KR20110095741A - Exercise apparatus having rotating force adjusting unit for pulling way with both arms - Google Patents

Abstract

PURPOSE: A both arms pulling type exercise device is provided to enable a user to exercise by controlling power necessary for operation thereof. CONSTITUTION: A both arms pulling type exercise device comprises: a case(110) forming external appearance; a torque control unit which is installed in the inner side of the case and is equipped with a rotary shaft capable of controlling torque; a connecting unit(140) connected to the rotary shaft of the torque control unit; and a string(120) which is equipped in the connecting unit.

Description

Exercise Apparatus Having Rotating Force Adjusting Unit For Pulling Way With Both Arms}

The present invention relates to an exercise device, and more specifically, to enable the adjustment of the load required during the exercise through the rotational force adjusting unit, by applying a tensile force in a string manner to exercise the rotational force to enable various forms A two-arm tug-of-war exercise device is provided.

Recently, with increasing interest in health, various types of exercise equipment have been installed and used in health clubs and private homes.

In general, the conventional exercise equipment is to adjust the amount of exercise by adjusting the amount of load required during exercise through the operation of increasing the weight more.

By the way, the weight of the exercise equipment to control the load using the weight, but the weight of the overall exercise equipment was inevitably increased, which caused a problem such as difficult to move or injury of the user during the exercise. .

To this end, in recent years, such as a rolling waist exercise equipment has been developed to enable the movement using a rotating unit that can be given a rotational force, such as a rotational exercise device, such a conventional exercise device that gives a rotational force is largely spring An elastic member type rotating unit using an elastic member such as a back, and a viscous fluid type rotating unit using a viscous fluid to impart rotational force have been applied.

However, as the number of times of use of the rotating unit of the elastic unit of the above-mentioned rotating unit has a problem that the elastic force of the elastic member is weakened to bring about a change in the rotational force to maintain a constant movement force.

On the other hand, the method using the viscous fluid method was made so that the rotational force is controlled by the resistance of the sealed oil when the shaft of the rotary unit is rotated after the oil is sealed in the rotary unit, the viscosity of the rotary unit of the fluid unit Even if the rotational force can not be adjusted there was a problem that you can only use the exercise equipment with a single load.

In addition, the conventional exercise equipment and the like to develop only the corresponding muscle by allowing only one operation for the corresponding muscle during exercise as an exercise device, as a single exercise device can be exercised in various forms, as well as various There is a need for exercise equipment that can bring about exercise effects.

The present invention has been made in order to solve the above-mentioned conventional problems and disadvantages, and has the following object.

First, an object of the present invention is to provide an exercise device that can exercise in various forms as one exercise device and utilize various muscles.

Secondly, an object of the present invention is to provide an exercise device capable of exercising with an optimal load for the user by adjusting the force required for its operation when the user uses the exercise device by adjusting the rotational force according to the situation.

In order to achieve the above object, the present invention is provided with a rotating shaft capable of adjusting the rotational force and the case forming the appearance and at the same time the connecting unit connected to the rotating shaft of the rotating force adjusting unit and the rotating force adjusting unit installed inside the case And it provides a two-arm tug-of-war exercise device having a rotational force control unit including a string provided on both sides of the connecting unit symmetrically rotatable when applying the tensile force.

Here, the rotational force adjusting unit forms a cylindrical accommodating space therein, the cover portion and the central portion of the body portion and the cover portion to close the receiving space is coupled to the open body portion and the open portion of the body portion on one side Rotating through the rotatable shaft to form an oil chamber filled with oil between the receiving space and the rotating shaft toward the inner wall of the receiving space from the rotating shaft to rotate the rotary shaft According to the rotation shaft in the oil chamber in the shaft, the control valve for adjusting the opening of the bypass flow path and the bypass flow path through which the vane for pushing the oil in the oil chamber and the oil pushed by the vane flows It may be made, including.

And, formed along the height of the inner wall of the receiving space toward the rotary shaft from the inner wall of the receiving space, to block the movement of oil in the oil chamber being pushed by the vanes and to limit the rotation range of the vanes The blocking block may be further provided, and the bypass passage may be provided to communicate one side and the other side of the blocking block.

In addition, the bypass flow path may be formed inside the body portion.

And, the control valve is located inside the installation groove to be elastically supported by the installation groove and the spring and the spring located inside the installation groove formed to penetrate the bypass flow path, in the position inside the installation groove In accordance with the valve body for adjusting the opening of the portion communicating with the bypass flow passage and the opening of the installation groove is closed the installation groove, while moving in or out of the installation groove according to the rotation amount of the valve It may include a control screw for supporting the body on the opposite side of the elastically supported by the spring.

The valve body may include an upper flange and a lower flange, and may be provided between the upper flange and the lower flange and include an O-ring formed in close contact with an inner surface of the installation groove. have.

On the other hand, the case is provided with a pair of rotational force adjustment unit in a state that the rotation shaft is positioned in the opposite direction to each other, the connection unit is connected to the rotational shaft of each rotational force adjustment unit, each of the said The string may be provided in both sides of the connection unit so that the rotation shaft is rotatable.

Two arms tug-of-war exercise device provided with the rotational force control unit of the present invention has the following effects.

First, by applying an external force applying member of the string method, it is possible to exercise in a variety of forms according to the direction of the tensile force applied to the string has the effect that can achieve various movement effects.

Secondly, since the rotational force can be adjusted, the user of the exercise device to which the rotational force of the present invention is applied has the advantage of adjusting the exercise load to fit his or her physical strength or muscle strength, and a separate configuration for adjusting the rotational force is provided. Since the configuration of the exercise equipment is not necessary because it is not necessary, the production is simple, the risk of failure is reduced, and the weight is light.

Third, since the rotational force is adjusted using the flow resistance according to the viscosity of the oil, the rotational force does not deteriorate with the number of times of operation or the passage of time.

1 is a perspective view schematically showing the appearance of a two-arm tug-of-war exercise device equipped with a rotational force adjusting unit according to a preferred embodiment of the present invention;
2 is a cross-sectional view of the main portion in FIG. 1;
3 and 4 are views for showing the form of exercise using the two-arm tug-of-war exercise device provided with the rotational force control unit of the present invention;
Figure 5 is a perspective view showing one form of the rotational force control unit applied to the present invention both arms tug-of-war exercise device;
6 is a perspective view showing the inside of the body of FIG.
7 is a perspective view showing the body portion of the rotational force adjusting unit of FIG.
8 is a cross-sectional perspective view of FIG. 4;
FIG. 9 is a sectional perspective view showing a cross section of a portion where the bypass flow path and a control valve of FIG. 4 are located; FIG.
10 is a cross-sectional view of FIG. 4;
FIG. 11 is a perspective view of the control valve of FIG. 4; FIG.
12 is a perspective view showing another form of the rotational force control unit applied to the present invention both arms tug-of-war exercise device;
13 is an exploded perspective view of FIG. 12;
FIG. 14 is a perspective view of the AA section of FIG. 12; FIG.
FIG. 15 is a perspective view of the BB section of FIG. 12; FIG.
FIG. 16 is a perspective view of the section taken along line CC of FIG. 12; FIG.
17 is a perspective view of the friction pad of FIG. 12; And,
FIG. 18 is a cross-sectional view illustrating a rotational force adjusting unit having a friction pad to which the pressing unit is configured in FIG. 12.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings. In describing the present embodiment, the same designations and the same reference numerals are used for the same components, and further description thereof will be omitted.

First, a structure according to a preferred embodiment of the present invention will be described with reference to the accompanying drawings.

Figure 1 of the accompanying drawings is a perspective view schematically showing the appearance of a tug-of-war exercise device using both arms provided with a rotational force adjustment unit of the present invention, Figure 2 is a cross-sectional view of the main part in FIG.

As shown, the two-arm tug-of-war exercise device 100 provided with the rotational force adjustment unit of the present invention includes a case 110 forming an exterior and a rotation shaft 230 capable of adjusting the rotational force during rotation, and the case 110 inside. The connecting unit 140 and the connecting unit 140 connected to the rotating shaft 230 of the rotating force adjusting unit 200 and the rotating shaft 230 are rotatable when the tensile force is applied to the connecting unit ( 140 is configured to include a string 120 that is bilaterally symmetrically connected.

At this time, the case 110 is provided with a pair of rotational force adjustment unit 200 so that the rotation shaft 230 is positioned in the opposite direction to each other, the rotational shaft 230 of each of the rotational force adjustment unit 200 is The connecting unit 140 is connected, but when the tensile force is applied to each of the rotary shaft 230 is rotatable so that the connecting unit 140 is provided with the string 120 on both sides symmetrically so that the movement independently from both sides It is desirable to enable this.

On the other hand, the connection unit 140 is a plate-shaped connecting plate 141 and the connecting plate 141 is formed in a symmetrical form on both sides of the connecting shaft 150 and the connecting shaft axially connected to the rotary shaft. It is provided on both sides of the string 120 is configured to include a connection rod 142 is connected.

And, the end of the string 120 is provided with a handle 130 for the convenience of use during exercise.

3 and 4 is a view showing a form of exercise using the two-arm tug-of-war exercise device provided with the rotational force adjustment unit of the present invention.

As shown in FIG. 3, the present invention both arms tug-of-war exercise device 100 grabs the handle 130 and pulls the string 120 while opening it at a predetermined angle inclined to both sides as well as perpendicular to the ground. You can exercise while giving tension.

Alternatively, as shown in FIG. 4, the string 120 may be staggered to provide a tensile force to exercise.

That is, the two-arm tug-of-war exercise device 100 provided with the rotation force adjusting unit of the present invention uses the string 120 to change the direction in which the flexible force is applied while the rotation shaft (the shaft). 230) can be rotated around the user, so that the user can exercise in a variety of forms, through which you can use a variety of muscles, as well as the fatigue of the body that can occur by exercise only one motion It can be reduced to increase the exercise effect.

Hereinafter, the rotational force adjusting unit installed in the present invention both arms tug-of-war exercise device will be described in more detail.

Rotational force adjusting unit 200 according to the present embodiment, as shown in Figure 5 and 8, the body portion 210 and the cover portion 220 and the rotary shaft 230 and vanes 240, bi Pass passage 260 and the control valve 270 may be included.

The body portion 210, as shown in Figures 6 and 8, forms the overall appearance of the rotational force control unit 200, the receiving space 212 is formed in a cylindrical shape therein is formed so that one side is opened. . In addition, the central portion of the body portion 210 is formed with a hole 215 through which the rotating shaft 230 to be described later.

In addition, as shown in FIG. 7, the cover part 220 is a component that is coupled to the opened portion of the body part 210 to close the receiving space 212. A hole through which the rotating shaft 230 to be described later is formed is also formed in the center of the cover portion 220.

The rotation shaft 230 rotatably penetrates the central portions of the body portion 210 and the cover portion 220, and an inner wall of the receiving space 212 of the body portion 210 and the rotation shaft 230. An oil chamber 214 in which oil is enclosed is formed between and.

In addition, a bearing 232 is provided at a portion of the rotary shaft 230 that is coupled to the body 210 and the cover 220 to rotatably couple the rotary shaft 230 to prevent oil from leaking. Can be.

And, the vane 240 is coupled to one side of the rotary shaft 230, as shown in Figures 7 and 8, from the rotary shaft 230 toward the inner wall of the receiving space 212 It extends along the rotary shaft 230. Therefore, the vane 240 is rotated about the rotary shaft 230 along the rotation of the rotary shaft 230, the vane 240 is in close contact with the inner wall of the receiving space 212 to the oil It is made to push the oil inside the chamber 214.

8 and 9, one end and the other end of the bypass passage 260 communicate with the oil chamber 214 so that the oil pushed by the vane 240 is the oil chamber ( 214) A passage that bypasses and flows outward.

In addition, as illustrated in FIGS. 7 and 8, a blocking block 250 protruding from the inner wall of the accommodation space 212 toward the rotation shaft 230 may be further provided. The blocking block 250 is made to block the oil that is pushed by the vane 240 continues to move. In addition, the rotation range of the vane 240 is also limited by the position and size of the blocking block 250.

Here, the bypass flow path 260 is formed in the body portion 210, it may be made to communicate one side and the other side of the oil chamber 214 of the point where the blocking block 250 is formed.

In the above description, the bypass flow path 260 is formed in the body portion 210 as an example, but the present invention is not limited thereto, and may be formed to penetrate the blocking block 250.

For convenience of description, as shown in FIG. 10, when the vane 240 is rotated in the counterclockwise direction, a space between the front side of the vane 240 and the blocking block 250 is defined by the first oil chamber. A space between the rear side of the vane 240 and the blocking block 250 will be referred to as a second oil chamber 218.

That is, if the vane 240 rotates in the counterclockwise direction, the oil in the first oil chamber 216 is pushed by the vane 240, and the bypass flow path 260 due to the blocking block 250. It is to flow to the second oil chamber 218 through). Of course, even when the vane 240 rotates in the clockwise direction, the oil of the second oil chamber 218 flows to the first oil chamber 216 through the bypass flow path 260.

8 and 10 illustrate that the bypass flow path 260 communicates with the outside of the body portion 210. However, when the bypass flow path 260 is formed, the bypass flow path 260 is drilled from the outside for the convenience of manufacturing. It is formed because it is easy, and after the bypass flow path 260 is made of a separate material is made so that the oil passing through the bypass flow path 260 does not leak.

On the other hand, the control valve 270 is made to adjust the flow resistance of the oil flowing in the bypass flow path 260 by adjusting the opening degree of the bypass flow path 260, as shown in FIGS. .

That is, when the opening degree of the bypass flow path 260 is maximized, the rotational force is minimum since the flow resistance of the oil is minimum, and when the opening degree of the bypass flow path 260 is minimum, the flow resistance of the oil is decreased. Since the maximum force is the maximum.

The control valve 270 as described above may include an installation groove 272, a spring 274, a valve body 275, and an adjustment screw 279.

The installation groove 272 is formed to pass through the bypass flow path 260. In this embodiment, since the bypass flow path 260 is formed in the body portion 210, the installation groove 272 is also formed in the body portion 210.

The end of the installation groove 272 is provided with a spring 274 for applying an elastic force in the longitudinal direction of the installation groove 272.

The valve body 275 is inserted into the installation groove 272 to be elastically supported by the spring 274.

The adjusting screw 279 is inserted into the installation groove 272 and is engaged with the inner circumferential surface of the installation groove 272 to seal the installation groove 272. In addition, the adjustment screw 279 is positioned on the opposite side of the valve body 275 is elastically supported by the spring 274 to support the valve body 275.

Accordingly, the adjustment screw 279 moves inward or outward of the installation groove 272 according to the rotation direction and the amount of rotation to change the position of the valve body 275 supported by the spring 274. .

In addition, the valve body 275 may include an upper flange 276 and a lower flange 277 and an O-ring 278 provided between the upper flange 276 and the lower flange 277.

Here, the O-ring 278 is preferably made of a thickness or height sufficient to seal the bypass passage 260.

The valve body 275 provided with the O-ring 278 is moved within the installation groove 272 by the adjustment screw 279 and the spring 274 to adjust the opening degree of the bypass flow path 260.

That is, when the valve body 275 provided with the O-ring 278 completely blocks a portion communicating with the bypass flow path 260 inside the installation groove 272, the bypass flow path 260 is completely blocked, thereby preventing oil. When the flow path is impossible, the rotational force is maximized. When the valve body 275 is positioned completely outside the portion communicating with the bypass flow path 260 of the installation groove 272, the bypass flow path 260 is completely removed. The opening force is minimized.

Therefore, after the rotation shaft 230 of the rotational force adjusting unit 200 according to the present embodiment is axially coupled to the connection shaft 150, the rotational force can be adjusted by adjusting the adjustment screw 279. That is, the rotational force of the rotary motion can be appropriately adjusted according to the user's physical strength and muscle strength, so that the user can expect an effect of increasing the exercise effect by providing an appropriate exercise load to the user.

On the other hand, as shown in Figure 2, in the case 110, the rotational force control unit 200 is installed in the portion is connected to the external or through the form or a link member (not shown) separately from the control valve 270, etc. It is preferable that the operation unit 115 is provided so that the user can easily adjust the rotational force from the outside.

Next, with reference to the accompanying Figures 12 to 18, it will be described a rotational force adjustment unit of another type applicable to the present invention both arms tug-of-war exercise equipment.

Another type of rotational force adjustment unit 300 to be applied to the exercise device of the present invention for adjusting the rotational force, as shown in Figure 12 and 13 attached, the base 310 and the housing 320 and the shaft 330 And a pivot arm 340 and friction pads 352 and 354.

As shown in FIGS. 13 and 15, the base 310 may be formed such that the support part 314 protrudes a predetermined height from the center of the substantially circular base plate 312 is formed.

The support portion 314 is formed in a substantially cylindrical shape, the end surface is made of a flat surface and a thread is formed on the outer peripheral surface.

In addition, the housing 320 is engaged to the outer circumferential surface of the support part 314 of the base 310, and is rotated after being engaged and moved to one side or the other side in the protruding longitudinal direction of the support part 314 according to the rotational direction. It is provided to be.

In addition, the housing 320 is formed to form a predetermined internal space 326 between the support portion 314 therein.

The openings 328 are symmetrically formed on the side surfaces of the housing 320 in the radial direction of the cylindrical support part 314 facing each other.

In this case, the housing may be divided into a first housing 322 and a second housing 324, as shown in Figure 13, 15 and 16.

The second housing 324 may be formed in a hollow hollow cylindrical shape in which one side and the other side are opened, and the side facing the bottom plate 312 of the base 310 to be engaged with the outer peripheral surface of the support portion 314. A thread is formed on the inner circumferential surface of the screw to be coupled to the support portion 314.

Therefore, the second housing 324 is moved in one direction or the other direction of the longitudinal direction of the support portion 314 by the rotation direction.

In addition, the first housing 322 is coupled to the opposite side engaged with the support portion 314 of the second housing 324. The first housing 322 is recessed to form a space therebetween with the support part 314. At this time, the side of the first housing 322 to engage with the second housing 324 is formed to be concave to face each other to form an opening 328 when combined with the second housing 324.

The shaft 330 is provided to penetrate the center of the base 310 and the housing 320. At this time, a bearing 302 is provided between the shaft 330 and the housing 320 to rotatably support the shaft 330.

As shown in FIGS. 13 and 15, the pivot arm 340 is coupled to the shaft 330 in the inner space 326 formed between the housing 320 and the support part 314 and the housing. It is provided to extend to the outside of the housing 320 through the opening 328 formed on both sides of the (320). At this time, the pivot arm 340 is formed to have a surface substantially parallel to the upper surface of the support portion 314. And, both ends of the pivot arm 340 is formed with a coupling hole 342 that can be combined with other external parts having the same axis as the shaft 330 as the rotation axis.

Since the shaft 330 is rotatable with respect to the housing 320, the pivot arm 340 is also rotatable with respect to the housing 320. However, as shown in FIG. 4, since the pivot arm 340 extends outside the housing 320 through the opening of the housing 320, the rotation range 304 of the pivot arm 340 is substantially reduced. As a result, the opening 328 is limited to the formed angle range.

13 and 14, the friction pads 352 and 354 are friction elements with the pivot arm 340 to adjust the rotational force of the pivot arm 340.

The friction pads 352 and 354 as described above are provided in the inner space of the housing 320 to the pivot arm 340 by the inner wall surface of the housing 320 moving in the longitudinal direction of the support part 314. It is made to be rubbed with the pivot arm 340 by being pressed.

In this case, the friction pads 352 and 354 are preferably made to rub against a surface perpendicular to the shaft 330 of the pivot arm 340, that is, a surface parallel to the upper surface of the support part 314. Do.

Meanwhile, a spacer 332 is provided between the shaft 330 and the pivot arm 340. The spacer 332 penetrates through the center of the shaft 330 and is key-coupled with the shaft 330 to rotate together with the rotation of the shaft 330. In addition, the pivot arm 340 may be configured to be pressed and fixed to the shaft 330. Of course, the pivot arm 340 does not necessarily need to be fixed to the shaft 330 and may be made to rotate freely.

As shown in FIGS. 13, 15, and 16, the friction pads 352 and 354 may include a first friction pad 352 and a second friction pad 354.

As shown in FIG. 17, the first friction pad 352 and the second friction pad 354 are formed in a substantially disk shape and have a hole 356 through which the shaft 330 and the spacer 332 pass through a central portion thereof. ) Is formed. In addition, a portion of the first friction pad 352 and the second friction pad 354 that is rubbed with the pivot arm 340 is provided with grooves 358 extending to the outer circumferential surface in a radial direction at predetermined intervals, thereby providing a friction pad 352. , 354 may be provided to collect dust in the groove 358 without remaining on the friction surface and to be discharged to the outside to improve the friction force.

15 and 16, the first friction pad 352 is provided in an inner space of the first housing 322, and is disposed between the first housing 322 and the pivot arm 340. It is provided.

In addition, the second friction pad 354 is provided between the pivot arm 340 and the support part 314 of the base 310 as shown in FIGS. 15 to 16.

Therefore, as the housing 320 is engaged with the outer circumferential surface of the support portion 314 and moves to one side and the other side in the longitudinal direction of the support portion 314, the first friction pad 352 and the second friction pad The force that the 354 is pressed toward the pivot arm 340 is different.

That is, when the housing 320 is moved to the bottom side of the base 310, the housing 320 presses the first friction pad 352 toward the pivot arm 340 and accordingly the pivot arm 340. ) Is pressed toward the second friction pad 354, so that the friction force between the friction pads 352 and 354 and the pivot arm 340 is increased, so that the rotational force for rotation is increased, and the housing 320 is the base ( When the first friction pad 352 and the second friction pad 354 are moved to a direction away from the 310, the force applied to the pivot arm 340 is weakened, so that the frictional force is weakened, and thus the rotation of the pivot arm 340 is reduced. The rotational force is weakened.

In addition, since the friction pads 352 and 354 are formed in a circular shape, the friction pads 352 and 354 come into contact with the friction pads 352 and 354 over the entire rotation range 304 of the pivot arm 340, thereby providing uniform rotational force. It works.

On the other hand, since the friction pads 352 and 354 attenuate the rotational force of the pivot arm 340 by rubbing with the pivot arm 340, wear may occur as the number of repeated frictions increases. As such, as the friction pads 352 and 354 wear, a gap between the pivot arm 340 and the friction pads 352 and 354 occurs or widens, so that the friction pads 352 and 354 may move to the pivot arm 340. The pressure that is pressed can be reduced and the torque can be reduced.

Therefore, as shown in FIG. 18, the pressing unit 360 may be further provided to move the friction pads 352 and 354 toward the pivot arm 340 as the friction pads 352 and 354 wear.

That is, Figure 18 is a cross-sectional view showing another form of the rotational force control unit applicable to the present invention both arms tug-of-war exercise device.

As shown, the rotational force adjustment unit 300 of another form comprises a base 310 and the housing 320, the shaft 330, the pivot arm 340, friction pads 352, 354, the Since the components are substantially the same as the above-described embodiment, a detailed description thereof will be omitted.

The friction control unit according to the present embodiment further comprises a pressing unit in the friction control unit of the above-described embodiment.

As described above, the pressing unit is a component that moves the friction pads 352 and 354 toward the pivot arm 340 as the friction pads 352 and 354 wear, and the friction pads 352 and 354. Is elastically pressed toward the friction pads 352 and 354 by the spring 360, so that the friction pads 352 and 354 move toward the pivot arm 340 as much as the friction pads 352 and 354 are worn. ) Can be maintained at all times.

Of course, the spring 360 is also stretched and contracted by the movement of the housing 320, so that the force for pressing the friction pads 352 and 354 toward the pivot arm 340 can be adjusted. It is adjustable.

Even in such a case, after connecting the connecting shaft 150 to the pivot arm 340 so as to be rotatable about the shaft 330, the rotational force is adjusted to achieve a rotational force applied with an appropriate load to perform a string motion. It becomes possible.

As described above, the preferred embodiments of the present invention have been described, and the fact that the present invention can be embodied in other specific forms in addition to the above-described embodiments without departing from the spirit or scope thereof has ordinary skill in the art. It is obvious to them. Therefore, the above-described embodiments should be regarded as illustrative rather than restrictive, and thus, the present invention is not limited to the above description and may be modified within the scope of the appended claims and their equivalents.

100: two-arm tug-of-war exercise equipment 110: case
120: string 130: handle
140: connecting portion 150: connecting shaft
200: rotational force adjustment unit 210: body portion
212: accommodation space 214: oil chamber
215: hole 216: first oil chamber
218: second oil chamber 220: cover portion
230: rotating shaft 232: bearing
240: vane 250: blocking block
260: bypass flow path 270: control valve
272: installation home 274: spring
275: valve body 276: upper flange
277: lower flange 278: O-ring

Claims (7)

A case forming an appearance;
A rotational force adjusting unit having a rotation shaft capable of adjusting rotational force and installed inside the case;
A connection unit connected to the rotation shaft of the rotation force adjusting unit; And
A string provided in the connection unit such that the rotation shaft is rotatable when a tensile force is applied;
Both arms tug-of-war exercise equipment provided with a rotational force adjustment unit comprising a. The method of claim 1,
The rotational force adjusting unit,
A cylindrical portion having a cylindrical accommodating space therein and having one side opened;
A cover part coupled to the opened part of the body part to close the receiving space;
A rotating shaft rotatably penetrating the central portion of the body portion and the cover portion to form an oil chamber filled with oil between the receiving space;
A vane formed along the rotary shaft toward the inner wall of the accommodation space from the rotary shaft to rotate the rotary shaft in the oil chamber according to the rotation of the rotary shaft to push oil in the oil chamber;
A bypass flow path through which the oil pushed by the vane flows; And
A control valve for adjusting the opening degree of the bypass flow path;
Both arms tug-of-war exercise device provided with a rotational force adjustment unit characterized in that comprises a. The method of claim 2,
Blocking block formed along the height of the inner wall of the receiving space from the inner wall of the receiving space toward the rotary shaft, blocking the movement of oil in the oil chamber being pushed by the vane and limits the rotation range of the vane Is further provided,
The bypass flow path,
Both arms tug-of-war exercise device provided with a rotational force control unit, characterized in that provided to communicate with one side and the other side of the blocking block. The method of claim 2,
The bypass flow path,
Both arms tug-of-war exercise device provided with a rotational force control unit, characterized in that formed in the body portion. The method of claim 2,
The control valve
An installation groove formed to penetrate the bypass flow path;
A spring located inside the installation groove;
A valve body positioned inside the installation groove so as to be elastically supported by the spring and adjusting an opening degree of a portion communicating with the bypass flow path according to a position in the installation groove;
An adjustment screw which is engaged with the opened portion of the installation groove and closes the installation groove, and moves in or out of the installation groove according to a rotation amount to support the valve body on the opposite side of the elastically supported by the spring;
Both arms tug-of-war exercise device provided with a rotational force adjustment unit characterized in that comprises a. The method of claim 5,
The valve body,
It is formed including the upper flange and the lower flange,
It is provided between the upper flange and the lower flange is a two-arm tug-of-war exercise equipment provided with a rotational force adjustment unit characterized in that it comprises an O-ring made to be in close contact with the inner surface of the installation groove. The method of claim 1,
The case is provided with a pair of rotational force adjusting unit so that the rotation shaft is positioned in the opposite direction to each other,
The connecting unit is connected to the rotary shaft of each of the torque adjustment unit,
Both arms tug-of-war exercise equipment provided with a rotational force adjusting unit, characterized in that the string is provided with both sides symmetrical to the connecting unit so that each of the rotary shaft is rotatable when applying a tensile force.

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