DE112014000651T5 - power tool - Google Patents

Abstract

Task: to provide a power tool improved with respect to a technique for attaching and detaching a battery. Solution: A power tool has a motor (110) that drives a tool bit (119), a tool body (101), a handle (109), and a battery mounting part (160A, 160B) to which a battery (170A, 170B ) is releasably secured on. The power tool has a plurality of battery mounting parts (160A, 160B), and the battery mounting part (160A, 160B) has a battery engagement part (161) to which the battery (170A, 170B) can be engaged. The battery (170A, 170B) is attached to the battery mounting part (160A, 160B) by pushing against the battery engaging part (161) in a crossing direction crossing the longitudinal direction of the tool bit (119).

Description

Field of the invention:

The present invention relates to a power tool that performs a predetermined operation.

Background of the invention:

The disclosed Japanese Patent Application No. 2010-5751 discloses a battery operated hammer drill in which the battery is provided as a power source. In this hammer drill, a battery is attached to a lower surface of a downwardly extending part connecting a tool body and a handle.

Summary of the invention:

Problem to be Solved by the Invention:

The battery used in the battery operated hammer drill is rechargeable, and if remaining battery charge is reduced, it is necessary to remove the battery from the hammer drill and charge the battery and then re-attach the battery.

However, the battery is heavy, and therefore there is room for improvement in battery attaching / detaching operation.

Accordingly, it is an object of the present invention, in view of the above-described problem, to provide a power tool improved with respect to a battery mounting and dismounting technique.

Means of solving the problem:

The aforementioned problem is solved by the present invention. In accordance with a preferred aspect of a power tool of the present invention, a power tool is provided that drives a removably mounted tool bit along a drive axis of the tool bit. The power tool has a motor that drives the tool bit, a tool body that houses the motor, a handle that is connected to the tool body, and a battery mounting part to which a battery for supplying electric power is detachably attached. The power tool has a plurality of battery mounting parts and can provide electrical power to the motor from the battery mounting part attached to the battery. The handle is provided so as to extend in a grip extension direction crossing a drive shaft extension direction in which the drive shaft extends. The battery fixing part has a battery engaging part with which the battery is engageable, and the battery fixing part holds the battery by engaging the battery with the battery engaging part. The battery is slid with respect to the battery engagement part in an intersection direction crossing both the drive shaft extension direction and the grip extension direction, and attached to the battery attachment part. Further, the handle is typically and preferably provided in a predetermined plane including the drive axle so that the handle extends in the handle extension direction crossing the drive axle extension direction.

According to the present invention, the power tool has a plurality of battery mounting parts, and each battery is detachably attached to the respective battery mounting part. Therefore, a degree of freedom in attaching the respective battery is increased. Further, according to the present invention, the battery in the crossing direction, which crosses both the drive shaft extension direction and the grip extension direction, is moved against the battery engagement part and fixed to the battery mounting part. Therefore, in the power tool in which vibration is generated in the drive axis extending direction, a detaching direction of the battery is perpendicular to a vibration direction. As a result, a possibility of dropping the battery from the battery mounting part due to vibration is reduced.

According to another aspect of the power tool of the present invention, a plurality of the battery mounting portions are aligned in the drive axis extending direction.

According to this aspect, a compact arrangement of several batteries is made possible. Accordingly, an arrangement of electrical wiring connected to the battery mounting part is simplified.

According to another aspect of the power tool of the present invention, the battery engaging parts are provided such that the batteries are pushed in relation to the crossing direction from the same side of the tool body and engaged with the battery engaging parts. In other words, the battery is slid against the tool body (the battery mounting part) in the crossing direction crossing both the drive shaft extension direction and the grip extension direction and attached to the battery mounting part. For example, in a case where the grip extension direction is defined as a vertical direction, the parts attached to the respective battery mounting parts attached batteries moved from one of the right side and the left side of the tool body.

According to this aspect, a battery attaching / detaching operation is performed on one side of the tool bit. Accordingly, operability of the operation for attaching / detaching the battery by a user is improved. That is, the attaching / detaching operation can be performed easily.

According to another aspect of the power tool of the present invention, a plurality of the battery mounting parts are arranged with respect to the motor in the drive axis extending direction on a side opposite to the tool bit. In other words, the motor is disposed between a plurality of the battery mounting parts and the tool bit.

According to this aspect, the battery attached to the battery mounting part is located away from the tool bit. Accordingly, when the operation is performed by contacting the tool bit with a workpiece, since the battery is located away from the workpiece, the battery prevents the operation of the tool bit from interfering.

According to another aspect of the power tool of the present invention, when the battery is fixed to the battery mounting part, a lower surface of the battery is formed to terminate with a lower surface of the tool body.

According to this aspect, in addition to the lower surface of the tool body, the lower surface of the battery serves as a contact surface when the power tool is placed on the ground or a floor. Accordingly, the power tool is stably placed.

According to another aspect of the power tool of the present invention, the battery mounting part is formed such that a length of the battery mounted on the battery mounting part is shorter in the drive axis extending direction than a length in the crossing direction.

According to this aspect, the battery is fixed to the battery mounting part such that the length of the battery in the drive axis extending direction is shorter than the length of the battery in the crossing direction. Accordingly, with respect to the drive axis extending direction, the overall length of the power tool to which the battery is mounted is shortened.

According to another aspect of the power tool of the present invention, the battery mounting part has an elastic member that protrudes toward the battery and contacts the battery when the battery is attached to the battery mounting part. Typically, the elastic member is formed as a rubber, a spring or the like and applies an elastic force to the battery.

According to this aspect, the elastic member elastically contacts the battery fixed to the battery mounting part. Accordingly, backlash of the battery due to vibration generated during operation is prevented by a biasing force of the elastic member.

According to another aspect of the power tool of the present invention, the grip is provided such that at least one end side thereof is connected to the tool body in the extending direction, and each battery mounting part is disposed on another end side of the grip in the grip extension direction. The handle preferably further comprises a cantilever handle in which only one end is connected to the tool body, and a loop-shaped handle, wherein both ends are connected to the tool body.

According to this aspect, the battery attached to the battery mounting part is located away from the tool bit. Therefore, when the operation is performed by bringing the tool bit into contact with a workpiece, the battery is disposed away from the workpiece. Accordingly, the battery is prevented from interfering with the operation of the tool bit.

According to another aspect of the power tool of the present invention, the handle has a gripping part held by a user and the gripping part is arranged on a drive axis line. Further, all the battery mounting parts are typically arranged in the grip extension direction on one side on the tool body.

According to this aspect, there is provided a power tool in which the grip part of the grip is disposed on the drive axis line. Thus, by applying a force from a user to the gripping member on the drive axis line to perform the work, the force is linearly transmitted to the tool bit. As a result, the work is performed effectively.

According to another aspect of the power tool of the present invention, the handle has a gripping part with one end side thereof the tool body, and a reinforcing member connecting another end side of the gripping member to the tool body. That is, the reinforcing member is provided separately from the gripping member. Thus, the reinforcing member connects a portion of the tool body, which differs from the connecting portion between the tool body and the gripping member, with another end side of the handle. In such a structure, a plurality of the battery fixing parts are preferably arranged on the reinforcing member.

According to another aspect of the power tool of the present invention, the motor is arranged such that an axis of rotation of the motor intersects the drive axis.

According to this aspect, there is provided a power tool in which the rotation axis of the motor and the drive shaft intersect each other.

According to another aspect of the power tool of the present invention, the motor is arranged such that an axis of rotation of the motor is parallel to the drive axis.

According to this aspect, there is provided a power tool in which the rotation axis of the motor and the drive axis are parallel.

Effects of the invention:

Accordingly, a power tool improved with respect to a battery attaching and detaching technique is provided.

Other objects, features and advantages of the present invention will become more readily apparent upon a consideration of the following detailed description when taken in conjunction with the accompanying drawings and the claims.

Brief description of the drawings:

1 shows a cross section of an entire structure of a hammer drill of a first embodiment according to the present invention.

2 FIG. 10 is an enlarged view showing a fixing state of battery packs attached to battery attaching parts. FIG.

3 shows a view along an arrow A in 1 ,

4 shows a view along an arrow B in 1 ,

5 shows a connection of the battery mounting part.

6 shows a perspective view of the battery pack.

7 shows a plan view of the battery pack.

8th shows a view along an arrow C in 6 ,

9 shows a view along an arrow D in 6 ,

10 shows a schematic view of a hammer drill and an arrangement of the battery packs with respect to the hammer drill a second embodiment according to the present invention.

11 shows a schematic view of a hammer drill and an arrangement of the battery pack with respect to the hammer drill of a third embodiment according to the present invention.

12 shows a schematic view of a hammer drill and an arrangement of the battery pack with respect to the hammer drill a fourth embodiment according to the present invention.

13 shows a schematic view of a hammer drill and an arrangement of the battery pack with respect to the hammer drill a fifth embodiment according to the present invention.

Description of the preferred embodiment:

Each of the additional features and method steps disclosed above and below may be employed separately or in conjunction with other features and method steps to provide improved power tools and a method of using such power tools and apparatus disclosed herein and manufacture. Representative examples of the invention, which may employ many of these additional features and method steps in conjunction with each other, will now be described in detail with reference to the drawings. This detailed description is merely intended to provide further details for practicing preferred aspects of the following teachings to a person skilled in the art and is not intended to limit the scope of the invention. It is the claims alone that define the scope of the present invention. Therefore, combinations of features and steps disclosed in the following detailed description may not be necessary to practice the invention in the broadest sense, and instead are merely taught to avoid the invention to describe in detail representative examples of the invention, the detailed description will now be given with reference to the accompanying drawings.

First Embodiment

A first embodiment of the present invention will be described below with reference to FIG 1 to 9 described. The first embodiment will be explained using a battery powered hammer drill as an example of a power tool. As in 1 shown is an electric hammer drill 100 on which a hammer bit 119 is fixed, the power tool that performs a drilling operation or a chisel operation on a workpiece by causing the attached hammer bit 119 performs a hammering movement in its longitudinal direction and a rotational movement about its longitudinal direction. The hammer bit 119 FIG. 10 is an example of a feature corresponding to a "tool bit" of the present invention.

The hammer drill 100 is in an overall view primarily with a main body 101 provided an outline of the hammer drill 100 forms. At a front area of the main body 101 is the hammer bit 119 via a cylindrical tool holder 159 releasably attached to the same. The hammer bit 119 is in a bit insertion hole of a tool operator 159 introduced and held so that it is in relation to the tool holder 159 can move back and forth in its longitudinal direction and prevents it from being in relation to the tool holder 159 rotates in its circumferential direction.

The main body 101 is primarily with a motor housing 103 that has an electric motor 110 and with a gearbox housing 105 , which is a movement transformation mechanism 120 , a hammer mechanism 140 and a power transmission mechanism 150 receives, provided. A handle 109 Being held by a user is on a hammer bit 119 in the longitudinal direction of the hammer bit 119 opposite side with the main body 101 connected. The main body 101 is an example of a feature corresponding to a "tool body" and the handle 109 is an example of a feature that corresponds to a "handle" of the present invention.

Further, in this embodiment, for clarity, with respect to the longitudinal direction of the hammer bit 119 or a longitudinal direction of the main body 101 the side of the hammer bit 119 as a front side of the hammer drill 100 designated, and the side of the handle 109 is called a back side of the hammer drill 100 designated. In addition, a top page in 1 as an upper side of the hammer drill 100 designated, and a lower side in 1 is considered a lower side of the hammer drill 100 designated.

In the main body 101 are in the longitudinal direction of the hammer bits 119 the gearbox 105 arranged in front and the motor housing 103 arranged at the back. Further, the handle 109 behind the motor housing 103 arranged. The motor housing 103 extends further down than a lower surface of the transmission housing 105 , and the electric motor 110 is located in this extended area. The electric motor 110 is arranged such that an axis of rotation of the electric motor 110 extends so that it is inclined with respect to a vertical direction and a hammer axis extending in the longitudinal direction of the hammer bit 119 extends, crosses. The electric motor 110 is an example of a feature corresponding to a "motor", and the hammers axis is an example of a feature corresponding to a "drive axle" of the present invention.

The hammer drill 100 According to the first embodiment, it is constructed such that the hammer axis of the hammer bit 119 perpendicular to the axis of rotation of the electric motor 110 Hereinafter, the hammer drill having such a structure will be referred to as a first form of hammer drill for the sake of simplicity. Further, the engine case 103 , the gearbox 105 and the handle 109 that the main body 101 form, with respect to the longitudinal direction of the hammer bit 119 each provided by connecting a left and a right housing component together.

A rotary output of the electric motor 110 becomes through the motion conversion mechanism 120 converted into a linear motion and then to the hammer mechanism 140 transferred and effected via the hammer mechanism 140 an impact force in the longitudinal direction of the hammer bit 119 (the lateral direction in 1 ). Furthermore, the rotational output of the electric motor 110 through the power transmission mechanism 150 delayed and then to the hammer bit 119 transferred, and the hammer bit 119 is rotated in its circumferential direction. The electric motor 110 is powered and powered when a pusher 109a that with the handle 109 is arranged, is pressed.

The movement transformation mechanism 120 is above a motor shaft 111 of the electric motor 110 arranged, and the motion conversion mechanism 120 converts the rotational output of the motor shaft 111 in the linear motion in a front-to-back direction of the hammer drill 100 around. The movement transformation mechanism 120 is primarily with an intermediate wave 121 coming from the motor shaft 111 is rotated, one rotating member 123 that at the intermediate shaft 121 is attached, a swivel component 125 that by a rotation of the intermediate shaft 121 (of the rotary member 123 ) in the front-to-rear direction of the hammer drill 100 is pivoted, a cylindrical piston 127 in the form of a drive member, by a pivoting movement of the pivot member 125 in the front-to-back direction of the hammer drill 100 is moved back and forth, and a cylinder 129 that the piston 127 receives, provided. The motor shaft 111 is arranged so that it is in relation to the intermediate shaft 121 is inclined. The cylinder 129 is as a back part of the tool holder 159 integral with the tool holder 159 educated.

The hammer mechanism 140 is above the motion conversion mechanism 120 and behind the tool holder 159 arranged, and the hammer mechanism 140 transmits a linear output in the front-to-back direction of the hammer drill 100 , in which the rotational output of the electric motor 100 from the motion conversion mechanism 120 is converted as a hammering force on the hammer bit 119 , That is, the hammer mechanism 140 is primarily with a striker 143 in the form of a striking element which is displaceable in the cylindrical piston 127 is arranged, and a firing pin 145 that before the impact device 143 is arranged and on the the impact device 143 meets, provided. Furthermore, an interior forms behind the impact device 143 in the piston 127 an air chamber 127a that is a displacement of the piston 127 by an air pressure fluctuation on the impact device 143 transfers.

The power transmission mechanism 150 is before the movement transformation mechanism 120 arranged, and the power transmission mechanism 150 transfers the rotational output of the electric motor 110 that from the intermediate shaft 121 the motion conversion mechanism 120 is transferred to the tool holder 159 , That is, the power transmission mechanism 150 is mainly provided with a transmission deceleration mechanism having a plurality of gears, including a first gear 151 that is integral with the intermediate shaft 121 is rotated, a second gear 153 that with the first gear 151 is engaged and meshes and on the tool holder 159 (the cylinder 129 ) is attached, etc.

The handle 109 is mainly with a gripping part 109A extending in a vertical direction perpendicular to the longitudinal direction of the hammer bit 119 (the hammer axis extension direction) extends provided. The hammer axis extension direction, which is a longitudinal direction of the hammer bit 119 is an example of a feature corresponding to a "drive axis extension direction" of the present invention. Further, the vertical direction is an example of a feature corresponding to a "grip extension direction" of the present invention. The gripping part 109A is with respect to an upper part of the motor housing 103 at a predetermined interval in the longitudinal direction of the hammer bit 119 arranged. An upper part of the gripping part 109A is with an upper connecting part 103a which extends substantially horizontally from a rear upper end portion of the motor housing 103 extends to the rear, connected, and a lower part of the gripping part 109A is with a lower connecting part 103b connected substantially horizontally from an intermediate area in the vertical direction of the motor housing 103 extends to the rear. Further, in the first embodiment, as in FIG 1 shown, the upper connecting part 103a and the lower connecting part 103b from the motor housing 103 and are formed integrally therewith, but these parts may be different from the gripping part 109A extend and be integrally formed therewith.

The lower connecting part 103b of the motor housing 103 extends substantially from the intermediate region in the vertical direction of the motor housing 103 to the rear and has a fastening part 160 on, on the lower surface of battery packs are attached. The fastening part 160 has two battery mounting parts or battery mounting sections 160A . 160B on. Further, respective battery packs 170A . 170B for providing an electric drive current for the electric motor 110 each individually detachable on a battery mounting part 160A . 160B appropriate. The two battery mounting parts 160A . 160B are an example of a feature corresponding to "multiple battery mounting parts" of the present invention and the battery pack 170A . 170B is an example of a feature that corresponds to a "battery" of the present invention. In 1 to 4 are the battery packs 170A . 170B represented by a double-dashed line.

Further, in the lower connection part 103b an interior formed, and a controller 130 for controlling the electric motor 110 is provided in the interior. That is, as in 1 shown is the controller 130 between the battery packs 170A . 170B and the handle 109 arranged. In other words, the controller 130 is horizontally above the battery packs 170A . 170B arranged. Further, as indicated by the double-dashed line in FIG 1 shown the control 130 behind the electric motor 110 between the battery packs 170A . 170B and the electric motor 110 be arranged.

The 6 to 9 show the details of the battery pack 170A . 170B (the 6 to 9 show a battery pack). The battery pack 170A . 170B is mainly with a substantially rectangular cuboid battery case 171 and a plurality of battery cells (not shown) housed in the battery case 171 are included, provided. The battery pack 170A . 170B becomes detachable on the respective battery mounting part 160A . 160B attached by placing it horizontally along a lower surface of the respective battery mounting part 160A . 160B in a lateral direction, both the longitudinal direction of the hammer bit 119 as well as the extension direction of the handle 109 crosses, is postponed. Further, each of the two battery packs 170A . 170B the same structure (same configuration) and is on both of two battery mounting parts 160A . 160B mountable.

To push the battery pack 170A . 170B against the battery mounting part 160A . 160B each is one of a pair of mounting guides 173 extending in a longitudinal direction of the battery pack 170A . 170B extend on a respective side surface of an upper surface of the battery case 171 intended. There is also a catch 175 to lock and a push button 177 provided for unlocking at a middle part on the top. The hook 175 for locking is with respect to a mounting direction of the battery pack 170A . 170B (A thrust direction when attached) provided at a rear part and biased by a spring (not shown) so that it from an upper surface of the battery case 171 protrudes. The push button 177 for unlocking is with respect to the mounting direction of the battery case 171 (a thrust direction) when attached to a rear part. Further, the push button is 171 mechanically so with the hook 175 Connected that when a user presses the button 177 presses, the hook 175 is moved in one direction in which the hook 175 from the upper surface of the battery case 171 is pulled down.

On the other hand, as in 1 and 2 shown in every battery mounting part 160A . 160B a pair of front and rear guide rails 161 provided, each in a lateral direction, which is the longitudinal direction of the hammer bits 119 (the hammer axis) crosses, extending so that the battery pack 170A . 170B from one side of the hammer drill 100 can be attached from. The guide rails 161 form a substantially U-shaped section in the lateral direction, and the mounting guide 173 of the battery pack 170A . 170B will be against the guide rails 161 pushed and introduced into this. That is, the guide rail 161 has a function as a guide means when the battery pack 160A . 160B on the battery mounting part 160A . 160B is attached, and a function as a means for preventing a fall, so that the battery pack is prevented 170A . 170B from the battery mounting part 160A . 160B falls down, up. The guide rail 161 FIG. 10 is an example of a feature corresponding to a "battery engagement part" of the present invention.

Furthermore, as in 4 shown, each battery attachment part 160A . 160B a recess engaging part 163 on, with that the hook 175 of the battery pack 170A . 170B can engage. The engaging part 163 is on a battery insertion side between the front and rear guide rails 161 arranged. Accordingly, if the battery pack 170A . 170B on the battery mounting part 160A . 160B is attached, the engaging part 163 engaged with the hook 173 , Therefore, the battery pack 170A . 170B on the battery mounting part 160A . 160B fixed, and a movement in a direction of solution (in a direction opposite to the direction of thrust when mounting) or falling of the battery pack 170A . 170B will be prevented. Furthermore, when attaching the battery pack 170A . 170B on the battery mounting part 160A . 160B a bevelled part of the hook 173 from the engaging part 163 pressed and moved down, and then comes the hook 173 in engagement with the engagement part 163 by moving back to its starting position.

Each on the respective battery mounting part 160A . 160B attached battery pack 170A . 170B is held such that an outer surface excluding an upper surface as a fastening surface attached to the battery mounting portion 160A . 160B is attached, exposed. Further, a lower surface of the battery pack 170A . 170B arranged so that it is connected to a lower surface of the motor housing 103 concludes. With such a structure, the bottom surfaces of the battery pack are 170A . 170B and the motor housing 103 is formed as a placement surface, and thereby the hammer drill 100 Stable placed on the ground or on a floor.

As previously described, the battery pack is 170A . 170B behind the electric motor 110 and below the handle 109 arranged so that the longitudinal direction of the battery pack 170A . 170B parallel to a crossing direction, which is both the longitudinal direction of the hammer bit 119 as well as the hand grip extension direction crosses. Two battery packs 170A . 170B are in the front-to-back direction (longitudinal direction of the hammer bit 119 ) arranged side by side. That is, the battery pack 170A . 170B is so on the battery mounting part 160A . 160B attached, its length in the longitudinal direction of the hammer bit 119 shorter than its length in one direction, which is the longitudinal direction of the hammer bit 119 crosses.

Further, in the first embodiment, with respect to the two battery packs 170A . 170B when viewed from the back of the hammer drill 100 be considered from an attachment direction of the battery pack 170A . 170B by a moving direction (pushing direction) from a left side to a right side of the hammer drill 100 (a direction in 3 and 4 indicated by an arrow F) while a solution direction of the battery pack 170A . 170B is defined by an opposite direction of movement. That is, in the first embodiment, the attaching / detaching direction of the battery pack is 170A and the attaching / detaching direction of the battery pack 170B the same direction. Further, in a modified example, the attaching / detaching direction of a battery pack 170A and another battery pack 170B be defined so that they are different directions. When looking from the back of the hammer drill 100 out can be a battery pack 170A from the right side of the hammer drill 100 from being attached, and another battery pack 170B can be from the left side of the hammer drill 100 be attached from.

Further, when the battery packs 170A . 170B on the battery mounting parts 160A . 160B be attached, respective connections 179 (please refer 6 and 7 ) of the battery packs 170A . 170B electrically with a respective connection 165 connected to a lower surface of each battery mounting part 160A . 160B is formed (see 5 ), and therefore will allow the electric motor 110 and the controller 130 electric current can be supplied.

Furthermore, as in 3 shown on the lower surface of the battery mounting part 160A . 160B four cylindrical rubber pins 167 provided so that each of them is disposed at respective corners of a virtual rectangle. These four rubber pins 167 project downward by a predetermined length and tighten four points on an upper surface of the battery pack 170A . 170B attached to the battery mounting part 160A . 160B is attached, elastic down in front. With such a construction, a wobble of the battery pack 170A . 170B be prevented due to vibration. The rubber stick 167 is an example of a feature corresponding to an "elastic member" of the present invention. In addition, the rubber stick 167 have a shape other than a cylindrical, and alternatively, a spring member such as a leaf spring or the like instead of the rubber pin 167 be used.

As described above, according to the first embodiment, the battery mounting parts 160A . 160B at two parts front and rear at the lower connecting part 103b of the motor housing 103 provided, and every battery pack 170A . 170B is detachable on the respective battery mounting part 160A . 160B attached. Therefore, for example, in the hammer drill 100 with a specification of 36 V two 18 V battery packs 170A . 170B attached and electrically connected in series. The 18V battery pack is much lighter compared to a 36V battery pack. Accordingly, a user can easily exchange the battery pack 170A . 170B or attaching / detaching the battery pack 170A . 170B to / from the battery mounting part 160A . 160B carry out. As a result, handleability in attaching / detaching the battery pack becomes 170A . 170B improved. Furthermore, in the hammer drill 100 with a specification of 18 V two battery packs 170A . 170B electrically connected in parallel with 18 V each. In such a case, a long term driving of the hammer drill becomes 100 allows. Furthermore, in the hammer drill 100 with a specification of 36 V / 18 V a connection mode of battery packs 170A . 170B be switched between a series mode and a parallel mode. In such a case, a switch may be preferably provided which is operated by a user to switch the connection mode.

In addition, the battery pack points 170A . 170B generally a shape of a substantially rectangular cuboid. According to the first embodiment, the 18 V battery packs 170A . 170B aligned in the front-rear direction and so on the lower connecting part 103b of the motor housing 103 arranged that their longitudinal directions perpendicular to the longitudinal direction of the hammer bit 119 are. That is, when the battery packs 170A . 170B on the battery mounting parts 160A . 160B attached, is every battery pack 170A . 170B arranged such that its length in the longitudinal direction of the hammer bit 119 shorter than its length in a direction crossing the longitudinal direction. With such a structure, a length of a space for arranging the battery packs becomes 170A . 170B in the longitudinal direction of the hammer bit 119 compared to a design where the longitudinal direction of the battery packs 170A . 170B parallel to the longitudinal direction of the hammer bit 119 is shortened. Accordingly, a compact hammer drill 100 obtained in which the length is shortened in the front-to-rear direction.

Further, according to the first embodiment, the battery pack 170A . 170B by insertion into the battery mounting part 160A . 160B from the side of the hammer drill 100 from on the battery mounting part 160A . 160B attached. Therefore, the battery pack crosses 170A . 170B the solution direction of the battery pack 170A . 170B the hammer axis of the hammer bit 119 or a direction of vibration caused by the hammer movement of the Hammer bits 119 is produced. Accordingly, the solution direction of the battery pack is correct 170A . 170B not with the vibration direction of the hammer drill 100 match, and the possibility that the battery pack 170A . 170B due to the vibration of the hammer drill 100 falls, is reduced.

Further, according to the first embodiment, the battery pack 170A . 170B by pushing the fixing guide 173 of the battery pack 170A . 170B along the guide rail 161 of the battery mounting part 160A . 160B on the battery mounting part 160A . 160B attached. Accordingly, the battery pack 170A . 170B be easily attached.

Further, according to the first embodiment, the battery pack 170A . 170B behind the motor housing 103 and below the handle 109 arranged. At the first form of the hammer drill 100 is due to a structural property, according to which is an area of the motor housing 103 that the electric motor 110 extends downwards, behind the downwardly extending area provided a free space extending below the handle 109 located. Therefore, as the battery packs 170A . 170B By using this free space to be arranged, the battery packs 170A . 170B arranged efficiently. Further, such a position of the battery packs 170A . 170B from a working point of the hammer bit 119 removed, and therefore disrupt the battery packs 170A . 170B the work operation is not.

Further, according to the first embodiment, the battery packs 170A . 170B behind the motor housing 103 and below the handle 109 arranged, and the bottom surface of the battery packs 170A . 170B is designed to fit with the bottom surface of the motor housing 103 concludes. If therefore the hammer drill 100 placed on the earth or the ground becomes the hammer drill 100 stably placed. Further, in the first embodiment, the hammer axis of the hammer bit 119 and the axis of rotation of the electric motor 110 inclined to each other, but not limited thereto. For example, the electric motor 110 be arranged such that the hammer axis of the hammer bit 119 and the axis of rotation of the electric motor 110 cut at an angle of 90 degrees.

Second Embodiment

Next, referring to 10 a second embodiment explained. As in 10 is shown in the second embodiment of the electric motor 110 arranged such that the axis of rotation of the electric motor 110 parallel to the hammer axis of the hammer bit. In addition to this is the gripping part 109A of the handle 109 arranged on the line of the hammer axis. The hammer drill 100 according to the second embodiment is referred to as a second form of hammer drill for the sake of simplicity. The handle 109 extends from a rear upper end portion of the motor housing 103 down and crosses the longitudinal direction of the hammer bit 119 , An extreme end of the gripping part 109A and a rear lower end portion of the motor housing 103 are for reinforcing the handle, which extends so that it is inclined to a top-bottom direction (vertical direction), by a support member 107 connected. That is, the handle 109 has a gripping part 109A and the support member 107 on. The supporting component 107 is an example of a feature that corresponds to a "reinforcing member" of the present invention. A rotation of the electric motor 110 becomes through the motion conversion mechanism 120 converted into a linear motion and then via the hammer mechanism 140 as an impact force on that of the tool holder 159 held hammer bit 119 transfer. Further, the rotation of the electric motor 110 via the power transmission mechanism 150 as a rotational movement on that of the tool holder 159 held hammer bit 119 transfer.

In the second form of the above-described hammer drill 100 are two battery mounting parts 160A . 160B in the longitudinal direction of the hammer bit 119 on the lower surface of the extreme end of the gripping part 109A and the support member 107 provided and aligned. Furthermore, every battery pack is 170A . 170B detachable on the respective fastening part 160A . 160B attached. The battery pack 170A . 170B by inserting (pushing) into the battery mounting part 160A . 160B in a direction that the longitudinal direction of the hammer bit 119 cruises, from the side of the hammer drill 100 from on the battery mounting part 160A . 160B attached. Thus, according to the second embodiment, in the second form of hammer drill 100 obtained a similar advantage as in the first embodiment.

Third Embodiment

Next, referring to 11 a third embodiment explained. According to the third embodiment, in the second form of the hammer drill 100 two battery mounting parts 160A . 160B in the longitudinal direction of the hammer bit 119 so provided and aligned that they extend over both lower surfaces of the motor housing 103 and the transmission housing 105 extend. Furthermore, every battery pack is 170A . 170B detachable on the respective battery attachment part 160A . 160B attached. The battery pack 170A . 170B by inserting (pushing) into the battery mounting part 160A . 160B , in one direction, the longitudinal direction of the hammer bits 119 cruises, from the side of the hammer drill 100 from on the battery mounting part 160A . 160B attached. Thus, according to the third embodiment, in the second form of the hammer drill 100 obtained a similar advantage as in the first embodiment.

Fourth Embodiment

Next, referring to 12 a fourth embodiment explained. As in 12 is shown in the fourth embodiment of the gripping part 109A of the handle 109 provided so that it extends from a lower portion of the rear end portion of the motor housing 103 extends downwards and the longitudinal direction of the hammer bit 119 crosses. The hammer drill 100 according to the fourth embodiment is referred to as a third form of hammer drill for the sake of simplicity.

In the third form of the above-described hammer drill 100 are two battery mounting parts 160A . 160b in the longitudinal direction of the hammer bit 119 on the bottom surface of the handle 109 acting as the extremity (the free end) of the handle 109 is formed, provided and aligned. Furthermore, every battery pack is 170A . 170B detachable on the respective battery attachment part 160A . 160B attached. The battery pack 170A . 170B by inserting (pushing) into the battery mounting part 160A . 160B in one direction, which is the longitudinal direction of the hammer bit 119 cruises, from the side of the hammer drill 100 from on the battery mounting part 160A . 160B attached. Thus, according to the fourth embodiment, in the third form of the hammer drill 100 obtained a similar advantage as in the first embodiment.

Fifth Embodiment

Next, referring to 13 a fifth embodiment explained. As in 13 5, in the fifth embodiment, in addition to the third form of the hammer drill described above, the extreme end of the gripping member 109A and a lower portion of a front end portion of the motor housing 103 to reinforce the handle by the support member 107 which extends so as to be inclined to an upper-lower direction (vertical direction). That is, the handle 109 has the gripping part 109A and the support member 107 on. The hammer drill 100 according to the fifth embodiment is referred to as a fourth form of hammer drill for the sake of simplicity. The supporting component 107 is an example of a feature that corresponds to a "reinforcing member" of the present invention.

In the fourth form of the hammer drill 100 are two battery mounting parts 160A . 160B in the vertical direction at a portion of a front surface of the support member 107 (on the support member 107 ) provided and aligned. Furthermore, every battery pack is 170A . 170B detachable on the respective battery attachment part 160A . 160B attached. The battery pack 170A . 170B by inserting (pushing) into the battery mounting part 160A . 160B in one direction, which is the longitudinal direction of the hammer bit 119 crosses, from one side of the hammer drill 100 from on the battery mounting part 160A . 160B attached. Thus, according to the fifth embodiment, in the fourth form of the hammer drill 100 obtained a similar advantage as in the first embodiment.

Further, the following modified examples other than the first to fifth embodiments may be provided, but for the sake of convenience, illustrations thereof are omitted.

(First modified example)

At the first form of the hammer drill 100 may be the lower surface of the lower connecting part 103b that the engine case 103 and the handle 109 connects, be formed so that they are connected to the lower surface of the motor housing 103 completes, and two battery mounting parts 160A . 160B can on the bottom surface of the motor housing 103 and / or the lower connecting part 103b provided and in the longitudinal direction of the hammer bits 119 be aligned. Furthermore, every battery pack 170A . 170B detachable on the respective battery attachment part 160A . 160B attached. The battery pack 170A . 170B is introduced by introducing ( Push) into the battery mounting part 160A . 160B in one direction, which is the longitudinal direction of the hammer bit 119 cruises, from the side of the hammer drill 100 from on the battery mounting part 160A . 160B attached.

(Second modified example)

At the second form of the hammer drill 100 can be a battery mounting part 160A on the lower surface of the lower connecting part 103b that the engine case 103 and the handle 109 connects, be provided, and another battery mounting part 160B can be provided so that it extends over both lower surface of the motor housing 103 and the gearbox 105 extends. The bottom surfaces of the motor housing 103 and the transmission housing 105 are designed to lock together. With such a structure, two battery mounting parts 160A . 160B provided away from each other. Furthermore, every battery pack 170A . 170B detachable on the respective battery attachment part 160A . 160B attached. The battery pack 170A . 170B by inserting (pushing) into the battery mounting part 160A . 160B in one direction, which is the longitudinal direction of the hammer bit 119 cruises, from the side of the hammer drill 100 from on the battery mounting part 160A . 160B attached.

(Third modified example)

At the second form of the hammer drill 100 can be a battery mounting part 160A on the lower surface of the gripping part 109A and the support member 107 be provided, and another battery mounting part 160B can on the upper surface of the gripping part 109A be provided. That is, two battery mounting parts 160A . 160B are provided away from each other. Furthermore, every battery pack 160A . 160B detachable on the respective battery attachment part 160A . 160B attached. The battery pack 170A . 170B by inserting (pushing) into the battery mounting part 160A . 160B in one direction, which is the longitudinal direction of the hammer bit 119 cruises, from the side of the hammer drill 100 from on the battery mounting part 160A . 160B attached.

(Fourth Modified Example)

In the third form of the hammer drill 100 can be a battery mounting part 160A on the bottom surface of the handle 109 acting as the extreme end (free end) of the handle 109 is formed, be provided, and another battery mounting part 160B may be provided so that it extends over both lower surfaces of the motor housing 103 and the transmission housing 105 extends. That is, two battery mounting parts 160A . 160B are provided away from each other. Furthermore, every battery pack 170A . 170B detachable on the respective battery attachment part 160A . 160B attached. The battery pack 170A . 170B by inserting (pushing) into the battery mounting part 160A . 160B in one direction, which is the longitudinal direction of the hammer bit 119 cruises, from the side of the hammer drill 100 off to the battery mounting part 160A . 160B attached.

(Fifth Modified Example)

In the third form of the hammer drill 100 can have two battery mounting parts 160A . 160B on the upper surface of the rear portion of the motor housing 103 provided and in the longitudinal direction of the hammer bits 119 be aligned. Furthermore, every battery pack 170A . 170B detachable on the respective battery attachment part 160A . 160B attached. The battery pack 170A . 170B by inserting (pushing) into the battery mounting part 160A . 160B in one direction, which is the longitudinal direction of the hammer bit 119 cruises, from the side of the hammer drill 100 from on the battery mounting part 160A . 160B attached.

(Sixth Modified Example)

In the fourth form of the hammer drill 100 can have two battery mounting parts 160A . 160B at the extreme end of the handle 109 (on the bottom surface of the handle 109 ) and in the longitudinal direction of the hammer bit 119 be aligned. Furthermore, every battery pack 170A . 170B detachable on the respective battery attachment part 160A . 160B attached. The battery pack 170A . 170B by inserting (pushing) into the battery mounting part 160A . 160B in one direction, which is the longitudinal direction of the hammer bit 119 cruises, from the side of the hammer drill 100 from on the battery mounting part 160A . 160B attached.

(Seventh modified example)

In the fourth form of the hammer drill 100 can be a battery mounting part 160A on the bottom surface of the handle 109 be provided, and another battery mounting part 160B Can be on the front surface of the supporting component 107 be provided. That is, two battery mounting parts 160A . 160B are provided away from each other. Furthermore, every battery pack 170A . 170B detachable on the respective battery attachment part 160A . 160B attached. The battery pack 170A . 170B by inserting (pushing) into the battery mounting part 160A . 160B in a direction crossing the longitudinal direction of the hammer bit, from the side of the hammer drill 100 from on the battery mounting part 160A . 160B attached.

(Eighth Modified Example)

In the fourth form of the hammer drill 100 can have two battery mounting parts 160A . 160B on the lower surface of the gearbox 105 provided and in the longitudinal direction (front-to-back direction) of the hammer bit 119 be aligned. Furthermore, every battery pack 170A . 170B detachable on the respective battery attachment part 160A . 160B attached. The battery pack 170A . 170B by inserting (pushing) into the battery mounting part 160A . 160B in one direction, which is the longitudinal direction of the hammer bit 119 cruises, from the side of the hammer drill 100 from on the battery mounting part 160A . 160B attached.

Moreover, in the first to fifth embodiments described above, the attachment part is 160 on the main body 101 or the handle 109 attached, but not limited to. For example, the fastening part 160 on the main body 101 or the handle 109 attachable or detachable from this. Furthermore, can the battery pack be attached via a predetermined adapter to an area of which the fastening part 160 has been removed. Further, in the first to fifth embodiments, two battery mounting parts 160A . 160B provided, however, it can be provided more than three battery mounting parts.

Further, in the first to fifth embodiments described above, the hammer drill became 100 where the hammer bit 119 however, it is not limited to this as an exemplary power tool for explanation. For example, the present invention can be applied to a hammer tool as the power tool that merely performs the hammering operation. In addition, the present invention can be applied to a cordless screwdriver, a cordless impact wrench, a cordless sander, a cordless reciprocating saw, or a cordless jigsaw as the power tool.

In view of one aspect of the present invention, the following features are provided as the power tool according to the present invention. Furthermore, each feature may be used independently or in conjunction with one or more other features or claimed inventions.

(Characteristic 1)

A power tool that drives a removably mounted tool bit along a drive axis of the tool bit, comprising:
a motor that drives the tool bit.
a tool body that picks up the engine,
a handle which is connected to the tool body, and
a plurality of battery mounting parts to which a battery for releasing electric power to the motor is detachably attached,
wherein the power tool is configured to be capable of providing electric power to the engine from a plurality of the batteries attached to the plurality of battery mounting parts;
the handle is provided in a predetermined plane including the drive axle so that the handle extends in a finger extension direction crossing a drive axle extension direction in which the drive axle extends;
each battery fixing part has a battery engaging part with which the battery is engageable and holds the battery by engaging with the battery engaging part and
the battery is pushed in the direction of a normal direction of the predetermined plane against the battery engaging part and fixed to the battery mounting part.

(Characteristic 2)

The battery engaging part has a guide rail on which the battery is engaged and pushed.

(Characteristic 3)

The guide rail of the battery engagement part is provided so as to extend in a direction crossing both the drive axis extension direction and the finger extension direction.

(Characteristic 4)

The tool body has a lower surface of the tool body which is formed to close to a lower surface of the battery when the battery is mounted to the battery mounting part.

(Characteristic 5)

Several of the battery mounting parts are electrically connected to each other so that the attached batteries are electrically connected in series.

(Characteristic 6)

Several of the battery mounting parts are electrically connected to each other so that the attached batteries are electrically connected in series.

(Characteristic 7)

A plurality of the battery mounting parts are electrically connected to each other so that a first connection mode in which the attached batteries are electrically connected in series and a second connection mode in which the attached batteries are electrically connected in parallel can be switched.

(Correspondence relationships between the constituents of the present embodiments and the constituents of the present invention)

The correspondence relationships between elements of the embodiments and elements of the present invention are as follows. Moreover, the embodiments merely give examples of configurations for carrying out the present invention, and the present invention is not limited to the configurations of the embodiments.

The main body 101 FIG. 12 is an example of a configuration corresponding to a "tool body" of the present invention.

The hammer bit 119 FIG. 12 is an example of a configuration corresponding to a "tool bit" of the present invention.

The electric motor 110 is an example of a configuration that corresponds to a "motor" of the present invention.

Two battery mounting parts 160A . 160B FIG. 15 is an example of a configuration corresponding to "multiple battery mounting parts" of the present invention.

The battery mounting part 160A . 160B FIG. 14 is an example of a configuration corresponding to a "battery mounting part" of the present invention.

The battery mounting part 160B FIG. 14 is an example of a configuration corresponding to a "battery mounting part" of the present invention.

The battery pack 170A FIG. 10 is an example of a configuration corresponding to a "battery" of the present invention.

The battery pack 170B FIG. 10 is an example of a configuration corresponding to a "battery" of the present invention.

The guide rail 161 FIG. 10 is an example of a configuration corresponding to a "battery engagement part" of the present invention.

The engaging part 163 FIG. 10 is an example of a configuration corresponding to a "battery engagement part" of the present invention.

The rubber stick 167 is an example of a configuration corresponding to an "elastic member" of the present invention.

The supporting component 107 FIG. 12 is an example of a configuration corresponding to a "reinforcing member" of the present invention.

LIST OF REFERENCE NUMBERS

100

Rotary Hammer

101

main body

103

motor housing

103a

upper connecting part

103b

lower connection part

105

gearbox

107

support member

109

handle

109A

gripping part

109a

handle

110

electric motor

111

motor shaft

119

Hammer-bit

120

Motion conversion mechanism

121

intermediate shaft

123

rotating member

125

pivotal member

127

cylindrical piston

127a

air chamber

129

cylinder

130

control

140

Hammers mechanism

143

impact device

145

firing pin

150

Power transmission mechanism

151

first gear

153

second gear

159

toolholder

160

attachment portion

160A

Battery attachment part

160B

Battery attachment part

161

guide rail

163

engaging part

165

connection

167

rubber pen

170A

battery Pack

170B

battery Pack

171

battery case

173

fastening guide

175

locking hook

177

Entriegelungsdruckknopf

179

connection

Claims (14)

A power tool that drives a removably mounted tool bit along a drive axis of the tool bit, comprising: a motor that drives the tool bit, a tool body that receives the motor, a handle that is connected to the tool body, and a A battery mounting part to which a battery for releasing electric power is detachably attached, wherein the power tool has a plurality of the battery mounting parts and can provide electric power from the battery mounting part attached to the battery for the motor, the handle being provided so as to be in one A grip extension direction which crosses a drive shaft extension direction in which the drive shaft extends, the battery attachment part extends a battery engagement part to which the battery is engageable; and the battery mounting part holds the battery by engaging the battery with the battery engaging part and slides the battery in an intersection direction crossing both the drive shaft extension direction and the finger extension direction with respect to the battery engagement part and attaches to the battery mounting part. A power tool according to claim 1, wherein a plurality of said battery mounting portions are aligned in the drive axis extending direction. A power tool according to claim 1 or 2, wherein the battery engaging parts are provided such that the batteries are slid in relation to the crossing direction from the same side of the tool body and engaged with the battery engaging parts. A power tool according to any one of claims 1 to 3, wherein a plurality of the battery mounting parts are arranged with respect to the motor in the drive axis extending direction on a side opposite to the tool bit. A power tool according to any one of claims 1 to 14, wherein when the battery is attached to the battery mounting part, a bottom surface of the battery is flush with a bottom surface of the tool body. A power tool according to any one of claims 1 to 5, wherein the battery mounting part is formed such that a length of the battery mounting part attached to the battery in the drive axis extension direction is shorter than a length of the battery in the crossing direction. A power tool according to any one of claims 1 to 6, wherein the battery mounting part comprises an elastic member that protrudes toward the battery and contacts the battery when the battery is attached to the battery mounting part. A power tool according to any one of claims 1 to 7, wherein the handle is provided such that at least one end side thereof is connected to the tool body in the finger extension direction, and a plurality of the battery mounting pieces are arranged on another end side of the handle in the finger extension direction. Power tool according to claim 8, wherein the handle has a gripping part, which is held by a user, and the gripping part is arranged on a drive axis line. A power tool according to claim 9, wherein a plurality of the battery mounting parts are provided with respect to the finger extension direction on one side on the tool body. A power tool according to claim 8, wherein the handle has a gripping part with one end side thereof connected to the tool body, and a reinforcing member connecting another end side of the gripping part with the tool body. A power tool according to claim 11, wherein a plurality of the battery mounting parts are arranged on the reinforcing member. Power tool according to one of claims 1 to 12, wherein the motor is arranged such that an axis of rotation of the motor cuts the drive axis. Power tool according to one of claims 1 to 12, wherein the motor is arranged such that an axis of rotation of the motor is parallel to the drive axis.

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