KR20170125446A - Multi-stage drive - Google Patents

Abstract

The present invention relates to a multi-stage driver and, more specifically, to a multi-stage driver which is a single driver comprising drivers having different thicknesses in multiple stages to be applied to screws of bolts having various sizes and used. To this end, the multi-stage driver comprises: a first bit unit having a first driver blade on one end thereof and a first hollow unit formed in the longitudinal direction inside a body; a second bit unit having a second driver blade corresponding to the shape of the first driver blade on one end thereof, and having an outer circumferential surface formed in a shape corresponding to the shape of the first hollow unit to slide in the longitudinal direction inside the first hollow unit; and a handle unit provided on the other side of the first bit unit and the second bit unit to press the other end of the second bit unit.

Description

Multistage Driver {MULTI-STAGE DRIVE}

The present invention relates to a multi-stage driver. More particularly, the present invention relates to a multi-stage driver in which drivers having different thicknesses are formed in a multi-stage manner and can be applied to screws or bolts of various sizes with one driver.

A screwdriver is a tool used to fasten screws or bolts. There are many kinds of drivers, but generally there are one (1) and ten (10) drivers. These drivers are classified into various standards depending on the size of screws or bolts to be fastened. For example, a relatively large screw is used for a relatively large screw or bolt, and a small screw is used for a relatively small screw or bolt requiring a small fastening force. In addition, the specifications of the driver to be fastened in accordance with the standard of a screw or the like are also changed.

It is necessary to use a screwdriver or a screw suitable for a bolt or the like. If a large screwdriver is used for a small screw or a small screwdriver is used for a large screw, the screwdriver or the screwdriver groove may be damaged because the screwdriver is used in an inconsistent state in a screwdriver formed in the head of a screw or the like. Screws, bolts, etc. are consumables, so if damaged, replace them with new ones. However, if the screw groove is damaged in the state where the screw is fastened, or if the screw is damaged instead of the screw, it may become very difficult to remove the screw or the like, or an expensive screwdriver may be discarded. Therefore, in the industrial field, drivers of various sizes are used, and a driver of an appropriate size suitable for the driver groove is used.

In general, however, it is often difficult or inefficient to provide a wide variety of drivers because drivers are not routinely used in homes. Therefore, it would be good if one screw driver can be used for screws of various sizes.

KR 20-0341634 Y1

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and it is an object of the present invention to provide a multi-step driver that can fasten or unscrew a screw or the like using a single driver It has its purpose.

The present invention as a technical means for solving the above problems is characterized in that a first bit portion having a first driver blade formed at one end thereof and a first hollow portion formed along the longitudinal direction inside the body; A second driver blade corresponding to the shape of the first driver blade is formed at one end and the outer peripheral surface is formed in a shape corresponding to the shape of the first hollow portion so that the sliding movement is performed along the longitudinal direction inside the first hollow portion A second bit portion configured to extend at a longer end than the other end of the first bit portion; And a grip portion provided on the other side of the first bit portion and the second bit portion to press the other end of the second bit portion.

According to a preferred embodiment of the present invention, the second bit portion has a second hollow portion formed along the longitudinal direction inside the body, and a second hollow portion is formed on the inner side of the second hollow portion, A driver blade is formed and an outer circumferential surface thereof is formed in a shape corresponding to the shape of the second hollow portion so as to slide along the longitudinal direction inside the second hollow portion and the other end is extended longer than the other end of the second bit portion And the handle portion may be structured such that the 2-bit portion and the 3-bit portion sequentially move while sliding.

In a preferred embodiment of the present invention, a first position adjusting groove is formed on the outer circumferential surface of the first bit portion, and a first elastic protrusion is formed on the other outer circumferential surface of the second bit portion, And a first protrusion formed to protrude outward on the other side of the first elastic part, and the handle part is formed on the inner side of the first elastic part, When the handle is slid to one side, the other side of the pressurized workpiece presses the other end of the second bit portion so as to slide.

In a preferred embodiment of the present invention, a first position adjusting groove is formed on the other side of the first bit portion, a first elastic protrusion is formed on the other side of the second bit portion, and the second bit portion is transmitted by the handle portion And the second positioning groove is formed on the outer circumferential surface of the other side of the second bit portion and the second positioning groove is formed on the other side of the third bit portion, A second elastic protrusion may be formed such that the third bit is slid to one side by a force transmitted by the handle and then inserted when the second elastic protrusion meets the second position adjusting groove.

In a preferred embodiment of the present invention, the first elastic projection may have a weaker elastic force than the second elastic projection.

In a preferred embodiment of the present invention, the first elastic protrusion has a first elastic portion configured such that a body portion of the first bit portion tapers toward the other side and the other end is configured as a free end, and a second elastic portion formed on the other side of the first elastic portion, And the second elastic protrusion has a second elastic part formed so that a part of the body of the third bit part tapers toward the other side and the other end is formed as a free end, and a second elastic part formed on the other side of the second elastic part, And the second elastic part may be formed to be thinner or longer than the second elastic part.

In a preferred embodiment of the present invention, the handle portion is formed with a pressing force inward, and when the knob is slid to one side, the other side of the pressing force presses the other end of the third bit and the second bit, . ≪ / RTI >

In the preferred embodiment of the present invention, two latching grooves are formed along the longitudinal direction on the outer peripheral surface of the first bit portion, and the latching portion is provided with a latching hook detachably attached to the latching groove, And can be selectively detached and fixed to the latching groove.

According to a preferred embodiment of the present invention, three latching grooves are formed on the outer circumferential surface of the first bit portion, and the latching portion is provided with a latching hook which is removably inserted into the latching groove, So that it can be fixed.

According to the multi-stage driver of the present invention, since one screwdriver can be used for screws and bolts of various sizes, it is possible to use the screwdriver efficiently, and it is possible to reduce the cost of installing the driver, There is an advantage that it is possible to solve the troublesome problem of

1 is a perspective view of a multi-stage driver according to the present invention;
2 is an exploded view of a multi-stage driver according to the present invention.
3 is a cross-sectional view of a multi-stage driver according to the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is a perspective view of a multi-stepped driver according to the present invention, FIG. 2 is an exploded view of a multi-stepped driver according to the present invention, and FIG. 3 is a cross-sectional view of a multi-stepped driver according to the present invention.

1 to 3, the multi-stage driver according to the present invention includes a bit unit 100 and a knob unit 200, and the bit unit 100 includes two or three bits in multiple stages If the thickness of the bit unit 100 permits, it may be formed of three or more stages. Hereinafter, a two-step driver and a three-step driver will be described as an example. However, the attached drawings show a three-step driver. The two-step driver is similar to the second bit unit 130 and the third bit unit 150 in the figure, in which case the second elastic protrusion 157 Need not be provided.

The bit portion 100 includes a first bit portion 110 having a first driver blade 111 formed at one end thereof and a first hollow portion 113 formed along the longitudinal direction of the body portion, A second driver blade 131 corresponding to the shape of the first driver blade 111 is formed and the outer circumferential surface of the first driver blade 111 has a shape corresponding to the shape of the first hollow portion 113, And a second bit unit 130 inserted into the first bit unit 130 and configured to be able to slide along the length direction. The driver blade may be configured as a ten-sided driver shape as shown in the figure, or may be configured as a one-sided driver shape, though not shown in the drawings. The second bit unit 130 included in the first bit unit 110 may be slidable in the longitudinal direction with respect to the first bit unit 110 but not rotated in the circumferential direction. Accordingly, the outer circumferential surface of the first hollow portion 113 and the second bit portion 130 inserted into the first hollow portion 113 is preferably polygonal. However, it is needless to say that a variety of well-known structures may be used as long as the second bit unit 130 can move only in the longitudinal direction without rotating in the first hollow unit 113. For example, even if the first hollow portion 113 is circular, a groove is formed along the longitudinal direction on the inner side surface, and a protrusion corresponding to the groove is formed on the outer peripheral surface of the second bit portion 130, Or a known structure such as a sawtooth structure of the outer circumferential surface of the first hollow portion 113 and the second bit may be applied.

The reason that the second driver blade 131 is formed in a shape corresponding to the first driver blade 111 is that the first driver blade 111 and the second driver blade 131 have the same shape, And the second bit portion 130 is inserted into the first hollow portion 113 formed in the first bit portion 110, the first driver bit 111 and the second bit portion 130 2 driver blade 131 are formed so as to have an integrated feeling. That is, the first driver blade 111 and the second driver blade are combined to form a natural and complete type of driver blade (see Fig. 3 (A)). The outer circumferential surface of the second bit portion 130 corresponds to the first hollow portion 113 when the first hollow portion is formed of a polygonal shape, The first hollow portion 113 may have the same size and shape as the hollow portion and may be inserted into the first hollow portion 113 to be slidable. In this case, the entire outer peripheral surface of the second bit portion 130 does not have to correspond to the shape of the first hollow portion 113, and the second bit portion 130 is formed in the first hollow portion 113 In the longitudinal direction may correspond to some or all of the sections so as to allow the elements to slide in the longitudinal direction without rotating in the circumferential direction.

When the first driver blade 111 and the second driver blade 131 are coupled to coincide with each other, the other end of the second bit 130 is connected to the other end of the first bit 110, So that the second bit unit 130 can be pressed by using the knob 200 to be described later. The configuration of the knob portion 200 and the method of pressing the second bit portion 130 using the knob portion 200 will be described later.

A first position adjustment groove 115 may be formed on the outer circumference of the first bit 110 and a first elastic projection 137 may be formed on the outer circumference of the second bit 130. The first elastic protrusion 137 includes a first elastic portion 137a having a free end formed so that a part of the body of the second bit portion 130 is tapered toward the other side and a second elastic portion 137b formed on the other side of the first elastic portion 137a And a first protrusion 137b configured to protrude outward. In this case, the second bit portion 130 is inserted into the first hollow portion 113 described above. As will be described later, the first projection portion 137b is fitted inside the first hollow portion 113 The first elastic part 137a is configured to be parallel to the outer circumferential surface of the body of the second bit unit 130 and the inner side of the first elastic part 137a is tapered toward the outer circumferential surface toward the other side (free end) . However, as described below, the structure of the present invention is not limited thereto. As described later, if the first elastic portion 137a is bent so as to touch the inner surface of the first hollow portion 113, Can be applied.

The first projecting portion 137b is provided adjacent to the other free end of the first elastic portion 137a and is configured to protrude outward. At this time. It is preferable that the first projection 137b is inclined so that the upper surface of the first projection 137b increases from one side to the other side. This is so that when the first elastic projection 137 meets the first hollow portion 113, the first hollow portion 113 can naturally move along the inclined surface to press the first projection 137b .

The first position adjusting groove 115 is provided on the movement path of the first projection 137b and is configured such that the first projection 137b can be inserted or mounted. For example, as shown in the drawing, the body portion may be formed in a size and shape corresponding to the first projection 137b. At least one first positioning groove 115 is provided, preferably two. When the second bit unit 130 moves to one side, the first protrusion 137b of the second bit unit 130 is inserted into the first position adjustment groove 115a provided at one side, and the second bit unit 130 The first projecting portion 137b can be inserted into the first position adjusting groove 115b in the other direction. A method of adjusting the position of the second driver blade 131 will be described later in detail.

The grip portion 200 is provided on the other side of the bit portion 100 and is configured to be fixed in the circumferential direction on the outer peripheral surface of the first bit portion 110 described above and to be able to slide only in the longitudinal direction. For this purpose, the outer circumferential surface of the first bit unit 110 is polygonal, and the first bit unit 110 is connected to the outer circumferential surface of the first bit unit 110, (Not shown) corresponding to the outer circumferential surface of the first bats 110, so that the first bats 110 can be inserted into the coupling holes. However, since the knob 200 is formed only in the longitudinal direction on the outer peripheral surface of the first bit portion 110, as in the case of the first bit portion and the second bit portion, Various structures known in the art can be applied.

On the inner side of the handle 200, a pressing work 210 is formed. The pressing work 210 includes the first bit unit 110 and the second bit unit 130, which are described above, and the other end of the second bit unit 130 has a free end structure. (130). When the knob 200 is moved to one side, the other side of the pressing portion 210 pushes the other end of the second bit portion 130 so that the second bit portion 130 contacts one side of the first bit portion 110 And protrudes. Thus, the second driver blade 131 protrudes from the first driver blade 111 and can be used as a relatively small driver blade. The fact that the other ends of the bit portions 110 and 130 are formed as free ends in the pressurized medium 210 does not mean only a structure in which the bit portions are not in contact with the outer side surface in the pressing operation, It is a concept that includes all the structures that are not disturbed by studying during pressurization.

On the other hand, the second driver blade 131 must protrude in one direction only when desired by the user, and the longitudinal direction needs to be fixed during use. Therefore, in the multi-stage driver according to the present invention, two latching recesses 119 are formed along the longitudinal direction on the outer circumferential surface of the first bit unit 110 at predetermined intervals, and the latching recesses 119 are detachably attached A hook 230 may be provided. After the second driver blade 131 is aligned with the first driver blade 111 or protruded from the first driver blade 111, the locking hook 230 is fixed to the locking groove 119, The portion 200 can be fixed so as not to move. 2 and 3, the outer circumferential surface of the first bit portion 110 may be recessed, and the striking hook may be formed in the shape of a rim of the handle 200 as shown in FIG. To the coupling surface with the first bit unit 110. The latching hook 230 may have a semicircular shape so that one side of the latching hook 230 can be pivotally coupled to the handle 200 and a middle portion of the latching hook 230 can be inserted into the latching groove 119. When the other side of the hook 230 is pushed outward and released from the grip 200, the hook 230 is released from the hook 119 and the other side of the hook 230 is pushed inward, The central portion of the hook 230 is inserted into the hook groove 119 and hooked. When the latching hook 230 is inserted into the latching groove 119, the knob 200 is fixed to the outer circumferential surface of the first bit 110 and can not slide.

In the case of a three-stage driver, as shown in the figure, the structure of the multi-stage driver according to the present invention is such that the longitudinal direction And the third hollow portion 133 is inserted into the second hollow portion 133 so that the third bit portion 150 can be slidingly moved. At this time, the third driver blade 151 of the third bit part 150 is formed in a shape corresponding to the second driver blade 131 described above, and the outer peripheral surface of the body is formed in the shape of the second hollow part 133 And the other end is configured to extend longer than the other end of the second bit unit 130. [ The second bit portion 110 protruding from the other end of the first bit portion 110 and the other end of the second bit portion 110 protruding from the other end of the first bit portion 110 are formed on the inner side of the pressing portion 210 of the grip portion 200, 130 and the other end of the third bit portion 150 protruding from the other end of the second bit portion 130 is provided in a free end structure.

A second position adjustment groove 135 is formed on the other side of the second bit unit 130 and a second elastic protrusion 157 is formed on the other side of the third bit unit 150, 150 are slid to one side by a force transmitted by the handle 200 and then inserted when the second projection 157b of the second elastic protrusion 157 meets the second positioning groove 135 . That is, the main configuration between the second bit unit 130 and the third bit unit 150 in the three-stage driver is similar to the main configuration between the first bit unit 110 and the second bit unit 130. However, in the case of an external force applied to the bit unit 100 by the knob 200, the second bit unit 130 is connected to the first bit unit 110 together with the third bit unit 150, As shown in Fig. However, since the third bit unit 150 is formed longer than the second bit unit 130 at the other end of the bit unit 100, a direct external force is applied to the third bit unit 150, 130 are not subjected to an external force. Therefore, in the case of the three-speed driver, it is necessary to make the first elastic portion 137a of the first elastic projection 137 be less elastic than the second elastic portion 157a of the second elastic projection 137, have.

For this purpose, the multi-step driver according to the present invention is characterized in that the first elastic protrusion 137 has a first elastic portion 137a formed such that a part of the body of the first bit portion 110 is tapered toward the other side, And a first protrusion 137b configured to protrude outward on the other side of the first elastic part 137a. The second elastic protrusion 157 is formed by a part of the body of the third bit part 150, And a second protrusion 157b protruding outward from the other side of the second elastic part 157a, and the second protrusion 157b is configured to protrude outward on the other side of the second elastic part 157a, One elastic part 137a may be formed thinner or longer (or elongated) than the second elastic part 157a. When the first elastic portion 137a is formed to be thinner or longer (or elongated) than the second elastic portion 157a, the first elastic portion 137a is easily bent by the external force than the second elastic portion 157a It is possible to move first because it is done. However, the above-described structure is a preferred example of the present invention, and various design modifications are possible if the first elastic protrusion 137 can be driven before the second elastic protrusion 157. [ For example, the first position adjusting groove 115b provided on the other side may be made smaller so that a part of the first toe shaft portion 115b may be hooked. The coupling force between the first position adjusting groove 115b and the first elastic projection 137 on the other side is weaker than the coupling force between the second position adjusting groove 135 and the second elastic projection 157 located on the other side, When an external force is applied to the other end of the unit 150, the second bit unit 130 having a weak coupling force may be slid first.

It is preferable that the three-stage driver has three latching recesses 119 formed on the outer circumferential surface of the first bit unit 110. Other configurations of the triple-stage driver are the same as those of the two-stage driver described above, so duplicate descriptions will be omitted.

Hereinafter, the driving principle of the multi-stage driver according to the present invention will be described with reference to a three-stage driver.

When the multistage driver according to the present invention is used as the largest driver blade, all of the driver blades are moved in the other direction so that the driver blades correspond to each other. At this time, it is preferable that each driver blade can move only to a specific position (a position where the three driver blades are combined so as to be mutually symmetrical) in the other direction. For this, as described above, the first position adjusting groove 115 and the second position adjusting groove 135 are formed as a pair (two), respectively. One side of the first position adjusting groove 115 and the second position adjusting groove 135 are located at positions And the other side can engage with the protrusion at a position where the inner adjacent driver blade is at the maximum retracted position. That is, when the first bit unit 110 is referred to as a reference, the first position adjustment groove 115a is engaged with the first protrusion 137b at a position where the second bit unit 130 moves to one side And the first position adjusting groove 115b on the other side may be engaged with the first protrusion 137b at a position where the second bit portion 130 moves to the other side as much as possible. Further, if necessary, means for setting a range in which the second bat part 130 can move to one side or the other side may be further provided on a coupling surface between the first bit part 110 and the second bit part 130 . For example, the above-mentioned means may be modified such that a portion of the first hollow portion 113 is divided into an extended portion (a portion having a larger diameter than the other portion, And a guide protrusion (not shown) that can move only in the extended section is formed on the outer circumferential surface of the second bit unit 130. [ In addition, various known configurations can be applied as long as the second bit can be moved only in a specific section within the first bat.

When the handle 200 is pushed to one side after the engagement hook 230 is disengaged from the engagement groove 119, the handle 200 is moved in one direction. When the knob 200 is moved in one direction, the other side of the pushing protrusion 210 pushes the other end of the third bit unit 150. At this time, the third bit portion 150 is hooked to the second position adjustment groove 135 provided at the other side of the third projection portion 157b, and the second bit portion 130 is engaged with the second projection portion 137b at the other side And the first elastic portion 137a is bent more easily than the second elastic portion 137a because the elastic force of the first elastic portion 137a is weaker than that of the second elastic portion 137a. Accordingly, the knob 300 directly presses the third bit unit 150, but in reality, the second bit unit 130 is first slidably engaged with the third bit unit 150, You can use the day. Finally, when the knob 200 is further pressed, the second elastic part 137a is bent, and the third bit part 150 slides inside the second bit part 130 while sliding. At this time, since the second bit unit 130 can not move to one side any more, the second bit unit 130 stops at that position.

When the driver blade is to be returned to its original position, the driver blade may be pushed in the other direction while gently pressing the protrusions 137b and 157b of the bit portions. To this end, the handle 200 may be configured such that a position corresponding to the first and second elastic portions 137 and 157 or the first and second protrusions 137b and 157b is exposed to the outside. Thus, the first and second protrusions 137b and 157b can be pressed from outside using a tool such as a pin.

After the driver blade is moved to a desired position, the hook 230 described above may be fixed to the hook groove 119 by being fixed thereto.

Although the present invention has been described in connection with certain exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. Therefore, the scope of the present invention should not be limited by the described embodiments, but should be defined by the appended claims and equivalents thereof.

100: bit portion
110: first bit portion
111: first driver blade
113: first hollow portion
115: first positioning groove
119: Retaining groove
130: second bit portion
131: second driver blade
133: second hollow portion
135: second positioning groove
137: first protrusion
150: third bit portion
151: Third Driver Day
157: second protrusion
200: Handle portion
210: Pressurization study
230: Retaining hook

Claims (9)

A first bit portion having a first driver blade formed at one end thereof and having a first hollow portion formed along a longitudinal direction thereof;
A second driver blade corresponding to the shape of the first driver blade is formed at one end and an outer peripheral surface is formed in a shape corresponding to the shape of the first hollow portion so that the sliding movement is performed along the longitudinal direction inside the first hollow portion A second bit portion configured to extend at a longer end than the other end of the first bit portion;
A grip portion provided on the other side of the first bit portion and the second bit portion so as to be able to press the other end of the second bit portion;
And a multi-step driver.
The method according to claim 1,
The second bit portion has a second hollow portion formed along the longitudinal direction inside the body,
A third driver blade having a shape corresponding to the second driver blade is formed at one end of the second hollow portion and an outer peripheral surface of the third driver blade has a shape corresponding to the shape of the second hollow portion, And the other end is configured to extend longer than the other end of the second bit portion,
Wherein the handle portion is configured so that the 2-bit portion and the 3-bit portion can be sequentially moved while sliding.
The method according to claim 1,
A first position adjusting groove is formed on the other outer circumferential surface of the first bit portion and a first elastic protrusion is formed on the other outer circumferential surface of the second bit portion,
The first elastic protrusion may include a first elastic portion formed to be tapered toward the other side of the second bit portion and having a free end at the other end, and a first protrusion configured to protrude outward at the other side of the first elastic portion Respectively,
Wherein the grip portion is formed with an inner pressurized portion so that the other side of the pressurizing member presses the other end of the second bit portion to slide when the handle is slid to one side.
The method of claim 2,
A first position adjusting groove is formed on the other outer circumferential surface of the first bit portion and a first elastic protrusion is formed on the other side of the second bit portion so that the second bit portion is slid to one side by a force transmitted by the grip portion Wherein the first elastic projection is configured to be inserted when the first positioning projection meets the first positioning groove,
A second position adjusting groove is formed on the other outer circumferential surface of the second bit portion and a second elastic protrusion is formed on the other side of the third bit portion so that the third bit portion is slid to one side by a force transmitted by the grip portion And wherein the second elastic projection is configured to be inserted when the second positioning projection meets the second positioning groove.
The method of claim 4,
Wherein the first elastic projection has a smaller elastic force than the second elastic projection.
The method according to claim 4 or 5,
Wherein the first elastic protrusion has a first elastic part configured such that a part of the body of the first bit part tapers toward the other side and the other end is a free end and a first protruding part protruding outward on the other side of the first elastic part Respectively,
The second elastic protrusion may include a second elastic part formed to be tapered toward the other side of the third bit part and a free end, and a second protrusion part configured to protrude outward at the other side of the second elastic part Respectively,
Wherein the first elastic portion is formed to be thinner or longer than the second elastic portion.
The method of claim 6,
Wherein the grip portion is formed with an inner pressurized portion and the other side of the pressurizing member presses the other end of the third bit and the second bit to slide when the handle is slid to one side.
The method of claim 3,
The hook portion is provided with a latching hook detachably attached to the latching groove, so that the latching hook can be selectively attached to and detached from the latching groove, A multistage driver configured to do so.
The method of claim 7,
And three hooking grooves are formed on an outer circumferential surface of the first bit portion, and the hooking portion is provided with a hooking hook that is removable in the hooking groove, so that the hooking hook can be selectively attached to and detached from the hooking groove Multistage drivers.

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