JP2015150665A - Dust collecting device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an improvement technology related to cooling of a controller of a dust collecting device attached to a working tool.SOLUTION: A dust collecting device 200 is attached to a hammer drill 101 to collect dust occurring during process work. The dust collecting device 200 includes: a dust collecting part 210; a dust collecting motor 231; a fan 232; and a controller 234 which controls the dust collecting motor 231. The dust collecting device 200 collects dust from the dust collecting part 210 and cools the controller 234 with air flow generated by the fan 232 being rotated by the dust collecting motor 231.

Description

  The present invention relates to a dust collector attached to a work tool.

  US 2004/0231871 discloses a work tool equipped with a dust collector. This dust collector has a motor and a fan, and is powered by a work tool to drive the motor. And the dust which generate | occur | produces at the time of a process operation | work is collected because a motor rotates a fan and produces an air flow.

US Patent Application Publication No. 2004/0231871

  In the above dust collector, a controller for controlling the motor generates heat during the processing operation. Then, this invention is made | formed in view of the above, and it aims at providing the improvement technique regarding the controller cooling of the dust collector with which a work tool is mounted | worn.

  The above problems are solved by the present invention. According to the preferable form of the dust collector which concerns on this invention, the dust collector which is mounted | worn with the working tool which processes a workpiece and collects the dust which generate | occur | produces at the said machining operation is comprised. This dust collecting apparatus includes a dust collecting motor, a fan driven by the dust collecting motor, a controller for controlling the dust collecting motor, a dust collecting section having an opening for collecting dust, and a collecting A dust storage unit that stores the collected dust, and a dust transfer unit that transfers the dust collected from the dust collection unit to the dust storage unit. Then, using the air flow generated by the rotation of the fan driven by the dust collection motor, the dust is collected from the dust collection unit and transferred to the dust storage unit, and the controller is cooled. The air flow generated by the rotation of the fan may be configured such that the air after the dust transfer further cools the controller. On the other hand, the air flow for dust transfer and the air flow for cooling the controller May be configured to be separated and distributed.

  According to the present invention, the air flow generated by the rotation of the fan not only collects dust but also cools the controller. Therefore, it is not necessary to separately provide a dust collecting fan and a controller cooling fan, and the number of parts of the dust collecting device can be reduced.

  According to the further form of the dust collecting apparatus according to the present invention, the drive mechanism receiving portion connected to the dust receiving portion and receiving the dust collecting motor and the controller, and disposed between the dust receiving portion and the drive mechanism receiving portion. And a filter. And the air which passed the filter after transferring dust to a dust accommodating part cools a controller.

  According to this embodiment, the controller is cooled after dust in the airflow is captured by the filter. Therefore, the influence which the dust in cooling air has with respect to a controller is suppressed.

  According to the further form of the dust collector which concerns on this invention, the controller is arrange | positioned between a filter and a fan so that the air produced by rotation of a fan may pass a filter, a controller, and a fan in order. This controller is arranged so that the air flowing into the dust collector from the opening passes through the filter, controller and fan in order and is discharged to the outside of the dust collector. The aspect arrange | positioned between a filter and a fan suitably includes the aspect arrange | positioned between a filter and a fan suitably as a physical position regarding the predetermined axial direction.

  According to the further form of the dust collector which concerns on this invention, the drive mechanism accommodating part has an airflow path through which air flows toward a fan from a filter. And a controller comprises at least one part of an air flow path, and air flows along the surface of the said controller. In addition, it is preferable that a controller has a metal heat sink which comprises an airflow path.

  According to this form, since a controller constitutes an air flow passage, a controller is cooled efficiently. Further, the controller has a function of controlling the driving of the dust collecting motor and a function of configuring an air flow passage. In other words, the controller is provided as a member having a plurality of functions, and the number of parts of the dust collector is reduced.

  According to the further form of the dust collector which concerns on this invention, the motor for dust collection is comprised as a DC motor. The controller functions as a transformer that transforms electricity supplied from an external power source and supplies power to the dust collection motor.

  In general, the output torque of a motor required for generating an air flow for collecting dust may be smaller than the output torque of a motor required for driving a working tool drive mechanism and a tip tool. Therefore, a small motor that can be driven at a low voltage is used as the dust collection motor. Therefore, according to this embodiment, since the controller has a function as a transformer, the dust collector having a small motor is rationally driven by the electric power supplied from the external power source.

  According to the further form of the dust collector according to the present invention, the work tool to which the dust collector is attached is driven by electricity supplied from an external power source. Typically, the work tool has an AC motor, and the tip tool is driven by driving the drive mechanism by the AC motor. The dust collector is driven by being fed with power from the work tool. The dust collection motor of the dust collector is configured as a DC motor, and the controller has a function as a converter that converts an alternating current supplied from an external power source into a direct current. Typically, the work tool is configured to drive the tip tool by an AC motor driven by an alternating current supplied from an external power source. Therefore, the controller converts the alternating current supplied from the work tool to the dust collector to a direct current before supplying the alternating current to the dust collecting motor.

  According to the present embodiment, the controller converts an alternating current supplied via the work tool into a direct current. Therefore, even when the work tool is driven by an alternating current, the dust collector attached to the work tool can drive the dust collecting motor configured as a DC motor.

  According to the preferable form of the dust collector according to the present invention, the controller is electrically connected to the work tool. Based on the signal output from the work tool, the controller controls the dust collection motor. Typically, the work tool includes an operation member that is operated by an operator to be switched between an ON state in which the work tool is driven and an OFF state in which the drive of the work tool is stopped. Furthermore, when the operation tool is switched to the ON state and the work tool is driven, the work tool outputs a drive signal to the dust collector, and the operation member is switched to the OFF state to drive the work tool. When stopped, the work tool outputs a stop signal to the dust collector. The controller of the dust collector that receives the drive signal output from the work tool receives the drive signal and simultaneously drives the dust collecting motor, and the controller that receives the stop signal receives the stop signal and receives a predetermined signal. After the time has elapsed, the drive of the dust collecting motor is stopped. In this case, as the drive signal and the stop signal, a form configured as current supply and current interruption in a predetermined electrical system of the dust collector achieved by switching of the switch operated by the operation member, or as a signal output device Preferably, the provided work tool controller suitably generates a predetermined signal based on switching of the operation member.

  According to this embodiment, the controller drives the dust collection motor based on the signal output from the work tool. Therefore, an individual switch for switching the drive of the dust collector (dust collector motor) is unnecessary, and the number of parts of the dust collector is reduced. Further, the dust collector is driven based on the operation of the operation member to drive the work tool. For this reason, the dust collector is rationally driven in accordance with the drive timing at which the work tool performs the machining operation without the operator performing a special operation on the dust collector. Furthermore, based on the operation of the operation member for stopping the drive of the work tool, the drive of the dust collector is stopped after a predetermined time has elapsed since the operation. Therefore, the dust collector continues to drive for a predetermined time even after the work tool stops the machining operation. Thereby, the dust which was not collected during the processing operation is effectively collected by driving the dust collector after the processing operation. Further, since the dust collector automatically stops after a predetermined time has elapsed, the dust collector is rationally driven in accordance with the stop timing of the processing operation.

  ADVANTAGE OF THE INVENTION According to this invention, the improvement technique regarding the controller cooling of the dust collector with which a work tool is mounted | worn is provided.

1 is a perspective view of a hammer drill and a dust collector according to a representative embodiment of the present invention. It is a side view of the hammer drill and dust collector of FIG. It is sectional drawing which shows the internal mechanism of a hammer drill. It is sectional drawing which shows the internal mechanism of a dust collector. It is a side view which shows the state with which the dust collector was mounted | worn with the hammer drill. It is sectional drawing of the hammer drill and dust collector of FIG. It is sectional drawing in the VII-VII line of FIG. It is a side view of the hammer drill and dust collector which concern on a modification.

  A representative embodiment of the present invention will be described with reference to FIGS. The present embodiment will be described using an electric hammer drill as an example of a work tool on which a dust collector is detachably mounted. As shown in FIGS. 1 and 2, the hammer drill 101 is composed mainly of a main body 103 and a handle 109. The main body 103 is mainly composed of a motor housing 105 and a gear housing 107 each housing an internal mechanism of the hammer drill 101.

  As shown in FIG. 2, the hammer bit 119 that performs a machining operation on the workpiece is detachably attached to the hammer drill 101 in the distal end side region (left side in FIG. 2) of the main body 103. The handle 109 has a grip portion 109A and a reinforcing portion 109B, and is provided in a rear end side region (right side in FIG. 2) opposite to the front end side region of the main body portion 103. Therefore, in the hammer drill 101, the hammer bit 119 side is referred to as a front side, and the handle 109 side is referred to as a rear side.

[Drive mechanism]
As shown in FIG. 3, the motor housing 105 is formed integrally with the handle 109 and accommodates the drive motor 111. The drive motor 111 is disposed such that the rotation axis is parallel to the long axis direction of the hammer bit 119. A cooling fan 112 is attached to the rotating shaft of the drive motor 111 in front of the drive motor 111. That is, the cooling fan 112 is provided between the drive mechanism and the drive motor 111 in the major axis direction of the hammer bit 119. Therefore, the cooling fan 112 is rotated by driving the drive motor 111, and cooling air is generated. The cooling fan 112 is formed as a centrifugal fan. Therefore, the cooling air flowing through the gear housing 107 is discharged from the opening 105 a provided on the lower surface of the motor housing 105 at a position corresponding to the cooling fan 112. The handle 109 is provided with a trigger 109a, and the operation of the trigger 109a switches on / off of the drive motor 111.

  As shown in FIG. 3, the gear housing 107 houses the motion conversion mechanism 113, the striking element 115, and the power transmission mechanism 117. The rotational output of the drive motor 111 is converted into a linear motion by a motion conversion mechanism 113 disposed in front of the drive motor 111 and transmitted to the striking element 115, and the longitudinal direction of the hammer bit 119 (the horizontal direction in FIG. 3). Generate impact force. The rotation output of the drive motor 111 is decelerated by the power transmission mechanism 117 disposed in front of the drive motor 111 and transmitted to the hammer bit 119, causing the hammer bit 119 to rotate in the circumferential direction. For convenience of explanation, the hammer bit 119 side is referred to as the front, and the handle 109 side is referred to as the rear.

  The motion conversion mechanism 113 is mainly composed of an intermediate shaft 125, a swing ring 129, and a cylindrical piston 131. The intermediate shaft 125 is rotated by the drive motor 111. As the intermediate shaft 125 rotates, the swing ring 129 is rocked in the major axis direction of the hammer bit 119 via the rotating body 127. The cylindrical piston 131 is reciprocated linearly in the long axis direction of the hammer bit 119 as the swing ring 129 swings.

  The power transmission mechanism 117 is mainly configured by a gear reduction mechanism including a plurality of gears. This gear reduction mechanism has a small diameter gear 133 that rotates integrally with the intermediate shaft 125, and a large diameter gear 135 that meshes with and engages with the small diameter gear 133. The power transmission mechanism 117 transmits the rotation of the drive motor 111 to the tool holder 137. The tool holder 137 is rotatably supported with respect to the gear housing 107 by a bearing 137a. Accordingly, the tool holder 137 is rotated, whereby the hammer bit 119 held by the tool holder 137 is rotated.

  The striking element 115 is mainly composed of a striker 143 and an impact bolt 145. The striker 143 is configured as a striker that is slidably disposed in the cylindrical piston 131. The impact bolt 145 is configured as an intermediate element slidably disposed in the tool holder 137. The striker 143 is driven via an air spring (pressure fluctuation) of the air chamber 131 a accompanying the sliding of the cylindrical piston 131 and collides with the impact bolt 145. As a result, the hammer bit 119 generates a striking force.

  In the hammer drill 101, when the drive motor 111 is energized and driven, the rotation of the drive motor 111 is converted into a linear motion through the motion conversion mechanism 113 and then transmitted to the hammer bit 119 through the striking element 115. The Thereby, the hammer bit 119 performs a hitting operation. The rotation of the drive motor 111 is transmitted to the hammer bit 119 via the power transmission mechanism 117. Thereby, the hammer bit 119 performs a hammering operation on the workpiece by performing a striking operation in the major axis direction and a rotating operation in the circumferential direction.

  The hammer drill 101 includes a mode switch (not shown) for switching the work mode. Then, when the operator operates the mode switch, the hammer drill mode and the drill mode as the work mode are switched. In the hammer drill mode, the hammer bit 119 performs a striking operation and a rotating operation. In the drill mode, the motion conversion mechanism 113 and the striking mechanism 115 are not driven, only the power transmission mechanism 117 is driven, and the hammer bit 119 performs a rotating operation. Thereby, a drilling operation is performed on the workpiece.

[handle]
As shown in FIG. 3, the grip portion 109 </ b> A of the handle 109 is formed so as to extend from the base end portion 109 </ b> A <b> 1 connected to the rear end portion of the motor housing 105 in a direction intersecting the major axis direction of the hammer bit 119. ing. A power cable 190 is provided at the distal end portion 109A2 of the grip portion 109A, and one end portion of the reinforcing portion 109B is coupled thereto. The other end of the reinforcing portion 109B is coupled to the motor housing 105 in front of the grip portion 109A. Therefore, the grip portion 109A, the reinforcing portion 109B, and the motor housing 105 are formed in a loop shape, and a protective space 261 surrounded by the grip portion 109A, the reinforcing portion 109B, and the motor housing 105 is formed. Therefore, the reinforcing portion 109B structurally reinforces the cantilever-shaped grip portion 109A and protects the operator's hand holding the grip portion 109A. That is, the operator's hand arranged in the protection space 261 is protected. A female connector 154 that is mechanically and electrically connected to the dust collector 200 is provided in the vicinity of the connecting portion between the reinforcing portion 109B and the motor housing 105. The power cable 190 is electrically connected to the drive motor 111 and the female connector 154 and is supplied with power through the power cable 190.

[Dust collector attachment]
Said hammer drill 101 is comprised so that the dust collector 200 may be attached so that attachment or detachment is possible. Specifically, as shown in FIGS. 1 to 3 and 7, the dust collector attaching portion formed on the hammer drill 101 includes a guide groove 151, a main body side engaging portion 152, an engaging groove 153, and a female connector. 154 is configured mainly. That is, the dust collector 200 is attached to the main body 103 and the handle 109 of the hammer drill 101. The guide groove 151 is composed of a pair of left and right grooves formed in a lower region of the gear housing 107. The guide groove 151 extends parallel to the long axis direction of the hammer bit 119. Further, as shown in FIG. 3, the main body side engaging portion 152 is constituted by a concave portion formed on the hammer bit 119 side with respect to the guide groove 151. The engagement groove 153 and the female connector 154 are formed on the front surface (surface on the hammer bit 119 side) of the reinforcing portion 109B of the handle 109.

[Dust collector]
Next, the dust collector 200 attached to the hammer drill 101 will be described. The dust collector 200 is also referred to as a dust collection attachment, and is configured as a portable dust collection attachment that can be carried with the hammer drill 101 while being attached to the hammer drill 101. Therefore, the hammer drill 101 can be driven with the dust collector 200 attached, and can be driven with the dust collector 200 removed. That is, the hammer drill 101 has either a drive mode in which the dust collector 200 is attached (also referred to as a dust collector attachment mode) or a drive mode in which the dust collector 200 is not attached (also referred to as a dust collector non-attachment mode). These drive modes are selected and driven.

  As shown in FIG. 4, the dust collector 200 is configured mainly with a main body 201, a dust collector 210, and a mounting mechanism 250. The main body 201 has a main body housing 201 </ b> A that forms the outline of the dust collector 200. The main body housing 201A accommodates a part of the dust transfer unit 215 and also accommodates the dust storage unit 220 and the drive unit 230.

  The dust collection unit 210 has an opening 211 formed as a through hole through which the hammer bit 119 is inserted. As shown in FIG. 6, the opening 211 is disposed so as to surround the hammer bit 119 in a state where the dust collector 200 is attached to the hammer drill 101. This dust collection part 210 and the opening part 211 are the implementation structural examples corresponding to the "dust collection part" and the "opening part" in this invention, respectively.

  As shown in FIG. 4, the dust transfer unit 215 includes a first transfer unit 215a and a second transfer unit 215b. The first transfer unit 215 a is a hollow resin member and is connected to the dust collection unit 210. Therefore, the inside of the 1st transfer part 215a and the opening part 211 are mutually connected. As shown in FIG. 6, the first transfer part 215 a extends in a direction intersecting with the major axis direction of the hammer bit 119 in a state where the dust collector 200 is attached to the hammer drill 101.

  As shown in FIG. 4, the second transfer unit 215 b extends in a direction that intersects the direction in which the first transfer unit 215 a extends. In other words, the second transfer part 215 b extends in parallel with the long axis direction of the hammer bit 119. The second transfer part 215b is mainly configured by a transfer hose 216, a first extension part 217, and a second extension part 218. The first extending part 217 and the second extending part 218 are each a hollow resin member. The second extending portion 218 is configured as a part of the main body housing 201A. The first extending part 217 is slidable inside the second extending part 218 with respect to the extending direction of the second transfer part 215a (the left-right direction in FIG. 4). That is, the first extension part 217 and the second extension part 218 are relatively movable. A bellows-shaped transfer hose 216 is disposed inside the first extension part 217 and the second extension part 218. Therefore, the transfer hose 216 expands and contracts when the first extension part 217 slides relative to the second extension part 218. One end of the transfer hose 216 is in communication with the first transfer unit 215 a, and the other end is in communication with the dust container 220. That is, the accommodating part 225 of the dust accommodating part 220 is connected to the opening part 211 of the dust collecting part 210 via the 1st transfer part 215a and the 2nd transfer part 215b (transfer hose 216). This dust transfer part 215 is the implementation structural example corresponding to the "dust transfer part" in this invention.

  As shown in FIG. 4, the dust accommodating part 220 is comprised mainly by the fixed part 221a and the movable part 221b. The fixing portion 221a is formed as a part of the main body housing 201A. On the other hand, the movable part 221b is rotatable around a fulcrum 222 provided in the main body housing 201A. The movable portion 221b has a latch 223, and the movable portion 221b is fixed to the fixed portion 221a by the latch 223 engaging with the fixed portion 221a. An accommodating portion 225 is provided in the movable portion 221b, and the transferred dust is temporarily accommodated in the accommodating portion 225. By releasing the engagement between the latch 223 and the fixed portion 221a and rotating the movable portion 221b, the storage portion 225 can be accessed, whereby the dust stored in the storage portion 225 is discarded. A filter 226 is disposed in a through hole formed above the accommodating portion 225 (on the driving portion 230 side). The accommodating part 225 and the filter 226 are implementation structural examples corresponding to the “dust accommodating part” and the “filter” in the present invention, respectively.

  As shown in FIG. 4, a drive unit 230 is provided in the main body housing 201 </ b> A above the dust container 220. The drive unit 230 is mainly composed of a dust collection motor 231, a fan 232, a male plug 233, and a controller 234. The dust collection motor 231 is configured as a direct current motor, and the rotation shaft is disposed substantially parallel to the second transfer unit 215 b of the dust transfer unit 215. A fan 232 is attached to the rotating shaft of the dust collection motor 231 on the front side of the dust collection motor 231. The drive unit 230 communicates with the storage unit 225 through the filter 226. The dust collection motor 231, the fan 232, and the controller 234 are implementation configuration examples corresponding to the “dust collection motor”, “fan”, and “controller” in the present invention, respectively. Further, the main body housing 201A is an implementation configuration example corresponding to the “drive mechanism housing portion” in the present invention.

  A male plug 233 that protrudes rearward from the main body housing 201 is disposed above the dust collection motor 231 on the side opposite to the dust container 220. The male plug 233 is composed of four plugs held by the plug holding part 233a. The front side of the plug holding portion 233a opposite to the male plug 233 is connected to the coil spring 233b. The coil spring 233b is further connected to the main body housing 201. Thereby, the plug holding part 233a and the male plug 233 can move in the front-rear direction (long axis direction of the hammer bit 119) via the coil spring 233b. The male plug 233 is electrically connected to the controller 234. As shown in FIG. 7, the controller 234 is disposed on the side of the drive motor 231 and controls the drive of the dust collection motor 231. The dust collection motor 231 is held by a plurality of ribs formed in the main body housing 201, and a space surrounded by the ribs and the controller 234 is defined as an air flow passage S. This air flow passage S is an implementation configuration example corresponding to the “air flow passage” in the present invention.

[Mounting mechanism]
As shown in FIGS. 4 and 7, the dust collector 200 includes a mounting mechanism 250 for attaching to the hammer drill 101. The mounting mechanism 250 is provided on the upper surface of the main body housing 201 on the main body housing 201, a guide rail 251 formed integrally with the main body housing 201, an engaging convex portion 252 formed integrally with the plug holding portion 233a. The latch 253 is mainly used.

  As shown in FIG. 7, the guide rail 251 is formed of a pair of convex portions facing each other. As shown in FIG. 4, the engaging convex portion 252 is formed so as to protrude rearward of the dust collector 200 in parallel with the male plug 233. Note that the latch 253 can rotate with respect to the main body housing 201 using the front end of the latch 253 as a fulcrum, and the rear end of the latch 253 is above the main body housing 201 by a spring element (not shown) (upper in FIG. 4). Is biased away from the main body housing 201.

[Attaching the dust collector to the hammer drill]
Next, attachment of the dust collector 200 to the hammer drill 101 will be described. The dust collector 200 is attached to the hammer drill 101 from the position shown in FIG. 2 in the long axis direction of the hammer bit 119 and attached as shown in FIG. Specifically, the guide groove 151 provided in the gear housing 107 of the hammer drill 101 is engaged with the guide rail 251 of the dust collector 200, so that the dust collector 200 moves from the hammer bit 119 toward the handle 109. It is slid from the front to the back. Thereafter, as shown in FIG. 6, the main body side engaging portion 152 of the hammer drill 101 and the latch 253 of the dust collecting device 200 are engaged, and the engaging groove 153 of the hammer drill 101 and the engaging convex portion 252 of the dust collecting device 200 are engaged. Engage. That is, the dust collector 200 is engaged with the gear housing 107 and the handle 109 of the hammer drill 101. Thereby, the dust collector 200 is fixed to the hammer drill 101. At the same time when the dust collector 200 is attached to the hammer drill 101, the female connector 154 of the hammer drill 101 and the male plug 233 of the dust collector 200 are mechanically connected, whereby the hammer drill 101 and the dust collector 200 are electrically connected. Connected.

  As described above, the dust collector 200 is attached to the hammer drill 101 by engaging with the gear housing 107 and the handle 109 of the hammer drill 101. As shown in FIG. 2, a stepped portion 201 a is formed on the upper surface of the main body housing 201 of the dust collector 200. With this stepped portion 201a, as shown in FIG. 5, when the dust collector 200 is mounted on the hammer drill 101, a heat radiation space is provided between the motor housing 105 of the hammer drill 101 and the main body housing 201 of the dust collector 200. 260 is formed. The opening 105 a of the motor housing 105 is formed in a region corresponding to the heat radiation space 260, and the cooling air generated by the cooling fan 112 cools the drive motor 111 in the motor housing 105 and then passes through the opening 105 a. It is discharged into the heat dissipation space 260. Therefore, the dust collector 200 is attached to the hammer drill 101 without blocking the cooling air discharge port provided in the hammer drill 101.

  When the dust collector 200 is attached to the hammer drill 101, power can be supplied to the controller 234 of the dust collector 200 from the power cable 190 of the hammer drill 101 through the electrically connected male plug 233 and female connector 154. It becomes. In other words, the dust collector 200 attached to the handle 109 of the hammer drill 101 is supplied with power through the handle 109. Therefore, the handle 109 is not only gripped by an operator, but also functions as a component for attaching the dust collector 200 and supplying power to the dust collector 200.

[Operation of hammer drill and dust collector]
Specifically, when a trigger 109a is operated by an operator to perform a predetermined work by the hammer drill 101, an alternating current is supplied to the drive motor 111 from the external power source to the hammer drill 101 via the power cable 190. Driven. Thereby, the motion conversion mechanism 113, the striking element 115, and the power transmission mechanism 117 as drive mechanisms are driven by the drive motor 111, and the hammer bit 119 is driven. The hammer bit 119 is pressed against the workpiece to perform a predetermined processing operation (hammer drilling operation, drilling operation). During this processing operation, the dust collecting portion 210 surrounding the hammer bit 119 also contacts the workpiece together with the hammer bit 119. The hammer bit 119 enters the workpiece, but the dust collecting portion 210 remains in contact with the workpiece surface. That is, as the processing operation progresses, the bellows-shaped transfer hose 216 contracts, and the first extending part 217 slides inside the second extending part 218, so that the dust collecting part 210 becomes the hammer bit 119. Move relative to.

  In the hammer drill 101, the trigger 109 a is operated to drive the drive motor 111, and at the same time, a drive signal is output to the dust collector 200. For example, when the trigger 109 a is operated, a trigger switch (not shown) is turned on, and a minute current as a drive signal is supplied to the dust collector 200. This drive signal is output from the hammer drill 101 to the dust collector 200 through a separate line from the dust collector drive power supply line supplied to the dust collector 200. Both wirings are electrically connected by the female connector 154 of the hammer drill 101 and the male plug 233 of the dust collector 200. Based on this drive signal, the controller 234 drives the dust collection motor 231. Specifically, the controller 234 receives the drive signal and simultaneously drives the dust collection motor 231 so that the hammer drill 101 and the dust collection device 200 are driven almost simultaneously. This drive signal is an implementation configuration example corresponding to the “drive signal” in the present invention. The trigger 109a is an implementation configuration example corresponding to the “operation member” in the present invention.

  Regarding the driving of the dust collector 200, the controller 234 reduces the voltage and converts alternating current into direct current before supplying the power supplied via the handle 109 of the hammer drill 101 to the dust collecting motor 231. To do. That is, the controller 234 functions as a transformer and functions as a converter. Then, the controller 234 supplies power to the dust collection motor 231 to control the drive of the dust collection motor 231. Thereby, the controller 234 controls the rotation of the fan 232.

  When the fan 232 is rotated, air is sucked from the opening 211 of the dust collector 210 as shown in FIG. As shown by the arrows in FIG. 6, the sucked air passes through the transfer hose 216, the accommodating portion 225, the filter 226, and the dust collection motor 231, reaches the fan 232, and enters the body housing 201 of the dust collection device 200. It is discharged from the formed exhaust port (not shown). Due to this air flow, dust generated during processing of the workpiece by the hammer bit 119 is sucked from the opening 211 of the dust collecting unit 210 and transferred to the storage unit 225. Then, when the sucked air passes through the filter 226, dust is captured by the filter 226 and accumulated in the housing portion 225.

  The air that has passed through the filter 226 passes through the air flow path S (see FIG. 7) between the controller 243 and the dust collection motor 231 and reaches the fan 232. As shown in FIG. 7, the air flow passage S is formed by a wall (for example, a heat radiating plate) constituting the outer surface of the controller 243 and a rib inside the main body housing 201 that holds the dust collection motor 231. Therefore, when the air passes through the air flow passage S, the controller 243 and the drive motor 231 are cooled.

  On the other hand, a stop signal is output to the dust collector 200 at the same time as the operation of the trigger 109 a is released to stop the drive of the drive motor 111. For example, when the trigger 109a is operated, a trigger switch (not shown) is turned OFF, and the supply of the minute current supplied as a drive signal to the dust collector 200 is cut off, thereby stopping. A signal is output. Based on this stop signal, the controller 234 stops the dust collection motor 231. Specifically, the controller 234 stops the dust collection motor 231 after a predetermined time (for example, 3 seconds) has elapsed after receiving the stop signal. Thereby, even after the hammer drill 101 stops driving, the driving of the dust collector 200 is continued. This stop signal is an implementation configuration example corresponding to the “stop signal” in the present invention.

  In the above embodiment, the handle 109 has the grip portion 109A and the reinforcing portion 109B, but is not limited thereto. For example, as shown in FIG. 8, the handle 109 may include only the grip portion 109A. In this case, the dust collector 200 has a handle connecting portion 255 at the rear end portion on the opposite side to the dust collecting portion 210. Then, a male terminal (not shown) provided at the handle connection portion 255 and a female terminal (not shown) provided at the attachment portion 109C at the tip of the grip portion 109A are engaged and electrically connected. At this time, a heat radiation space 270 is formed by the dust collector 200, the motor housing 105 (main body 103), and the handle 109. That is, since the dust collector 200 is provided with the stepped portions 201a and 201b, when the dust collector 200 is attached to the hammer drill 101, the heat radiation space 270 is formed. The heat radiation space 270 not only discharges the cooling air from the opening 105a but also functions as a space for placing the operator's finger holding the grip 109A. Therefore, the dust collector 200 attached to the hammer drill 101 protects the operator's finger holding the grip portion 109 </ b> A when the hammer drill 101 is operated.

  According to the above embodiment, the dust collector 200 is attached to the handle 109. Therefore, the handle 109 is used not only as a grip part gripped by an operator but also as a dust collector attachment part to which the dust collector 200 is attached.

  Further, according to the above embodiment, the dust collector 200 is attached to the main body 103 and the handle 109 of the hammer drill 101. That is, the dust collector 200 is held at a plurality of locations of the hammer drill 101. Therefore, the dust collector 200 is stably attached to the hammer drill 101.

  Further, according to the above embodiment, the dust collector 200 is attached to the handle 109 and is supplied with power through the handle 109. Therefore, the wiring for supplying power to the dust collector 200 is disposed inside the handle 109 of the hammer drill 101. In general, in a work tool, mechanical parts such as a drive mechanism for driving a tip tool are not arranged inside the handle 109. Therefore, mechanical system elements such as a drive mechanism and electrical system elements such as wiring are rationally separated.

  Moreover, according to the above embodiment, the dust collector 200 is attached to the hammer drill 101 so that the heat radiation spaces 260 and 270 are formed between the hammer drill 101 and the dust collector 200. In other words, the stepped portions 201 a and 201 b are provided so that the heat radiation spaces 260 and 270 are formed when the dust collector 200 is attached to the hammer drill 101. Therefore, the dust collector 200 does not block the opening 105a as an outlet for the cooling air discharged from the hammer drill 101. As a result, the cooling air generated by the cooling fan 112 is reliably discharged from the inside of the main body 103 to the outside.

  Moreover, according to the above embodiment, the side wall of the controller 243 constitutes the air flow passage S. That is, the controller 243 is disposed so as to be exposed to the air flow path S. Therefore, the cooling efficiency of the controller 243 due to the air flow generated by the rotation of the fan 232 is increased. That is, the heat generated when the controller 234 operates as a transformer and a converter is efficiently dissipated.

  Further, according to the above embodiment, in the air flow generated by the rotation of the fan 232, the air is cooled as air and cools the dust collection motor 231 and the controller 234 after passing through the filter 226. Since dust is captured by the filter 226, the air after passing through the filter 226 cools the dust collection motor 231 and the controller 234 as clean air. Therefore, the influence of dust on the dust collection motor 231 and the controller 234 is suppressed.

  Moreover, according to the above embodiment, after the drive of the hammer drill 101 stops, the dust collector 200 continues a drive. That is, dust generated by the processing operation on the workpiece is collected by the dust collector 200 even after the processing operation is completed. Therefore, dust is rationally collected by the dust collector 200.

  In the above embodiment, the dust collector 200 is configured to be attached to the hammer drill 101 by engaging with the guide groove 151 and the handle 109 of the hammer drill 101, but is not limited thereto. . For example, the dust collector 200 may be attached only to the handle 109 of the hammer drill 101, and the dust collector 200 may be configured to be held fixed to the hammer drill 101.

  Moreover, in the above embodiment, although this invention was applied to the hammer drill as an example of a working tool, it is not restricted to this. For example, the present invention can be applied to a work tool that generates dust when processing a workpiece, such as an electric hammer, an electric drill, a multi-tool, and a cutting tool.

In view of the gist of the invention, the following modes can be configured for the dust collector and the work tool according to the invention. Each aspect is used not only alone or in combination with each other, but also in combination with the invention described in the claims.
(Aspect 1)
The controller has a heat sink,
The said heat sink comprises at least one part of the said air flow path.
(Aspect 2)
The air flow passage is formed so as to be sandwiched between the dust collection motor and the controller in a direction orthogonal to the direction in which air flows in the air flow passage.
(Aspect 3)
Air sucked from the opening of the dust collector passes through the filter, the controller, and the fan in order through the air flow passage and is discharged to the outside of the dust collector.
(Aspect 4)
The controller is disposed between the filter and the fan with respect to the rotational axis direction of the dust collecting motor.
(Aspect 5)
The work tool to which the dust collector is attached is
A tool body part to which the tip tool is attached to the tip side region;
A drive mechanism motor housed in the tool body;
A drive mechanism that is driven by the drive mechanism motor and drives the tip tool;
With respect to the drive shaft extending direction in which the drive shaft of the tip tool extends, the tool main body is connected to a rear end region separated from the tip side region and intersects the drive shaft extending direction. An extended handle,
The dust collector is
A dust collector with an opening for collecting dust;
A handle connecting portion connected to the dust collecting portion and connected to the handle of the work tool;
The dust collector is attached to the work tool by connecting the handle connecting portion to the handle.
(Aspect 6)
The dust collector is supplied with electric power from the handle via the handle connecting portion and drives the dust collecting motor.
(Aspect 7)
A work tool provided with the dust collector,
The work tool has an AC motor for driving the tip tool,
The AC motor is configured to be driven by an alternating current supplied from an external power source,
The dust collector is configured to be supplied with an alternating current through the work tool,
The dust collection motor is configured as a DC motor,
The controller has a function as a converter that converts the alternating current into a direct current.

(Correspondence between each component of this embodiment and each component of the present invention)
The correspondence between each component of the present embodiment and each component of the present invention is shown below. In addition, this embodiment shows an example of the form for implementing this invention, and this invention is not limited to the structure of this embodiment.
The hammer drill 101 is an example of a configuration corresponding to the “work tool” of the present invention.
The trigger 109a is an example of a configuration corresponding to the “operation member” of the present invention.
The dust collector 200 is an example of a configuration corresponding to the “dust collector” of the present invention.
The main body 201 is an example of a configuration corresponding to the “drive mechanism housing portion” of the present invention.
The main body housing 201A is an example of a configuration corresponding to the “main body” of the present invention.
The dust collection unit 210 is an example of a configuration corresponding to the “dust collection unit” of the present invention.
The opening 211 is an example of a configuration corresponding to the “opening” of the present invention.
The dust transfer unit 215 is an example of a configuration corresponding to the “dust transfer unit” of the present invention.
The accommodating part 225 is an example of a structure corresponding to the "dust accommodating part" of the present invention.
The filter 226 is an example of a configuration corresponding to the “filter” of the present invention.
The dust collection motor 231 is an example of a configuration corresponding to the “dust collection motor” of the present invention.
The fan 232 is an example of a configuration corresponding to the “fan” of the present invention.
The controller 234 is an example of a configuration corresponding to the “controller” of the present invention.
The air flow passage S is an example of a configuration corresponding to the “air flow passage” of the present invention.

DESCRIPTION OF SYMBOLS 101 Hammer drill 103 Main body part 105 Motor housing 105a Opening part 106 Sliding guide 107 Gear housing 107a Bearing holding part 107b Opening part 108 Bellows member 109 Handle 109A Grip part 109B Reinforcement part 109C Attachment part 109a Trigger 109b Engagement convex part 109c Trigger switch 110 Mode changeover switch 111 Drive motor 111a Commutator 112 Cooling fan 113 Motion conversion mechanism 115 Stroke element 117 Power transmission mechanism 119 Hammer bit 125 Intermediate shaft 127 Rotating body 129 Oscillating ring 131 Cylindrical piston 131a Air chamber 133 Small diameter gear 135 Large diameter gear 137 Tool holder 137a Bearing 143 Striker 145 Impact bolt 151 Guide groove 152 Main body side engaging portion 153 Engaging groove 154 Female connector 90 Power cable 200 Dust collector 201 Main body housing 201a Stepped portion 201b Stepped portion 210 Dust collecting portion 211 Opening portion 215 Dust transfer portion 215a First transfer portion 215b Second transfer portion 216 Transfer hose 217 First extension portion 218 First 2 Extension part 220 Dust accommodating part 221a Fixed part 221b Movable part 222 Supporting point 223 Latch 225 Accommodating part 226 Filter 230 Driving part 231 Dust collection motor 232 Fan 233 Male plug 233a Plug holding part 233b Coil spring 234 Controller 250 Mounting mechanism 251 Guide Rail 252 Engaging convex portion 253 Latch 255 Handle connection portion 260 Heat radiation space 261 Protective space 270 Heat radiation space

Claims (8)

A dust collector that is attached to a work tool that performs a work on a workpiece and collects dust generated by the work,
A dust collecting motor;
A fan driven by the dust collecting motor;
A controller for controlling the dust collecting motor;
A dust collector with an opening for collecting dust;
A dust container for storing the collected dust;
A dust transfer unit that transfers dust collected from the dust collection unit to the dust container,
Using the air flow generated by the rotation of the fan driven by the dust collection motor, the dust is collected from the dust collection unit and transferred to the dust storage unit, and the controller is cooled. Dust collector characterized by being made. It is a dust collector of Claim 1, Comprising:
A drive mechanism housing portion connected to the dust housing portion and housing the dust collection motor and the controller;
A filter disposed between the dust container and the drive mechanism container,
The dust collector is configured such that air that has passed through the filter after transferring dust to the dust container cools the controller. It is a dust collector of Claim 2, Comprising:
The dust collector according to claim 1, wherein the controller is disposed between the filter and the fan. It is a dust collector of Claim 3, Comprising:
The drive mechanism housing portion has an air flow passage through which air flows from the filter toward the fan,
The dust collector, wherein the controller constitutes at least a part of the air flow passage, and air flows along a surface of the controller. It is a dust collector of any one of Claims 1-4,
The dust collection motor is configured as a DC motor,
The said controller has a function as a transformer which transforms the electricity supplied from an external power supply and supplies electric power to the said motor for dust collection, The dust collector characterized by the above-mentioned. A dust collector according to any one of claims 1 to 5,
The work tool to which the dust collector is mounted is driven by electricity supplied from an external power source,
The dust collector is configured to be powered and driven from the work tool,
The dust collection motor is configured as a DC motor,
The dust collecting apparatus, wherein the controller has a function as a converter that converts an alternating current supplied from the external power source into a direct current. It is a dust collector of any one of Claims 1-6,
The controller is electrically connected to the work tool, and is configured to control the dust collection motor based on a signal output from the work tool. . It is a dust collector of Claim 7, Comprising:
The work tool to which the dust collecting device is attached is an operation member that is operated by an operator and is switched between an ON state in which the work tool is driven and an OFF state in which the drive of the work tool is stopped. Have
When the operation member is switched to the ON state and the work tool is driven, the work tool outputs a drive signal to the dust collector,
When the operation member is switched to the OFF state and driving of the work tool is stopped, the work tool outputs a stop signal to the dust collector,
The controller that has received the drive signal, simultaneously with receiving the drive signal, drives the dust collection motor,
The dust collecting apparatus, wherein the controller that has received the stop signal stops driving the dust collecting motor after a predetermined time has elapsed after receiving the stop signal.

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