediate portion 36 is connected to the valve operating portion 34. The intermediate portion 36 is disposed inside the main handle 14, and is not shown. The intermediate portion 36 rotates integrally with the valve operating portion 34. The stopper 38 extends rightward from the outer peripheral edge of the intermediate portion 36. The stopper 38 can be abutted against the pressing portion 30 of the trigger member 24. When the valve operating portion 34 is rotated forward, the stopper 38 is rotated, and the stopper 38 abuts against the pressing portion 30. When the valve operating portion 34 is further rotated forward from this state, the stopper 38 is rotated forward together with the pressing portion 30. When the valve operating portion 34 is fixed in the desired rotational position, the stopper 38 is fixed. The stopper 38 suppresses the pressing portion 30 from moving toward the rear. Thus, the amount of depression of the switch 32a of the sensor 32 does not become equal to or less than a predetermined value.

As shown in fig. 3, the casing 4 includes a fan housing chamber 50, a motor housing chamber 52, an air inlet 54, an air flow path 56, and an exhaust port 58 (see fig. 5). The fan housing chamber 50 is partitioned inside the main casing 6. The motor housing chamber 52 is partitioned by the main casing 6 and the side casing 8. The motor housing chamber 52 is disposed on the left side of the fan housing chamber 50. The fan housing chamber 50 and the motor housing chamber 52 are communicated with each other through an opening 59 formed in the left side surface of the main casing 6. The air inlet 54 is disposed on the right side surface of the main casing 6. The air inlet 54 penetrates the right side surface of the main casing 6. The air inlet 54 communicates with the fan accommodating chamber 50. The air flow path 56 communicates with the fan accommodating chamber 50. As shown in fig. 5, the air flow path 56 extends in a spiral shape around an axis extending in the left-right direction. When the blower 2 is viewed rightward, the air flow path 56 extends counterclockwise from the inside toward the outside. The discharge port 58 communicates with the air flow path 56. The discharge port 58 is disposed on the upper front surface of the main casing 6.

As shown in fig. 3, blower 2 further includes a cover 60, a motor 62, a motor case 64, a control board 66, a metal plate 67, a centrifugal fan 70, a cooling fan 72, and a cutter 74. The cover 60 is disposed on the right side surface of the main casing 6. The cover 60 is rotatable with respect to the main casing 6 around a rotation shaft extending in the vertical direction as a center axis. The cover 60 covers the suction port 54. A plurality of small openings are formed in the cover 60.

The motor housing 64, the motor 62, and the control board 66 are disposed in the motor accommodating chamber 52. The motor housing 64 is fixed to the left side surface of the main casing 6 with screws. The motor housing 64 covers the opening 59 of the main housing 6. The motor housing 64 has a motor suction opening 78 and a motor discharge opening 79. The motor inlet port 78 is disposed on the left side surface 64a of the motor housing 64. The motor suction port 78 penetrates the left side surface 64a of the motor housing 64. The motor discharge port 79 is disposed on the right side surface 64b of the motor case 64. The motor discharge port 79 penetrates the right side surface 64b of the motor housing 64. The right side face 64b of the motor housing 64 is opposed to the left side face of the main casing 6.

The motor 62 is disposed inside the motor housing 64. The motor 62 is, for example, a brushless motor. In the modification, the motor 62 may be a brush motor. The rotating shaft 62a of the motor 62 is rotated by the electric power of the battery B. The rotary shaft 62a of the motor 62 extends in the left-right direction. The rotation shaft 62a penetrates the opening 59 of the main casing 6. The left end of the rotating shaft 62a is disposed in the motor housing chamber 52, and the right end of the rotating shaft 62a is disposed in the fan housing chamber 50.

Control board 66 is disposed at a position close to battery B. The control substrate 66 is electrically connected to the motor 62 and the sensor 32. When the switch 32a of the sensor 32 is pressed by the push-in operation of the trigger member 24, the control substrate 66 drives the motor 62. The control board 66 adjusts the rotation speed of the motor 62 according to the pressed amount of the switch 32 a.

As shown in fig. 4, the metal plate 67 is disposed between the left side surface of the main casing 6 and the control board 66. In addition, in fig. 4, the periphery of the enlarged portion is surrounded by a quadrangle for easy viewing of the drawing. The metal plate 67 is connected to the main handle 14 via a wiring not shown.

As shown in fig. 3, centrifugal fan 70, cooling fan 72, and cutter 74 are disposed in fan compartment 50. The centrifugal fan 70 is made of a resin material. The centrifugal fan 70 is fitted to the vicinity of the right end of the rotating shaft 62a of the motor 62. The cooling fan 72 is made of a resin material. Cooling fan 72 is disposed between centrifugal fan 70 and opening 59 of main casing 6 in the left-right direction. The cooling fan 72 is disposed on the rear surface of the centrifugal fan 70. The centrifugal fan 70 has a back surface facing the left side surface of the main casing 6. The cutter 74 is fitted to the right end portion of the rotary shaft 62a of the motor 62.

As shown in fig. 6, the blower 2 also has heat radiating fins 68. The heat dissipation fins 68 are disposed on the control substrate 66. The heat radiation fin 68 has a plurality of fins. The plurality of fins are arranged with a gap therebetween. The heat radiation fins 68 extend in the left-right direction.

The main housing 6 also has a communication hole 84. The communication hole 84 has an elongated shape. When the blower 2 is viewed from the right, the communication holes 84 overlap the heat dissipating fins 68. As shown in fig. 3, the communication hole 84 penetrates the left side surface of the main casing 6. The communication hole 84 communicates the fan housing chamber 50 and the motor housing chamber 52. The communication hole 84 is disposed at a position farther from the opening 59 of the main casing 6 toward the radial outer side of the rotation shaft 62 a. The communication hole 84 is disposed radially inward of the rotation shaft 62a relative to the peripheral edge of the centrifugal fan 70. The communication hole 84 is disposed to overlap the centrifugal fan 70 in the left-right direction. The communication holes 84 are disposed in the vicinity of the control substrate 66 and the heat dissipation fins 68. The control board 66 is disposed on a virtual line connecting the communication hole 84 and the motor inlet port 78 of the motor case 64.

As shown in fig. 5, blower 2 further has a fixed nozzle 80 and a blowing nozzle 82. A stationary nozzle 80 extends through the discharge port 58. The fixed nozzle 80 is a cylinder extending in the length direction. The air passing through the discharge port 58 flows toward the fixed nozzle 80.

The air blowing nozzle 82 is attached to the distal end portion of the fixed nozzle 80 so as to be detachable from the distal end portion of the fixed nozzle 80. The air blowing nozzle 82 is a vertically long nozzle. The air blowing nozzle 82 is, for example, a nozzle for a rain gutter. The nozzle for the rain gutter is used when blowing up fallen leaves and the like accumulated in the rain gutter attached to a building. The air blowing nozzle 82 has a length of, for example, 2m or more. The air blowing nozzle 82 extends in the longitudinal direction and then bends and extends near the tip end thereof.

Next, the air blowing operation of the blower 2 in the case of use in the air blowing mode will be described. When the blower 2 is used in the air blowing mode, the main handle 14 is held by the operator. When the operator pushes the trigger member 24 to rotate the motor 62, the centrifugal fan 70, the cooling fan 72, and the cutter 74 rotate about the rotation shaft 62 a. Accordingly, the air flows leftward from the air inlet 54 and flows into the fan accommodating chamber 50. The air flowing into the fan accommodating chamber 50 is sent out radially outward of the rotary shaft 62a by the centrifugal fan 70. This air is guided to main casing 6, and is discharged to the outside of main casing 6 from discharge port 58 through air flow path 56. Then, the air passes through the fixed nozzle 80 and the air blowing nozzle 82, and is blown out from the tip opening of the air blowing nozzle 82. Thus, for example, when the distal end opening of the air blowing nozzle 82 faces the rain gutter, fallen leaves accumulated in the rain gutter are blown up. Further, when the operator operates the constant-speed-cruise valve 26 to rotate the valve operating portion 34 of the constant-speed-cruise valve 26 toward the front and fix it at a predetermined position, the switch 32a of the sensor 32 is maintained in a state of being pressed by a predetermined amount. Thereby, even in a state where the operator releases the trigger member 24, fallen leaves accumulated in the rain gutter are blown up.

While the centrifugal fan 70 is rotated by the motor 62, the pressure of the air flow passage 56 and the pressure of the fan housing chamber 50 near the communication hole 84 increase. Accordingly, the pressure of the fan storage chamber 50 near the communication hole 84 is higher than the pressure of the motor storage chamber 52 near the communication hole 84. Therefore, the air flows from the fan storage chamber 50 to the motor storage chamber 52 through the communication hole 84 as indicated by an arrow Fi in fig. 3. Since the pressure in the vicinity of the opening 59 of the fan housing chamber 50 becomes negative by the rotation of the cooling fan 72, the air passing through the communication hole 84 flows through the motor housing chamber 52 and flows through the opening 59 to the fan housing chamber 50. Specifically, first, the air passing through the communication holes 84 is guided to the heat dissipation fins 68 and flows on the control board 66. While the air flows on the control board 66, the air merges with the air flowing from the outside of the blower 2 to the motor storage chamber 52 through the air inlet 20 (i.e., the air flowing in the direction of the arrow Fg shown in fig. 3). Next, as shown by an arrow Fm in fig. 3, the air flows toward the motor intake port 78 and is sucked into the motor housing 64. Next, the air flows from the motor storage chamber 52 to the fan storage chamber 50 through the motor discharge port 79 and the opening 59 as indicated by an arrow Fo in fig. 3. Then, at least a part of the air sent toward the radial outside of the rotating shaft 62a by the cooling fan 72 passes through the communication hole 84, and flows from the fan housing chamber 50 to the motor housing chamber 52. Thus, a circulation flow path of air is formed between the fan housing chamber 50 and the motor housing chamber 52 through the communication hole 84 and the opening 59. As a result, the control board 66 disposed in the air circulation flow path is cooled.

The structure of the blower 2 used in the suction mode will be described with reference to fig. 7. The parts of the components of the blower 2 used in the suction mode are different from the parts of the components of the blower 2 used in the air blowing mode. As shown in fig. 7, the blower 2 has a suction nozzle 92, a joint 94, a flexible nozzle 96, and a dust bag 98 instead of the fixed nozzle 80 and the air blowing nozzle 82. The suction nozzle 92 is attached to a portion of the main casing 6 located on the periphery of the air inlet 54 (not shown in fig. 7) in a state where the cover 60 is opened.

The joint 94 penetrates the discharge port 58, and illustration thereof is omitted. The flexible nozzle 96 is attached to the tip end of the joint 94. A dust bag 98 is attached to the other end of the flexible nozzle 96.

Furthermore, the blower 2 has a harness 100. Both ends of the harness 100 are detachably attached to the case 4. The back belt 100 is attached to the dust bag 98 at an arbitrary position between both end portions so as to be detachable from the dust bag 98.

The suction operation of the blower 2 in the case of use in the suction mode will be described. When the blower 2 is used in the suction mode, the main handle 14 and the sub handle 18 are held by the operator. Furthermore, the harness 100 is hung on the shoulder of the operator. When the trigger member 24 is pushed by the operator to rotate the motor 62, the centrifugal fan 70, the cooling fan 72, and the cutter 74 rotate about the rotation shaft 62 a. When the tip opening of the suction nozzle 92 is directed to the ground from this state, the fallen leaves on the ground are collected from the suction nozzle 92 into the dust bag 98 through the air inlet 54, the fan storage chamber 50, the air flow path 56, the discharge port 58, the joint 94, and the flexible nozzle 96 in this order. The fallen leaves are crushed by the cutter 74. In the blower 2 used in the air blowing mode, as described above, a circulation flow path of air is formed between the fan storage chamber 50 and the motor storage chamber 52 via the communication hole 84 and the opening 59.

In the present embodiment, as shown in fig. 8, the control substrate 66 is capable of executing a normal mode M1 and a slow mode M2. The normal mode M1 is a mode set when the main power switch 42 is pressed by the operator to switch the blower 2 from the off state to the on state. When the main power switch 42 is pressed for a predetermined number of seconds or more in a state where the control substrate 66 is in the normal mode M1, the control substrate 66 switches from the normal mode M1 to the mitigation mode M2. At this time, the display window 44b (see fig. 1) of the display unit 44 is lit. Further, when the main power switch 42 is pressed for a predetermined number of seconds or more in a state where the control substrate 66 is in the relaxing mode M2, the control substrate 66 switches from the slow mode M2 to the normal mode M1. At this time, the display window 44b of the display unit 44 is turned off. The predetermined number of seconds is, for example, 1 second or more, and in the present embodiment, 2 seconds.

The normal mode M1 is mainly used when the blower 2 is used in the blowing mode. As shown in fig. 8, when the control board 66 is in the normal mode M1, when the trigger member 24 is not pressed, that is, when the pressed amount of the trigger member 24 is 0%, the pressed amount of the switch 32a of the sensor 32 is 0%, and the rotation speed of the motor 62 is zero. As the press-in amount of the trigger member 24 increases from 0% to 100% of the maximum, i.e., the press-in amount of the switch 32a of the sensor 32 increases from 0% to 100%, the rotation speed of the motor 62 gradually increases to the maximum rotation speed R1. Thus, when the blower 2 is used in the air blowing mode, the higher the pressed amount of the trigger member 24, the higher the flow rate of the air blown out from the distal end opening of the air blowing nozzle 82.

The relaxation mode M2 is mainly used when the blower 2 is used in the suction mode. When the control board 66 is in the relaxing mode M2, when the trigger member 24 is not pressed, that is, when the pressed amount of the trigger member 24 is 0%, the pressed amount of the switch 32a of the sensor 32 is 0%, and the rotation speed of the motor 62 is zero. As the pressed amount of the trigger member 24 increases from 0% to 100% of the maximum, i.e., the pressed amount of the switch 32a of the sensor 32 increases from 0% to 100%, the rotation speed of the motor 62 gradually increases to the target rotation speed R2. Thus, when the blower 2 is used in the suction mode, the higher the pressed amount of the trigger member 24, the higher the flow rate of the air sucked toward the distal end opening of the suction nozzle 92. Therefore, the higher the pressed amount of the trigger member 24, the higher the force with which the attraction material is attracted. In addition, the target rotation speed R2 is, for example, 70% or less of the maximum rotation speed R1 in the normal mode M1. In the modification, the target rotation speed R2 is, for example, 50% or less of the maximum rotation speed R1.

When the motor 62 is rotated at the target rotation speed R2 in the relaxation mode M2, the blower 2 sucks a comparatively light attraction such as fallen leaves (for example, an attraction of 5g or less), but does not suck a comparatively heavy attraction such as small stones (for example, an attraction of 5g or more). When the motor 62 is rotated at the target rotation speed R2 in the mild mode M2, the suction power of the blower 2 is 50-100W. Here, the intake power is a numerical value calculated by multiplying the intake air amount, the intake pressure, and a predetermined coefficient.

In the present embodiment, blower 2 has housing 4, motor 62, centrifugal fan 70, and control substrate 66. The housing 4 has a motor housing chamber 52 and a fan housing chamber 50 therein which are communicated with each other through an opening 59. As shown in fig. 3, the motor 62 is disposed in the motor housing chamber 52, and the rotating shaft 62a penetrates the opening 59. The centrifugal fan 70 is disposed in the fan housing chamber 50 and is driven by the motor 62 to rotate about the rotary shaft 62a as a center axis. The control board 66 is disposed in the motor housing chamber 52 and controls driving of the motor 62. The housing 4 further has a communication hole 84 that communicates the motor housing chamber 52 and the fan housing chamber 50 and is disposed separately from the opening 59. In this configuration, when the pressure of the fan housing chamber 50 is higher than the pressure of the motor housing chamber 52, air flows from the fan housing chamber 50 to the motor housing chamber 52 through the communication hole 84, and flows from the motor housing chamber 52 to the fan housing chamber 50 through the opening 59. Therefore, even when the pressure of the fan accommodating chamber 50 is higher than the pressure of the motor accommodating chamber 52, air flows through the motor accommodating chamber 52, and the control board 66 is sufficiently cooled by the air. As a result, the control board 66 can be prevented from becoming high in temperature.

As shown in fig. 3, the communication hole 84 is disposed to overlap the centrifugal fan 70 in the direction of the rotation shaft 62 a. In this structure, the centrifugal fan 70 sends out air toward the radial outside. Therefore, by disposing the communication hole 84 so as to overlap the centrifugal fan 70 in the direction of the rotation shaft 62a, the air sent by the centrifugal fan 70 can be suppressed from flowing from the fan housing chamber 50 to the motor housing chamber 52 through the communication hole 84. This can suppress a decrease in the flow rate of the air blown by the blower 2.

The blower 2 also has a battery B for supplying electric power to the motor 62. In this configuration, the blower 2 can be used even in a work area where no external power supply is present.

The battery B is disposed close to the control board 66. In this configuration, the length of the wiring for connecting the battery B and the control board 66 can be shortened. This enables the wiring to be processed satisfactorily.

The blower 2 further includes heat radiating fins 68 that are disposed in the motor accommodating chamber 52 and that guide air flowing through the motor accommodating chamber 52. The heat dissipation fins 68 are disposed on the control substrate 66. In this structure, air is guided by the heat radiation fins 68 and flows on the control board 66. This enables the control board 66 to be efficiently cooled. As a result, the control board 66 can be prevented from becoming high in temperature.

As shown in fig. 3, the blower 2 further includes a cooling fan 72 disposed between the opening 59 and the centrifugal fan 70 in the direction of the rotation axis 62 a. The cooling fan 72 rotates together with the centrifugal fan 70. In this structure, when the cooling fan 72 rotates, the pressure of the space in the vicinity of the cooling fan 72 decreases. This enables air to efficiently flow from the motor housing chamber 52 to the fan housing chamber 50 through the opening 59. Therefore, the flow rate of the air flowing through the motor accommodating chamber 52 is increased, and the control board 66 is efficiently cooled. As a result, the control board 66 can be prevented from becoming high in temperature.

Further, as shown in fig. 5, the casing 4 has an outlet 58, and the outlet 58 discharges the air sent by the centrifugal fan 70 to the outside of the casing 4. Blower 2 also has a blowing nozzle 82 through which air discharged from discharge port 58 flows. The air blowing nozzle 82 is a vertically long nozzle. In a normal case, when a vertically long nozzle is used as the air blowing nozzle, the pressure of the fan housing chamber 50 is increased in a state where the centrifugal fan 70 is rotated. Therefore, in the configuration in which the blower 2 does not have the communication hole 84, when the pressure of the fan housing chamber 50 is higher than the pressure of the motor housing chamber 52, it may be difficult for air to flow from the motor housing chamber 52 to the fan housing chamber 50 through the opening 59. As a result, the control board 66 may not be sufficiently cooled and may become high in temperature. In the above configuration, since the communication hole 84 communicates the motor storage chamber 52 and the fan storage chamber 50, even when a vertically long nozzle is used as the air blowing nozzle 82, sufficient air flows in the motor storage chamber 52, and the control board 66 is sufficiently cooled. Therefore, the control board 66 can be prevented from becoming high in temperature.

As shown in fig. 3, the control board 66 is disposed in a flow path through which air flows from the communication hole 84 toward the motor 62 in the motor accommodating chamber 52. In this structure, air flows on the control substrate 66. This enables the control board 66 to be efficiently cooled. As a result, the control board 66 can be prevented from becoming high in temperature.

As shown in fig. 3, the blower 2 further includes a motor housing 64 that houses the motor 62. The motor housing 64 has a motor inlet port 78 for sucking air into the motor housing 64. The control board 66 is disposed on an imaginary line connecting the communication hole 84 and the motor intake port 78. In this configuration, the control board 66 is disposed at the shortest distance between the communication hole 84 and the motor intake port 78. Therefore, the control board 66 can be efficiently cooled. As a result, the control board 66 can be prevented from becoming high in temperature.

In the present embodiment, the blower 2 has a motor 62, a centrifugal fan 70, a housing 4, a trigger member 24, and a control substrate 66. The centrifugal fan 70 is rotated around the rotation shaft 62a as a center axis by the rotation of the motor 62. The casing 4 houses the motor 62 and the centrifugal fan 70, and the casing 4 guides air from the air inlet 54 to the air outlet 58 in accordance with the rotation of the centrifugal fan 70. The trigger member 24 is pressed in by the operator. The control substrate 66 controls driving of the motor 62. As shown in fig. 8, the control board 66 has a normal mode M1 and a slow mode M2, the normal mode M1 adjusts the rotation speed of the motor 62 in accordance with the pressed amount of the trigger member 24, and the slow mode M2 adjusts the rotation speed of the motor 62 to a target rotation speed R2 lower than the maximum rotation speed R1 of the motor 62 in the case where the pressed amount of the trigger member 24 in the normal mode M1 is the maximum amount. In this structure, the target rotation speed R2 of the motor 62 in the mild mode M2 is lower than the maximum rotation speed R1 of the motor 62 in the normal mode M1. Therefore, the rotational speed of the centrifugal fan 70 in the mild mode M2 is lower than the rotational speed of the centrifugal fan 70 in the normal mode M1. As a result, the suction force of the blower 2 in the mild mode M2 is smaller than the suction force of the blower 2 in the normal mode M1. Thus, in the relaxation mode M2, the attraction of small stones can be suppressed as compared with the normal mode M1. As a result, the control board 66 is set to the relaxation mode M2, whereby the attraction of the pebbles can be stably suppressed.

Further, as shown in fig. 8, in the case where the control substrate 66 is in the relaxing mode M2, the rotation speed of the motor 62 gradually increases to the target rotation speed R2 as the pressed amount of the trigger member 24 increases to the maximum amount. In this configuration, the flow rate of the air sucked into the air inlet 54 changes according to the amount of pressing the trigger 24. Therefore, the rotation speed of the motor 62, that is, the flow rate of the air sucked into the air inlet 54 can be freely adjusted according to the state of the working area.

Further, the blower 2 also has a switch 42 that switches the normal mode M1 and the slow mode M2 of the control substrate 66. In this structure, the operator can switch the normal mode M1 and the slow mode M2 by a simple operation of pressing the main power switch 42.

The switch 42 is a main power switch 42 that switches between an on state that allows driving of the motor 62 and an off state that prohibits driving of the motor 62. In the case of long-pressing the main power switch 42, the normal mode M1 and the slow mode M2 of the control board 66 are switched. In this configuration, the operator can perform the switching operation of the on state and the off state of the blower 2 and the switching operation of the normal mode M1 and the slow mode M2 with the main power switch 42. Therefore, it is not necessary to separately provide a switch for switching the normal mode M1 and the slow mode M2.

Further, blower 2 includes display unit 44 capable of displaying that control board 66 is in relaxation mode M2. In this configuration, the operator can easily confirm whether or not the control board 66 is in the relaxation mode M2 by the display content displayed on the display unit 44.

As shown in fig. 4, the metal plate 67 is disposed between the left side surface of the main casing 6 and the control board 66. The metal plate 67 is connected to the main handle 14 via a wiring not shown. In the blower 2, when the centrifugal fan 70 rotates, static electricity is accumulated in the main casing 6. Therefore, for example, when a metal material such as the metal plate 67 is not disposed between the left side surface of the main casing 6 and the control board 66, the control board 66 may malfunction due to static electricity accumulated in the main casing 6. In the above configuration, the static electricity accumulated in the main case 6 moves from the metal plate 67 to the ground through the wiring, the main handle 14, and the body of the operator who grips the main handle 14. This can prevent malfunction of the control board 66 due to the influence of static electricity.

(corresponding relationship)

The motor housing chamber 52 is an example of the "1 st housing chamber" and the fan housing chamber 50 is an example of the "2 nd housing chamber".

(embodiment 2)

Embodiment 2 is explained with reference to fig. 9. In embodiment 2, points different from embodiment 1 are explained, and the explanation of the points same as embodiment 1 is omitted. In the 2 nd embodiment, the relaxing mode M3 executed by the control substrate 66 is different from the relaxing mode M2 of the 1 st embodiment. As shown in fig. 9, when the control board 66 is in the relaxing mode M3, the rotation speed of the motor 62 is constant at the target rotation speed R3 regardless of the pressed amount of the trigger member 24. When the trigger member 24 is not pressed, the rotation speed of the motor 62 is also constant at the target rotation speed R3. Therefore, when the control board 66 is in the relaxation mode M3, the rotation speed of the centrifugal fan 70 is constant regardless of the pressed amount of the trigger member 24. In addition, the target rotation speed R3 is, for example, 70% or less of the maximum rotation speed R1 in the normal mode M1. In the modification, the target rotation speed R3 is, for example, 50% or less of the maximum rotation speed R1.

In the present embodiment, as shown in fig. 9, when the control board 66 is in the relaxing mode M3, the rotation speed of the motor 62 is constant at the target rotation speed R3 regardless of the pressed amount of the trigger member 24. In this configuration, the rotation speed of the centrifugal fan 70 is constant regardless of the pressed amount of the trigger member 24, and the suction force can be made constant. This allows the operator to easily perform the suction operation by using the blower 2.

Specific examples of the present invention have been described above in detail, but these specific examples are merely illustrative and do not limit the claims. The techniques recited in the claims include various modifications and alterations to the specific examples illustrated above.

The communication hole 84 according to an embodiment may be disposed radially outward of the rotation shaft 62a with respect to the centrifugal fan 70.

The blower 2 of an embodiment may not have the heat radiation fins 68.

The blower 2 of one embodiment may be electrically connected to an external power source via a lead wire.

The cooling fan 72 according to an embodiment may be disposed in the motor storage chamber 52.

Blower 2 according to an embodiment may have a switch for switching control board 66 between normal mode M1 and slow mode M2, in addition to main power switch 42. The switch may be a push button or a dial.

In blower 2 according to one embodiment, when control board 66 is in relaxation mode M3, the rotation speed of motor 62 may be zero when trigger member 24 is not pressed.

The technical elements described in the present specification or drawings exhibit technical usefulness by themselves or in various combinations, and are not limited to the combinations described in the claims at the time of filing. Further, the technology illustrated in the present specification or the drawings can achieve a plurality of objects at the same time, and achieving one of the objects has technical usefulness by itself.

Claims (9)

1. A blower is characterized in that a blower body is provided with a blower body,

the blower has:

a housing having a 1 st housing chamber and a 2 nd housing chamber therein which are communicated with each other through an opening;

a motor disposed in the 1 st housing chamber, a rotation shaft of the motor penetrating the opening;

a centrifugal fan disposed in the 2 nd housing chamber and driven by the motor to rotate about the rotation shaft as a center axis; and

a control board disposed in the 1 st accommodation chamber and controlling driving of the motor,

the housing further has a communication hole that communicates the 1 st housing chamber and the 2 nd housing chamber and is disposed separately from the opening.

2. The blower according to claim 1,

the communication hole is arranged to overlap the centrifugal fan in the rotation axis direction.

3. The blower according to claim 1 or 2,

the blower also has a battery that supplies power to the motor.

4. The blower according to claim 3,

the battery is disposed adjacent to the control substrate.

5. The blower according to claim 1,

the blower further includes heat radiating fins disposed in the 1 st housing chamber and guiding air flowing in the 1 st housing chamber,

the radiating fins are configured on the control substrate.

6. The blower according to claim 1,

the blower further includes a cooling fan disposed between the opening and the centrifugal fan in the direction of the rotation axis,

the cooling fan rotates together with the centrifugal fan.

7. The blower according to claim 1,

the casing has an outlet port for discharging the air sent by the centrifugal fan to the outside of the casing,

the blower further has a blowing nozzle through which air discharged from the discharge port flows,

the air supply nozzle is a lengthwise nozzle.

8. The blower according to claim 1,

the control board is disposed in a flow path through which air flows from the communication hole to the motor in the 1 st accommodation chamber.

9. The blower according to claim 1,

the blower also has a motor housing that houses the motor,

the motor housing has a motor suction port for sucking air into the motor housing,

the control board is disposed on an imaginary line connecting the communication hole and the motor suction port.

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