DE102006012963B4 - Locking device for an output shaft of a power tool - Google Patents

Abstract

The present invention discloses a locking device for an output shaft of a rotary power tool. The locking device comprises a blocking plate having a plurality of first connecting portions and at least one coupling portion; a driver having a plurality of evenly spaced insert portions; a lock ring disposed on the outer peripheries of the insert portions; and a plurality of locking pins, which is inserted in the driver, disposed between the locking plate and the locking ring. The first connecting portions of the locking plate are mounted on the insert portions so as to be disposed in the driver, and the coupling portion is disposed on the upper surfaces of the insert portions, so that the lock plate is inserted into the driver to reduce the depth of the driver and To increase the depth of the blocking plate and therefore to reinforce the structures that are used to firmly lock the output shaft.

Description

Field of the invention

The present invention relates to a lock device for a main shaft, and more particularly to a lock device for an output shaft of a rotary power tool.

Background of the invention

A rotating power tool can serve both as an electric drill and as an electric screwdriver, provided that a chuck for clamping a drill or screwdriver bit is present, which can be electrically operated or hand-operated.

In a conventional rotary power tool, an electric motor directly drives the chuck to rotate via a deceleration mechanism, and in the case where the rotary power tool serves as an electric screwdriver, the motor rotates the driver bit directly at the front end of the chuck; and in the case where the rotary power tool is used to turn screws, an opposite negative rotational force is generated against the output shaft coupling with the chuck, which operates against the motor, whereby the screwdriver can not be hand-operated.

Therefore, a locking mechanism to be mounted to the output shaft of the deceleration mechanism is introduced, and in the case where the motor rotates the output shaft positively, the locking mechanism allows the output shaft to be driven; while in the case where a negative rotational force is applied to the output shaft, the locking mechanism immediately disables the output shaft so that the output shaft can not rotate, whereby the output shaft is locked and the rotary power tool can be used as a hand tool.

US 6,311,787 B1 relates to a drill in which a drive shaft can be locked automatically. An anvil includes three flat surfaces and three drive finger receiving surfaces over which the anvil is disposed on the inner surfaces of three spaced drive fingers of a planetary carrier. An annular roller cage with three pairs of cage fingers receives three rollers as well as the drive fingers.

DE 297 15 257 U1 describes a driving device for a spindle of a motor-driven, hand-held working tool. A sheet metal part comprises three driving openings, in which engage three axial claws of a gear. Clamping elements are arranged between an outer wall of the sheet metal part and a housing-fixed ring. The clamp bodies can be unlocked by means of unlocking elements.

The Taiwanese utility model TW 443 165 U revealed as in the 3 to 4B shown a locking device which is mounted on an output shaft of a rotating power tool.

As in 3 shown, the locking device for an output shaft of a rotating power tool assigns a locking ring 21 in a housing (not shown). A rotating driver 22 is in the lock ring 21 arranged and an insert section 221 is on a forward facing surface of the driver 22 arranged. The insert section 221 defines a variety of grooves 222 in its outer circumference, arranges a plurality of protruding ribs 223 on its inner circumference and houses an output shaft 23 that in the insert section 221 is used. A variety of recessed grooves 231 that the protruding ribs 223 on the inner circumference of the insert section 221 is further in a coupling portion of the output shaft 23 , with the insert section 221 is coupled, defined, so that the output shaft 23 firmly in the driver 22 can be used. The input end of the driver 22 is coupled to a deceleration mechanism and a motor (not shown) such that the driver 22 the output shaft 23 drives to turn to output a driving force, as in 4A shown.

A curved surface 232 is between each adjacent recessed grooves 231 educated. At least two rolling pins 24 are in corresponding opening grooves 222 in a direction parallel to the output shaft 23 arranged. The width of each of the recessed grooves 231 is slightly larger than that of each of the protruding ribs 223 , In the case where a negative force is applied, the output shaft performs either a slight, positive, deflecting rotation or a negative, deflecting rotation; and if the output shaft 23 makes such a distracting turn push the arched surfaces 232 the rolling pins 24 so that the rolling pins 24 against the inner periphery of the fixed locking ring 21 issue. Therefore, as in 4B shown the output shaft 23 completely locked and can not turn. The power tool can thus be hand-operated, since no driving force from the electric motor is present, and z. B. a hand-operated screwdriver instead of an electric screwdriver.

However, in the above conventional technology, the driver holds 22 and the insert section 221 of which the whole positive or negative to the output shaft 23 applied torsion force, whereby, when the driving force on the same component, the driver concentrated, the component easily breaks due to excessive distortion. As a result, in the above conventional technology, the driver breaks 22 easily, resulting in a reduced life for the rotating power tool that uses the structure. At the same time presents the variety of grooves 222 an open surface, causing the rolling pins 24 fall out easily, making assembly more difficult.

5 illustrates another locking device for an output shaft of a rotating power tool. As shown, the locking device for an output shaft of a power tool comprises at least one driver 31 ; a blocking plate 33 ; a locking ring 35 ; and a plurality of locking pins 37 , The driver 31 includes insert sections 311 similar to the insert section 221 of the driver 22 according to the aforementioned prior art, wherein the insert sections 311 are equally spaced from each other. Inner circumferences of the insert sections 311 are used to pick up the locking ring 35 used. The locking pins 37 are in the columns that are between the lock ring 35 and a portion of the lock plate 33 where the insert sections 311 protrude, trained, arranged. At the same time, the depth h1 of the blocking plate 33 generally equal to that of the locking ring 35 ,

However, in the above conventional lock devices, the lock plate carries 33 the driver and in the case where the output shaft 23 turns abruptly, the output shaft can 23 because of the low weight or coarse surface of the driver 31 not be locked immediately, causing the output shaft 23 is locked after turning over a certain angle. Furthermore, the total length of the conventional locking device is the sum of the depth of the driver 31 and the depth of the lock plate 33 where the depth of the locking plate 33 is relatively low, causing the blocking plate 33 due to a twist easily breaks. In addition, the locking pins 37 simply because of the small depth of the driver 31 separated. At the same time, only the insert sections hold 311 of the driver, whether rotating or locked, the driving force was in conventional locking devices, whereby the insert sections 311 at the connecting portion of the driver 31 break easily.

Accordingly, it is desirable to provide a structure for a locking device of an output shaft of a rotary power tool, which can lock the output shaft immediately and has a reinforced structure, thereby eliminating the disadvantages of short life and the difficulties encountered with conventional locking devices.

Summary of the invention

With respect to the disadvantages of the above-mentioned conventional technologies, the primary object of the present invention is to provide a locking device for an output shaft of a rotary electric power tool having a reinforced structure for immediately locking the output shaft.

It is another object of the present invention to provide a locking device for an output shaft of a rotary power tool that reduces the overall length thereof.

In accordance with the above and other objects, the present invention provides a locking device for an output shaft of a rotary power tool, the locking device primarily comprising: a blocking plate, a dog, a locking ring and at least three locking pins.

The lock plate includes at least three first connection portions and at least one coupling portion extending outward from an upper surface of the lock plate. The driver comprises at least three spaced insert portions, wherein the blocking plate is disposed in inner peripheries of the insert portions via the first connecting portions and the coupling portion of the blocking plate is disposed on upper surfaces of the insert portions. The locking ring is arranged on outer peripheries of the insert sections. At least three locking pins are inserted into the space between the at least three insert sections and positioned between the locking plate and the locking ring.

Preferably, the first connecting portions are recessed grooves or guide rails.

The insert portions are selected from protruding blocks, protruding ribs, recessed portions and protruding flanges. In one embodiment of the present invention, the depth of the lock plate is less than or equal to the depth of the follower; and in an alternative embodiment, the depth of the lock plate is greater than or equal to the depth of the follower.

Preferably, the locking ring comprises a second connecting portion which is arranged on the outer circumference of the insert portions. The second connection section is a Through hole. The driver further includes a third connecting portion for disposing the blocking plate. The third connection portion is a through hole. The lock plate further includes a fourth connection portion. The fourth connection portion is a D-shaped lock opening.

In the case where the cam is driven to rotate positively, the output shaft is positively driven to rotate in synchronism with the cam; while in the case where the output shaft is driven to rotate negatively, the blocking plate is driven to perform a deflecting rotation, so that the locking pins are pushed so as to abut against the insert portions and restrict the movement of the locking pins. In this case, the lock pins block the lock plate so that the lock plate 13 the output shaft locks, allowing the rotating power tool to be manually operated.

The lock plate of the present invention is inserted into the cam, which reduces the depth of the cam and increases the depth of the lock plate, whereby the problem resulting from the small depth of the lock plate can be solved. The reinforced structures of the lock plate and the driver do not break easily in the locked state; therefore, they can be firmly applied to lock the output shaft immediately.

At the same time, the blocking plate is disposed in the driver, which reduces the depth of the insert sections without reducing the overall strength. Moreover, the dog is driven uniformly due to the coupling portions, which prevents the insert portions of the dog from easily breaking, and solves the problem in the prior art that occurs in the connecting portion of the dog. Moreover, the locking pins are arranged in a closed space, which is cooperatively formed by the inner periphery of the lock ring, the space between the adjacent insert portions of the follower and the outer periphery of the lock plate. The closed space prevents the locking pins from slipping during assembly.

It should be understood by those skilled in the art that the above description is illustrative only of specific embodiments and examples of the present invention. The present invention is therefore intended to cover various modifications and changes made to the structure and functions of the present invention described herein.

Brief description of the drawings

1 Fig. 10 is an exploded isometric view of an embodiment of the output shaft blocking device of a rotary power tool of the present invention;

2 Fig. 10 is an isometric view of an embodiment of the output shaft locking device of a rotary power tool of the present invention in the assembled state;

3 Fig. 10 is an exploded isometric view of a conventional output shaft locking device of a rotary power tool;

4A Fig. 12 is a schematic sectional view showing a conventional output shaft locking device which outputs a driving force positively;

4B Fig. 12 is a schematic sectional view showing a conventional output shaft locking device which outputs a driving force negatively; and

5 Fig. 10 is an exploded isometric view of an alternative conventional locking device for an output shaft of a rotary power tool.

Detailed Description of the Preferred Embodiments

The following embodiments are described to explain the features of the present invention in detail, which should not be construed as limiting the scope of the present invention.

Referring to 1 For example, the present invention primarily comprises a locking ring 11 , a driver 12 , a blocking plate 13 and a plurality of locking pins 14 , It should be noted that the locking device for an output shaft of a rotary electric tool as an example for locking a main shaft (such as the output shaft 15 in the present embodiment) and can be used in conventional power tools whose structures and operations are similar to those given herein. To clearly describe the features of the present invention, those structures and descriptions that are not related to the present invention are omitted hereinbelow.

As in 1 shown is the lock ring 11 a fixed component in one Gear for a power tool (not shown) is arranged. One side of the driver 12 is coupled to a gear drive assembly (not shown) and the other side is with a plurality of evenly spaced insert portions 121 arranged annularly, wherein the insert sections 121 projecting blocks, protruding ribs or other equivalent structures. The lock plate 13 includes a plurality of first connection portions 131 and a plurality of coupling sections 133 wherein the first connecting portions 131 can be recessed grooves, guide rails or other equivalent structures, the protruding blocks or projecting ribs of the insert sections 121 correspond; and the coupling sections 133 are structures that extend from an upper surface of the blocking plate 13 extend to the outside.

As in 2 are shown, the first connecting portions during assembly 131 in the driver 12 through the inner peripheries of the insert sections 121 arranged; the coupling sections 133 the locking plate 13 be on the top surfaces of the insert sections 121 arranged; the locking ring 11 becomes at the outer peripheries of the insert sections 121 arranged; and the locking pins 14 be in the driver 12 , arranged between the blocking plate 13 and the locking ring 11 used. At the same time, the locking ring 11 a second connecting portion 111 such as B. include a through hole that is used to the driver 12 , the lock plate 13 and the locking pins 14 record; the driver 12 may further include a third connection portion 123 such as B. comprise a through hole, for arranging the locking plate 13 is used. It should be understood that the above assembly sequence is not to be considered as limiting the scope of the present invention.

Although the driver 12 the present embodiment with five insert sections 121 such as B. protruding blocks or protruding ribs may be formed, the structure and number of insert sections 121 not to be considered as limiting the scope of the present invention. For example, there may be three, four or more insert sections 121 be trained; and the insert portions may be recessed portions, protruding flanges, or other equivalent structures, and thus are not limited to those shown by way of example in the figures. At the same time, in the present invention, the plurality of coupling portions 133 in accordance with the first connection sections 131 arranged; while in other embodiments only one coupling section 133 may be arranged, provided the coupling section 133 at right angles to those on the upper surface of the insert sections 121 arranged first connecting portions 131 and extends outward from them. That is, in the present invention, at least one coupling portion 133 arranged, extending from the first connecting sections 131 attached to the top surface of the insert sections 121 are arranged, extending outwards. In addition, the third connection section 123 also be cross-shaped, rectangular, zigzag or other equivalent shaped structures over which the locking plate 13 at the output shaft 15 is mounted.

The lock plate 13 is disposed in the space which is annular through the inner periphery of the insert portions 121 of the driver 12 is formed, so that the locking plate 13 can perform a distracting rotation in it. The lock plate 13 forms a plurality of thrust sections 135 that relate to the first connecting sections 131 are arranged offset. The lock plate 13 may further include a fourth connecting portion 137 comprising, wherein the fourth connecting portion 137 a D-shaped locking hole or other equivalent structure for mounting the output shaft 15 can be.

The locking pins 14 are arranged in the space cooperatively through the inner periphery of the locking ring 11 , the space between the adjacent insert sections 121 of the driver 12 and the push sections 135 the locking plate 13 is formed. The distance between two adjacent insert sections 121 of the driver 12 is greater than the diameter of each of the locking pins 14 so the locking pins 14 to be able to roll distractingly. The output shaft 15 gets into the driver 12 and the lock plate 13 in a manner described hereinafter, which should not be taken as limiting the scope of the present invention. For example, as in 1 shown is a first end 151 the output shaft 15 for insertion in the driver 12 and the lock plate 13 is used at the fourth connection portion 137 the locking plate 13 mounted and extends through the third connecting portion 123 of the driver 12 ; and a second end 153 the output shaft 15 is used to mount a chuck (not shown) for mounting screwdriver bits or drills.

In the case where the driver 12 is driven to turn positively, the output shaft 15 positively driven to get in sync with the driver 12 to turn; while in the case where the output shaft 15 is driven to turn negative, the lock plate 13 is driven to perform a deflecting rotation.

As a result, the locking pins become 14 through the push sections 135 the locking plate 13 to the application sections 121 pushed out, leaving the locking pins 14 be pushed so that they are against the insert sections 121 abut, so as to move the locking pins 14 restrict, after which the locking pins 14 the blocking plate 13 block, leaving the lock plate 13 the output shaft 15 locks, whereby the rotating power tool can be manually operated.

Therefore push the push sections 135 the locking plate 13 the locking pins 14 in a locked position, so the output shaft 15 in the case where the output shaft 15 Negatively powered, lock. In summary, in the case where the output shaft 15 positively driven, the driver 12 driven to the output shaft 15 to turn synchronously; while in the case where the output shaft 15 Negatively driven, between the driver 12 and the locking ring 11 inserted locking pins 14 be pushed so that they are against the locking plate 13 abut the output shaft 15 lock, whereby a rotating power tool can be hand-operated without energy provided.

Comparing the 2 to 5 , is the thickness of a conventional locking plate 33 h1, whereas the blocking plate 13 the present invention in the driver 12 whose thickness is the sum of h1 and h2 (equal to H, as in 2 shown), which is the thickness h1 of a conventional barrier plate 33 clearly exceeds. In addition, the upper surfaces of the locking plate 13 with the upper surface of the locking ring 11 - or slightly deeper than this - aligned. Accordingly, the present invention solves the problem in which the insert portion 121 of the driver 12 is easily broken in the conventional technology, and effectively shortens the length of the locking device for an output shaft of a rotary power tool.

At the same time are the coupling sections 133 extending from the lock plate 13 extend to the outside, with the driver 12 in the direction of the total thickness in contact, causing the driver 12 is driven uniformly, and as a result, the insert portions break 121 of the driver not easy. Therefore, the present invention enhances the structure so as to eliminate the difficulties resulting from the short life of the conventional technology. In addition, the coupling sections extend 133 outwardly to be located on the driver and so the friction between the locking plate 13 and the driver 12 to reduce; and the extending structure of the coupling portions 133 also strengthens the locking plate 13 so that the lock plate 13 in the locked state does not break easily. Furthermore, the present invention provides sufficient structural strength and the lock plate 13 can take a certain depth in the driver 12 extend so as to shorten the length of the locking device for an output shaft of a rotating power tool. That is, the depth H is less than or at most equal to the thickness of the driver; However, in other embodiments, the depth H of the lock plate may be greater than or equal to the thickness of the follower 12 be.

In addition, the locking pins 14 arranged in a closed space, which cooperatively through the inner periphery of the locking ring 11 , the space between the adjacent insert sections 121 of the driver 12 and the outer periphery of the lock plate 13 is formed. The closed space prevents the locking pins 14 slip during assembly to facilitate assembly and solve the problem of slippage of conventional structures.

It should be understood by those skilled in the art that the above description is illustrative only of specific embodiments and examples of the present invention. It is therefore intended that the present invention cover various modifications and changes to the structure and functions of the present invention described herein provided they come within the scope of the present invention as defined in the appended claims.

Claims (9)

Locking device for an output shaft ( 15 ) of a rotary power tool, which comprises at least: a blocking plate ( 13 ) with at least three first connecting sections ( 131 ) and at least one coupling section ( 133 ) extending from an upper surface of the locking plate ( 13 ) extends outwards; a driver ( 12 ) with at least three spaced insert sections ( 121 ), wherein the blocking plate ( 13 ) in inner peripheries of the insert sections ( 121 ) over the first connecting sections ( 131 ) is arranged and the coupling section ( 133 ) of the blocking plate ( 13 ) on upper surfaces of the insert sections ( 121 ) is arranged; a locking ring ( 11 ) at the outer peripheries of the insert sections ( 121 ) is arranged; and at least three locking pins ( 14 ), which are in the space between the at least three spaced insert sections ( 121 ) and between the locking plate ( 13 ) and the locking ring ( 11 ) are arranged. Locking device for an output shaft ( 15 ) of a rotary power tool according to claim 1, wherein said first connecting portions ( 131 ) are recessed grooves. An output shaft locking device of a rotary electric tool according to claim 1, wherein said first connecting portions (16) 131 ) Guide rails are. Locking device for an output shaft ( 15 ) of a rotary power tool according to claim 1, wherein the insert sections ( 121 ) are selected from protruding blocks, protruding ribs, recessed portions and protruding flanges. Locking device for an output shaft ( 15 ) of a rotary power tool according to claim 1, wherein the height of the blocking plate ( 13 ) less than or equal to the height of the driver ( 12 ). Locking device for an output shaft ( 15 ) of a rotary power tool according to claim 1, wherein the height of the blocking plate ( 13 ) greater than or equal to the height of the driver ( 12 ). Locking device for an output shaft ( 15 ) of a rotary power tool according to claim 1, wherein the locking ring ( 11 ) a through hole ( 111 ) located on the outer periphery of the insert sections ( 121 ) is arranged. Locking device for an output shaft ( 15 ) of a rotary power tool according to claim 1, wherein the driver ( 12 ) further comprises a through hole ( 123 ) for arranging the blocking plate ( 13 ). Locking device for an output shaft ( 15 ) of a rotary power tool according to claim 1, wherein the blocking plate ( 13 ) Furthermore, a D-shaped locking opening ( 137 ) for connection to the output shaft ( 15 ).

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