The present invention relates to a hammer drill adapted to apply an axial striking force against a rotatingly driven output bit through the use of reciprocating movement of a striker caused by means of a motion conversion member.
Hammer drills are employed to do a task of, e.g., drilling a concrete structures. There arises such an instance that a screw is tightened to an anchor embedded into a hole formed by the drilling work. However, typical hammer drills are always accompanied by striking motion and therefore cannot be used in tightening the screw, which requires the additional use of an electric driver.
Also known in the art is a hammer drill of the type capable of releasing a striking motion and transmitting only a rotation force to an output bit. This type of hammer drill has no ability to tighten the screw with a suitable torque but tends to, not infrequently, tighten the screw too heavily.
In the meantime, Japanese Patent Laid-open Publication Nos. 2000-233306 and H7-1355 disclose a vibratory drill and an impact drill wherein a vibratory load or an impact load can be released and a tightening torque can be controlled using a tightening-torque adjusting clutch. However, no tightening-torque adjusting clutch has heretofore been employed in the hammer drills in which an axial striking force is applied against a rotatingly driven output bit through the use of an axially reciprocating striker. For this reason, the conventional hammer drills still require the use of an electric driver to perform the task of tightening a screw as noted above.
It is, therefore, an object of the present invention to provide a hammer drill that can deactivate axial striking motion and further can allow a user to control a screw tightening torque with the use of a tightening-torque adjusting clutch.
In accordance with the present invention, there is provided a hammer drill including: a motor; a spindle rotatingly driven by the motor and holding an output bit; a motion conversion member for converting rotational movement of the motor to reciprocating movement; a striker reciprocatingly driven by the motion conversion member for applying an axial striking force to the output bit; a striking-motion-releasing mechanism for releasing the striking force applying action exercised by the striker; and a tightening-torque adjusting clutch for interrupting the transfer of the rotational force to the output bit by increasing a load torque.
The above and other objects and features of the present invention will become apparent from the following description of preferred embodiments, given in conjunction with the accompanying drawings, in which:
The present invention will now be described with reference to the embodiments illustrated in the accompanying drawings. In accordance with a first preferred embodiment of the present invention, a connecting shaft 13 is operatively connected to an output shaft 10 of a motor through gears 11 and 12, as shown in
The motion conversion member 2 includes a rotating portion 20 affixed to and rotatable with the connecting shaft 13 as a unit, an outer race 21 rotatably fitted to an inclined surface of the rotating portion 20, and a rod 22 protruding from the outer race 21. The rod 22 is connected to a piston 30 that can be moved within a cylinder 3 along an axial direction thereof. As the connecting shaft 13 rotates, the rod 22 and the outer race 21 are subjected to oscillating movement because the connection of the rod 22 to the piston 30 restrains any rotation of the rod 22 and the outer race 21 relative to the connecting shaft 13. This reciprocates the piston 30 in an axial direction.
The cylinder 3 is rotatable about its axis, on the outer circumferential surface of which a rotating body 40 having a gear meshed with the pinion 14 of the connecting shaft 13 is coupled for sliding movement in an axial direction of the cylinder 3 and also for rotational movement with respect to the cylinder 3. At one side of the rotating body 40, a clutch plate 41 is secured to the cylinder 3 by means of a key 49.
The rotating body 40 is of a ring shape and has a plurality of axially penetrating holes into which steel balls 42 are received. A clutch spring 45 is disposed to press a ball retainer 44 against the steel balls 42. Pressing action of the clutch spring 45 brings the steel balls 42 into engagement with conical engaging recesses formed on the clutch plate 41.
During the time when the steel balls 42 retained in the holes of the rotating body 40 are engaged with the recesses of the clutch plate 41, the rotating body 40 rotates about the axis of the cylinder 3 together with the clutch plate 41 as a unit, thereby ensuring that the rotational force of the connecting shaft 13 is transmitted to the cylinder 3 through the rotating body 40 and the clutch plate 41.
The clutch spring 45 that makes contact with the ball retainer 44 at one end is supported at the other end by means of a movable plate 46 lying around the outer periphery of the cylinder 3. Along with the rotation of a clutch handle 48, the movable plate 46 can be moved in an axial direction of the cylinder 3 to thereby change the level of compression of the clutch spring 45.
A spindle 5 is attached to an axial front end of the cylinder 3 for unitary rotation with the cylinder 3. The spindle 5 is provided at its axial front end with a chuck portion 51 for holding an output bit 50 in such a manner that the output bit 50 can be rotated with the chuck portion 51 as a unit and also can be slid axially within a limited range of movement.
The spindle 5 is further provided with a ball 56 for preventing any backward removal of an intermediate member 52, which is retained within the spindle 5 in an axially slidable manner, and a ball 57 for restraining the retractable movement of the intermediate member 52 at a position in front of the ball 56. As shown in
The piston 30 is of a cylindrical shape having a closed rear end and an opened front end. A striker 35 is slidably received within the piston 30. As the piston 30 makes reciprocating movement, the striker 35 is also caused to reciprocate, at which time the air within the space of the piston 30 enclosed by the striker 35 plays a role of an air spring. Disposed on the inner circumference of the rear end portion of spindle 5 is an O-ring 58 that resiliently engages with the outer circumference of the front end portion of the striker 35 to prevent backward movement of the striker 35.
The backward movement of the intermediate member 52 is restrained under the condition illustrated in
Concurrently, the rotational movement of the connecting shaft 13 is converted to reciprocating movement of the piston 30 by virtue of the motion conversion member 2. At this moment, the striker 35 is kept retained by the spindle 5, for the reason of which the striker 35 does not make any reciprocating movement and therefore only the rotational force is applied to the output bit 50.
At the time when a task of tightening, e.g., a screw, using the rotating output bit 50, if the load torque becomes greater than the engaging force between the steel balls 42 and the recesses of the clutch plate 41 caused by the clutch spring 45, the steel balls 42 are escaped from the recesses thus inhibiting any transfer of the rotational force of the rotating body 40 to the clutch plate 41 (cylinder 3). This restrains the tightening torque.
The tightening torque can be increased by turning the clutch handle 48 in the manner as set fort above so that the movable plate 46 can be moved backward to increase the level of compression of the clutch spring 45. This means that the rotating body 40 and the clutch plate 41 cooperate with the steel balls 42, the movable plate 46 and the clutch spring 45 to form a tightening-torque adjusting clutch 4. In addition, spherical recesses are formed on the portions of the ball retainer 44 with which the steel balls 42 make rolling contact.
If the restraint piece 47 is removed from around the ball 57 by the backward movement of the movable plate 46 as shown in
Referring to
In accordance with the second preferred embodiment, a striking-motion-activated mode can be shifted to a striking-motion-deactivated mode and vice versa regardless of the tightening torque adjusted. Thus, the hammer drill of the second preferred embodiment includes a mechanism for making the tightening-torque adjusting function inoperative in the striking-motion-activated mode by directly connecting the rotation transfer members through the use of the tightening-torque adjusting clutch 4.
The mechanism includes a pin 8 for directly coupling the rotating body 40 serving as a driving member to the clutch plate 41 functioning as a driven member, a spring 80 for pressing the pin 8 toward a position where the direct coupling takes place, and a conversion plate 81 for pushing the pin 8 against the spring 80 into a release position where the direct coupling is released. In the illustrated embodiment, the conversion plate 81 is adapted to interlock with the movement of the collar 15.
Specifically, in order to have the collar 15 engaged with the rotating portion 20 to perform the striking motion in concert with the rotating motion as depicted in
The holes 402 formed through the rotating body 40 for receiving the steel balls 42 have a pitch circle differing from that of the holes 408 for accommodating the pin 8 and the spring 80 as clearly shown in
In this regard, the engaging groove 480 is of a comb-like shape, i.e., has a portion extending in a circumferential direction of the clutch handle 48 and a plurality of axially extending portions. In the striking-motion-activated mode, i.e., hammer drill mode, the lever 79 enters one of the axially extending portions (“X” in
The connecting shaft 13 is operatively connected to an output shaft 10 of the motor 19 through gears 11 and 12. The connecting shaft 13 is provided at its front end with the pinion 14 integrally formed therewith. The motion conversion member 2 is disposed at an intermediate part of the connecting shaft 13. The motion conversion member 2 includes the rotating portion 20 affixed to and rotatable with the connecting shaft 13 as a unit, the outer race 21 rotatably fitted to an inclined surface of the rotating portion 20, and the rod 22 protruding from the outer race 21. The rod 22 is connected to the piston 30 that can be moved within the cylinder 3 along an axial direction.
The collar 15 that forms the engaging clutch in cooperation with the rotating portion 20 is provided on the connecting shaft 13 in such a fashion that the collar 15 can rotate with the connecting shaft 13 as a unit and also can be slid in an axial direction with respect to the connecting shaft 13. The collar 15 is pressed against the rotating portion 20 by means of the spring 16 into engagement with the rotating portion 20 to thereby transfer the rotational force of the connecting shaft 13 to the rotating portion 20. As the rotating portion 20 makes rotational movement, the rod 22 and the outer race 21 whose rotation about the connecting shaft 13 is restrained by the connection to the piston 30 are subjected to oscillating movement. This causes the piston 30 to reciprocate in its axial direction.
If the switching handle 7 (see
The cylinder 3 is rotatable about it axis, on the outer circumferential surface of which the rotating body 40 having a gear meshed with the pinion 14 of the connecting shaft 13 is coupled for sliding movement in an axial direction of the cylinder 3 and also for rotational movement with respect to the cylinder 3. At one side of the rotating body 40, the clutch plate 41 is secured to the cylinder 3.
The rotating body 40 is of a ring shape and has a plurality of axially penetrating holes into which the steel balls 42 are received. The clutch spring 45 is disposed to press a ball retainer (thrust plate) 44 against the steel balls 42. Pressing action of the clutch spring 45 brings the steel balls 42 into engagement with conical engaging recesses formed on the clutch plate 41.
During the time when the steel balls 42 retained in the holes of the rotating body 40 are engaged with the recesses of the clutch plate 41, the rotating body 40 rotates about the axis of the cylinder 3 together with the clutch plate 41 as a unit, thereby ensuring that the rotational force of the connecting shaft 13 is transmitted to the cylinder 3 through the rotating body 40 and the clutch plate 41. The clutch spring 45 that makes contact with the ball retainer 44 at one end is supported at the other end by means of a movable plate 46 lying around the outer periphery of the cylinder 3. Along with the rotation of the clutch handle 48, the movable plate 46 can be moved in an axial direction of the cylinder 3 to thereby change the level of compression of the clutch spring 45.
The pin 8 for directly coupling the rotating body 40 serving as a driving member to the clutch plate 41 functioning as a driven member (see
The conversion plate 81 is disposed around the outer circumference of the cylinder 3 in an axially movable manner. If the conversion plate 81 is pressed by the spring 82 to move forward, the distal end of the direct-coupling pin 8 is placed at a boundary surface of the rotating body 40 and the clutch plate 41 as illustrated in
The spindle 5 is attached to the axial front end of the cylinder 3 for unitary rotation with the cylinder 3. The spindle 5 is provided at its axial front end with the chuck portion 51 for holding the output bit 50″. The chuck portion 51, which corresponds to an SDS-plus type shank, includes a removal-inhibiting ball 510 and a rotation-transferring internal protrusion 511 (see
The piston 30 is of a cylindrical shape having a closed rear end and an opened front end. The striker 35 is slidably received within the piston 30. As the piston 30 makes reciprocating movement, the striker 35 is also caused to reciprocate, at which time the air within the space of the piston 30 enclosed by the striker 35 plays a role of an air spring. By the reciprocating movement thus caused, the striker 35 applies a striking force to the output bit 50″ in an axial direction through the intermediate member 52 axially slidably retained within the spindle 5. Reference numeral 56 in the drawings designates a ball for keeping the intermediate member 52 from backward removal out of the spindle 5.
In the process of tightening, e.g., a screw, through the use of the rotating output bit 50″ in the striking-motion-deactivated mode, if the load torque becomes greater than the engaging force between the steel balls 42 and the clutch plate 41 imparted by the clutch spring 45, the steel balls 42 are escaped from the engaging recesses of the clutch plate 41, thus interrupting the transfer of the rotational force from the rotating body 40 to the clutch plate 41 (cylinder 3). This restrains the tightening torque.
The tightening torque can be increased by turning the clutch handle 48 as set forth above and displacing the movable plate 46 backward to increase the level of compression of the clutch spring 45. This means that the rotating body 40 and the clutch plate 41 cooperate with the steel balls 42, the movable plate 46 and the clutch spring 45 to form a torque-adjusting clutch 4. At the time when the clutch spring 45 has been compressed to the maximum extent by the manipulation of the clutch handle 48, the steel balls 42 is kept in a condition that it cannot be escaped from the engaging recesses. This condition is suitable for what is called a drilling work.
Under the situation illustrated in
The switching handle 7 is adapted to displace the collar 15 out of engagement with the rotating portion 20. The pressing force of the spring 16 is used in causing the collar 15 to move toward and smoothly engage with the rotating portion 20. The spring 16 is designed to have a pressing force greater than that of the spring 82 for pressing the conversion plate 81. Furthermore, the pressing force of the spring 82 is greater than that of the spring 80 for pressing the direct-coupling pin 8.
In the meantime, such an output bit 50″ as a drill bit or a driver bit is provided with no SDS-plus type shank for use with the hammer drill and therefore is mounted with the use of an adapter 50′ having the SDS-plus type shank. The SDS-plus type shank employed in the adapter 50′ differs somewhat from a typical SDS-plus type shank shown in
More specifically, as illustrated in
Thus, even when the output bit 50″ such as a drill bit or a driver bit is mounted through the adapter 50′ in the striking-motion-activated mode, i.e., hammer drill mode, where the rotational force and the striking force are applied jointly, there is no possibility that the striking force is applied to the adapter 50′. This also precludes the possibility that the adapter 50′, the output bit 50 such as a drill bit or a driver bit, and the screw or the like in contact with the distal end of the output bit 50″ are damaged by the striking vibration. In addition, the striker 35 continues to be retained in position by means of the O-ring 58 for the reasons noted above.
In the event that, as the output bit 50″, a hammer drill bit having the typical SDS-plus type shank illustrated in
The slide groove 501 of the adapter 50′ differs not only in length but also in inner end shape from that of the typical shank. The internal protrusion 511 has a front end comprised of a flat inclined surface. For this reason, if the front end of the internal protrusion 511 makes contact with the inner end of the slide groove 501 of the typical shank shown in
In this regard, the adapter 50′ may be stored, when not in use, within a holder portion 95 provided in the connecting portion 92 of the housing 9. As depicted in
In order to store the adapter 50′ carrying the output bit 50″ in the holder portion 95 with no removal of the output bit 50″, the front end of the output bit 50″ is inserted into the void part 953 as illustrated in
In addition to the above, the connecting portion 92 is shaped not to protrude forward over a line joining the lower end of the battery pack 91 and the front end of the hammer drill (see
The hammer drill in accordance with the present invention performs an operating mode where a rotational force alone is transferred to an output bit, while allowing a user to control a screw tightening torque with the use of a tightening-torque adjusting clutch. This makes it possible for a single hammer drill to carry out two kinds of works, namely, a task of drilling an object member, such as a concrete structure or the like, and a task of tightening a screw.
While the invention has been shown and described with respect to the preferred embodiments, it will be understood by those skilled in the art that various changes and modifications may be made without departing from the scope of the invention as defined in the following claims.
Number | Date | Country | Kind |
---|---|---|---|
2005-154701 | May 2005 | JP | national |
2005-357011 | Dec 2005 | JP | national |
This application is a divisional of pending U.S. patent application Ser. No. 11/441,141, filed on May 26, 2006, which claims priority to Japanese Patent Applications No. 2005-154701, filed on May 26, 2005 and No. 2005-357011, filed on Dec. 9, 2005.
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Number | Date | Country | |
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Parent | 11441141 | May 2006 | US |
Child | 12472988 | US |