JP5502581B2 - Work tools - Google Patents

Description

  The present invention relates to a work tool including a dust collecting device that collects dust generated when a predetermined processing operation is performed.

  For example, in a work tool that performs a work such as a hammer work or a hammer drill work using a tool bit on a work piece such as concrete, dust is generated during the work. For this reason, some of the conventional working tools of this type include a dust collecting device that sucks and collects dust generated during machining operations. For example, in Japanese Patent Laid-Open No. 64-87304 (Patent Document 1), a dust suction part for sucking dust is provided at the tip of a pipe extending in parallel with a tool bit, and the dust suction part is brought into contact with a workpiece together with the tool bit. Disclosed is a dust collector configured to suck dust generated by the machining operation when the machining operation is performed in a state of being collected, and collect the dust through a dust transfer passage in the pipe and the work machine body. ing.

  When drilling at a predetermined position of a workpiece using a work tool, it is important that the work position or tool bit position to be drilled can be easily confirmed.

JP-A 64-87304

  An object of the present invention is to provide a technique effective in easily confirming a work position or a tool bit position in a work tool including a dust collecting device for collecting dust generated during a machining operation.

To achieve the above object, according to a preferred embodiment of the work tool according to the present invention, there is provided a work tool that drives a tool bit attached to a tip region of a work tool body to perform a predetermined work on a workpiece. Composed. The work tool is attached to the work tool main body, and connected to the work tool body. When the work tool is attached to the work tool main body, the tool bit attached to the work tool main body is at least around the longitudinal direction of the tip of the bit. And a dust collecting device having a dust collecting unit for transferring dust collected by the dust collecting unit to the downstream side. And the dust collector is a tool bit attached to a work position or a work tool body as a work target position of the work material when the tool bit approaches or comes into contact with the work material in order to perform a work work. further have a lighting device for illuminating a predetermined position of the lighting device is in the deployed configuration in a recess formed in the distal end portion outside of the dust collecting unit.

According to the present invention, the illumination device is disposed in the concave portion formed on the outer side of the tip of the dust collecting unit in the dust collecting device. The working position or the position of the tool bit can be easily confirmed, and the usability of the working tool can be improved. As the “illuminating device” in the present invention, an LED light, an incandescent bulb, a fluorescent lamp, or the like can be suitably applied.

  According to the further form of the working tool which concerns on this invention, it has a suction source which produces the suction | attraction force which attracts | sucks dust to a dust collection part, and the said suction source is provided in the dust collector. Here, the “suction source” in the present invention typically corresponds to a prime mover and a suction fan that generate a suction force. According to the present invention, since the dust collector itself is provided with a suction source, an extra large dust collector is moved as compared with the case where the dust collector is connected to a dust collector separate from the work tool to collect dust. Work becomes unnecessary.

According to the further form of the work tool which concerns on this invention, when the dust collector was mounted | worn with the work tool main body, it was set as the structure by which the wiring of an illuminating device is connected with the wiring by the side of a work tool. For “connection between lighting device side wiring and work tool side wiring”, typically, one wiring terminal is configured as a male connector, and the other wiring terminal is configured as a female connector. The electrical terminals are connected to each other by connecting these male and female connectors.
According to the present invention, the wiring of the lighting device can be connected to the wiring on the work tool side simply by performing the work of mounting the dust collector on the work tool body, and the convenience is improved.

According to the further form of the work tool which concerns on this invention, it has the motor accommodated in the work tool main body, and drives a tool bit, and the operation member which was able to be operated by the operator for the energization drive of a motor. The lighting device is turned on in conjunction with the operation of the operation member. Note that “interlocking” in the present invention suitably includes not only a mode in which the lighting device is turned on simultaneously with the energization of the drive motor but also a mode in which the lighting device is turned on prior to the energization driving of the drive motor. To do.
According to the present invention, since the lighting device is turned on in conjunction with the energization drive operation of the motor, the operation is simplified and the usability of the work tool can be further improved.

  According to the further form of the work tool which concerns on this invention, the illuminating device is comprised so that it may light only for the predetermined time at the beginning of work, and it may turn off. Once the processing operation is started, it may not be necessary to continue lighting the lighting device thereafter. Therefore, according to the present invention, it is possible to eliminate waste of electric energy by adopting a configuration in which the lighting device is turned off after the machining operation is started.

  ADVANTAGE OF THE INVENTION According to this invention, in a work tool provided with the dust collector for collecting the dust which arises at the time of a process operation, a technique effective in confirming a work position or a tool bit position easily will be provided. It was.

It is a sectional side view showing the whole hammer composition provided with the dust collection attachment concerning a 1st embodiment of the present invention. It is sectional drawing which shows the principal part of a hammer. It is sectional drawing which shows the whole structure of a dust collection attachment. It is the A section enlarged view of FIG. It is the B section enlarged view of FIG. It is an electric circuit diagram. It is an external view which shows the whole structure of the dust collection attachment which concerns on the 2nd Embodiment of this invention. It is sectional drawing which shows the state which mounted | wore the hammer drill with the dust collection attachment which concerns on 2nd Embodiment. It is CC sectional view taken on the line of FIG.

  Hereinafter, the first embodiment of the present invention will be described in detail with reference to FIGS. In this embodiment, a rechargeable hammer drill will be described as an example of a work tool. As shown in FIG. 1, the hammer drill 101 according to the present embodiment is generally viewed from a main body 103 that forms an outline of the hammer drill 101 and a distal end region (left side in the drawing) of the main body 103 via a tool holder 137. A hammer bit 119 that is detachably attached and a hand grip 109 that is connected to the opposite side of the hammer bit 119 of the main body 103 are mainly configured. The main body 103 corresponds to the “work tool main body” in the present invention, and the hammer bit 119 corresponds to the “tool bit” in the present invention. The hand grip 109 is provided as a main handle that is gripped by the user. The hammer bit 119 is held by the tool holder 137 so that the hammer bit 119 can be reciprocated relatively in the major axis direction, and the relative rotation in the circumferential direction is restricted. For convenience of explanation, the hammer bit 119 side is referred to as the front and the handgrip 109 side is referred to as the rear in a state where the main body 103 is placed in a direction in which the major axis direction of the hammer bit 119 is the horizontal direction.

  The main body 103 mainly includes a motor housing 105 that houses a drive motor 111 and a gear housing 107 that houses a motion conversion mechanism 113, a striking element 115, and a power transmission unit 117 as a drive mechanism. The handgrip 109 extends in the vertical direction intersecting the major axis direction of the hammer bit 119, and its upper end and lower end are connected to the main body 103, thereby constituting a loop handle (D-shaped handle). ing. A battery mounting portion 109A is formed at the lower end of the handgrip 109, and a rechargeable battery pack 110 serving as a power source for the drive motor 111 is detachably mounted on the battery mounting portion 109A.

  FIG. 2 shows the motion converting portion 113, the striking element 115, and the power transmission portion 117 as an enlarged sectional view. The rotational output of the drive motor 111 is appropriately converted into a linear motion by the motion conversion mechanism 113 and then transmitted to the striking element 115, and the major axis direction of the hammer bit 119 (the left-right direction in FIG. 1) via the striking element 115. Generates an impact force on. The rotation output of the drive motor 111 is appropriately decelerated by the power transmission unit 117 and then transmitted as a rotational force to the hammer bit 119, and the hammer bit 119 is rotated in the circumferential direction. The drive motor 111 is arranged in an intersecting manner on the lower side in the long axis direction of the hammer bit 119 so that the extension line of the axis of the output shaft 112 crosses the long axis (long axis direction) of the hammer bit 119. The drive motor 111 is energized and driven by an operator pulling and operating a trigger 109 a disposed on the handgrip 109.

  The motion conversion mechanism 113 is mainly configured by a drive gear 121, a driven gear 123, an intermediate shaft 125, a rotating body 127, a swing ring 129, and a bottomed cylindrical cylindrical piston 130. The drive gear 121 is provided on the motor output shaft 112 of the drive motor 111 extending in the vertical direction intersecting the long axis direction of the hammer bit 119, and is configured by a small bevel gear that is rotationally driven in a horizontal plane. The driven gear 123 is constituted by a large bevel gear that meshes with and engages with the drive gear 121, and rotates together with the intermediate shaft 125. The rotating body 127 rotates integrally with the intermediate shaft 125, and a swing ring 129 is attached to the outer peripheral surface of the rotating body 127 via a bearing 126 so as to be relatively rotatable. The rocking ring 129 is provided as a rocking member that rocks in the major axis direction of the hammer bit 119 as the rotating body 127 rotates, and is integrally formed above the direction intersecting the major axis direction of the hammer bit 119. The rocking rod 128 is provided in a projecting manner, and the rocking rod 128 is connected to a bottomed tubular cylindrical piston 130 and a cylindrical body 124 so as to be relatively rotatable. The rotating body 127, the swinging ring 129, and the cylindrical piston 130 constitute a swinging mechanism.

  The power transmission unit 117 is engaged with and engaged with a first transmission gear (not shown for convenience) formed on the other end (front end) in the major axis direction of the intermediate shaft 125 and the first transmission gear. The second transmission gear 133 is rotated around the major axis of the tool, and the tool holder 137 rotated around the major axis of the hammer bit 119 together with the second transmission gear 133.

  The striking element 115 is composed mainly of a striker 143 as a striking element slidably disposed on the bore inner wall of the cylindrical piston 130 and an impact bolt 145 as a middle element slidably disposed on the tool holder 137. Is done. The striker 143 is driven via an air spring (pressure fluctuation) of the air chamber 130 a that accompanies the sliding motion of the cylindrical piston 130, collides with (impacts) the impact bolt 145, and the hammer bit 119 passes through the impact bolt 145. The striking force is transmitted to

  In the hammer drill 101 configured as described above, when the drive motor 111 is energized and driven by the pulling operation of the trigger 109a by the user, and the intermediate shaft 125 is rotationally driven, the motion conversion mechanism mainly composed of a swing mechanism. The cylindrical piston 130 is linearly slid in the tool holder 137 via 113, and the striker 143 is caused by the action of the air pressure in the air chamber 130a of the cylindrical piston 130, that is, the action of the air spring. A linear motion is made in the cylindrical piston 130. The striker 143 collides with the impact bolt 145 to transmit the kinetic energy to the hammer bit 119.

  On the other hand, when the first transmission gear is rotated together with the intermediate shaft 125, the tool holder 137 is rotated in the vertical plane via the second transmission gear 133 engaged and engaged with the first transmission gear. The hammer bit 119 held at 137 is rotated integrally. Thus, the hammer bit 119 performs the hammering operation in the axial direction and the drilling operation in the circumferential direction, and performs a drilling operation on the workpiece (concrete).

  The hammer drill 101 according to the present embodiment is a drill that causes the hammer bit 119 to perform only the drill operation in addition to the working mode in the hammer drill mode that causes the hammer bit 119 to perform the hammer operation and the circumferential drill operation. Although it is possible to switch to the mode of operation in the mode, the switching mechanism of this mode is not directly related to the present invention, and therefore the description thereof is omitted.

  Next, a dust collection attachment 150 that is attached to the hammer drill 101 configured as described above and absorbs dust generated during processing on a workpiece (for example, concrete) will be described mainly with reference to FIG. To do. The dust collection attachment 150 corresponds to the “dust collector” in the present invention.

  The dust collection attachment 150 according to the present embodiment is a suction source built-in system in which a dust collection motor 153 and a suction fan 155 as a dust collection power source are built in the attachment body 151, and a specific configuration is omitted for convenience. However, when the hammer drill 101 is moved horizontally from the front to the rear of the main body 103, the attachment main body 151 is detachably mounted on the attachment mounting portion in the lower front area of the main body 103. The attachment main body 151 corresponds to an “attachment portion” in the present invention.

  As shown in FIG. 3, the dust collection attachment 150 is mainly configured by an attachment main body 151, a dust suction unit 161, a dust transfer unit 171, a dust collection container 157, a suction fan 155, and a dust collection motor 153. When the suction fan 155 is rotationally driven by the dust collection motor 153, a suction force acts on the dust suction unit 161 through the dust collection container 157 and the dust transfer unit 171. Dust generated during the processing operation is sucked from the dust suction port 163a of the dust suction unit 161 by the suction force of the dust suction unit 161, and is collected in the dust collecting container 157 through the dust transfer unit 171. The dust suction unit 161 corresponds to the “dust collection unit” in the present invention, the dust transfer unit 171 corresponds to the “dust transfer unit” in the present invention, and the dust collection motor 153 and the suction fan 155 correspond to “ Corresponds to “suction source”.

  The attachment main body 151 has a vertical region extending linearly downward from the rear end of the dust transfer unit 171 and a horizontal region extending rearward from the lower end of the vertical region. The vertical region is provided as a container attachment portion 151A to which the dust collection container 157 is mounted, and the horizontal region is provided as a motor housing portion 151B that houses the dust collection motor 153.

  The dust collection motor 153 is disposed in the motor housing portion 151B with the rotation axis direction parallel to the long axis direction of the hammer bit 119 (the long axis direction of the dust transfer portion), and a suction fan 155 disposed in front of the dust collection motor 153 is provided. A suction force is generated in the dust collecting container 157 by being rotationally driven. This suction force acts on the dust suction unit 161 via the dust transfer unit 171.

  The dust collecting container 157 is formed in a substantially rectangular box shape, and is attached in a state of being in contact with the vertical front surface portion of the container mounting portion 151A in the attachment main body 151 from the front, and the rear lower region of the dust transfer portion 171 Placed in. The dust collecting container 157 has an engagement recess 157a having a substantially semicircular arc shape at the rear end portion on the lower surface side, and a locking claw 157b on the rear surface side on the upper surface side. Then, when the dust collection container 157 is rotated backward in a forward inclined posture with the engagement recess 157a engaged with the circular receiving portion 151b formed at the lower front end of the motor mounting portion 151B in the attachment main body 151, The locking claw 157b is elastically engaged with a locking hole (groove) 171b formed on the dust transfer portion 171 side. Therefore, if the engagement of the locking claw 157b with the locking hole 171b is released, the dust collecting container 157 can be removed from the container mounting portion 151A. That is, the dust collection container 157 is configured to be detachably secured to the container mounting portion 151A. The dust collection container 157 attached to the container attachment portion 151A has a connection port 157c communicating with the internal passage of the dust transfer portion 171. Further, a dust filter 159 is accommodated in the dust collecting container 157 at a position close to the suction fan 155.

  The dust suction part 161 has a suction cylinder part 163 whose front is opened as a dust suction opening 163a, and extends downward from the side surface of the suction cylinder part 163 and intersects the major axis direction of the hammer bit 119. It has a hollow suction body 165 whose end is connected to the dust transfer part 171. The suction cylinder portion 163 covers (surrounds) the bit tip end portion 119a of the hammer bit 119 extending through the rear end wall surface 163b formed at the rear and extending to the front dust suction port 163a at a predetermined interval. It is provided as a dust suction member and is pressed against the workpiece during processing. For example, a rubber cover 167 made of a flexible material through which the hammer bit 119 passes is provided on the inner rear surface side of the suction cylinder portion 163. The rubber cover 167 uses the elastic deflection of the rubber cover 167 to prevent the dust sucked into the suction cylinder portion 163 from leaking outside, and the hammer bit 119 relatively moves in the long axis direction. Allow that. The dust sucked into the suction cylinder portion 163 is transferred to the dust transfer portion 171 through the inside of the suction main body portion 165.

  The dust transfer unit 171 connected to the suction body 165 extends in parallel with the long axis direction of the hammer bit 119 at a position spaced from the hammer bit 119 in a direction intersecting the long axis direction of the hammer bit 119. Yes. When the machining operation is performed on the workpiece by the hammer bit 119 in a state where the suction cylinder portion 163 is pressed against the workpiece together with the hammer bit 119, the work progresses (the hammer bit 119 enters the workpiece). Accordingly, it is necessary that the dust suction portion 161 in which the suction cylinder portion 163 is pressed against the workpiece is retracted relative to the hammer bit 119 toward the main body portion 103 side.

  In order to enable the dust suction unit 161 to move backward, the dust transfer unit 171 is configured as an extendable dust transfer cylinder member extending in parallel with the hammer bit 119. The telescopic dust transfer part 171 is configured by a movable cylinder part 171A and a fixed cylinder part 171B that are fitted so as to be relatively slidable in the major axis direction, and the front end of the movable cylinder part 171A is connected to the suction body part 165. . The fixed cylinder portion 171B is formed as a part of the attachment main body 151. Therefore, the dust suction part 161 is connected to the attachment main body 151 via the dust transfer part 171 so as to be movable in the major axis direction of the hammer bit 119.

  An expandable / contractible bellows-like hose 173 is disposed inside the movable cylinder portion 171A and the fixed cylinder portion 171B, and dust is transferred through the inside of the hose 173. The hose 173 has a front end connected to the rear end of the suction body 165 and a rear end connected to the rear end of the fixed cylinder 171B. The dust transfer unit 171 is moved by the elastic force of the bellows-like hose 173. Usually, it is held in an extended state (initial state). In this way, by adopting a configuration in which the dust is transferred through the hose 173, it is possible to prevent the dust from being caught in the sliding surfaces of the movable cylinder portion 171A and the fixed cylinder portion 171B.

  The suction body 165 is provided with a light unit 175 in the vicinity of the connecting part with the dust transfer part 171, that is, at a position away from the hammer bit 119. The light unit 175 corresponds to the “lighting device” in the present invention. The light unit 175 is mainly composed of an LED light (light emitting diode) as a light source and a light case made of a translucent material (transparent resin, glass, etc.) that accommodates the LED light. The LED light of the light unit 175 is a work position of the work material, that is, a work target position of the work material when the bit tip portion 119a of the hammer bit 119 approaches or comes into contact with the work bit, and The light irradiation direction is set so as to illuminate the bit tip portion 119a abutted against the workpiece. The light unit 175 is disposed in a recess formed in the suction main body 165 so as not to protrude from the front surface of the suction main body 165. For this reason, interference with the workpiece during the machining operation is avoided.

  In the present embodiment, when the trigger 109a is pulled to energize and drive the drive motor 111, the energization drive of the drive motor 111 and the dust collection motor 153 are energized and the LED light of the light unit 175 is turned on. Configured as follows. The trigger 109a corresponds to the “operation member” in the present invention. FIG. 6 is a block diagram showing an electric circuit for controlling the drive motor 111, the dust collection motor 153, and the light unit 175. As shown in the figure, a switch 177 operated by a trigger 109a is connected to a main body side controller 179 that controls the drive motor 111 via a wiring 178, and an attachment side controller 181 that controls the dust collection motor 153 and the light unit 175 is connected to the main body portion. The side controller 179 and the connector 183 are connected by wires 182 and 184. When the switch 177 is switched from the normal OFF state to the ON state by the pulling operation of the trigger 109a by the operator, the main body controller 179 energizes and drives the drive motor 111 based on the ON signal of the switch 177. The side controller 181 is configured to energize and drive the dust collection motor 153 and turn on the LED light of the light unit 175.

  As shown in FIG. 4, the switch 177 includes a motor switch unit 177 </ b> A that controls the drive motor 111 and the dust collection motor 153, and a light switch unit 177 </ b> B that controls the light unit 175. The motor switch unit 177A includes a fixed contact 177Aa and a movable contact 177Ab, and is always maintained in an off (open) state. The light switch unit 177B includes a fixed contact 177Ba and a movable contact 177Bb, and is always maintained in an off (open) state. The switch parts 177A and 177B are configured such that when the trigger 109a is pulled, the movable contacts 177Ab and 177Bb are fixed contacts 177Aa and 177Ba together by the cam member 109b that is linearly pushed backward by the trigger 109a. Is brought into an on (closed) state.

  In the present embodiment, the light switch unit 177B is turned on in the middle of the pulling operation of the trigger 109a, and the motor switch unit 177A is delayed when the trigger 109a is pulled to the maximum. The operation timings of the movable contacts 177Ab and 177Bb by the cam member 109b are varied so as to be turned on. As a result, the operator first turns on the LED light of the light unit 175, confirms the work position of the workpiece and the tip position of the hammer bit pressed against the workpiece, and then energizes the drive motor 111 and the dust collection motor 153. It can be driven to perform machining operations.

  Next, the connector 183 that connects the wiring 182 on the main body side and the wiring 184 on the attachment side will be described. As shown in FIG. 5, in the present embodiment, the connector 183B on the dust collection attachment side is a male connector formed by a protruding member that protrudes horizontally from the rear end surface of the attachment main body 151 toward the rear, The connector 183A on the main body side is a female connector formed by a concave member that is recessed rearward at the front end portion of the main body portion 103 (motor housing 105). When the dust collection attachment 150 is moved horizontally from the front to the rear and assembled to the main body 103, the male connector 183B is simultaneously inserted into the female connector 183A, and the terminals of the wiring 184 on the dust collection attachment side are inserted. 184a is connected to a terminal (not shown for convenience) of the wiring 182 on the main body side.

  The hammer drill 101 according to the present embodiment is configured as described above. When a worker performs a machining operation, when the operator pulls the trigger 109a, the light switch portion 177B of the switch 177 is turned on in advance. Then, the LED light of the light unit 175 is turned on. When the trigger 109a is further pulled to the stroke end, the motor switch 177A is turned on, and the drive motor 111 and the dust collection motor 153 are energized and driven. Therefore, the worker can perform the processing work by the hammer bit 119 after confirming the work position of the bit tip portion 119a of the hammer bit 119 and the workpiece by irradiation of the LED light. Dust generated by the processing operation is sucked into the dust suction part 161 through the dust suction port 163a of the dust suction part 161 of the dust collection attachment 150, and from the dust suction part 161 to the dust collecting container 157 via the dust transfer part 171. Dust is collected.

  As described above, according to the present embodiment, the light unit 175 is provided in the dust collection attachment 150, so that the work position of the workpiece or the position of the hammer bit 119 can be easily confirmed. Usability can be improved. In particular, by arranging the light unit 175 in the dust suction portion 161 located at the forefront of the hammer drill 101, irradiation can be performed at a position closer to the work position of the workpiece and the tip of the hammer bit 119.

  In the present embodiment, the LED light of the light unit 175 is turned on in conjunction with the pulling operation of the trigger 109a, which is the operating member of the drive motor 111. Therefore, the operation of the drive motor 111 and the operation of the light unit 175 are performed. Compared to the configuration in which the above is performed individually, the operation is easier and the usability can be further improved. In particular, in the present embodiment, in addition to the interlocking configuration, the LED light of the light unit 175 is turned on prior to the energization driving of the drive motor 111 and the dust collection motor 153, so the hammer bit 119 is prior to the processing operation. In addition, the work position can be confirmed, and the convenience of work is improved.

  Further, in the present embodiment, the dust suction attachment 150 includes a dust collection motor 153 that is a power source for sucking dust and a dust collection container 157 that stores dust. For this reason, the mobility of the hammer drill 101 which is an advantage of the cordless rechargeable hammer drill 101 is not impaired.

  Further, in the present embodiment, when the dust collection attachment 150 is assembled to the main body portion 103 of the hammer drill 101, the assembling operation, that is, the operation of moving the dust collection attachment 150 linearly toward the main body portion 103 is used. Since the attachment-side wiring 184 and the main-body-side wiring 182 are connected via the connector 183, work for the connection can be easily performed.

Further, the lighting of the LED light of the light unit 175 is necessary prior to the machining operation, and may be unnecessary during the machining operation. For this reason, waste of electrical energy can be eliminated by configuring the LED light to turn off when a predetermined time has elapsed after the start of the machining operation using a timer, for example.
In addition, although this embodiment demonstrated the work tool using a battery as a power supply, it is applicable to the work tool using an external power supply (AC power supply).

(Second embodiment of the present invention)
Next, a second embodiment of the present invention will be described with reference to FIGS. The dust collection attachment 250 according to the present embodiment covers the entire hammer bit 219. In addition to the hammering operation that moves the hammer bit 219 linearly in the major axis direction, the dust collecting attachment 250 is moved around the major axis while linearly moving in the major axis direction. The present invention is applied to an electric hammer drill capable of performing a hammer drill operation for drilling by rotating it.

  FIG. 7 shows a barrel portion 203 constituting the tip region of the main body portion to which the hammer bit 219 is mounted in the overall structure of the hammer drill. As shown in the figure, the hammer bit 219 is detachably attached to the barrel portion 203 via a tool holder 237, and the tool holder 237 allows relative reciprocation in the major axis direction, and in the circumferential direction thereof. Are held in a state where their relative rotation is restricted. The hammer bit 219 is disposed in the tool holder 237 and is struck by an impact bolt 245 that is driven in the long axis direction by a striking element (not shown), and is rotated integrally with the tool holder 237 so that the hammer drill is driven. It is set as the structure which performs work.

  The barrel portion 203 constituting the tip region of the main body portion is provided as a hollow member having a substantially circular cross section for accommodating the tool holder 237. And the dust collection attachment 250 of this embodiment is mounted | worn with the said barrel part 203 so that the chuck | zipper 205 with which the barrel part 203 and the tool holder 237 were mounted | worn may be covered.

  The dust collection attachment 250 of the present embodiment is formed to be able to expand and contract in the major axis direction of the hammer bit 219 and the cylindrical mounting portion 251 made of synthetic resin formed in a substantially conical shape with both ends in the major axis direction opened. And a substantially cylindrical rubber bellows-shaped bit cover portion 253 having both ends in the major axis direction opened.

  The cylindrical attachment portion 251 has a bit cover portion 253 side (front side) as a small diameter cylindrical portion 251a, an opposite side (rear side) as a large diameter cylindrical portion 251b, and an intermediate region gradually toward the small diameter cylindrical portion 251a. A cylindrical member having a tapered cylindrical portion 251c with a reduced diameter. The small-diameter cylindrical portion 251a is provided as a connection region with the bit cover portion 253, and is inserted into the rear end opening of the bit cover portion 253 from behind and connected. In the rear region (right side in FIG. 7) of the large-diameter cylindrical portion 251b, an extended cylindrical portion 251d is formed that is divided in the circumferential direction by a plurality of slits 251e extending in the axial direction and is allowed to elastically deflect in the radial direction. .

  The dust collection attachment 250 covers the barrel portion 203 by moving the cylindrical attachment portion 251 from the front (left side in the figure) to the rear, and in this state, the extended cylindrical portion 251d of the large diameter cylindrical portion 251b is attached to the barrel portion 203. The side grip mounting band 207 is fixed. FIG. 7 shows an attachment band 207 constituting a grip attachment portion of the side grip. The attachment band 207 is disposed so as to wrap around the outer surface of the grip mounting portion 203a formed on the barrel portion 203, and is configured to be tightened or loosened using a screw structure (not shown). That is, the dust collection attachment 250 is fixed to the grip mounting portion 203 a of the barrel portion 203 by tightening the extension cylinder portion 251 d which is a rear region of the large diameter cylinder portion 251 b of the cylindrical attachment portion 251 with the attachment band 207. The cylindrical attachment portion 251 corresponds to the “attachment portion” in the present invention.

  The bit cover portion 253 of the dust collection attachment 250 is disposed so as to cover the hammer bit 219 when the cylindrical attachment portion 251 is attached to the barrel portion 203. The bit cover portion 253 covers the entirety of the hammer bit 219 and forms a passage 255 (space) through which dust passes between the outer surface of the hammer bit 219. The bit cover 253 is configured such that the opening at the tip is set as a dust suction port 257 and the tip of the hammer bit 219 is positioned in the dust suction port 257. Further, the opening on the opposite side of the bit cover portion 253 is detachably fitted to the small diameter cylindrical portion 251a of the cylindrical mounting portion 251. Thereby, the bit cover part 253 is configured to be detachable from the cylindrical attachment part 251. The bit cover part 253 corresponds to the “dust collecting part” in the present invention.

  A hose connection port 259 that communicates with the passage 255 of the bit cover 253 is formed in the small-diameter cylindrical portion 251 a of the cylindrical attachment portion 251. The hose connection port 259 is provided so as to protrude obliquely rearward from the outer surface of the small-diameter cylindrical portion 251a, and is connected by a dust collection hose of a dust collector not shown for convenience and a hose joint 221. The passage 255 and the hose connection port 259 of the bit cover 253 correspond to the “dust transfer part” in the present invention.

  In the dust collection attachment 250 configured as described above, the working position of the workpiece, that is, the bit tip portion of the hammer bit 219 is performed inside the tapered cylindrical portion 251c of the cylindrical mounting portion 251. A light unit 261 with a built-in battery for illuminating the processing target portion of the workpiece and the hammer bit 219 when the 219a approaches or abuts is provided. The light unit 261 includes an LED light (light emitting diode) as a light source, a battery (for example, a button battery) as a power source, a light case 263 that houses the LED light and the battery, and a lighting provided in the light case 263. A push button switch (ON switch) 265a and a push button switch (OFF switch) 265b for turning off are mainly configured. The light unit 261 corresponds to the “lighting device” in the present invention. The light unit 261 is formed of a material (transparent resin, glass, or the like) through which at least the light accommodating portion can transmit light.

  The light unit 261 is disposed at a position close to the small-diameter cylindrical portion 251a and is attached to the tapered cylindrical portion 251c by a set screw 269. The light unit 261 is attached such that the placement surface of the push button switches 265a and 265b is exposed to the outer surface of the cylindrical portion through an opening formed in the tapered cylindrical portion 251c, and the operator can perform a switch operation. Further, when the light unit 261 is attached to the tapered cylindrical portion 251c, the rubber seal 258 comes into contact with the rear surface of the rubber seal 258 inserted from the rear into the rear end opening of the small diameter cylindrical portion 251a, so that the rubber seal 258 is attached. A stopper stopper 267 that prevents the small-diameter cylindrical portion 251a from slipping out is provided. The stopper stopper 267 is provided as a protruding member that protrudes inward from the rear end of the light case. The rubber seal 258 is provided as a member that closes a gap between the inner peripheral surface of the cylindrical mounting portion 251 and the outer peripheral surface of the hammer bit 219.

  The light unit 261 is set so that the LED light is turned on by pressing and operating the lighting push button switch 265a, and the light unit 261 is turned off when, for example, 10 seconds elapses after a predetermined time elapses. When the lighting push button switch 265a is pressed for a long time, the lighting is set to continue, and at this time, the lighting push button switch 265b is set to be turned off by the pressing operation.

  The present embodiment is configured as described above. Accordingly, when a hammer operation or a hammer drill operation is performed using a hammer drill, the lighting push button switch 265a is pushed and the LED light of the light unit 261 is turned on. Thereby, the front is irradiated through the passage 255 of the bit cover 253, and after confirming the working positions of the hammer bit 219 and the workpiece, the hammer drill can be driven to perform the machining operation. Dust generated by the processing operation is sucked through the dust suction port 257 of the bit cover portion 253 of the dust collection attachment 250 by driving the dust collector, and collected in the dust collection container of the dust collector from the passage 255 in the bit cover portion 253 via the dust collection hose. Can be dusty.

  According to the present embodiment, it is possible to easily check the working position of the hammer bit 219 and the workpiece by turning on the LED light of the light unit 261 prior to the hammer drill work, and the usability of the hammer drill can be improved. . In addition, according to the present embodiment, since the LED light of the light unit 261 is turned off after a predetermined time has elapsed after the light is turned on, it is possible to eliminate battery waste. On the other hand, when the lighting push button switch 265a is pressed for a long time, the LED light is continuously lit, so that it can be used for a short time depending on the situation of the work position.

Note that the present invention is not limited to the above-described embodiment, and can be appropriately modified as described below.
For example, in the first embodiment, the dust collection attachment 150 includes the dust collection motor 153 and the dust collection container 157 constituting the suction source. However, the dust collection attachment 150 is changed to a configuration in which the suction source is built in the machine drill side, that is, the hammer drill 101. May be. In addition, the suction source may be changed from the above-described built-in method to a configuration in which a dust collector that exists separately from the work tool is used, that is, the dust collector is connected to the dust collection attachment 150.

In the first embodiment, a motor switch portion 177A and a light switch portion 177B are set for the switch 177 that is turned on and off by operating the trigger 109a, and the cam member is pushed by the trigger 109a. Although it is configured to mechanically turn on and off with a time difference using the straight movement operation of 109b, it is detected that the trigger 109a has moved to the middle position of the pulling operation using a position sensor instead of this configuration, The LED light of the light unit 175 may be turned on based on the detection signal.
In the first embodiment, the LED light may be turned on at the same time without preceding the energization drive of the drive motor 111 and the dust collection motor 153. Similarly, the operation of turning on / off the LED light may be performed separately from the energization driving of the drive motor 111 or the dust collection motor 153.

In the second embodiment, a dust collector is connected to the dust collection attachment 250. However, the dust collection motor 153 and the dust collection container 157 as the suction source described in the first embodiment are connected to the dust collection attachment 250 or the work. You may change into the structure incorporated in a tool.
In the second embodiment, the LED light of the light unit 261 may be changed to a configuration in which the LED light is turned on in conjunction with the energization drive of the drive motor, as in the first embodiment. The lighting can be configured to be performed simultaneously with or in advance of the energization driving of the drive motor.

  By the way, the dust collection attachments 150 and 250 of the first and second embodiments have a dust suction portion for the hammer bits 119 and 219 when the hammer bits 119 and 219 enter the material to be processed. 161 or the bit covering portion 253 is a retractable type that is pushed backward by the work piece, but is different from this, but as a different type, it is a non-stretchable type mainly used for hammering the ceiling surface of a building. There is a dust attachment.

  This non-expandable dust collection attachment is a non-expandable conical cylinder (wrapper) that gradually expands the diameter of the elastic bellows-shaped bit cover 253 of the dust collection attachment 250 in the second embodiment toward the distal end side. The tip portion of the hammer bit protrudes from the tip of the bit cover portion with a predetermined length. By adopting such a configuration, dust collection by the bit cover part is avoided while avoiding the bit cover part interfering with the workpiece (ceiling surface) and hampering the hammer work during hammering work. (Ease of catching) is improved. That is, the non-expandable dust collection attachment is suitably used for an electric hammer in which the hammer bit performs only a striking operation.

  By installing a light unit that illuminates the work position of the workpiece and the hammer bit on the non-expandable dust collection attachment as described above, the work position of the workpiece or the position of the tool bit can be easily confirmed. Thus, the usability of the work tool can be improved.

In view of the gist of the present invention, the following configuration is possible.
(Aspect 1)
“The dust collector includes a dust collector that covers the tip of the bit and sucks dust, and a hollow shape that is connected to the dust collector and extends in parallel with the tool bit at a position away from the tool bit. A working tool, wherein the lighting device is disposed in a connection region between the dust collecting part and the dust transporting part. "

(Aspect 2)
“The dust collector has a stretchable bit cover portion that covers the tool bit, and a cylindrical mounting portion that is connected to the bit cover portion and is attached to the tip region of the tool body, The work tool is arranged inside the cylindrical mounting portion. "

101 Hammer drill (work tool)
103 Main body (work tool main body)
105 Motor housing 107 Gear housing 109 Hand grip 109A Battery mounting portion 109a Trigger (operation member)
109b Cam member 110 Battery pack 111 Drive motor 112 Motor output shaft 113 Motion conversion mechanism 115 Impact element 117 Power transmission unit 119 Hammer bit (tool bit)
119a Bit tip portion 121 Drive gear 123 Driven gear 124 Cylindrical body 125 Intermediate shaft 126 Bearing 127 Rotating body 128 Oscillating rod 129 Oscillating ring 130 Cylindrical piston 130a Air chamber 133 Second transmission gear 137 Tool holder 143 Striker 145 Impact bolt 150 Dust collection attachment (dust collector)
151 Attachment body (Mounting part)
151A Container mounting portion 151B Motor housing portion 151b Circular receiving portion 153 Dust collection motor (suction source)
155 Suction fan (suction source)
157 Dust collection container (suction source)
157a Engaging recess 157b Locking claw 157c Connection port 159 Dust filter 161 Dust suction part (dust collecting part)
163 Suction cylinder part 163a Dust inlet 163b Rear end wall surface 165 Suction body 167 Rubber cover 171 Dust transfer part 171A Movable cylinder part 171B Fixed cylinder part 171b Locking hole 173 Hose 175 Light unit (lighting device)
177 Switch 177A Motor switch portion 177Aa Fixed contact 177Ab Movable contact 177B Write switch portion 177Ba Fixed contact 177Bb Movable contact 178 Wiring 179 Main unit side controller 181 Attachment side controller 182 Wiring 183 Connector 183A Female connector 183B Male connector 184 Wiring 184a Electrical terminal 203 Barrel portion 203a Grip mounting portion 205 Chuck 207 Mounting band 219 Hammer bit 219a Bit tip portion 221 Hose joint 237 Tool holder 245 Impact bolt 250 Dust collecting attachment (dust collecting device)
251 Cylindrical mounting part (mounting part)
251a Small diameter cylindrical portion 251b Large diameter cylindrical portion 251c Tapered cylindrical portion 251d Extended cylindrical portion 251e Slit 253 Bit covering portion (dust collecting portion)
255 passage (dust transfer part)
257 Dust suction port 258 Rubber seal 259 Hose connection port (dust transfer part)
261 Light unit (lighting device)
263 Light case 265a Light-on pushbutton switch 265b Light-off pushbutton switch 267 Retaining stopper 269 Set screw

Claims (5)

A work tool that drives a tool bit attached to the tip region of the work tool body to perform a predetermined machining operation on the workpiece,
An attachment portion that can be attached to the work tool main body, and a long axis direction of at least a bit tip portion of the tool bit attached to the work tool main body when connected to the attachment portion and attached to the work tool main body A dust collection device having a dust collection unit surrounding the dust collection unit and a dust transfer unit configured to transfer the dust collected by the dust collection unit to the downstream side;
The dust collecting device is attached to the work position or the work tool body as a work target position of the work material when the tool bit approaches or comes into contact with the work material to perform a work work. A lighting device for illuminating a predetermined position of the tool bit;
The lighting device is disposed in a recess formed outside a tip end portion of the dust collecting portion . The work tool according to claim 1,
A work tool having a suction source for generating a suction force for sucking dust in the dust collecting portion, and the suction source is provided in the dust collecting device. The work tool according to claim 1 or 2,
A work tool characterized in that when the dust collector is mounted on the work tool body, the wiring of the lighting device is connected to the work tool side wiring. The work tool according to claim 3,
A motor that is housed in the work tool main body and that drives the tool bit; and an operation member that can be operated by an operator for energization driving of the motor, and the operation member is operated in conjunction with the operation of the operation member. A work tool characterized in that the lighting device is turned on. The work tool according to any one of claims 1 to 4,
The lighting device is configured to turn on and off for a predetermined time at the beginning of work.

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