The present invention relates to an hammer tool which drives a tool bit and performs a hammering operation on a workpiece, in which the tool bit moves linearly in a longitudinal direction of the tool bit.
A hammer tool disclosed in Japanese Unexamined Patent Application Publication No. 2002-79476, drives a striker via an air pressure fluctuation within an air chamber or an air spring effect caused by relative movement between a piston as a driving element and the striker as a hammering element, and the driven striker moves forward and hits a hammer bit.
In the hammer tool described above, when a hammering operation while pushing a tip of the hammer bit against a workpiece, a stroke amount of the piston is varied in accordance with pushing force that a user applies to a grip of the hammer tool. Thereby, the hammer tool controls impact force during the hammering operation.
In the hammer tool which drives the striker via the air spring effect, after the striker hits the hammer bit, the striker moves toward the piston by reaction force (hereinafter called as hammering reaction force) caused by the hitting and vacuum force caused within the air chamber when the piston returns to a position before the striker hits the hammer bit. The inventor found that a return speed of the striker or a return amount of the striker is not always constant due to differences of hammering operation aspects, for example a kind of a workpiece, especially hardness of a workpiece. That is, the inventor found that as the hardness of a workpiece is harder, hammering reaction force applied on the striker becomes larger, as the hardness of a workpiece is softer, hammering reaction force becomes smaller, and further the return speed of the striker and the return amount of the striker are varied by the hammering reaction force. As described above, when the return speed or the return amount of the striker varies, a distance between the striker and the piston varies, and impact energy transmitted from the striker to the hammer bit varies.
The object of the present invention is, in consideration with the above-described problem, to provide an improved hammer tool which is capable of performing a rational hammering operation.
The above-described problem is solved by the invention according to claim 1. According to a preferable aspect of a hammer tool according to the present invention, the hammer tool which drives a tool bit at least linearly in a longitudinal direction of the tool bit and performs a hammering operation on a workpiece is constructed. The hammer tool comprises a main body, a cylinder which is arranged in the main body and extended in the longitudinal direction of the tool bit, a hammering element which drives linearly in the longitudinal direction of the tool bit in the cylinder and hits the tool bit, a driving element which is slidably arranged in the cylinder and is configured to moves the hammering element, and a driving apparatus which drives the driving element. The driving element is arranged inside the cylinder such that it is reciprocally movable between a first position which is remote from the tool bit and a second position which is close to the tool bit. When the driving element is moved from the first position to the second position, the driving element moves the hammering element toward the tool bit and the hammering element hits the tool bit. Further, a stroke center position of a reciprocating movement of the driving element which is reciprocally moved between the first position and the second position is configured to be changeable.
Further, a stroke length is a distance between the first position and the second position. The stroke center position is positioned at the same distance from the first position and the second position between the first position and the second position. Further, the first position and the second position are moved due to a movement of the stroke center position. The stroke center position may be changed by moving a part of a driving apparatus for driving the driving element, or by moving whole of the driving apparatus.
According to the present invention, since the stroke center position of the reciprocating movement of the driving element which is moved between the first position and the second position is changeable, a hammer tool which is capable of performing a rationalized hammer operation according to an operation aspect is provided. For example, in the hammer tool which is constructed to drive the hammering element via an air spring effect of an air chamber, the characteristic of the air spring is varied by changing the distance between the driving element and the hammering element based on the hardness of a workpiece. Specifically, if a workpiece is harder, the stroke center position of the driving element is moved to be remote from the tool bit, and if a workpiece is softer, the stroke center position of the driving element is moved to be close to the tool bit. Thereby, by controlling the characteristic of the air spring, variation in impact energy based on the hardness of a workpiece is suppressed. As a result, the hammering operation is appropriately performed.
Further, for example, when the hammering operation is started, in order to move actively the resting hammering element, the stroke center position of the driving element is moved to be close to the tool bit. On the other hand, after starting the hammering operation, the stroke center position of the driving element may be moved to be remote from the tool bit.
According to a further aspect of the hammer tool according to the present invention, the hammer tool comprises a switch apparatus for changing the stroke center position. Further, change of the stroke center position by the switch apparatus may be performed in a stepping manner or in a stepless manner.
According to this aspect, the stroke center position of the reciprocating movement of the driving element is changed by the switch apparatus.
According to a further aspect of the hammer tool according to the present invention, the switch apparatus is configured to be manually operable by a user.
According to this aspect, as the switch apparatus is manually operable by a user, a user can change the stroke center position of the reciprocating movement of the driving element according to an operation aspect.
According to a further aspect of the hammer tool according to the present invention, the hammer tool comprises a control apparatus which controls the switch apparatus. Further, the control apparatus is configured to change the stroke center position by controlling the switch apparatus.
According to this aspect, as the control apparatus controls the switch apparatus and thereby changes the stroke center position, the stroke center position is automatically changed.
According to a further aspect of the hammer tool according to the present invention, the hammer tool comprises a first sensor which measures reaction force caused by the hammering operation of the tool bit. Further, the control apparatus is configured to control the switch apparatus based on a measured result of the first sensor and change the stroke center position.
According to this aspect, the control apparatus controls the switch apparatus based on the reaction force caused by the hammering operation of the tool bit. Accordingly, the stroke center position of the reciprocating movement of the driving element is automatically changed based on a reaction force level of the reaction force.
According to a further aspect of the hammer tool according to the present invention, the hammer tool comprises a second sensor which measures a position of the tool bit. Further, the control apparatus is configured to control the switch apparatus based on a measured result of the second sensor and change the stroke center position. Further, the second sensor may directly detect the position of the tool bit or detect the position of the tool bit by detecting the position of the hammering element.
According to this aspect, the control apparatus controls the switch apparatus based on the position of the tool bit. Accordingly, the stroke center position of the reciprocating movement of the driving element is automatically changed based on the position of the tool bit.
According to a further aspect of the hammer tool according to the present invention, the hammer tool comprises a third sensor which measures vibration caused on the main body. Further, the control apparatus is configured to control the switch apparatus based on a measured result of the third sensor and change the stroke center position.
According to this aspect, the control apparatus controls the switch apparatus based on a vibration level of the vibration caused on the main body. Accordingly, the stroke center position of the reciprocating movement of the driving element is automatically changed based on the vibration caused on the main body.
According to a further aspect of the hammer tool according to the present invention, the hammer tool comprises a fourth sensor which measures a parameter applied on the driving apparatus, the parameter indicating a load state of the hammer tool. Further, the control apparatus is configured to control the switch apparatus based on a measured result of the fourth sensor and change the stroke center position.
Further, the parameter indicates the load state of the hammer tool corresponds to, for example, current of a motor or a heat generation of the motor.
According to this aspect, the control apparatus controls the switch apparatus based on the load state of the hammer tool. Accordingly, the stroke center position of the reciprocating movement of the driving element is automatically changed based on the load state of the hammer tool.
According to a further aspect of the hammer tool according to the present invention, the driving apparatus comprises a motor and a crank mechanism which is rotationally driven by the motor. The crank mechanism comprises a crank shaft which has an eccentric shaft, the crank shaft rotationally driven by the motor, and a swing member which is connected to the eccentric shaft swingably around the eccentric shaft. The hammer tool further comprises a connecting member which connects the swing member and the driving element, one end side of the connecting member is swingably connected to the swing member and the other end side is swingably connected to the driving element, and a control member one end side of which is swingably connected to the swing member and the other end side of which is swingably connected to a support part arranged on the main body. Further, the stroke center position is changed by changing a position of the support part. Further, the position of the support part may be configured to be automatically changed or manually changeable by a user.
According to this aspect, the stroke center position is changed by changing the position of the support part of the control apparatus.
According to a further aspect of the hammer tool according to the present invention, the hammer tool comprises a switch apparatus for changing the stroke center position, a control apparatus which controls the switch apparatus, and a fifth sensor which measures load applied on the support part. Further, the control apparatus is configured to control the switch apparatus based on a measurement result of the fifth sensor and change the stroke center position.
According to this aspect, a position of the support part is automatically changed based on the load applied on the support part.
According to a further aspect of the hammer tool according to the present invention, a stroke length of the driving element is changed when the stroke center position is changed.
According to this aspect, the stroke length of the driving element is changed due to a position change of the driving element. In such a case, it is preferable that when the stroke center position is moved to be close to the tool bit, the stroke length becomes shorter, and when the stroke center position is moved to be remote from the tool bit, the stroke length becomes longer. Thus, the hammer tool is appropriately driven according to operation aspects.
According to a further aspect of the hammer tool according to the present invention, the hammer tool comprises a connection rod which is connected to the driving element, and a crank mechanism which is connected to the connection rod and drives the driving element. While the driving element is moved from a bottom dead center which is the most remote from the tool bit to a top dead center which is the closest to the tool bit, a straight line passing a connecting part of the connection rod and the driving element and a connecting part of the connection rod and the crank mechanism is arranged to be parallel to the cylinder. Further, the driving element typically corresponds to a piston which slides within the cylinder.
At the bottom dead center which corresponds to 0 degree crank angle and the top dead center which corresponds to 180 degrees crank angle, the velocity of the driving element in a moving direction of the driving element becomes equal to zero. That is, to drive the hammering element toward the tool bit while the driving element is moved from the bottom dead center to the top dead center is reasonable. For example, in an air driving type hammer tool, as the hammering element is slidable, air inside the cylinder maximally compressed while the driving element is moved from the bottom dead center to the top dead center is preferable. According to the aspect, while the driving element is moved from the bottom dead center to the top dead center, the connection rod is arranged to be parallel to the cylinder. Accordingly, in a maximally compressed status, force in a direction crossing the moving direction of the driving element is prevented from applying on the driving element. Thus, friction loss between the driving element and the cylinder is reduced. As a result, the driving element is efficiently driven.
According to a further aspect of the hammer tool according to the present invention, with respect to a crank angle of the crank mechanism, the bottom dead center corresponds to 0 degree crank angle and the top dead center corresponds to 180 degrees crank angle. Further, when the driving element is located at substantially 90 degrees crank angle position during a rotation from the bottom dead center to the top dead center, the connection rod becomes parallel to the cylinder.
In the hammer tool in which the driving element is driven by the crank mechanism, velocity of the driving element toward the tool bit becomes maximum speed in substantially 90 degrees crank angle position of the crank mechanism. For example, in the hammer tool in which the tool bit is hit by utilizing an air spring, when the driving element is located at substantially 90 degrees angle position on the way to the top dead center from the bottom dead center, an air chamber which serves the air spring is defined to be maximally compressed. Accordingly, it is preferable that at the substantially 90 degrees crank angle position, the connection rod becomes parallel to the cylinder. Further, in this aspect, the substantially 90 degrees means a range between 70 degrees through 110 degrees.
Further, according to a further aspect of the hammer tool according to the present invention, when the connection rod is parallel to the cylinder, the hammering element is configured to start to move toward the tool bit. According to this aspect, force applied on the driving element in a direction crossing the moving direction of the driving element is reduced. Thus, friction loss between the driving element and the cylinder is reduced. As a result, kinetic energy of the driving element is efficiently transmitted to the hammering element.
Further, according to a further aspect of the hammer tool according to the present invention, a rotation center of the crank mechanism is arranged to be offset from a reciprocating moving line of the driving element moved inside the cylinder with respect to a direction crossing the reciprocating moving line.
According to this aspect, the rotation center of the crank mechanism is offset from the reciprocating moving line of the driving element in the direction crossing the reciprocating moving line. Accordingly, by adjusting an offset amount, the connection rod is easily set to be parallel to the cylinder while the driving element is moved from the bottom dead center to the top dead center.
Further, according to a further aspect of the hammer tool according to the present invention, the crank mechanism comprises a rotatable crank shaft and an eccentric shaft connected to the crankshaft at a position eccentric from a rotational axis of the crank shaft. Further, the hammer tool further comprises a swing member which is interveningly arranged between the eccentric shaft and the connection rod and swingably connected to both of the eccentric shaft and the connection rod respectively, and a control member one end side of which is swingably supported on the main body and the other end side of which is swingably connected to the swing member.
According to this aspect, as the swing member is arranged between the eccentric shaft and the connection rod, when the eccentric shaft is rotated, a connecting part of the swing member which is connected to the connection rod performs an orbital motion along substantially ellipse track. The longitudinal axis of the ellipse extends along the moving direction of the driving element. Thus, a moving amount of the connecting part in the moving direction of the driving element is larger than a moving amount of the eccentric shaft in the moving direction of the driving element. That is, with respect to the moving direction of the driving element, the moving amount of the eccentric shaft is amplified and transmitted to the driving element. Therefore, a moving amount of the eccentric shaft in a direction crossing the moving direction of the driving element is much smaller than the moving amount of the driving element. Accordingly, swing angle of the connection rod becomes smaller and thereby interference of the connection rod against the cylinder is prevented. Further, axial length of the connection rod may be shortened. As a result, the driving apparatus is able to be arranged close to the cylinder. Thus, downsizing of the hammer tool is achieved.
Further, according to a further aspect of the hammer tool according to the present invention, the hammer tool comprises a first support part which connects the swing member and the connection rod in a swingable manner to each other, and a second support part which connects the swing member and the control member in a swingable manner to each other. Further, the eccentric shaft is arranged between the first support part and the second support part in an extending direction of a line passing the first support part and the second support part.
According to this aspect, each component of the crank mechanism is rationally arranged.
Accordingly, an improved hammer tool which is capable of performing a rational hammer operation is provided.
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 hammer tools and method for using such hammer 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 is explained as below with reference to
As shown in
A hand grip 107 held by a user is connected to an opposite end region which is opposite to the front end region. The hand grip 107 is provided as a substantially D-shaped main handle in a side view, in which it is extended in a vertical direction of
In the first embodiment, for convenience of explanation, the hammer bit 119 side of the main housing 101 in a longitudinal direction of the main housing 101 is defined as a front side or a forward side, the hand grip 107 side of the main housing 101 is defined as a rear side or a rearward side.
As shown in
Moreover, torque of the electric motor 110 is transmitted to the hammer bit 119 via the tool holder 159 after its rotation speed is decelerated by the motion transmitting mechanism. 150, and then the hammer bit 119 is rotationally driven in its circumference direction. The tool holder 159 is housed within the main housing 101 and holds the hammer bit 119 at the front end region (left hand side of
As shown in
As shown in
As shown in
Next, the link type crank mechanism 160 for linearly reciprocating the piston 131 is explained with reference to
The crank shaft 161 is rotatably supported by the main housing 101 and rotated by the driven bear 123. The crank shaft 161 has a crank pin 162 which is arranged at a position offset from the rotation center of the crank shaft 161 in a predetermined distance in a radial direction of the crank shaft 161. Further, the crank shaft 161 is arranged such that its rotation axis is offset from a moving center axis of the piston 131 in a predetermined distance in a direction crossing the moving center axis of the piston 131. One end of the connection rod 165 in its axial direction is connected in a relatively rotatable manner to the piston 131 via a piston pin 164. The crank pin 162 is an example of a feature which corresponds to “an eccentric shaft” of the present invention.
The link 163 is arranged so as to extend perpendicular to a longitudinal direction of the piston 131. Further, an intermediate region in the extending direction of the link 163 is connected in a relative rotatable (swingable) manner to the crankpin 162 of the crankshaft 161. Further, one end of the link 163 in its extending direction is rotatably connected to the other end of the connection rod 165 in its axial direction via the link pin 166.
The control lever 167 is arranged so as to extend in the front-rear direction. One end of the control lever 167 is connected in a relatively rotatable manner to other end of the link 163 in its extending direction via a connection pin 168. Further, the other end of the control lever 167 is connected in a swingable manner to the main housing 101. Accordingly, the control lever 167 swings and thereby controls movement of the link 163. In other words, the control lever 167 is provided as a regulation member which regulates the degree of freedom of movement of the link 163 such that the link type crank mechanism 160 performs a predetermined operation.
In the hammer drill 100 constructed above, when the electric motor 110 is tuned on and driven, the piston 131 is linearly moved within the cylinder 141 via the link type crank mechanism 160. Accordingly, air pressure in the air chamber 141a is fluctuated, and thereby the striker 143 is moved forward by the air spring effect. As a result, the impact bolt 145 hits the hammer bit 119. On the other hand, the motion transmitting mechanism 150 rotates the tool holder 159 together with the hammer bit 119 around the longitudinal direction of the hammer bit 119. Thus, the hammer bit 119 performs a hammering operation in its axial direction and a drilling operation around the axial direction, and thereby operation on a workpiece such as concrete and so on is performed.
The piston 131 is reciprocated between the top dead center and the bottom dead center. When, the piston 131 is moved forward from the bottom dead center to the top dead center, the striker 143 is moved forward via the air spring effect of the air chamber 141a and hits the hammer bit 119 via the impact bolt 145. As shown in
In the hammer drill 100 which drives the striker 143 via the air spring effect of the air chamber 141a, maximum air compression state of the air chamber 141a is defined by positions of the piston 131 and the striker 143. As shown in
The inventor found that the hammering reaction force applied to the striker 143 is changed based on a kind of a workpiece, especially hardness of the workpiece. Further, a return speed or a return amount of the striker 143 is changed by such a fluctuation of the reaction force. As a result, distance between the piston 131 and the striker 143 is changed. That is, when workpiece is hard, distance between the piston 133 and the striker 143 becomes short, and when workpiece is soft, distance between the piston 133 and the striker 143 becomes long. Accordingly, the inventor found that impact energy transmitted to the hammer bit 119 is changed based on change of the distance between the piston 133 and the striker 143.
Taking the above description into consideration, in order to suppress the fluctuation of the impact energy, the hammer drill 100 controls the distance between the piston 131 and the striker 143 by changing the center position of a stroke of reciprocal movement of the piston 131 based on hardness of a workpiece. Thus, as shown in
As shown in
As shown in
The electrical actuator 175 is controlled by the controller 113 illustrated in
As shown in
The hammering reaction force sensor 181 is an example of a feature which corresponds to “a first sensor” of the present invention, and the position sensor 183 is an example of a feature which corresponds to “a second sensor” of the present invention, and the vibration sensor 185 is an example of a feature which corresponds to “a third sensor” of the present invention, and the load sensor 187 is an example of a feature which corresponds to “a fifth sensor” of the present invention.
One of the sensors described above may be utilized independently. On the other hand, some of the sensors may be utilized together. Further, the electrical actuator 175 is controlled such that it adjusts rotational angel of the control shaft 171 in a continuously variable manner. That is, the stroke center position of the piston 131 is adjusted not only in two positions of its front position and rear position but also in any positions between the front point and the rear position. On the other hand, the stroke center position of the piston 131 may be switched in a multistage manner.
If the controller 113 detects based on the result of from the sensor that the hardness of a workpiece is hard, the controller 113 drives the electrical actuator 175 such that the eccentric shaft 172 of the control shaft 171 is moved forward. Thus, the swinging fulcrum of the control lever 167 is moved forward. Accordingly, the link 163 is rotated in a clockwise direction in
On the other hand, if the controller 113 detects based on the result from the sensor that the hardness of a workpiece is soft, the controller 113 drives the electrical actuator 175 such that the eccentric shaft 172 of the control shaft 171 is moved rearward. Thus, the swinging fulcrum of the control lever 167 is moved rearward. Accordingly, the link 163 is rotated in a counter-clockwise direction around the crank pin 162, and the piston 131 is moved forward via the connection rod 165. That is, the stroke center position of the piston 131 is moved forward. As a result, the distance between the piston 131 and the striker 143 is decreased.
As described above, according to the first embodiment, the stroke center position of the piston 131 is moved based on the hardness of a workpiece, and thereby the distance between the piston 131 and the striker 143 is adjusted according to the workpiece. Accordingly, variation in impact energy transmitted to the hammer bit 119 is suppressed. That is, the characteristic of the air spring of the air chamber 141a is controlled according to the hardness of a workpiece, and the hammer drill 100 is driven under an appropriate hammering performable status.
Further, in a state that the hammering reaction force is not occurred before the hammering operation, the piston 131 is controlled such that the stroke center position of the piston 131 is located at a forward position within a movable area. Accordingly, lack of rearward movement of the striker 143 by the air chamber 141a is prevented.
Further, according to the first embodiment, the controller 113 changes the stroke center position of the piston 131 according to the hardness of a workpiece. That is, the controller 113 automatically changes the position of the piston 131 based on the hardness of a workpiece.
Further, according to the first embodiment, the piston 131 is driven by the link type crank mechanism 160. Accordingly, as the stroke center position of the piston 131 is changed, a stroke length of the piston 131 is changed. As a straight line which passes a rotational center of the crank shaft 161 and is perpendicular to a piston moving direction is defined as a reference line, when an angle theta 1 between the reference line and a line connecting the link pin 166 and the connection pin 168 when the piston 131 is located in the bottom dead center substantially equals to an angle theta 2 between the reference line and the line connecting the link pin 166 and the connection pin 168 when the piston 131 is located in the top dead center, the stroke length of the piston 131 becomes the longest. On the other hand, when the angle theta 1 and the angle theta 2 are different to each other, the larger the angle difference is, the shorter the stroke length of the piston 131 becomes.
In the first embodiment, the angle difference between the angle theta 1 and theta 2 when the stroke center position of the piston 131 is moved rearward is defined to be smaller than the angle difference between the angle theta 1 and the theta 2 when the stroke center position of the piston 131 is moved forward. Therefore, when the stroke center position of the piston 131 is moved forward, the stroke length of the piston 131 becomes shorter, and when the stroke center position of the piston 131 is moved rearward, the stroke length of the piston 131 becomes longer. Accordingly, as the stroke length is changed due to the changing of the stroke center position of the piston 131, controllable region of the characteristic of the air spring is appropriately defined when the hammer drill 100 is manufactured.
In the first embodiment, the stroke center position of the piston 131 is changed according to the hardness of a workpiece, however it is not limited to this. For example, before and after a timing of the hammering operation is started in which the striker 143 is resting, the stroke center position of the piston 131 may be changed. Specifically, before the hammering operation is started, in order to move actively the resting striker 143, the stroke center position of the piston 131 may be moved to a front side which is close to the hammer bit 119. After the hammering operation is started, and when the striker 143 is driven in a predetermined stroke, the stroke center position of the piston 131 may be moved to a rear side which is remote from the hammer bit 119.
Further, in the first embodiment, the stroke center position of the piston 131 is changed automatically, however it is not limited to this. For example, as shown in
In such a construction in which a user manually operates and switches the operation lever 177, before the hammering operation by the hammer drill 100, a user operates the operation lever 177 based on the hardness of a workpiece in such a manner illustrated by continuous lines and double-dashed lines in
Next, a second embodiment is explained with reference to
Further, a configuration in which the controller controls the electrical actuator and a configuration to measure the hardness of a workpiece are similar to the configuration of the first embodiment.
According to the second embodiment, similar to the first embodiment, the stroke center position of the piston 131 is changed according to the hardness of a workpiece. Therefore, the characteristic of the air spring of the air chamber 141a is controlled according to the hardness of a workpiece. As a result, the hammer drill 100 is driven under an appropriate hammering performable status.
Next, a third embodiment is explained with reference to
The link pin 166 which connects the crank mechanism 160 and the connection rod 165 is an example of a feature which corresponds to “a first support part” according to the present invention. Further, the control lever 167 is an example of a feature which corresponds to “a control member” according to the present invention. Further, the connection pin 168 which connects the control lever 167 and the link 163 is an example of a feature which corresponds to “a second support part” according to the present invention.
The piston 131 reciprocally moves between the top dead center and the bottom dead center. Further, the piston 131 moves forward from the bottom dead center to the top dead center through the position illustrated in
In the third embodiment, as shown in
Accordingly, when the piston 131 moving from the bottom dead center to the top dead center is moved to the position of approximately 90 degrees in the crank angle, the air chamber 141a becomes the maximally compressed status. At this time, the connection rod 165 and the moving line (R) of the piston 131 is to be parallel to each other. Therefore, a force direction applied to the piston 131 by the connection rod 165 is matched with the moving direction of the piston 131. That is, the piston 131 is prevented from being biased by force in the direction crossing the moving direction of the piston 131. Thus, the piston 131 is prevented from being pressed against the inner wall of the cylinder 141. As a result, friction loss between the piston 131 and the cylinder 141 is reduced and thereby the piston 131 is efficiently driven.
Further, according to the third embodiment, in the crank mechanism 160, the link 163 is swingably and interveningly provided between the crank pin 162 and the connection rod 165. Thus, as the crankpin 162 is rotated, the link 163 is swung around the connection pin 168 as a fulcrum, which connects the link 163 and the control lever 167. Accordingly, as shown in
A distance between the link pin 166 and the connection pin 168 is longer than a distance between the crank pin 162 and the connection pin 168. That is, the link pin 166 is located further away from the connection pin 168 than the crankpin 162. Therefore, a moving amount of the rink pin 166 in a direction parallel to the moving line (R) is larger than a moving amount of the crank pin 162 in the direction parallel to the moving line (R). That is, moving amount of the crankpin 162 is amplified and transmitted to the piston 131 in the moving direction of the piston 131. In other words, the moving amount is increased by the principle of leverage. Therefore, a moving amount of the crank pin 166 in a direction crossing the moving line (R) is smaller than a moving amount of the piston 131. Accordingly, a swing angle of the connection rod 165 becomes to be smaller. As a result, interference between the connection rod 165 and the cylinder 141 is avoided. Further, axial length of the connection rod 165 is able to be shorter. Further, as the crank shaft 161 is able to be provided proximal to the cylinder 141, to downsize the hammer drill 100 is achievable.
Further, according to the third embodiment, as the crank pin 162 is arranged between the link pin 166 and the connection pin 168, each components of the crank mechanism 160 is rationally arranged.
Next, a fourth embodiment is explained with reference to
As shown in
According to the fourth embodiment, similar to the third embodiment, when the piston 131 moving from the bottom dead center to the top dead center is moved to the position of approximately 90 degrees in the crank angle, the air chamber 141a becomes the maximally compressed status. At this time, the connection rod 139 and the moving line (R) of the piston 131 is to be parallel to each other. Therefore, a force direction applied to the piston 131 by the connection rod 139 is matched with the moving direction of the piston 131. That is, the piston 131 is prevented from being biased by force in the direction crossing the moving direction of the piston 131. Thus, the piston 131 is prevented from being pressed against the inner wall of the cylinder 141. As a result, friction loss between the piston 131 and the cylinder 141 is reduced and thereby the piston 131 is efficiently driven.
Further, in the embodiments described above, the hammer drill 100 as one example of the hammer tool is utilized to explain, however it is not limited to this. For example, the present invention may be applied to a hammer in which the hammer bit 119 performs only hammer operation. Further in the hammer tool, the piston 131 may hit directly the striker 143.
Taking into consideration the above objects of the present invention, the following aspects of the hammer tool according to the present invention are configurable.
(Aspect 1)
An hammer tool which at least linearly drives a tool bit at least linearly in a longitudinal direction of the tool bit and performs a hammering operation on a workpiece, comprising:
The hammer tool according to Aspect 1, as an angle corresponding to the bottom dead center is defined as 0 degree and an angle corresponding to the top dead center is defined as 180 degrees with respect to a crank angle of the crank mechanism,
The hammer tool according to Aspect 1 or 2, when the connection rod is parallel to the cylinder, the hammering element is configured to start toward the tool bit.
(Aspect 4)
The hammer tool according to any one of Aspects 1 to 3, wherein a rotation center of the crank mechanism is arranged offset from a reciprocating moving line of the piston which is moved in the cylinder with respect to a direction crossing the reciprocating moving line.
(Aspect 5)
The hammer tool according to according to anyone of Aspects 1 to 4, wherein the crank mechanism comprises a rotatable crank shaft and an eccentric shaft which is connected to the crank shaft at a position eccentric from a rotation axis of the crank shaft,
The hammer tool according to Aspect 5, wherein a moving amount of the piston is configured to be larger than a moving amount of the eccentric shaft in a moving direction of the piston.
(Aspect 7)
The hammer tool according to Aspect 5 or 6, comprising a first support part which connects the swing member and the connection rod in a swingable manner to each other, and a second support part which connects the swing member and the control member in a swingable manner to each other,
The hammer tool according to claim 11, wherein the switch apparatus comprises an operation member which is operable by a user, and a support member which is provided as a movable member of which position is changed due to movement of the operation member,
The hammer tool according to claim 11, wherein the switch apparatus comprises an operation member which is operable by a user, and a movable member of which position is changed due to movement of the operation member,
The correspondence relationships between the constituent elements of the present embodiments and the constituent elements of the present invention are as follows. Furthermore, the present embodiments describe one example of a mode for carrying out the present invention, but the present invention is not limited to the configuration of the present embodiments.
The main housing 101 is one example of a structural element which corresponds to “a main body” of the present invention.
The hammer bit 119 is one example of a structural element which corresponds to “a tool bit” of the present invention.
The electric motor 110 is one example of a structural element which corresponds to “a motor” of the present invention.
The piston 131 is one example of a structural element which corresponds to “a driving element” of the present invention.
The striker 143 is one component or portion of “a hammering element” of the present invention.
The bottom dead center is one example of a structural element which corresponds to “a first position” of the present invention.
The top dead center is one example of a structural element which corresponds to “a second position” of the present invention.
The crank mechanism 133 is one example of a structural element which corresponds to “a crank mechanism” of the present invention.
The crank shaft 161 is one example of a structural element which corresponds to “a crank shaft” of the present invention.
The crank pin 162 is one example of a structural element which corresponds to “an eccentric shaft” of the present invention.
The link 163 is one example of a structural element which corresponds to “a swing member” of the present invention.
The connection rod 165 is one example of a structural element which corresponds to “a connection member” of the present invention.
The control lever 167 is one example of a structural element which corresponds to “a control member” of the present invention.
The eccentric shaft 172 is one example of a structural element which corresponds to “a switch apparatus” of the present invention.
The electrical actuator 175 is one example of a structural element which corresponds to “a switch apparatus” of the present invention.
The eccentric shaft 172 is one example of a structural element which corresponds to “a support part” of the present invention.
The controller 113 is one example of a structural element which corresponds to “a control apparatus” of the present invention.
The hammering reaction force sensor 181 is one example of a structural element which corresponds to “a first sensor” of the present invention.
The position sensor 183 is one example of a structural element which corresponds to “a second sensor” of the present invention.
The vibration sensor 185 is one example of a structural element which corresponds to “a third sensor” of the present invention.
The load sensor 187 is one example of a structural element which corresponds to “a fifth sensor” of the present invention.
The current sensor is one example of a structural element which corresponds to “a fourth sensor” of the present invention.
100 hammer drill
101 main housing
107 hand grip
107
a trigger
110 electric motor
111 output shaft
113 controller
119 hammer bit
120 motion converting mechanism
121 driving gear
123 driven gear
131 piston
133 crank mechanism
135 crank shaft
137 crank pin
139 connection rod
140 hammering element
141 cylinder
141
a air chamber
143 striker
145 impact bolt
150 motion transmitting mechanism
151 intermediate gear
153 intermediate shaft
155 small bevel gear
157 large bevel gear
159 tool holder
160 crank mechanism
161 crank shaft
162 crank pin
163 link
164 piston pin
165 connection rod
166 link pin
167 control lever
168 connection pin
171 control shaft
172 eccentric shaft
173 arm
175 electrical actuator
175
a working element
177 operation lever
181 hammering reaction force sensor
183 position sensor
185 vibration sensor
187 load sensor
Number | Date | Country | Kind |
---|---|---|---|
2012-193582 | Sep 2012 | JP | national |
2012-193583 | Sep 2012 | JP | national |
Filing Document | Filing Date | Country | Kind |
---|---|---|---|
PCT/JP2013/073355 | 8/30/2013 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2014/034862 | 3/6/2014 | WO | A |
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Oct. 8, 2013 International Search Report issued in International Patent Application No. PCT/JP2013/073355. |
Dec. 22, 2015 Office Action issued in Japanese Patent Application No. 2012-193583. |
Dec. 22, 2015 Office Action issued in Japanese Patent Application No. 2012-193582. |
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Mar. 3, 2015 International Preliminary Report on Patentability issued in International Patent Application No. PCT/JP2013/073355. |
Number | Date | Country | |
---|---|---|---|
20150246438 A1 | Sep 2015 | US |