KR101900908B1 - A manual composite Screwdriver - Google Patents

Abstract

The present invention relates to a manual complex screwdriver with high efficiency in bit replacing work and bit storage. To this end, according to the present invention, the manual complex screwdriver comprises: a rotary shaft having a cross-shaped groove longitudinally formed along a periphery; a rear body including a carrier to rotate the rotary shaft while moving along one path or the other path of the cross-shaped groove; a rotational power transmission means installed at an end part of the rotary shaft; a front body detachably attached to one side of the rear body, wherein a bit storage box and a plurality of bits stored in the bit storage box are installed therein; a bit cover to shield the bit storage box, having a plurality of entry holes formed in a circumferential direction to communicate with the outside, and having a central hole formed at the center of the entry holes to communicate with the bit storage box; and a bit driver coupling one end part to the rotational power transmission means and having the other end part protruding to the outside of the front body through the central hole, wherein the bit is detachably attached to the other end part.

Description

[0001] The present invention relates to a manual composite screwdriver,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a passive compound screw driver, and more particularly, to a passive compound screw driver that maximizes rotational torque using a planetary gear assembly and stores a plurality of replacement bits therein, .

In general, screw pieces (screws) are the most important basic parts of fastening elements among many parts used in various mechanical devices and construction work, and are used as fastening means between fastening objects.

A fastening tool such as a screwdriver or a wrench is required to perform the fastening operation using the fastening means.

The fastening means used in the fastening operation varies in shape and dimensions depending on the use and the use.

Therefore, the worker using the fastening means must prepare the fastening tools corresponding to the various fastening means.

As a typical fastening tool, a screw driver for tightening or loosening a screw piece is provided.

A screwdriver is a fastening tool having a bit corresponding to a screw-piece head having a groove in the shape of a letter or cross, such that a screwdriver bit is aligned with the head of the screw-piece and rotated to tighten the screw- It can be solved.

1 is a view showing a conventional screw driver according to the prior art.

As shown in Figure 1, the screwdriver 1 comprises a bit 2 and a handle 3 for rotating the bit 2.

By selecting the bit 2 considering the shape of the head part 5 of the screw piece 4 and aligning the bit 2 with the head part 5 of the screw piece 4 and then rotating the knob 3 The screw pieces 4 are assembled or the screw pieces 4 are loosened.

However, the above-mentioned conventional manual screw driver is tightened or loosened only by the rotational force of the operator, so that there is a problem that rotational torque is different for each worker and it is difficult to increase the rotational torque.

In addition, when a large amount of fastening operation is required, there has been a problem in that the work productivity is deteriorated due to an increase in fatigue of an operator and an excessive time required for the operation.

Further, there is a problem in that it is difficult to cope with various types of screw pieces 4 only with a single screw driver, and a screw driver corresponding to the head portion 5 of each screw piece 4 must be used alternately.

In order to solve this problem, an electric screwdriver has been introduced to improve the convenience of the operator.

However, the electric driver also had the following problems.

First, there is a problem that the electric energy supply must be always performed, thereby limiting the use area.

Of course, although a rechargeable wireless motor is provided, it is troublesome to always check whether or not the battery is charged, and there is a problem that the use time is limited.

Second, there is a problem that the workpiece fatigue easily occurs because it is relatively large in size and heavy in weight compared to a manual screwdriver.

Third, the convenience of replacing and repairing consumables is lower than that of a manual screwdriver, which has a problem of high management cost.

Fourth, since each bit corresponding to each screw-piece head type has to be carried separately, it is necessary to carry and replace the bit, so that there is a problem that it is necessary to bring about a loss of a separate storage and a bit.

In other words, since the portable box in which the electric screwdriver is stored is provided with various types of bits separately stored, it is necessary to always carry the portable box, and there is a possibility that storage in the portable box may be missed after using the bit, It was.

Korea Publication No. 10-2006-0126018 Korean Pub. No. 10-2012-0025796

It is an object of the present invention to provide a passive compound screw driver in which efficiency of screw-piece manual operation is enhanced by maximizing rotational force by applying a planetary gear assembly.

It is another object of the present invention to provide a passive compound screw driver in which a variety of bits can be stored and replaced in one body by configuring a bit storage box, thereby improving the convenience of bit replacement and bit management.

In order to achieve the above-mentioned object, the present invention provides a rotary shaft, comprising: a rotary shaft having a cross-shaped groove formed in a longitudinal direction along a circumference of the rotary shaft; A rear body provided with a carrier for rotating the rotary shaft while moving along a path, a rotary power transmitting means provided at an end of the rotary shaft, a detachable one of the rear body, A plurality of outlets communicating with the outside are formed in the circumferential direction and a center hole is formed at the center of the outlets to form a central hole communicating with the bit storage box, the front body having a plurality of bits, ; And a bit driver, one end of which is coupled to the rotary power transmitting means and the other end is projected to the outside of the front body through the central hole and the bit is detached at the other end, A plurality of planetary gears meshing with the circumference of the sun gear, a ring gear meshed with the plurality of planetary gears meshing with the inner circumferential surface, a ring gear interposed between the plurality of planetary gears and the rotary shaft, And a rotating body for transmitting a rotational force to the planetary gear, wherein the bit storage box is provided with a cartridge having a plurality of bits mounted thereon, and between the bit storage box and the front body, To allow the cartridge to reciprocate within the bit holder, The front body includes a first front body having a rotary power transmitting means disposed on the inner side thereof and a second front body disposed on the inner side of the second front body, Wherein the first and second inclined projections are arranged in the direction of the first inclined projection, and the first and second inclined projections are disposed in the direction of the first inclined projection, And a second inclined projection forming a second inclined surface corresponding to the inclined surface, wherein the first inclined projection is rotated and moved along the second inclined surface when the second body is rotated .

The passive compound screw driver according to the present invention has the following effects.

First, the conversion means for converting the linear motion into the rotary motion is applied. By applying the planetary gear assembly, the bit rotation torque can be maximized.

That is, since the rotation torque of the bit can be maximized only by the linear motion such as the pumping action, the efficiency of the screw-piece work can be increased.

As a result, the maximum rotational torque can be output with a small force, so that the range of the manual work of the screw pieces can be widened, and the productivity of the work according to the convenience of the screw pieces can be improved.

Second, a bit storage box is provided inside the body, and a plurality of various types of bits are stored in the bit storage box, thereby improving the efficiency of bit management and bit replacement operations.

Accordingly, it is possible to prevent bit loss concerns and improve convenience for bit management.

1 is a perspective view showing a screw driver according to the related art;
2 is a perspective view illustrating a passive compound screw driver according to a preferred embodiment of the present invention.
Figure 3 is an exploded perspective view of a passive composite screwdriver according to a preferred embodiment of the present invention,
4 is an exploded perspective view of the passive compound screw driver according to a preferred embodiment of the present invention,
5 is a cross-sectional view of a passive compound screw driver according to a preferred embodiment of the present invention;
6 is a cross-sectional view showing the line II in Fig. 5
7A and 7B are cross-sectional views illustrating a state in which a cartridge is moved in a passive compound screw driver according to a preferred embodiment of the present invention
8 is a perspective view illustrating a state in which a rear body of a passive compound screw driver according to a preferred embodiment of the present invention is detached from a front body to perform a screw piece fastening operation.
9A and 9B are cross-sectional views illustrating the operation of a passive compound screw driver according to a preferred embodiment of the present invention.

It is to be understood that the words or words used in the present specification and claims are not to be construed in a conventional or dictionary sense and that the inventor can properly define the concept of a term in order to describe its invention in the best possible way And should be construed in light of the meanings and concepts consistent with the technical idea of the present invention.

Hereinafter, a passive compound screw driver according to a preferred embodiment of the present invention will be described with reference to FIGS. 2 to 9B.

The manual composite screwdriver can apply the means for converting the linear motion into the rotational motion, but applying the planetary gear assembly can maximize the bit rotation torque.

Accordingly, the range of use of the manual screw driver can be increased, and the convenience of the screw-piece work can be enhanced.

In addition, various types of bits can be stored in the tool itself, thereby avoiding the possibility of bit loss and improving the convenience of bit management.

2 to 4, the manual composite screwdriver includes a rotary shaft 100, a rear body 200, a rotary power transmitting means 300, a front body 400, An elastic means 500, a bit cover 600, and a bit driver 700. As shown in FIG.

The rotary shaft 100 generates a rotational force by rectilinear motion of the rear body 200 and is formed in the form of a bar.

At this time, a cross groove 110 is formed around the rotating shaft 100 in the longitudinal direction of the rotating shaft 100.

The cross groove 110 provides a path for a carrier to be described later and is formed in a state where the spiral grooves formed around the rotating shaft 100 are crossed with each other.

One end of the rotating shaft 100 is provided with an engaging end portion 120 for engaging with the rotating power transmitting means 300 and the other end of the rotating shaft 100 is provided with a restraining means L. [

The restraining means L is configured to restrain the front body 400 and the rear body 200 from being separated from each other and is provided in the rear body 200 to be described later so as to be detachable from each other.

In other words, the restraining means L is for restricting the use of the front body 400 and the rear body 200 in close contact with each other so as to improve the efficiency of prevention and storage of safety accidents.

It is preferable that the restraining means L formed on the rotating shaft 100 is provided as a plurality of engaging grooves 130 formed along the circumference of the rotating shaft 100.

Next, the rear body 200 constitutes the rear side of the passive composite screwdriver and serves to generate rotational force in the rotary shaft 100. [

The rear body 200 linearly moves in the longitudinal direction of the rotary shaft 100 to rotate the rotary shaft 100 in the forward and reverse directions.

The inside of the rear body 200 has a hollow shape, and the rotary shaft 100 is positioned.

One side of the rear body 200 is in close contact with the front body 300 in an opened state and the restraining means L is provided at the other side of the rear body 200.

The restraining means L provided on the rear body 200 includes a rotating cap 200a and a ball plunger 200b.

The rotary cap 200a constitutes the rear end of the rear body 200 and is installed to be rotatable on the rear body 200. [

The ball plunger 200b is disposed in the engagement groove 130 of the rotary shaft 100 to prevent the rear body 200 from being separated from the front body 400 and a plurality of ball plungers 200b are provided on the inner peripheral surface of the rotary cap 200a .

The rotation of the rotary cap 200a causes the ball plunger 200b to be inserted into or released from the engagement groove 130. [

The concrete action of the restraining means L will be described later.

The rear body 200 is preferably separated as shown in FIGS. 3 and 4, and includes a carrier 210.

The carrier 210 is configured to rotate the rotary shaft 100 while moving along the cruciform groove 110 of the rotary shaft 100 when the rear body 200 reciprocates and is installed inside the rear body 200 .

The carrier 210 is provided in a pair so that the travel path in the cruciform groove 110 can be varied.

That is, by allowing one of the carriers 210 to be moved only in one direction of the cross groove 110 and the other carrier 210 to be moved only in the other direction of the cross groove 9110) Forward and reverse rotation are performed.

At this time, the carrier 210 has a cylindrical shape surrounding the rotating shaft 100, and an inner peripheral surface of the carrier 210 has an interference protrusion 211 corresponding to the cross groove 110.

The interference protrusions 211 are formed at different positions of the respective carriers 210.

That is, the interference protrusions 210, which are moved only in one direction of the cross groove 110, and the interference protrusions 210, which are moved only in the other direction of the cross groove 110, must be positioned opposite to each other.

For convenience of explanation, the separated rear body 200 is divided into a first rear body 220 and a second rear body 230.

The first rear body 220 constitutes the front end of the rear body 200 and corresponds to the rear end of the front body 400.

The first rear body 220 may have a cylindrical shape with both sides penetrating therethrough, and the tip of the first rear body 220 may be stepped.

This is to provide stable engagement with the front body 400. [

The pair of carriers 210 are installed inside the first rear body 220.

The first rear body 220 is provided with a switch S for controlling the operation of the pair of carriers 210.

The switch S is capable of controlling the rotation direction of the rotary shaft 100 by restricting the movement of the carrier 210 to the cross groove 110 by limiting the operation of the carrier 210 of the pair of carriers 210.

The switch S is configured to slide on the first rear body 220 and may rotate or rotate the rotary shaft 100 depending on the position of the switch S or may restrict the rotation of the rotary shaft 100 have.

The second rear body 230 is coupled to the first rear body 220 to form the rear end of the rear body 200.

The second rear body 230 is configured such that the rotary shaft 100 passes through the first rear body 220 and the end portion of the rotary shaft 100 is positioned and the rotary cap 200a of the above- Respectively.

At this time, the second rear body 230 is preferably provided with an extension bar 231.

The extension bar 231 is configured to extend the length of the bit driver 700 described later in order to maximize the rotational torque of the rotary shaft 100.

The extension bar 231 is inserted and stored in the second rear body 230 as shown in FIG.

The second rear body 230 is provided with a hinge-coupled opening / closing member 232 for protecting the extension bar 231.

5, the rotating shaft 100 and the bit driver 700 are connected to each other by a connecting member (not shown) Respectively.

The rotary power transmitting means 300 maximizes the rotational force obtained through the rotary shaft 100 and transmits the rotational force to the bit driver 700. [

In other words, the passive screw driver is the key to maximizing the rotational torque. In the present invention, the rotational power transmitting means 300 is applied to maximize the rotational torque, thereby improving the efficiency of the screw-piece operation.

3, 4 and 6, the rotational power transmitting means 300 includes a rotating body 310, a planetary gear 320, a ring gear 330, and a sun gear 340 .

The rotating body 310 transmits the rotating force of the rotating shaft 100 to the planetary gear 320 and includes a coupling groove 311 into which the coupling end 120 of the rotating shaft 100 is inserted and fixed, And a triangular body 312 for axial coupling with the triangular body 312.

The triangular body 312 is formed in a triangular shape and a coupling shaft 312a for coupling with the planetary gear 320 is formed to protrude from each corner portion

The planetary gear 320 transmits the rotational force of the rotating body 310 to the sun gear 340.

The planetary gear 320 transmits the rotational force to the sun gear 340 while rotating along the inner peripheral surface of the ring gear 330 by the rotation of the rotating body 310.

The planetary gears 320 are provided in a number corresponding to the engagement shaft 312a of the triangular body 312. [

The ring gear 330 provides a frame for rotation of the planetary gear 320, and is formed in a circular shape.

6, the ring gear 330 is fixed to the inner circumferential surface of the front body 400, which will be described later.

Teeth for engagement with the planetary gears 320 are formed on the inner circumferential surface of the ring gear 330.

Accordingly, the plurality of planet gears 320 move while rotating along the inner peripheral surface of the ring gear 330.

The outer circumferential surface of the ring gear 330 is preferably knurled for engagement with the front body 400.

This is to maximize the fixing force of the ring gear 330 by raising the frictional force between the front body 400 and the ring gear 330 when the ring gear 330 is fixed to the inner peripheral surface of the front body 400.

The sun gear 340 interlocks with the rotation of the planetary gear 320 to generate a rotational force.

The sun gear 340 is installed at the end of a bit driver 700 to be described later and is engaged with a plurality of planetary gears 320 by gears.

Next, the front body 400 constitutes the front of the screwdriver.

A bit storage box 410 for storing a plurality of various bits is formed at a front end of the front body 400 and a rotary power transmitting means 300 is installed at a rear end of the front body 400.

At this time, the front body 400 is also preferably separated as shown in FIGS.

The rear end of the front body 400 is referred to as a first front body 420 and the front end of the front body 400 is referred to as a second front body 430. [

A predetermined space in which the rotational power transmitting means 300 is installed is formed inside the first front body 420 and a predetermined space is opened toward the second front body 430.

At this time, the inner circumferential surface of the first front body 420 forming the predetermined space is preferably knurled.

This is to maximize the fixing force of the ring gear 330 fixed to the inner peripheral surface of the first front body 420, as described above.

6, the inner circumferential surface of the first front body 420 corresponding to the outer circumferential surface of the ring gear 330 is also knurled so that the first front body 420 and the second front body 420 are mutually engaged when the ring gear 330 is engaged with the first front body 420. [ It is possible to maximize the clamping force.

Meanwhile, the rear body 200 is closely attached to the outer end of the first front body 420. The outer end of the rear body 200 is stepped as shown in FIG. 4 so that the rear body 200 can be stably contacted .

That is, as described above, the penetrating portion formed by the tip of the first rear body 220 is formed in a stepped groove shape. Since the outer end of the first front body 420 is formed in the shape of a stepped portion, And adhesion between them can be stably performed.

At this time, a shaft hole 421 and a support groove 422 are formed at the outer end of the first front body 420.

The shaft hole 421 is a passage through which the rotating shaft 100 is passed to be positioned inside the first front body 420 and passes through both sides of the first front body 420.

The support groove 422 is configured to be inserted and supported at one end of the elastic means 500, which will be described later, and has a groove at the outer end thereof.

The shaft hole 421 is formed at the center of the first front body 420 and the support groove 422 is formed at both sides of the shaft hole 421.

The second front body 430 is formed in a circular shape passing through both sides and is coupled to the inner circumferential surface of the first front body 420 as shown in FIG.

The second front body 430 is coupled to rotate about the inner circumferential surface of the first front body 420.

A plurality of various bits B are mounted on the cartridge 440 and the plurality of bits B are mounted on the inner side of the second front body 430, .

The cartridge 440 is formed of a circular plate corresponding to the inner diameter of the second front body 430 and a plurality of mounting grooves 441 are formed along the circumference of the circular plate so that a plurality of bits B can be partitioned and mounted .

At this time, it is preferable that a magnet (not shown) is installed inside the mounting groove portion 441.

Thus, the bit B of the metal can be easily detached and attached to each mounting groove portion 441. [

The cartridge 440 is installed to be reciprocated in the bit storage box 410 by the rotation of the second front body 430.

That is, through the movement of the cartridge 440 in the bit storage unit 410, the bits B mounted on the cartridge 440 can be moved in and out of the bit cover 600 described later.

In order to effect the movement of the cartridge 440, there is provided an access power means P interlocked with the rotation of the second front body 430.

When the second front body 430 rotates, the access power means P moves the cartridge 440 using the principle that the access force means P is moved along the oblique surface, A second slanting protrusion 431 provided on the second front body 430, and a second slanting protrusion 431 provided on the second front body 430.

7A and 7B, the first inclined projection 442 protrudes from the cartridge 440 and one surface of the first inclined projection 442 has a first inclined surface 442a inclined in a protruding direction, .

At this time, the first inclined projection 442 is formed toward the opposite direction of the mounting groove portion 441.

The second inclined projection 431 is provided on the inner side of the second front body 430 and protrudes toward the first inclined projection 442.

At this time, the second inclined projection 431 forms a second inclined surface 431a which is opposed to the first inclined surface 442a, as shown in FIGS. 7A and 7B.

Through the configuration of the slant projections 431 and 442, the cartridge 440 can be moved in both directions when the second front body 430 rotates, and the operation of the cartridge 440 will be described later.

The inclined projections 431 and 442 are preferably formed in a spiral cylindrical shape and the centers of the inclined projections 431 and 442 are formed to pass through the bit driver 700.

Next, the elastic means 500 provides an elastic force to the rectilinear motion of the rear body 200, thereby making the reciprocating motion of the rear body 200 effective.

The elastic means 500 is installed between the front body 400 and the rear body 200 and is preferably provided as a spring.

The springs 500 are preferably provided on both sides of the rotating shaft 100, but the number is not limited.

One end of the spring 500 is inserted into the support groove 422 of the front body 500 and the other end of the spring 500 is fixed to the inner rear end of the rear body 200.

At this time, it is preferable that a guide bar 510 is installed inside the spring 500 so that the expansion and contraction action of the spring 500 can be stably performed without deviating from the straight path.

With such an elastic means 500 installed, the rear body 200 can flexibly move toward the front body 400.

Next, the bit cover 600 shields the open front end of the front body 400 and is engaged with the front end of the front body 400.

3 and 4, the bit cover 600 includes an entrance hole 610 as a passage through which a plurality of bits B mounted on the cartridge 440 enter and exit the inside and the outside of the bit storage box 410, A center hole 620 through which the tip end of the bit driver 700 passes is formed.

The access hole 610 is formed in the circumferential direction along the longest edge of the bit cover 600 and the number of the access holes 610 is equal to the number of the bits B of the cartridge 440.

At this time, the diameter of the entry / exit hole 610 may be large enough to allow the bit B to move.

The center hole 620 is formed at the center of the access holes 610 and is a portion where the bit driver 700 is inserted as shown in FIG.

Next, the bit driver 700 is configured such that the bit B is mounted. The bit driver 700 receives the rotational power of the rotational power transmitting means 300 and performs a screw piece fastening and separating operation while being rotated.

The bit driver 700 is preferably formed of a straight circular bar and is installed inside the front body 400 as shown in FIG.

One end of the bit driver 700 is coupled to the rotational power transmitting means 300 and a mounting groove 710 for mounting the bit B is formed at the other end of the bit driver 700.

One end of the bit driver 700 is a portion where the sun gear 340 is formed. In fact, one end of the bit driver 700 is engaged and coupled between the planetary gears 320.

It is preferable that a magnet (not shown) is installed inside the mounting groove 710 so that the mounting of the bit B can be facilitated like the mounting groove 441 of the cartridge 440.

Hereinafter, the operation of the passive composite screw driver constructed as described above will be described.

First, the operation of replacing the bit B mounted on the bit driver 700 will be described with reference to FIGS. 7A and 7B.

7A shows a state in which a plurality of bits B are stored in the bit storage box 410 and the first inclined surface 442a of the first inclined projection 442 and the second inclined surface 431a of the second inclined projection 431 are inclined, Are engaged with each other in a mutually coincident manner.

Thereafter, the second front body 430 is rotated about the first front body 420 to replace the bit B mounted on the bit driver 700.

7B, the lowest point of the first slanting protrusion 442 is a distance between the second slanting protrusion 431 and the second slanting protrusion 431. In this case, the second slanting protrusion 431 rotates in conjunction with the second front body 430, And is moved along the second inclined surface 431a.

The lowest point of the first inclined projection 442 is located at the highest point of the second inclined projection 431 and the cartridge 440 is positioned at the highest point of the second inclined surface 431a and the lowest point of the second inclined projection 431a Move.

In other words, the second slant projection 431 rotates and pushes the first slant projection 442.

The cartridge 440 moves toward the bit cover 600 and a plurality of bits B mounted on the cartridge 440 are exposed to the outside of the bit cover 600 through each of the access holes 610 do.

Thereafter, the operator substitutes the selected bit B in the cartridge 440 with the bit B of the bit driver 700 and mounts it.

Thereafter, when the worker continuously rotates the second front body 430 in the same direction, the lowest point of the first slant projection 442 located at the highest point of the second slant projection 431 is the second slant face 431a The bit cover 600 is moved to the opposite side.

Thereafter, the cartridge 440 is returned, and the bit replacement operation is completed as a plurality of bits B are drawn into the trough 410. [

Next, the screw piece fastening and dismounting operation of the screwdriver will be described with reference to FIGS. 8 to 9B.

For the screw-piece operation, prepare the screwdriver to rotate the bit driver (7000).

To this end, the restraining means L is released to separate the front body 400 and the rear body 200, which are in close contact with each other, as shown in FIG.

When the rotary cap 200a constituting the rear end of the rear body 200 is rotated, the ball plunger 200b positioned in the engagement groove 130 of the rotary shaft 100 is contracted and the engagement groove 130 ).

Accordingly, the rear body 200, which was the shape holding the rear end of the rotary shaft 100, is separated from the front body 400 as shown in Fig. 8 by the restoring force of the spring 500 which has been contracted.

The distal end of the rear body 200 is positioned at the rear end of the rotary shaft 100 and the carrier 210 is also located at the rear end of the rotary shaft 100 as shown in FIG.

Thereafter, the operator manipulates the switch S to constrain any one of the carriers 210 among the pair of carriers 210.

Accordingly, only one interference protrusion 211 of the carrier 210 which is not constrained by the switch S can move along one path of the cross groove 110.

Then, the operator straightens the rear body 200 toward the front body 400.

At this time, the rear body 200 moves to the rear end of the front body 400, and the soup ring 500 contracts with elastic force.

In this process, as the carrier 210 moves in the longitudinal direction of the rotating shaft 100, the rotating shaft 100 generates rotational force in one direction.

At this time, the rotating body 310 coupled to the end of the rotating shaft 100 interlocks with the rotating shaft 100 to rotate the planetary gear 320.

The plurality of planetary gears 320 rotate and move along the inner peripheral surface of the ring gear 330 and the sun gear 340 engaged between the planetary gears 320 is rotated.

Since the sun gear 340 constitutes one end of the bit driver 700, as the sun gear 340 rotates, the bit B of the bit driver 700 is also rotated to perform a screw-piece operation.

Thereafter, when the pushing force of the rear body 200 is released, the rear body 200 is returned to its original position due to the restoring force of the spring 500.

Thereafter, such a series of operations is repeated to perform the screw-piece operation.

Meanwhile, in order to vary the rotational direction of the bit driver 700, the switch S is moved to vary the restraint of the carrier 210.

Thus, the path of the cruciform groove 110 in which the carrier 210 moves varies, so that the direction of rotation of the bit driver 700 is variable.

At this time, the configuration of the gear ratio is not limited, but the gear ratio of the sun gear 340 and the planetary gear 320 can be designed to be 1: 4.

The rear body 200 spaced apart from the front body 400 may be separated from the front body 400 in a state in which the rotary shaft 100 is rotated twice with respect to the movement distance of the carrier 210 moved along the rotary shaft 100, , The sun gear 340 is rotated eight times by the gear ratio.

Accordingly, since the rotation efficiency of the bit driver 700 can be maximized only by one operation of the rear body 200, the efficiency of the screw-piece operation can be maximized.

As described above, the passive compound screw driver according to the present invention maximizes the rotational torque by applying the planetary gear assembly.

In addition, the passive compound screw driver according to the present invention can improve the efficiency of the bit replacement operation and the bit storage and management operation by providing a bit storage box inside the body.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is evident that many alternatives, modifications and variations will be apparent to those skilled in the art.

100: rotating shaft 110:
120: engagement end 130:
200: rear body 200a: rotating cap
200b: Ball plunger 210: Carrier
211: interference protrusion 220: first rear body
230: second rear body 231: extension bar
232: opening and closing member 300: rotational power transmitting means
310: Rotor 311: Coupling groove
312: triangular body 312a:
320: planetary gear 330: ring gear
340: sun gear 400: front body
410: bit storage box 420: first front body
421: shaft hole 422: support groove
430: second front body 431: second oblique projection
431a: second inclined surface 440: cartridge
441, 710: mounting groove portion 442: first oblique projection
442a: first inclined surface 500: elastic means
510: Guide Bar 600: Bit Cover
610: Entrance ball 620: Central ball
700: bit driver 710: mounting groove

Claims (4)

A rotary shaft having a cross groove formed in the longitudinal direction along the periphery;
A rear body that is linearly moved in the longitudinal direction of the rotary shaft and has a carrier for rotating the rotary shaft while moving along one side of the cross groove or the other side of the cross groove in the linear movement;
Rotating power transmission means provided at an end of the rotating shaft;
A front body detachably attached to one side of the rear body and having a plurality of bits stored therein in a bit storage box and a bit storage box;
A bit cover which is coupled to the front body and shields the bit storage box, a plurality of outflow holes communicating with the outside are formed in the circumferential direction, and a center hole is formed at the center of the outflow holes,
And a bit driver, one end of which is coupled to the rotary power transmitting means and the other end of which protrudes to the outside of the front body through the central hole and the bit is detached at the other end,
The rotary power transmitting means includes:
A sun gear installed at one end of the bit driver;
A plurality of planetary gears meshingly engaged with the sun gear;
A ring gear which is engaged with the inner circumferential surfaces of the plurality of planetary gears;
And a rotating body interposed between the plurality of planetary gears and the rotating shaft for transmitting rotational force of the rotating shaft to the planetary gears,
Wherein the bit storage box is provided with a cartridge in which a plurality of bits are mounted,
Wherein the cartridge is reciprocated within the bit storage box through a rotation operation of the bit storage box relative to the front body so as to allow the bit mounted on the cartridge to pass through the access hole, Means are provided,
The front body includes:
A first front body having a rotary power transmitting means disposed on an inner side thereof and a second front body rotated along an inner diameter of the first front body and having a bit storage box,
The entrance /
A first inclined projection which is installed toward the first front body from the cartridge and forms a first inclined surface;
And a second inclined projection which is provided from the second front body toward the first inclined projection and forms a second inclined surface corresponding to the first inclined surface. When the second body is rotated, the first inclined projection is rotated, And wherein the screw is moved along an inclined plane. The method according to claim 1,
Between the front body and the rear body, an elastic means for providing an elastic force to the rectilinear motion of the rear body to the front body is interposed,
And a restraining means for restraining a rectilinear motion of the rear body is provided at an end of the rear body and the rotary shaft.


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