1. Field of the Invention
The invention relates to a power tool which performs a predetermined operation on a workpiece at least by axial linear movement of a tool bit.
2. Description of the Related Art
In a power tool in which an operation such as a hammering operation or a hammer drill operation is performed on a workpiece such as concrete by a tool bit, vibration is caused in the axial direction of the tool bit when the tool bit is driven. Therefore, some conventional power tools are provided with a vibration reducing mechanism for reducing vibration caused when the tool bit is driven.
For example, Japanese non-examined laid-open Patent Publication No. 2004-154903 discloses a power tool having a dynamic vibration reducer which serves to reduce vibration caused in the axial direction when the tool bit is driven, and the dynamic vibration reducer includes a dynamic vibration reducer body in the form of a cylindrical element, a weight which is housed within the cylindrical element and allowed to move in the axial direction of the tool bit, and an elastic element which connects the weight to the cylindrical element.
According to the power tool having the dynamic vibration reducer, a burden on the user can be alleviated by reduction of vibration caused during operation. However, the size of the power tool itself may be increased by installing the dynamic vibration reducer in the power tool, and in this point, further improvement is desired.
Accordingly, it is an object of the invention to provide a technique that contributes to size reduction in a power tool having a dynamic vibration reducer.
In order to solve the above-described problem, according to a preferred embodiment of the invention, a power tool is provided which performs a predetermined operation on a workpiece at least by axial linear movement of a tool bit coupled to a front end region of a housing. The power tool has a driving mechanism and a dynamic vibration reducer. The driving mechanism is housed within the housing and linearly drives the tool bit. The dynamic vibration reducer includes a weight which is allowed to linearly move under a biasing force of an elastic element, and by movement of the weight in the axial direction of the tool bit, the dynamic vibration reducer reduces vibration caused during operation. The “power tool” in the invention typically represents a hammer and a hammer drill, depending on the need for vibration reduction by a dynamic vibration reducer.
The preferred embodiment of the invention is characterized in that a dynamic vibration reducer housing space for housing the weight and the elastic element of the dynamic vibration reducer is integrally formed with the housing.
According to the invention, with the construction in which the dynamic vibration reducer housing space for housing the weight and the elastic element is integrally formed with the housing, compared with a conventional construction, for example, in which a cylindrical element for housing the weight and the elastic element is separately formed and installed in the housing, the number of parts can be reduced and size reduction can be realized.
According to a further embodiment of the power tool of the invention, the housing has an inner housing which houses the driving mechanism, and an outer housing which houses the inner housing, and the dynamic vibration reducer housing space is formed in the inner housing.
According to the invention, with the construction in which the dynamic vibration reducer housing space is formed in the inner housing, when the outer housing is removed, the inner housing including the dynamic vibration reducer housing space can be exposed to the outside. Thus, according to the invention, maintenance or repair of the dynamic vibration reducer can be made with the outer housing removed, so that this construction is rational.
According to a further embodiment of the power tool of the invention, the dynamic vibration reducer housing space has an elongate form extending in the axial direction of the tool bit and has one axial open end. The weight and the elastic element are inserted and housed in the dynamic vibration reducer housing space through an opening of the open end. Further, the dynamic vibration reducer has a sealing member which compresses the elastic element and seals the opening under a biasing force of the elastic element. The housing has a retaining member that retains the sealing member placed in a position to seal the opening. The manner of “sealing” by the sealing member in this invention suitably includes both the manner of fitting (inserting) the sealing member into the opening and the manner of fitting the sealing member over the opening. Further, the manner in which the retaining member “retains the sealing member placed in a position to seal” in this invention typically represents the manner in which the sealing member is inserted into the opening while compressing the elastic element, and then turned in the circumferential direction such that a rear surface of the sealing member in the direction of insertion is oppositely held in contact with the retaining member.
According to the invention, after the weight and the elastic element are inserted and installed in the dynamic vibration reducer housing space through the opening, the sealing member is inserted into the opening or fitted over the opening while compressing the elastic element and then held in a position to seal the opening by the retaining member. In this manner, the dynamic vibration reducer can be installed in the housing. Thus, according to the invention, the dynamic vibration reducer can be easily installed and dismantled.
According to a further embodiment of the power tool of the invention, a handgrip designed to be held by a user is detachably mounted to the housing on the side opposite the tool bit. When the handgrip is removed from the housing, the opening of the dynamic vibration reducer housing space faces the outside.
According to the invention, the dynamic vibration reducer can be easily installed and dismantled with respect to the housing with the handgrip detached from the housing.
According to a further embodiment of the power tool of the invention, a slide guide is provided within the dynamic vibration reducer housing space, and the weight is slidably held in contact with the slide guide. Further, the slide guide is held pressed against the sealing member by the biasing force acting in a direction of the opening.
According to the invention, by provision of the slide guide for the weight, smooth sliding movement of the weight can be ensured, and wear of the sliding surface can be prevented so that durability can be enhanced. Further, with the construction in which the slide guide is biased toward the opening, rattle of the slide guide caused in the longitudinal direction can be minimized so that noise can be prevented, and the slide guide can be easily taken out from the housing space when the dynamic vibration reducer is dismantled.
According to a further embodiment of the power tool of the invention, the driving mechanism includes a crank mechanism which converts rotation of the motor into linear motion and then drives the tool bit, and actively drives the weight by utilizing pressure fluctuations caused in an enclosed crank chamber which houses the crank mechanism.
The dynamic vibration reducer is inherently a mechanism which passively reduces vibration of the tool body when the weight is vibrated due to vibration of the housing. In this invention, the dynamic vibration reducer designed as such a passive vibration reducing mechanism is constructed such that the weight is vibrated by utilizing pressure fluctuations caused in the crank chamber, or the weight is actively driven, so that the vibration reducing function of the dynamic vibration reducer can be further enhanced. Particularly, in this invention, pressure fluctuations caused in the crank chamber are utilized as a means for driving the weight, so that it is not necessary to additionally provide the driving means for the weight. Therefore, consumption of power can be effectively reduced, and it can also be structurally simplified.
According to this invention, a technique is provided which contributes to size reduction in a power tool having a dynamic vibration reducer. Other objects, features and advantages of the present invention 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 power tools and method for using such power tools and devices utilized therein. Representative examples of the present 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.
An embodiment according to the invention is now described with reference to
The body 103 includes a motor housing 105 that houses a driving motor 111, a gear housing 107 that includes a barrel 106 and houses a motion converting mechanism 113, a striking mechanism 115 and a power transmitting mechanism 117, and an outer housing 104 that covers (houses) the gear housing 107. The motor housing 105 and the gear housing 107 are connected to each other by screws or other fastening means. The gear housing 107 and the outer housing 104 are features that correspond to the “inner housing” and the “outer housing”, respectively, according to the invention.
The driving motor 111 is disposed such that its rotation axis runs in a vertical direction (vertically as viewed in
The motion converting mechanism 113 mainly includes a crank mechanism. When the crank mechanism is rotationally driven by the driving motor 111, a driving element in the form of a piston 129 which forms a final movable member of the crank mechanism linearly moves in the axial direction of the hammer bit within a cylinder 141. The power transmitting mechanism 117 mainly includes a gear speed reducing mechanism consisting of a plurality of gears and transmits the rotational power of the driving motor 111 to the tool holder 137. Thus, the tool holder 137 is caused to rotate in a vertical plane and thus the hammer bit 119 held by the tool holder 137 is also caused to rotate. The constructions of the motion converting mechanism 113 and the power transmitting mechanism 117 are well-known and therefore their detailed description is omitted.
The striking mechanism 115 mainly includes a striking element in the form of a striker 143 which is slidably disposed within the bore of the cylinder 141 together with the piston 129, and an intermediate element in the form of an impact bolt 145 which is slidably disposed within the tool holder 137. The striker 143 is driven via an air spring action (pressure fluctuations) of an air chamber 141a of the cylinder 141 which is caused by sliding movement of the piston 129, and then the striker collides with (strikes) the impact bolt 145 and transmits the striking force to the hammer bit 119 via the impact bolt 145.
Further, the hammer drill 101 can be switched between a hammer mode in which an operation on a workpiece is performed by applying only a striking force in the axial direction to the hammer bit 119 and a hammer drill mode in which an operation on the workpiece is performed by applying a striking force in the axial direction and a rotational force in the circumferential direction to the hammer bit 119. This operation mode switching, however, is a known technique and not directly related to the invention, and therefore it is not described in further details.
In the hammer drill 101 constructed as described above, when the driving motor 111 is driven, the rotating output of the driving motor 111 is converted into linear motion via the motion converting mechanism 113 and then causes the hammer bit 119 to perform linear movement in its axial direction or striking movement via the striking mechanism 115. Further, in addition to the above-described striking movement, rotation is transmitted to the hammer bit 119 via the power transmitting mechanism 117 driven by the rotating output of the driving motor 111, so that the hammer bit 119 is also caused to rotate in its circumferential direction. Specifically, in hammer drill mode, the hammer bit 119 performs a hammer drill operation on the workpiece by striking movement in its axial direction and rotation in its circumferential direction. In hammer mode, transmission of the rotational power by the power transmitting mechanism 117 is interrupted by a clutch, so that the hammer bit 119 performs only the striking movement in its axial direction and thus performs a hammering operation on the workpiece.
The outer housing 104 covers an upper region of the body 103 which houses the driving mechanism, or the barrel 106 and the gear housing 107. Further, the handgrip 109 is integrally formed with the outer housing 104 and is designed as a handle which is generally D-shaped as viewed from the side and has a hollow cylindrical grip region 109A which extends in a vertical direction transverse to the axial direction of the hammer bit 119, and upper and lower connecting regions 109B, 109C which substantially horizontally extend forward from upper and lower ends of the grip region 109A.
In the handgrip 109 constructed as described above, the upper connecting region 109B is elastically connected to an upper rear surface of the gear housing 107 via a vibration-proofing first compression coil spring (not shown), and the lower connecting region 109C is elastically connected to a rear cover 108 covering a rear region of the motor housing 105 via a vibration-proofing second compression coil spring (not shown). Further, a front end region of the outer housing 104 is elastically connected to the barrel 106 via an O-ring 147. In this manner, the outer housing 104 including the handgrip 109 is elastically connected to the gear housing 107 and the motor housing 105 of the body 103 at a total of three locations, or the upper and lower ends of the grip region 109A of the handgrip 109 and the front end region. With such a construction, in the above-described hammering operation or hammer drill operation, transmission of vibration caused in the body 103 to the handgrip 109 is prevented or reduced. Further, the outer housing 104 including the handgrip 109 is designed to be detachable from the gear housing 107 and the motor housing 105 of the body 103.
The hammer drill 101 according to this embodiment is provided with a pair of right and left dynamic vibration reducers 151 in order to reduce vibration caused in the body 103 during hammering operation or hammer drill operation. Further, the right and left dynamic vibration reducers 151 have the same structure. In this embodiment, housing spaces 149 for the dynamic vibration reducers 151 are integrally formed with the gear housing 107. As shown in
As shown in
Each of the front and rear biasing springs 155F, 155R is formed by a compression coil spring. One end of the front biasing spring 155F is held in contact with the front spring receiver 161 disposed on the closed end of the housing space 149 and the other end is held in contact with an axial front end surface of the large-diameter portion 153a of the weight 153. One end of the rear biasing spring 155R is held in contact with the rear spring receiver 163 disposed on the open end of the housing space 149 and the other end is held in contact with an axial rear end surface of the large-diameter portion 153a of the weight 153. With such a construction, the front and rear biasing springs 155F, 155R apply respective spring forces to the weight 153 toward each other when the weight 153 moves in the longitudinal direction (the axial direction of the hammer bit 119) within the housing space 149.
The guide sleeve 157 is biased rearward in the longitudinal direction by a pressure spring 159 for preventing a rattle. The pressure spring 159 is formed by a compression coil spring and is designed such that one end is held in contact with a radial engagement surface (a stepped portion between the small-diameter bore and the large-diameter bore) 149b in an inner surface of the housing space 149 and the other end is held in contact with a front end surface of the guide sleeve 157. With such a construction, the guide sleeve 157 is biased rearward (toward the opening 149a) and a rear end surface of the guide sleeve 157 is received by the rear spring receiver 163. The rear spring receiver 163 is shaped like a cylindrical cap and designed such that its bottom receives the rear biasing spring 155R and its open front end surface is held in contact with the rear end surface of the guide sleeve 157.
The rear spring receiver 163 is fitted (inserted) into the opening 149a of the housing space 149 and seals the opening 149a via an O-ring 165 disposed between an outer circumferential surface of the rear spring receiver 163 and an inner circumferential surface of the opening 149a. Further, the rear spring receiver 163 fitted into the opening 149a compresses the front and rear biasing springs 155F, 155R and the pressure spring 159 and is in turn subjected to rearward biasing force. In this state, the rear spring receiver 163 is detachably retained (fastened) with respect to the gear housing 107 via a retaining plate 167. In order to allow attachment and detachment of the rear spring receiver 163 with respect to the retaining plate 167, an engagement protrusion 163a is formed on part of a rear outer surface of the rear spring receiver 163 in the circumferential direction and protrudes in a radial direction (a direction transverse to the axial direction of the hammer bit). The engagement protrusion 163a is engaged with (fitted into) an engagement recess 167b formed in the retaining plate 167, from the front. The rear spring receiver 163 and the retaining plate 167 are features that correspond to the “sealing member” and the “retaining member”, respectively, according to this invention.
As shown in
Further, installation of the dynamic vibration reducer 151 into the gear housing 107 is made as described below. Firstly, the front spring receiver 161, the pressure spring 159, the guide sleeve 157, the front biasing spring 155F, the weight 153, the rear biasing spring 155R and the rear spring receiver 163 are inserted into the housing space 149 through the opening 149a in this order. Thereafter, the rear spring receiver 163 is retained by the retaining plate 167 in the above-described procedure. In this manner, the dynamic vibration reducer 151 can be easily installed in the gear housing 107. In order to dismantle the dynamic vibration reducer 151, the rear biasing spring 155R is pressed forward such that the engagement protrusion 163a is disengaged from the engagement recess 167b of the retaining plate 167, and turned around the axis. Thereafter, when the pressing force is released, components of the dynamic vibration reducer 151 can be easily taken out from the housing space 149.
Further, the housing space 149 which houses the dynamic vibration reducer 151 is partitioned into a front chamber 171 and a rear chamber 173 opposed to each other by the weight 153. The rear chamber 173 communicates with a crank chamber 177 which is formed as an enclosed space for housing the motion converting mechanism 113 in an internal space of the gear housing 107, via a communication hole 157a formed in a rear region of the guide sleeve 157 and a passage 107a formed in the gear housing 107 (see
When the hammer drill 101 is driven, pressures of the crank chamber 177 and the cylinder housing space 175 fluctuate as the motion converting mechanism 113 and the striking mechanism 115 are driven, and a phase difference between their pressure fluctuations is about 180 degrees. Specifically, the pressure of the cylinder housing space 175 is lowered when the pressure of the crank chamber 177 is raised, while the pressure of the cylinder housing space 175 is raised when the pressure of the crank chamber 177 is lowered. This is well known, and therefore it is not described in further detail.
In this embodiment, the pressure which fluctuates as described above is introduced into the front and rear chambers 171, 173 of the dynamic vibration reducer 151 and the weight 153 of the dynamic vibration reducer 151 is actively driven by utilizing the pressure fluctuations within the crank chamber 177 and the cylinder housing space 175. The dynamic vibration reducer 151 serves to reduce vibration by this forced vibration. With such a construction, a sufficient vibration reducing function can be ensured.
In this embodiment, the housing space 149 for housing the weight 153 and the biasing springs 155F, 155R of the dynamic vibration reducer 151 is integrally formed with the gear housing 107. Therefore, compared with a construction in which a cylindrical container for housing the weight 153 and the biasing springs 155F, 155R is separately formed and installed in the gear housing 107, the number of parts can be reduced and size reduction can be realized.
Further, according to this embodiment, in order to install the dynamic vibration reducer 151 in the housing space 149, components of the dynamic vibration reducer 151 such as the weight 153 and the biasing springs 155F, 155R are inserted into the housing space 149 through the opening 149a one by one. Thereafter, the rear spring receiver 163 is inserted into the opening 149a while compressing the biasing springs 155F, 155R and then turned around the axis such that the engagement protrusion 163a of the rear spring receiver 163 is elastically engaged with the engagement recess 167b of the retaining plate 167. In this manner, the dynamic vibration reducer 151 can be easily installed in the housing space 149. Further, the dynamic vibration reducer 151 in the housing space 149 can be easily dismantled by disengaging the engagement protrusion 163a of the rear spring receiver 163 from the engagement recess 167b of the retaining plate 167.
Further, in this embodiment, the guide sleeve 157 which is loosely fitted in the housing space 149 in order to ensure the sliding movement of the weight 153 is biased toward the opening 149a and pressed against the front end surface of the rear spring receiver 163 by the pressure spring 159. With such a construction, the guide sleeve 157 can be prevented from rattling, and compared with a construction in which the guide sleeve 157 is prevented from rattling, for example, by using an O-ring, the guide sleeve 157 can be more easily removed from the housing space 149 when the dynamic vibration reducer 151 is dismantled. Moreover, grooving of the guide sleeve 157 which is necessary for the construction using an O-ring can be dispensed with, so that cost reduction can also be achieved.
Further, according to this embodiment, when the outer housing 104 including the handgrip 109 is removed, the opening 149a of the housing space 149 faces the outside or is exposed. Therefore, even in the construction in which the housing space 149 of the dynamic vibration reducer 151 is integrally formed with the gear housing 107, maintenance or repair of the dynamic vibration reducer 151 can be easily made.
Further, in the above-described embodiment, the hammer drill 101 is described as a representative example of the power tool, but the invention can be applied not only to the hammer drill 101 but to a hammer and other power tools which perform an operation on a workpiece by linear movement of a tool bit. For example, it can be suitably applied to a jig saw or a reciprocating saw which performs a cutting operation on a workpiece by reciprocating movement of a saw blade.
Further, in this embodiment, the handgrip 109 is described as being integrally formed with the outer housing 104, but the technique of the invention can also be applied to a hammer drill or an electric hammer of the type in which the handgrip 109 is separately formed from the outer housing 104 and detachably mounted to the body 103 including the outer housing 104, the gear housing 107 and the motor housing 105.
Further, in this embodiment, the retaining plate 167 for retaining the rear spring receiver 163 inserted into the opening 149a of the housing space 149, in the inserted position is described as being fastened to the gear housing 107 by the screws 169. The retaining plate 167, however, may be integrally formed with the gear housing 107. Further, it is described as being constructed such that the rear spring receiver 163 is inserted (fitted) into the opening 149a, but it may be constructed such that the rear spring receiver 163 is fitted over the opening 149a.
In view of the aspect of the invention, following features can be provided.
“A power tool, which performs a predetermined operation on a workpiece at least by axial linear movement of a tool bit coupled to a front end region of a housing, comprising:
a driving mechanism that is housed within the housing and linearly drives the tool bit, and
a dynamic vibration reducer that includes a weight which is allowed to linearly move under a biasing force of an elastic element, and reduces vibration caused during operation, by movement of the weight in the axial direction of the tool bit, wherein:
a dynamic vibration reducer housing space for housing the weight and the elastic element of the dynamic vibration reducer is integrally formed with the housing, so that size reduction is realized.”
“The power tool as defined in claim 3, wherein the retaining member is separately formed from the housing and fastened to the housing by screws.”
“The power tool as defined in claim 3, wherein the retaining member is integrally formed with the housing.”
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