KR101640453B1 - Apparatus for increasing of torque of rotary tool - Google Patents

Abstract

The present invention relates to an apparatus to increase a torque of a rotary tool and, more specifically, relates to the variable force type apparatus to increase the torque of the rotary tool, capable of various types of processing including a soft material by a rotary forces of a hand tool or an electric tool, and a solid object by the rotary force increased by a rotational reduction member. According to the present invention, the apparatus comprises: a driving force transferring part to be integrated with a hand tool or an electric tool; a housing rotationally integrated with the driving force transferring part on an upper side; and a rotary tool connected to a lower part of the housing, and to be rotated by receiving the rotary force of the hand tool or the electric tool, and further including a downshift unit arranged inside the housing, to reduce the rotation of the driving force transferring part. The rotary tool is provided to be rotated by the rotary force increased by the rotational reduction on the downshift unit.

Description

[0001] APPARATUS FOR INCREASING OF TORQUE OF ROTARY TOOL [0002]

More particularly, the present invention relates to an apparatus for increasing the rotational force of a tool, and more particularly, to an apparatus and a method for manufacturing a tool, which can process a loose material by turning force from a hand tool or an electric tool, To a power variable-type tool torque-increasing device.

In general, a drill is a hole in a workpiece, and a drill bit is rotated by a motor that generates a rotational force, thereby causing a metal or a wood to be drilled. Other machine tools can be used for tapping, screwdrivers, etc.

Of these, the hand tap can be manually drilled manually while the operator manually turns it. Thus, since the structure is relatively simple, it is easy to move, and since the workpiece can be processed by hand, it can be used more easily or can be applied easily, and convenience can be ensured.

On the other hand, a hard workpiece is hard to machine, so a drilling machine is used, and a thick drill can be used.

However, it takes a considerable amount of time to move heavy and large workpieces to drilling machines. However, it is not possible to work with a hole in a big metal chunk by hand, so it is difficult to work the work.

Therefore, there is a desperate need for a technology proposal that enables easy drilling work.

Registered Patent No. 10-0967036 (issued on June 30, 2010) Registered utility model No. 20-0147143 (published on June 15, 1999)

In order to solve the above problems, the present invention has been created in order to more positively solve the above problems. In constructing a single tool torque increasing device, the transmission structure of the power is selected according to the strength of the workpiece or the working condition To be utilized in a timely manner.

Another object of the present invention is to provide a structure different from that of a power transmission unit, a reduction gear unit, and a rotating tool binder unit, including a housing, which can be operated by a predetermined power variable unit.

Yet another object of the present invention is to make it possible to maximize the rotational force with the same rotation ratio initially provided by enabling the power varying means to implement a change in power or the like due to the reduction of the rotational ratio according to the embodiment.

According to an aspect of the present invention, there is provided a power tool comprising: a power transmission unit to which a hand tool handle or a power tool is coupled; A housing rotatably coupled to the power transmission unit; And a reduction gear unit coupled to the housing and including a turning tool that is rotated by receiving the turning force of the tool handwheel or the electric tool and is located inside the housing and decelerating the rotation of the power transmitting unit, And to rotate the turning tool by a rotational force that is increased by rotation deceleration in the portion of the power tool.

In a preferred embodiment of the present invention, the rotational deceleration ratio between the power transmitting portion and the speed reducing speed portion is set to a predetermined value. And a rotation deceleration ratio between the deceleration transmission portion and the rotary tool binder portion; The rotational force of the power transmitting portion is increased at a predetermined ratio in accordance with the rotational speed reduction ratio of at least one of the rotational speed reduction ratio and the rotational speed reduction ratio.

According to a preferred embodiment of the present invention, an inlet friction pad is provided at a portion where the housing and the power transmitting portion are in contact with each other, the one end of the power transmitting portion being rotatably engaged with the housing, And a selector lever operating member which is engaged with one side of the housing or selectively engaged with one side of the power transmitting portion by movement of the sleeve gear operated by the selector lever; Wherein the housing is rotated by the power transmitting portion by a predetermined frictional force by the inflowing friction pad and the turning tool is rotated by the rotation of the housing.

In a preferred embodiment of the present invention, a housing rotation operation for rotating the turning tool by the rotation of the power transmitting portion and the housing by a predetermined frictional force by the inflow friction pad; Or a reduction in rotation operation in which the rotational force of the power transmitting portion is transmitted to the reduction speed change portion due to the resistance of the turning tool exceeding a predetermined frictional force by the inflow friction pad and the rotation tool is rotated by the rotational force increased by the rotation deceleration in the reduction speed portion The power variable tool torque increasing device according to claim 1,
That is, in a preferred embodiment of the present invention, the housing rotation operation is performed by rotating the housing together with the frictional force of the inflow friction pad when the power transmission unit rotates, and rotating the rotation tool coupled to the housing under the rotation of the housing. Or a reduction in rotation operation in which the rotational force of the power transmitting portion is transmitted to the reduction speed change portion due to the resistance of the turning tool exceeding a predetermined frictional force by the inflow friction pad and the rotation tool is rotated by the rotational force increased by the rotation deceleration in the reduction speed portion The power variable tool torque increasing device according to claim 1,

In a preferred embodiment of the present invention, the reduction gear transmission portion is composed of one or more sets of planetary gears.

In a preferred embodiment of the present invention, the reduction transmission portion includes: a shaft constituting a reduction shaft; A third gear positioned on the upper side of the shaft and meshing with the first gear of the power transmitting portion and rotated at a reduced speed; And a fourth gear positioned below the shaft and meshing with the second gear of the tilting tool binder and rotating the fourth gear.

In a preferred embodiment of the present invention, the power transmitting portion further includes a latch actuating portion that rotates in one direction.

In a preferred embodiment of the present invention, the power transmitting portion is coupled to the hand tool handle or the power tool. A housing rotatably coupled to the power transmission unit; And a reduction gear unit coupled to the housing and including a turning tool that is rotated by receiving the turning force of the tool handwheel or the electric tool and is located inside the housing and decelerating the rotation of the power transmitting unit, And a portion of the power transmitting portion which is rotatably engaged with the housing is provided with an inflow portion for restricting one side of the power transmitting portion by a frictional force, The housing is rotated together with the frictional force of the inflow friction pad when the power transmission portion rotates, and the housing rotates together with the housing, And the reduction transmission portion rotates the pivoting tool coupled to the lower side, A shaft which is rotated and constitutes a reduction shaft; A third gear positioned on the upper side of the shaft and meshing with the first gear of the power transmitting portion and rotated at a reduced speed; And a fourth gear disposed on the lower side of the shaft and engaged with a second gear of a tilting tool coupling portion coupled to the tilting tool.

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According to the present invention configured as above, it is possible to provide a tool rotation force increasing device capable of selectively varying the power transmission structure according to the strength of the workpiece or the working conditions by a combination of predetermined different components. It is possible to perform an effective pivoting tool operation and perforation operation even for a relatively thick object which can not be formed with a turning tool only by a normal tool rotation force increasing device, thereby enabling a wider use.

Further, another effect of the present invention is that, in setting the path from the steering wheel to the turning tool, a desired level of turning force is imparted through the housing, the power transmitting portion, the speed reducing speed portion, It is possible to implement the change of the power due to the reduction of the rotation ratio according to the embodiment, so that it is possible to seek the maximization of the rotation force with the same rotation ratio initially provided.

1 is a perspective view showing the external appearance of a tool torque increasing apparatus according to the present invention.
FIG. 2 is an exemplary view showing an example in which the reduction transmission portion is located inside the tool rotational force increasing apparatus according to the present invention.
FIG. 3 is a diagram illustrating an example in which the internal reduction gear portion and the outer ring of the housing are gear-engaged in the tool rotational force increasing apparatus according to the present invention.
4 is a diagram illustrating an example in which the internal reduction gear portion and the central shaft portion are gear engaged in the tool rotational force increasing device according to the present invention.
5 is an exemplary view illustrating a state in which a latch operation portion is provided in a power transmission portion of a tool rotational force increasing device according to the present invention.
6 is an exploded perspective view illustrating a detailed configuration of a housing of a tool rotational force increasing apparatus according to the present invention.
7 is an exploded perspective view of an upper housing and a power transmitting portion of a tool rotational force increasing apparatus according to the present invention.
8 is an exploded perspective view of the lower housing, the speed reduction transmission portion, and the rotation tool binding portion of the tool torque increasing device according to the present invention.
Fig. 9 is an operational example showing an example in which the tool is rotated by the reduction speed portion of the embodiment provided inside the housing in the tool torque increasing apparatus according to the present invention.
10 is an exemplary view of a rotation operation through a housing in a tool rotational force increasing apparatus according to the present invention.
11 is an exemplary view of a use state in which a power tool is coupled to a tool torque increasing apparatus according to the present invention.

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

That is, as shown in FIGS. 1 to 11 and the like, the power variable tool rotational force increasing apparatus 100 according to the present invention has a structure in which a manual handle 10 or a power tool is coupled to one side, a hole is punched in the other side, And the turning tool 90 is rotated with a strong rotational force even if rotational resistance due to the workpiece is generated, so that the workpiece can be easily machined.

These and other objects and advantages of the present invention will become more apparent from the following detailed description of the present invention when taken in conjunction with the accompanying drawings. However, it is to be understood that the present invention is not limited to the disclosed embodiments, but may be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. It is intended that the disclosure of the present invention be limited only by the terms of the appended claims. And, throughout the specification, like reference numerals refer to like elements.

That is, the present invention relates to a tool rotating force increasing apparatus (100) used in combination with a rotating tool such as a thread cutting tool, and a workpiece is processed by a rotational force provided from a hand tool or an electric tool.

Particularly, the present invention solves all the problems inherent in the conventional structure, and further employs a predetermined power variable means to secure a better working efficiency, so that the power variable type tool rotational force Gt; 100 < / RTI >

The power varying means generally refers to the related elements that are featured in the present invention. The power varying means includes a power transmitting portion 20 including a housing 30, a reduction transmission portion 40, and a turning tool executing portion 50 And detailed configurations related thereto will be described in detail below with reference to the related drawings.

As shown in FIGS. 1 and 2, the power variable tool rotational force increasing apparatus 100 of the present invention is significantly different from the conventional structure, and includes a power transmitting portion (not shown) 20 and the pivoting tool 90 are separated from each other in the upper and lower regions, and a change in the rotational force can be induced by the power transmission structure between the power transmitting portion and the pivoting tool through the predetermined housing 30.

Therefore, the tool rotational force increasing apparatus is relatively simple in structure, and can be easily moved and handled.

In addition, it is possible to easily work on a workpiece which is difficult to be machined by a rotational force that is increased by decelerating the rotational force. In particular, it has an advantage that a drilling operation can be performed on a metal block even with a small rotational force, such as a manual handle.

To this end, the tool rotating force increasing apparatus 100 according to the present invention comprises a housing 30 constituting an overall body to which a hand tool handle 10 or a power tool is coupled, and a power transmitting portion, a reduced speed transmitting portion, .

More specifically, a power transmitting portion 20 to which a hand tool handle 10 or an electric power tool is coupled is provided for performing operations such as drilling or tapping with a turning tool.

A housing 30 is provided which is rotatably coupled to the power transmission unit 20 while forming the body of the tool rotation force increasing apparatus 100 according to the present invention.

As an embodiment of the housing 30, as shown in the accompanying drawings, the power transmitting portion may be received and housed, and the interior of the housing 30 may be divided into upper and lower portions so as to form a hollow internal space.

And a pivoting tool 90 coupled under the housing 30 and rotated by receiving the rotational force of the hand tool handle 10 or the power tool.

And further includes a reduction transmission portion 40 located inside the housing 30 and decelerating the rotation of the power transmission portion 20.

In particular, to rotate the turning tool 90 by a rotational force increased by rotation deceleration in the reduction transmission portion 40. [

And a turning tool binding portion 50 including a turning tool holder 51 so that a turning tool 90 for forming a turning tool of the workpiece is detachably attached while extending down through the housing.

The speed reduction ratio between the power transmission portion 20 and the speed reduction transmission portion 40 and the rotation speed reduction ratio between the reduction transmission portion 40 and the rotation tool engagement portion 50 The rotating force of the power transmitting portion 20 is increased at a predetermined ratio in accordance with any one or more of the deceleration ratios to rotate the turning tool 90. [

More preferably, it is preferable that all portions are decelerated so that a rotating force enough to pierce the metal block is generated even if the force is turned by a user's hand.

The housing 30 is provided with an inflow friction pad 70 for restraining the power transmission portion 20 by a frictional force at a portion contacting the upper power transmission portion 20.

The housing 30 is rotated by the predetermined friction force by the inflow friction pad 70 and is rotated by the rotation of the housing 30 to rotate the turning tool 90.

A selector lever which is not shown in the drawing or which is capable of selectively transmitting the rotational force of the power transmitting portion 20 to the housing 30 or selectively transmitting the rotational force of the power transmitting portion 20 to the reduction transmission portion 40 and a sleeve gear And a sleeve gear that is engaged with one side of the housing 30 by movement or selectively coupled to one side of the power transmission portion 20. By the operation of the selection lever of the selector lever actuating member, a sleeve gear (not shown) can be provided for interlocking with one side of the housing 30, the speed reduction transmission portion 40, or the like. The configuration for the selection lever operating member such as the selection lever, the sleeve gear (synchronizer sleeve, etc.) and the like may be applied by employing the techniques used in a general transmission.

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In this way, a rotational force is transmitted to the housing 30 or the reduction transmission portion 40 side by a selection lever operation member including a friction pad, a selection lever, an associated gear, or the like. In the case of some friction pads, 40, the housing may transmit the rotational force at a slow speed by the frictional force of the friction pad. The rotational force of the power transmitting portion 20 is transmitted to the rotating tool 90 by at least one of the housing 30 and the reduction transmission portion 40 due to the friction pad and the selection lever. In the following description of the technical description and accompanying drawings, one embodiment employing a friction pad is described as a preferred embodiment, and the present invention may be applied to various environments. In addition, when the friction pad and the selection lever operation member are provided together, the operation may be easily performed in various environments.

The power transmitting portion 20 and the turning tool binding portion 50 may be configured such that the rotational force resulting from the handle 10 is transmitted to the housing 30 and the reduction transmission portion 40, (40).

In this connection, depending on whether the state of engagement with the housing is implemented or not, the power transmitting portion and the turning tool binding portion respectively transmit rotational force from the handle to the housing through the reduction transmission portion or through both the housing and the reduction transmission portion And the state of engagement (restrained) with the housing at this time can be achieved by the friction pads 70, 80 and the tightening means 71, 81 which will be described later.

That is, the housing rotation operation in which the turning tool 90 is rotated by the rotation of the power transmitting portion 20 and the housing 30 by a predetermined frictional force by the inflow friction pad 70.

The rotational force of the power transmitting portion 20 is transmitted to the reduction transmission portion 40 due to the resistance of the pivoting tool 90 exceeding the predetermined frictional force by the inflow friction pad 70, And to operate in a decelerating rotation operation in which the turning tool 90 is rotated by an increased rotational force.

For example, when a separate tightening means presses the power transmitting portion 20 and the turning tool binding portion 50 from the housing 30 via the friction pad, the rotational force of the handle is not limited to the power transmitting portion, The rotating tool 90 is operated without increasing or decreasing the rotation ratio through the handle 10. [

On the other hand, when the power transmitting portion and the turning tool binding portion are placed in a free state so as to be independent of the action of the friction pad and the tightening means, the turning force of the handle leads to the speed reducing speed transmitting portion through the power transmitting portion, At this time, the rotational force provided from the handle is reduced by the rotation rate of the corresponding gear ratio by passing through the reduction transmission portion, thereby further increasing the rotational force of the rotation tool engagement portion. In addition, the rotation of the housing 30 can be realized at an appropriate level while inducing the execution of the reduction transmission portion 40 due to the manner in which the tightening means adjusts the degree of pressing of the friction pads.

The housing 30 is a component that enables rotation path setting from the handle 10 to the turning tool 90. The housing 30 is formed in a vertically-divided structure as shown in the figure, The power transmitting portion 20 and the turning tool binding portion 50 are received and accommodated to be in an organic connection state with the drawn power transmitting portion and the rotating tool binding portion to achieve the desired purpose.

For this, an annular inlet block 31 is protruded from the upper end of the housing to place a related constitution of the power transmitting portion 20 and exercise a restraining force, and an annular withdrawing block 32 The protruding portion is formed so as to position the relevant structure of the pivoting tool binding portion 50 and exert the same binding force. Further, in the inner space of the housing, the reduction transmission portion 40 is further disposed so as to be adjacent to the position where the power transmitting portion and the rotating tool binding portion are located, thereby functioning as a connecting means of the power transmitting portion and the rotating tool binding portion short- A recessed groove 35 for guiding the engagement state is formed on the inner space of the housing so as to be provided with a predetermined shaft rotation support portion 42. The upper and lower regions of the reduction transmission portion are rotatably supported by the shaft rotation support portion do.

That is, the housing 30, which is featured in the present invention, includes an annular pull-in block 31 which is vertically inwardly inwardly for pulling in the power transmitting portion 20, An annular drawing block 32 and a recess 35 formed on the same vertical line so as to support the shaft of the reduction transmission portion are formed in the drawing.

Preferably, the handle 10 acts as a means for imparting an initial rotational force, and is further configured to have both a manual and an electric motor so that a wrench, a driver, and an electric screwdriver can be operated.

It should be noted that the coupling grooves are not shown in the drawings but may be provided in various forms so as to enable general use as described above, and are not limited to any specific shape.

As shown in FIG. 5, the latch operation unit 60 may be further provided with a ratchet type that rotates the axis of the power transmission unit 20 to which the handle 10 is coupled in one direction. Thus, the user can rapidly rotate the rotary shaft by operating the latch handle continuously in rapid succession.

As shown in FIG. 11, the tool rotational force increasing apparatus 100 proposed in the present invention is a main purpose of providing a power transmission structure selectively variable according to the strength of a workpiece or a work condition so as to be utilized in a timely manner The housing 30, the power transmitting portion 20, the reduction transmission portion 40, and the rotary tool binder 50 are essential elements for this purpose.

The power transmitting portion 20, the speed reduction transmission portion 40, the speed reduction transmission portion, and the turning tool binding portion 50 are connected to each other by means of a gear- It is more preferable to be able to induce the variation of the rotational power transmitted from the handle 10.

The tool rotational force increasing apparatus 100 according to the present invention thus provided generates a strong rotational force so that a drilling operation can be performed on a workpiece such as a metal block by only the operating force of the handle 10 which can be turned by the user, If a weak torque is generated for a loose material, it is possible to drill for a loose material only by the rotational force through the housing. On the other hand, a metal block or the like is hard to be machined by increasing the rotational force due to rotation deceleration through the reduction transmission portion 40 in the housing 30. [ The example of the drawings attached thereto shows the reduction transmission portion 40 of various embodiments as an example. 3, 4, and the like, the reduction transmission portion 40 is formed of one or more planetary gears. FIG. 3 shows an example in which the rotational force is transmitted to the housing as an outer outer ring in FIG. 3, and FIG. 4 shows an example in which rotational force of the planetary gear is transmitted to a central output shaft coupled with the housing. The planetary gear technology in the transmission system of the planetary gear according to the present invention adopts the planetary gear technology which is generally used. Therefore, the planetary gear support cage and the like can be suitably supported according to the embodiment in which the planetary gear is supported, So that it can be provided with a good rotation output. A detailed description of this planetary gear technology will be omitted by applying a general planetary gearing technique thereto. In addition to the planetary gear technology, various deceleration techniques for reducing the rotational speed of the input side while being provided inside the housing may be applied in various applications.

7 to 10 and the like, the rotation is decelerated through a single shaft in the housing, and the decelerated rotational force is transmitted to the output side freely rotating with the housing, so that it can be transmitted to the turning tool 90 with the rotational force increased by deceleration FIG.

Hereinafter, the detailed configuration of the embodiment will be mainly described.

That is, FIGS. 7 to 10 illustrate exemplary embodiments in which changes in power due to a reduction in the rotation ratio can be implemented according to the embodiment of the present invention, thereby maximizing the rotational force even at the same rotation ratio initially provided.

FIG. 7 is a perspective exploded perspective view showing details of a related structure of a housing and a power transmitting portion which are essential parts of the present invention, and FIG. 8 is a plan view of a reduction gear portion and a turning tool binding portion, It is a perspective view.

7, the power transmitting portion 20, which is a characteristic feature of the present invention, is arranged in a position above the housing 30, and is disposed laterally in the housing with respect to the reduction transmission portion 40 Thereby enabling the transmission of rotational force.

Specifically, the power transmitting portion 20 includes a threaded portion 21 fixedly coupled to the handle, a body 22 extending up to the inner space of the housing while extending downward from the threaded portion, An annular protruding portion 23 having a diameter narrower than an inner diameter, a step portion 24 interposed on the body with a narrow diameter as compared with the annular protruding portion, A bearing 25 for supporting the load is provided. A lower cap 26 fixed to a vertical position of the bearing and fixedly coupled through an inner surface of the housing so that upward and downward movement of the body is not allowed, and an upper cap 27 fixedly connected to the inlet block so as to restrain upward movement of the body And a first gear 28 transversely coupled to the lower end of the body.

The input block 31 is configured to receive the annular protrusion 23 and the bearing 25 as an inner space and further include an elastic material inflow friction pad 70 as an outer circumferential surface of the annular protrusion, So that the friction pads and the annular protrusions are pressed by the plurality of tightening means (71).

As a result, the rotational force of the handle 10 is applied to the housing 30 and the power transmission unit 20, Which means it is transmitted to the tool. 10 is a perspective view of a rotating tool coupling unit 50 according to an embodiment of the present invention. Referring to FIG. 10, Fig.

For example, when the handle 10 is operated in the above-described situation, the rotation of the power transmitting portion 20 coupled to the handle is induced. At this time, the annular protrusion 23 of the power transmitting portion is guided by the inflow friction pad 70 and the tightening means The rotation of the power transmitting portion results in the rotation of the housing, and the operation of the tool rotation force increasing device as shown in FIG. 10 is performed.

The annular protrusion 23 is received in the inner space provided by the inlet block 31 of the housing and is further interposed between the inlet block and the annular protrusion so that the position of the annular protrusion on the inlet block You can arrest them.

The drawing block is provided with the tightening means 71 so that the pressing force against the annular protrusion can be exercised by means of the friction pad. The tightening means can be a screw type, .

The bearing 25 is used not only as a means for rotating the body 22 but also as a supporting means for enduring a load to be exerted. In order to avoid problems such as dislocation and breakage of the components due to the method of inducing the rotation while pushing down the tool rotation force increasing device 100, there is a problem in that, for example, a thrust bearing or a conical bearing And the like.

As shown in Fig. 8, the turning tool binding portion 50, which is featured in the present invention, is arranged in a position below the housing 30, and is disposed laterally inside the housing, And a rotational state can be given by inducing a coupled state.

In detail, the turning tool binding portion 50 includes a turning tool holder 51 to which attachment of the turning tool 90 is determined, a body which is upwardly extended from the turning tool holder, An extension protrusion 53 interposed on the body 52 and having a smaller diameter than the inner diameter of the draw-out block, a fitting portion 54 interposed on the body with a smaller diameter than the extension protrusion, A bearing 55 fixedly mounted on the inner surface of the housing so as to hold the vertical line position of the bearing and to prevent vertical movement of the body, A cap 56 and an outer cap 57 fixedly fixed on the take-out block so as to restrain downward movement of the body, and a second gear 58 transversely coupled to the upper end of the body.

The withdrawing block 32 is configured to accommodate the extending projections 53 and the bearings 55 as internal spaces and further includes a friction pad 80 made of an elastic material on the outer circumferential surface of the extending projections, The friction pad 80 and the extending projection 53 are pressed by the tightening means 81 or more.

As a result, the rotating force of the handle 10 is applied to the housing 30 and the rotating tool binding unit 50 in a similar manner as described above, And is transmitted to the turning tool 90. 10 is a cross-sectional view showing that the rotational force provided from the handle can be transmitted to the rotating tool binder sequentially through the power transmitting portion and the reduction transmission portion according to the preferred embodiment of the present invention.

The extension protrusions 53 of the other rotation tool binding portion are in a state of being restrained on the housing 30 by the friction pad 80 and the tightening means 81. Consequently, the rotation action of the power transmission portion 20 results in the rotation action of the housing The operation of the tool rotational force increasing device as shown in Fig. 10 is performed, which is the same as the operation mode of the annular ridge 23 described above. In addition, since the extension projections 53 have the same structure and function as the annular projections, the predetermined purpose is achieved, and the friction pad 80 and the tightening means 81 are the same as those described above, .

Meanwhile, the deceleration transmission portion 40 shown in the present invention is provided to induce the increase of the rotational force due to the decrease of the rotation ratio, and the reduction transmission portion 40 includes the power transmission portion 20 and the turning tool engagement portion 50 in the upper and lower spaces, Thereby realizing rotational movement.

In this regard, the reduction transmission portion 40 includes a shaft 41 restrained by means of a groove 35 formed on the same vertical line inside the housing 30, A third gear 43 interposed on the shaft so as to be engaged with the second gear 28 and a second gear 58 engaged with the second gear 58 employed in the rotating tool engagement portion 50, 4 gears 44, respectively.

The third gear 43 is located on the upper side of the shaft 41 and the first gear 28 and the second gear 28 of the power transmission portion 20 are connected to each other, And is decelerated and rotated. The fourth gear 44 is located below the shaft 41 and engages with the second gear 58 of the turning tool binding portion 50 and rotates.

For example, the gear ratios of the first gear 28 and the third gear 43, the second gear 58 and the fourth gear 44 may be 1: 2, 2: 1 And the rotating action provided from the handle 10 is sequentially passed through the power transmitting portion 20, the power varying portion 40 and the turning tool binding portion 50, At the time of rotation, the turning tool binding portion 50 makes one turn, and accordingly, the turning force is increased accordingly.

According to the present invention configured as described above, it is possible to provide a tool rotational force increasing device capable of selectively varying the power transmission structure according to the strength of a workpiece or a work condition by a combination of predetermined different components, This peculiarity makes it possible to perform an effective pivoting tool operation and perforating operation even for a relatively thick object which can not be formed by a conventional tool rotation force increasing device alone, thereby achieving an effect of wider use.

That is, in the present invention, when setting the path from the steering wheel to the turning tool, a desired level of turning force can be imparted through the housing, the power transmitting portion, the speed reducing speed portion, and the turning tool binding portion , It is possible to realize a change in the power due to the reduction of the rotation ratio according to the embodiment, and thereby it is possible to seek the maximization of the rotational force even at the same rotation ratio initially provided.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, Should be clarified. Therefore, it is intended that the present invention cover the modifications and variations of this invention provided they come within the scope of the appended claims and their equivalents.

10: handle 20: power transmission part
30: Housing 40: Reduction speed section
50: rotating tool binding portion 100: tool rotating force increasing device

Claims (7)

A power transmitting portion to which a hand tool handle or a power tool is coupled;
A housing rotatably coupled to the power transmission unit; And
And a turning tool coupled to the housing and rotated by receiving the turning force of the hand tool handle or the power tool,
And a decelerating transmission portion located inside the housing and decelerating rotation of the power transmitting portion,
And the turning tool is rotated by an increased rotational force due to rotation deceleration in the reduction transmission portion,
And an inflow friction pad that restrains one side of the power transmitting portion, which is rotatably engaged with the housing, by frictional force by pressure, at a portion where the housing and the power transmitting portion are in contact with each other,
The housing is rotated together with the frictional force of the inflowing friction pad when the power transmission unit is rotated, and the rotation of the housing is rotated by the rotation of the housing, Lt; / RTI >
The reduction transmission portion
A shaft rotatable within the housing and defining a deceleration axis;
A third gear positioned on the upper side of the shaft and meshing with the first gear of the power transmitting portion and rotated at a reduced speed; And
And a fourth gear located on the lower side of the shaft and engaging with the second gear of the tilting tool coupling portion engaged with the tilting tool to rotate the fourth gear.
The method according to claim 1,
A rotation deceleration ratio between the power transmitting portion and the speed reduction speed portion; And
A rotation speed reduction ratio between the reduction speed change portion and the rotation tool binding portion;
The rotational force of the power transmitting portion is increased at a predetermined ratio to rotate the turning tool.
delete The method according to claim 1,
A housing rotation operation in which the housing rotates together with the frictional force of the inflow friction pad when the power transmission unit rotates, and rotates the pivoting tool coupled to the lower side of the housing by rotation of the housing; or
The rotational force of the power transmitting portion is transmitted to the reduction transmission portion due to the resistance of the pivoting tool beyond the predetermined frictional force by the inflowing friction pad and is operated by the reduction rotation operation for rotating the pivoting tool by the rotational force increased by the rotation deceleration at the reduction transmission portion Wherein the power transmission mechanism comprises:
The method according to any one of claims 1, 2, and 4,
Wherein the reduction transmission portion comprises at least one set of planetary gears.
delete The method according to any one of claims 1, 2, and 4,
Wherein the power transmitting portion further includes a latch operating portion for rotating the power transmitting portion in one direction.

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