Patent Grant
10022852
The present application claims priority from Japanese Patent Applications No. 2014-102791 filed on May 16, 2014, the entire contents of which are incorporated by reference herein.
The present invention relates to an impact tool which performs a predetermined operation.
Japanese non-examined laid-open Patent Publication No. 2010-052115 discloses an impact tool which drives a tool bit linearly in its longitudinal direction by a swing member. The impact tool has a dynamic vibration reducer for reducing vibration generated during an operation.
In the impact tool described above, since a user holds a handle and operates the impact tool during the operation, vibration generated during the operation is transmitted to the user. In this respect, less vibration transmission to the user is preferable for ensuring usability. Thus, regarding vibration reducing technique of the impact tool, further improvement is desired.
Accordingly, an object of the present disclosure is, in consideration of the above described problem, to provide an improved vibration reduction technique for an impact tool.
Above-mentioned problem is solved by the present invention. According to a preferable aspect of the present disclosure, an impact tool which drives an elongate tool bit in a longitudinal direction of the tool bit and performs a predetermined operation is provided. The impact tool comprises a motor which includes a motor shaft, a driving mechanism which is driven by the motor and drives the tool bit, and a main housing which houses the driving mechanism. The main housing may house not only the driving but also the motor. The impact tool comprises a first crank mechanism which has a first rotation shaft and a first eccentric shaft which is offset from the rotational center of the first rotation shaft. The first crank mechanism is configured to be driven by the motor and drive the driving mechanism. That is, the first crank mechanism for driving the tool bit via the driving mechanism is provided.
Further, the impact tool comprises a handle which includes a grip portion extending in a cross direction crossing the longitudinal direction of the tool bit, and a biasing member which is arranged between the main housing and the handle and applies biasing force on the handle. The handle is configured to be moved with respect to the main housing. Thus, the handle is configured to prevent vibration transmission from the main housing to the handle during the operation by relatively moving with respect to the main housing in a state that the biasing force of the biasing member is applied on the handle. That is, the handle is formed as a vibration proof handle which prevents vibration transmission from the main housing by utilizing elastic deformation of the biasing member.
Further, the impact tool comprises a weight which is housed in the main housing and movable with respect to the main housing, and a second crank mechanism which has a second rotation shaft and a second eccentric shaft which is offset from the rotational center of the second rotation shaft. The second crank member is configured to be driven by the motor and drive the weight such that the weight is relatively moved with respect to the main housing. That is, the second crank mechanism for driving the weight is provided. The second crank mechanism may be connected to the motor shaft and driven by the motor or connected to the first crank mechanism and driven by the motor via the first crank mechanism.
According to this aspect, the weight reduces vibration generated on the main housing during the operation and the handle prevents the vibration from being transmitted to the handle from the main housing by relatively moving against the main housing in a state that the biasing member biases the handle. In other words, the impact tool has two kinds of vibration reduction mechanisms. Accordingly, vibration on the grip portion held by a user is reduced during the operation. As a result, usability of the impact tool is improved.
According to a further preferable aspect of the present disclosure, the impact tool comprises an intervening member which is arranged between the weight and the second eccentric shaft. The weight is driven by the second crank mechanism via the intervening member. In a construction in which the intervening member is provided by an elastic member, the weight and the elastic member serve as a dynamic vibration reducer. The weight of the dynamic vibration reducer is forcibly driven by the second crank mechanism.
According to a further preferable aspect of the present disclosure, a moving amount of the second eccentric shaft in the longitudinal direction of the tool bit is defined to be equal to a moving amount of the weight in the longitudinal direction of the tool bit. Accordingly, the second crank mechanism drives the weight in a predetermined phase. The weight may be connected directly to the second eccentric shaft without the intervening member.
According to a further preferable aspect of the present disclosure, the first and second eccentric shafts are disposed such that when the first eccentric shaft is positioned at the closest position to the tool bit in the longitudinal direction of the tool bit within its movable range, the second eccentric shaft is positioned at a position other than the closest position to the tool bit in the longitudinal direction of the tool bit and the most distant position from tool bit in the longitudinal direction of the tool bit within its movable range in the longitudinal direction of the tool bit. That is, the first and second eccentric shafts are driven other than the same phase and the opposite phase to each other. Accordingly, the weight driven by the second eccentric shaft is driven in a phase different from a phase of the hammering operation caused by the first eccentric shaft. Thus, the phase of the weight with respect to the phase of the hammering operation is effectively defined to reduce the vibration generated on the main housing during the operation.
According to a further preferable aspect of the present disclosure, the motor is arranged such that the motor shaft crosses the axial line of the tool bit.
According to a further preferable aspect of the present disclosure, the driving mechanism comprises a hammering element for hammering the tool bit, and a cylinder which holds the hammering element slidably therein. The cylinder is coaxial with the axial line of the tool bit. The weight is disposed corresponding to the cylinder.
Specifically, according to one aspect of the arrangement of the weight, the weight is arranged outside of the cylinder so as to surround at least part of the cylinder. That is, the weight is arranged outside of the cylinder on a cross section perpendicular to the axial direction of the cylinder. The weight is formed as substantially C-shaped or circular member to surround the cylinder on the cross section. The weight is arranged along the outer periphery of the cylinder in the axial direction of the cylinder. Accordingly, the weight is slid in the axial direction of the cylinder at the outer region of the cylinder.
Further, according to other aspect of the arrangement of the weight, the weight comprises a pair of weight components which are arranged at both outsides of the cylinder with respect to a plane including the axial line of the tool bit and a grip portion extending line, respectively. In other words, as the grip portion extends in a vertical direction of the impact tool, the weight components are arranged right and left sides of the cylinder, respectively. Accordingly, the pair of the weight components balances the impact tool in the lateral direction of the impact tool.
Further, according to another aspect of the arrangement of the weight, the weight is arranged in at least one of outer regions of the cylinder in the crossing direction. That is, as the grip portion extends in a vertical direction of the impact tool, the weight is arranged only in an upper region of the cylinder, only in a lower region of the cylinder or both in the upper and lower regions of the cylinder in the vertical direction. Typically, the weight is arranged on a plane including the axial line of the tool bit and a grip portion extending line. Accordingly, the weight is arranged on the singular plane with the grip portion and thereby usability of the impact tool is improved.
According to a further preferable aspect of the present disclosure, the gravity center of the weight is arranged so as to overlap with the cylinder on a cross section perpendicular to the axial line of the tool bit. That is, the gravity center point of the weight is located within the cylinder bore on the cross section perpendicular to the axial line of the tool bit. Typically, the weight is formed as substantially circular member in the cross section perpendicular to the axial line of the tool bit. Further, the weight may be provided by a plurality of weight components and the gravity center of the weight components may be located within the cylinder bore.
According to a further preferable aspect of the present disclosure, the handle is relatively moved with respect to the main housing in the longitudinal direction of the tool bit. In the impact tool, the tool bit is linearly driven in the longitudinal direction of the tool bit. Thus, vibration mainly in the longitudinal direction of the tool bit is generated on the main housing. Accordingly, as the handle is moved against the main housing in the longitudinal direction of the tool bit which is main component of the vibration, a vibration transmission from the main housing to the handle is effectively prevented.
Typically, the handle is moved with respect to the main housing on a plane including the axial direction of the tool bit and a grip portion extending line. In this aspect, whole of the handle may be moved with respect to the main housing parallel to the longitudinal direction of the tool bit or one end of the grip portion may be rotatably connected to the main housing and rotated with respect to the main housing. In such a construction in which the whole part of the handle is moved parallel to the longitudinal direction of the tool bit, the grip portion may be formed as a cantilever only one end of which is connected to the main housing, or both end of the grip portion may be connected to the main housing. On the other hand, in such a construction in which the grip portion is rotated with respect to the main housing, one end of the grip portion is connected to the main housing as a pivot, and another end of the grip portion is connected to the main housing via the biasing member arranged therebetween.
According to a further preferable aspect of the present disclosure, the impact tool comprises an outer housing which covers at least a part of a region of the main housing which houses the driving mechanism and the motor. The handle is connected to the outer housing and integrally moved with the outer housing with respect to the main housing. The biasing member is interveningly arranged between the outer housing and the main housing, and thereby the outer housing serves as a vibration proof housing. Accordingly, vibration transmission from the main housing to the outer housing during the operation is prevented. As a result, vibration transmission to the handle is prevented.
According to a further preferable aspect of the present disclosure, the impact tool comprises an auxiliary handle attachable part to which an auxiliary handle is detachably attached. The auxiliary handle attachable part is connected to the outer housing and integrally moved with the handle connected to the outer housing with respect to the main housing. Accordingly, the outer housing serves as not only the vibration proof housing but also a connecting part which connects the handle and the auxiliary handle attachable part. Thus, the auxiliary handle attached to the auxiliary handle attachable part and the handle are integrally moved against the main housing. As a result, usability of the impact tool for a user who holds the auxiliary handle and the handle is improved.
According to a further preferable aspect of the present disclosure, the first rotation shaft and the second rotation shaft are arranged coaxially with each other. In both constructions of the second crank mechanism is connected to the motor shaft and the second crank mechanism is connected to the first crank mechanism, as the first and second rotation shafts are coaxially arranged, rotation of the motor is rationally transmitted to the first and second crank mechanism.
According to a further preferable aspect of the present disclosure, the impact tool comprises a controller which controls rotation speed of the motor to be driven at substantially constant rotation speed. The substantially constant rotation speed means rotation speed within a predetermined range. That is, the controller controls the motor at a predetermined rotation speed within a predetermined range even though rotation speed of the motor may be fluctuated due to load applied on the motor during the operation. In other words, the motor is controlled at substantially constant rotation speed state by the controller. Accordingly, the motor keeps the predetermined rotation speed in spite of load applied on the motor during the operation. As a result, working efficiency of the impact tool is prevented from fluctuating. Specifically, in a case that the motor serves as a brushless motor, a controller for driving the brushless motor is necessary. Thus, by utilizing the controller for driving the brushless motor, the motor is driven in substantially constant rotation speed.
Accordingly, an improved vibration reduction technique for an impact tool is provided.
Other objects, features and advantages of the present disclosure will be readily understood after reading the following detailed description together with the accompanying drawings and the claims.
Each of the additional features and method steps disclosed above and below may be utilized separately or in conjunction with other features and method steps to provide and manufacture improved impact tools and method for using such impact tools and devices utilized therein. Representative examples of the invention, which examples utilized many of these additional features and method steps in conjunction, will now be described in detail with reference to the drawings. This detailed description is merely intended to teach a person skilled in the art further details for practicing preferred aspects of the present teachings and is not intended to limit the scope of the invention. Only the claims define the scope of the claimed invention. Therefore, combinations of features and steps disclosed within the following detailed description may not be necessary to practice the invention in the broadest sense, and are instead taught merely to particularly describe some representative examples of the invention, which detailed description will now be given with reference to the accompanying drawings.
A first embodiment of the present disclosure is explained with reference to
As shown in
An outer housing 105 is disposed outside the main housing 103. The outer housing 105 is cylindrically formed so as to extend in the longitudinal direction of the hammer bit 119 and cover the whole main housing 103. A pair of hand grips 500 held by a user during the chipping operation to operate the electrical hammer 100 is disposed on the outer housing 105. The pair of the hand grips 500 is symmetrically disposed with respect to an axial line extending in the longitudinal direction of the hammer bit 119. Further, each hand grip 500 linearly extends in a direction perpendicular to the axial line of the hammer bit 119. One end of the hand grip 500 is connected and fixed to the outer housing 105. Therefore, the hand grip 500 is formed as a cantilever. The hand grip 500 is one example which corresponds to “a handle” of this disclosure. Further, the outer housing 105 is one example which corresponds to “an outer housing” of this disclosure.
The electrical hammer 100 is constructed as a large-size hammer of approximately 30 kilogram. Accordingly, a user holds the pair of the hand grips 500 by respective hands and, basically, operates the electrical hammer 100 such that the hammer bit 119 is disposed downwardly during the chipping operation. Therefore, for convenience of explanation, the hammer bit 119 side in the longitudinal direction of the hammer bit 119 (longitudinal direction of the main body 101) is called lower side of the electrical hammer 100, and the hand grip 500 side in the longitudinal direction of the hammer bit 119 is called upper side of the electrical hammer 100.
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The electric motor 110 is driven by current provided from AC power source. As shown in
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The second crank shaft 221 is rotatably supported such that the shaft portion 229a of the outer crank shaft 229 is held by a needle bearing 237 which is held by a bearing holder 235. Accordingly, the second crank shaft 221 is held by the bearing holder 235. The bearing holder 235 is held by the gear housing 103B which is one component of the main housing 103.
As shown in
In the electrical hammer 100 described above, a user holds the pair of the hand grips 500 by his/her each hand and makes the electrical hammer 100 to perform the operation in a state that the hammer bit 110 extends downwardly. The user pushes the trigger 520 by his/her one hand which holds one of the hand grips 500 and switches the electrical switch 510 into turn-on state, and thereby the electric motor 110 is driven. Thus, the hammer bit 119 is linearly driven by the first motion converting mechanism 120 and the hammering mechanism 140 and thereby the hammering operation on a workpiece is performed.
At this time, the counterweight 231 corresponding to the drive of the hammer bit 119 is linearly driven in the longitudinal direction of the hammer bit 119 by the second motion converting mechanism 220. The counterweight 231 is set to be driven in an approximately opposite phase against the striker 143. That is, when the striker 143 is moved downward, the counterweight 231 is moved upward. And when the striker 143 is moved upward, the counterweight 231 is moved downward. Accordingly, the counterweight 231 prevents vibration generated on the electrical hammer 100 during the hammering operation. Further, the counterweight 231 may be set to be driven in an approximately opposite phase against the impact bolt 145.
Specifically, phase differences between the phase of the eccentric shaft 223 of the second motion converting mechanism 220 and the phase of the eccentric shaft 121a of the first motion converting mechanism 120 is set to approximately 90 degrees. Further, as the striker 143 and the impact bolt 145 are driven by the air spring of the air chamber 141a, phase differences between the driving of the eccentric shaft 121a and the driving of the striker 143 and the impact bolt 145 is occurred. By taking the phase differences into consideration, the phase differences between the eccentric shaft 223 and the eccentric shaft 121a is preferably set to a predetermined phase other than the opposite phase.
During the hammering operation, the hand grip 500 (outer housing 105) is moved against the main housing 103 in the longitudinal direction of the hammer bit 119 in a state that biasing force of the compression coil spring 321 is applied to the hand grip 500. That is, kinetic energy of the vibration generated by the hammering operation makes the compression coil spring 321 expand/contract and thereby vibration transmission to the hand grip 500 from the main housing 103 is prevented. That is, the electric hammer 100 has two vibration preventing mechanism of the vibration proof handle (hand grip 500) and the counterweight 231, and thereby vibration transmission to a user's hand holding the hand grip 500 is prevented during the hammering operation. As a result, operability of the electrical hammer 100 is improved.
Next, a second embodiment of the present disclosure is explained with reference to
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Rotation of the electric motor 110 is transmitted to the first motion converting mechanism 120 via the gear mechanism 113 and converted to a linear motion by the first motion converting mechanism 120. Thereafter, the linear motion is transmitted to the hammering mechanism 140 and thereby the hammer bit 119 is hit by the hammering mechanism 140 in the longitudinal direction of the hammer bit 119. Thus, a hammering force by the hammer bit 119 against a workpiece is generated. Furthermore, the rotation of the electric motor 110 is transmitted to the second motion converting mechanism 220 via the first motion converting mechanism 120 and converted to a linear motion by the second motion converting mechanism 220 and thereafter transmitted to a dynamic vibration reducer 160. The first motion converting mechanism 120, the gear mechanism 113 and the hammering mechanism 140 have similar constructions as those in the first embodiment, and explanations thereof are therefore omitted.
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The weight 161 is slidable in a state that the outer surface of the weight 161 contacts with the inner surface of the barrel portion 104. The biasing springs 163F, 163R are provided by compression coil springs, respectively. The rear side biasing spring 163R is disposed such that one end of the biasing spring 163R contacts with a front surface of a flange portion 165a of a slide sleeve 165 as a spring receiving member and another end of the biasing spring 163R contacts with a rear part of the weight 161. Further, the front side biasing spring 163F is disposed such that one end of the biasing spring 163F contacts with a front part of the weight 161 and another end of the biasing spring 163F contacts with a ring-like member 167 as a spring receiving member which is fixed on the barrel portion 104. The slide sleeve 165 is slidable in the longitudinal direction of the hammer bit 119 with respect to the cylinder 141 along the periphery of the cylinder 141. The slide sleeve 165 is contactable with the front end of the second connection rod 225. Thus, the slide sleeve 165 is slid by the second motion converting mechanism 220. The weight 161 is one example which corresponds to “a weight” of this disclosure. Further, the biasing spring 163R is one example which corresponds to “an intervening member” and “an elastic member” of this disclosure. Further, the slide sleeve 165 is one example which corresponds to “an intervening member” of this disclosure.
When the second connection rod 225 is moved forward, the slide sleeve 165 is pushed forward by the second connection rod 225 and the slide sleeve 165 compresses the biasing springs 163F, 163R against the biasing force of the biasing springs 163F, 163R. On the other hand, when the second connection rod 225 is moved rearward, the slide sleeve 165 is pushed rearward by the biasing force of the biasing spring 163F. That is, during the hammering operation, the weight 161 of the dynamic vibration reducer 160 is forcibly driven by the second motion converting mechanism 220 via the biasing springs 163F, 163R. Accordingly, vibration generated on the main housing 103 during the hammering operation is reduced. In this case, phase differences between the eccentric shaft 223 of the second motion converting mechanism 220 and the eccentric shaft 121a pf the first motion converting mechanism 120 is set similar to the one in the first embodiment.
As shown in
The barrel cover 105 is a cylindrical member which covers a part of the barrel portion 104 of the main housing 103 other than the front end region of the barrel portion 104. The rear end of the barrel cover 105C is contacted and engaged with the front end of the upper housing cover 105A and the lower housing cover 105B, and fixedly connected by a plurality of screws.
As shown in
The outer housing 105 and the hand grip 109 are connected to the main housing 103 via a slide guide 211 and a compression coil spring 219 in a relatively slidable manner in the longitudinal direction of the hammer bit 119, and thereby a vibration proof handle is constructed. The compression coil spring 219 is one example which corresponds to “a biasing member” of this disclosure.
As shown in
Each of the upper connection part 109B and the lower connection part 109C of the hand grip 109 includes the slide cylinder 217 corresponding to the guide shaft 215. The guide shaft 215 is disposed such that an outer surface of a protruding part 215b is slidable against an inner surface of a cylindrical hole 217a of the slide cylinder 217 and thereby the guide shaft 215 is slidably fitted into the slide cylinder 217. In
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Further, as shown in
In the electrical hammer 200 described above, during the hammering operation, the outer housing 105 and the hand grip 109 are slid against the main housing 103 in a state that biasing force of the compression coil spring 219 is applied to the outer housing 105 and the hand grip 109. Specifically, as shown in
During the hammering operation, the hammer bit 119 is driven via the first motion converting mechanism 120. At the same time, the dynamic vibration reducer 160 is driven by the second motion converting mechanism 220. Accordingly, the dynamic vibration reducer 160 reduces effectively vibration generated on the main housing 103 during the hammering operation. Furthermore, as the hand grip 109 is relatively moved against the main housing 103 via the compression coil spring 219, vibration transmission to the hand grip 109 is more effectively prevented.
Next, a third embodiment of the present disclosure is explained with reference to
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The engagement hole 253 has a length in the longitudinal direction of the hammer bit 119, which is the same length as the diameter of the eccentric shaft 251. Further the engagement hole 253 has a length in a lateral direction perpendicular to the longitudinal direction of the hammer bit 119, which is longer than the diameter of the eccentric shaft 251. Thus, the engagement hole 253 is provided as an elongated hole along the lateral direction. On the other hand, the first guide hole 254 and the second guide hole 255 are provided as an elongated hole along the longitudinal direction of the hammer bit 119. Further, phase differences between the eccentric shaft 251 of the second motion converting mechanism 250 and the eccentric shaft 121a pf the first motion converting mechanism 120 is set similar to the one in the first embodiment.
When the eccentric shaft 251 is rotated in the engagement hole 253, the eccentric shaft 251 is moved in the lateral direction within the engagement hole 253 and the eccentric shaft 251 pushes the movable plate 252 in the longitudinal direction of the hammer bit 119. Thus, the movable plate 252 is reciprocated in the longitudinal direction of the hammer bit 119 (front-rear direction). At this time, the intermediate shaft 157 engages with the first guide hole 254 and the guide pin 256 engages with the second guide hole 255. Therefore, the movable plate 252 is stably guided in the longitudinal direction of the hammer bit 119. Further, as shown in
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A trigger 109a is disposed on the hand grip 109. When a user pulls (manipulates) the trigger 109a, the electric motor 110 is driven by the controller 171. Thus, the hammer bit 119 performs the hammer-drill operation on a workpiece. In the third embodiment, the controller 171 controls the electric motor 110 under substantially constant rotation speed state similar to the first embodiment.
The hand grip 109 moves against the main body 103 in a state that the biasing force of the compression coil spring 219 is applied to the hand grip 109 during the hammer-drill operation. Accordingly, vibration transmission to the hand grip 109 from the main body 103 is prevented.
Further, the movable plate 252 of the second motion converting mechanism 250 is moved in the front-rear direction by rotation of the electric motor 110 during the hammer-drill operation. Thereby the push arm 257 drives the driving member 166 by contacting with the contact part 166a. Accordingly, as shown in
In the electrical hammer drill 300, two dynamic vibration reducers 160 are arranged on left side and right side with respect to the cylinder 141, respectively. Thus, with respect to a lateral direction of the electrical hammer drill 300, the gravity center of the two weights 161 approximately coincides with the center of the cylinder 141. Accordingly, vibration generated on the main housing 103 during the hammer-drill operation is effectively reduced by the two dynamic vibration reducers 160. Further, the dynamic vibration reducer 160 is arranged between the cylinder 141 and the electric motor 110 in the vertical direction of the electrical hammer drill 300. Therefore, with respect to the vertical direction, the dynamic vibration reduce 160 is disposed close to the gravity center of the electrical hammer drill 300 and vibration generated on the main housing 103 during the hammer-drill operation is further effectively reduced by the two dynamic vibration reducers 160.
Next, a fourth embodiment of the present disclosure is explained with reference to
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The hammering mechanism 140 is mainly provided with the cylinder 142, a striker 143 as a hammering element and an impact bolt 145 as an intermediate element. The striker 143 is slidably disposed in the piston cylinder 142. By the driving of the first motion converting mechanism 120, the piston cylinder 142 is slid in the tool holder 131 and thereby the striker 143 is driven by an air spring (air fluctuation) of an air chamber 142a formed in the piston cylinder 142. Therefore, the striker 143 hits the impact bolt 145 and thereby the impact bolt 145 hits the hammer bit 119. The hammering mechanism 140 is one example which corresponds to “a driving mechanism” of this disclosure. Further, the piston cylinder 142 and the striker 143 are examples which correspond to “a cylinder” and “a hammering mechanism” of this disclosure, respectively.
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Specifically, the counterweight 231 has an engagement hole 231a which engages with the eccentric shaft 273. The engagement hole 231a is formed as an elongate hole extends in a lateral direction crossing the longitudinal direction of the hammer bit 119. Further, two guide shafts 232 are disposed so as to penetrate the counterweight 231 in the longitudinal direction of the hammer bit 119. The guide shaft 232 is disposed parallel to the longitudinal direction of the hammer bit 119 and fixed on the gear housing 103B. Thereby the counterweight 231 is guided by the guide shaft 232 in the longitudinal direction of the hammer bit 119.
By a circular movement of the eccentric shaft 273 of the second motion converting mechanism 270, the eccentric shaft 273 moves within the engagement hole 231a of the counterweight 231 in the lateral direction and, at the same time, the eccentric shaft 273 moves in the longitudinal direction of the hammer bit 119. Thereby the counterweight 231 is moved in the longitudinal direction of the hammer bit 119. Further, phase differences between the eccentric shaft 253 of the second motion converting mechanism 270 and the eccentric shaft 121a pf the first motion converting mechanism 120 is set similar to the one in the first embodiment. The counterweight 231 is one example which corresponds to “a weight” of this disclosure.
As shown in
Further, a trigger 109a is disposed on the hand grip 109. When the trigger 109a is pulled, the electric motor 110 is turned on and driven. Accordingly, the electrical hammer drill 400 performs the operation based on the driving mode selected by the mode switching dial 290.
The hand grip 109 is moved with respect to the main housing 103 during the operation in a state that biasing force of the compression coil spring 219 is applied. Accordingly, vibration transmission to the hand grip 109 from the main housing 103 is prevented.
Further, during the hammering operation or the hammer-drill operation, the second motion converting mechanism 270 is driven by rotation of the electric motor 110 and thereby the counterweight is linearly reciprocated in the longitudinal direction of the hammer bit 119 between a position shown in
The counterweight 231 is arranged above the piston cylinder 142 in the vertical direction of the electrical hammer drill 400. On the other hand, the electric motor 110 having relatively large weight is arranged below the piston cylinder 142. Accordingly, the electrical hammer drill is balanced by the counterweight 231 and the electric motor 110.
According to the embodiments described above, the hand grip 109, 500 is moved with respect to the main housing 103 during the operation in a state that biasing force of the biasing member is applied. Therefore, vibration transmission from the main housing 103 to the hand grip 109, 500 during the operation is prevented. Further, as the electric motor 110 drives the counterweight 231 or the weight 161 of the dynamic vibration reducer 160 forcibly, vibration generated on the main housing 103 during the operation is reduced. That is, the impact tool of this disclosure has a vibration proof mechanism which prevents vibration transmission to the hand grip and a vibration reduction mechanism which reduces vibration generated on the main housing. Accordingly, vibration of the hand grip which is held (griped) by a user is reduced and thereby usability of the impact tool is improved.
Further, according to the second and third embodiments, in the electrical hammer 200 and the electrical hammer drill 300 which have the dynamic vibration reducer 160, the controller 171 controls the electric motor 110 under substantially constant rotation speed state. In the dynamic vibration reducer 160, the weight 161 and biasing members 163F, 163R are set to work effectively under a predetermined frequency based on mass of the weight 161 and the spring constant of the biasing members 163F, 163R such that the dynamic vibration reducer 160 can reduce vibration generated on the main housing 103. Accordingly, as the controller 171 controls rotation speed of the electric motor 110, the weight 161 is driven by the predetermined frequency. Therefore, the dynamic vibration reducer 160 effectively reduces vibration generated on the main housing 103. In this regard, in the first and fourth embodiments, the electric motor 110 may not be controlled under the substantially constant rotation speed state.
In the embodiments described above, the main housing houses the electric motor 110, and the hammering mechanism 140, the first motion converting mechanism 120 and the second motion converting mechanism 220, 250, 270 as a driving mechanism, however it is not limited to such a construction. For example, the electric motor 110 may not be housed by the main housing 103 but the hand grip 109, 500.
Further, in the third embodiment, the weight 161 is arranged below the cylinder 141 and, in the fourth embodiment, the counterweight 231 is above the piston cylinder 142, however it is not limited to such a construction. For example, the weight 161 may be arranged above the cylinder 141 and the counterweight 231 may be arranged below the piston cylinder 142.
Further, in the fourth embodiment, the electrical hammer drill 400 comprises the mode switching dial 290 which switches the driving mode of the electrical hammer drill 400. However, it is not limited to such a construction. That is, the impact tool of this disclosure may be configured to perform at least the hammering operation, and the drilling operation or the hammer-drill operation may not be performed.
The correspondence relationships between components of the embodiments and claimed inventions are as follows. The embodiments describe merely examples of configurations for carrying out the claimed inventions. However the claimed inventions are not limited to the configurations of the embodiments.
The electrical hammer 100, 200 is one example of a configuration that corresponds to “an impact tool” of the invention.
The electrical hammer drill 300, 400 is one example of a configuration that corresponds to “an impact tool” of the invention.
The main housing 103 is one example of a configuration that corresponds to “a main housing” of the invention.
The outer housing 105 is one example of a configuration that corresponds to “an outer housing” of the invention.
The hand grip 109, 500 is one example of a configuration that corresponds to “a handle” of the invention.
The electric motor 110 is one example of a configuration that corresponds to “a motor” of the invention.
The motor shaft 110 is one example of a configuration that corresponds to “a motor shaft” of the invention.
The compression coil spring 219, 321 is one example of a configuration that corresponds to “a biasing member” of the invention.
The counterweight 231 is one example of a configuration that corresponds to “a weight” of the invention.
The weight 161 is one example of a configuration that corresponds to “a weight” of the invention.
The first motion converting mechanism 120 is one example of a configuration that corresponds to “a first crank mechanism” of the invention.
The second motion converting mechanism 220, 250, 270 is one example of a configuration that corresponds to “a second crank mechanism” of the invention.
The hammering mechanism 140 is one example of a configuration that corresponds to “a driving mechanism” of the invention.
The rotation transmitting mechanism 151 is one example of a configuration that corresponds to “a driving mechanism” of the invention.
The cylinder 141 is one example of a configuration that corresponds to “a cylinder” of the invention.
The piston cylinder 142 is one example of a configuration that corresponds to “a cylinder” of the invention.
The striker 143 is one example of a configuration that corresponds to “a hammering element” of the invention.
The second connection rod 225 is one example of a configuration that corresponds to “an intervening member” of the invention.
The slide sleeve 165 is one example of a configuration that corresponds to “an intervening member” of the invention.
The biasing spring 163R is one example of a configuration that corresponds to “an intervening member” of the invention.
The biasing spring 163R is one example of a configuration that corresponds to “an elastic member” of the invention.
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| 2014-102791 | May 2014 | JP | national |
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| Number | Date | Country | |
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| 20150328759 A1 | Nov 2015 | US |
