KR20070006256A - Chest expander - Google Patents

Abstract

A chest expander having a pair of actuation arms, compressed spring between the arms and an elastic force controller is provided to reduce stress concentration on spring connection part, to randomly regulate intensity of elastic force of the spring and distance between the arms by fabricating the controller on either of the arms to move one end of the spring up and down along the arm. The chest expander comprises: a pair of actuation arms(10,30) moving near or apart from each other by a pivot part(35); a compressed spring(50) that is located between the arms in an inclined direction to give elastic force to the arms in a direction for spacing the arms apart from each other by compression generated when the arms are adjacent each other; and a control part(70) that is arranged on top side of either arm to make one end of the compressed spring to move up and down along the arm as closed to an imaginary arch around the other end of the spring, thereby regulating intensity of elastic force given by the spring.

Description

Force {CHEST EXPANDER}

1 is a front view of a tensioner according to a first embodiment of the present invention.

2 is an exploded perspective view of a tensioner according to a first embodiment of the present invention.

3 is a front sectional view of a tensioner according to a first embodiment of the present invention.

4 is a view showing another example of a compression spring in the first embodiment of the present invention.

5 is an operation diagram when adjusting the strength and weakness of the tensioner according to the first embodiment of the present invention.

6 is an operation diagram when adjusting the distance of the armature according to the first embodiment of the present invention.

7 is a perspective view of a tensioner according to a second embodiment of the present invention.

8 is a partially exploded perspective view of a tensioner according to a second embodiment of the present invention.

9 is an exploded perspective view of a tensioner according to a second embodiment of the present invention.

10 is an exploded perspective view of a tensioner according to a third embodiment of the present invention.

11 is a cross-sectional view of a tensioner according to a third embodiment of the present invention.

12 is an operation diagram when adjusting the distance of the armature according to the third embodiment of the present invention.

The present invention relates to a tensioner.

In general, the force device is a type of exercise equipment used to strengthen the strength of the arm or shoulder. The armature grips the grips provided on the pair of operating arms with both hands, and then presses the pair of operating arms to access each other so that the muscles are applied to the arm or shoulder by the elastic force of the spring to release the force again. When a pair of handles are separated from each other, the principle of restoring the strength of the arm or shoulder is returned to its original state. By repeating such an operation, the user can improve the strength of the arm and the shoulder.

However, in such a tensioner, a conventional tensioner uses a tension coil spring to provide an elastic force. Coil spring is installed between a pair of operating arms which are installed so as to be accessible and spaced apart from each other around the hinge coupling portion, and a horizontal member extending in the horizontal direction of the hinge coupling portion from the upper side of the operating arm so that the user grips the operating arm. The coil spring is stretched to provide elastic force when approaching each other.

However, the conventional tensioner using the elastic force exerted when the coil spring is tensioned, there is a problem that the stress is concentrated in the connection portion of the coil tension spring when the working arm approaches each other, so that the connection portion of the coil spring is easily broken. Therefore, there is a problem that the durability of the tensioner depends on the rigidity of the connection portion of the coil spring.

On the other hand, the conventional tensioner had a disadvantage that it is impossible to exercise using the tensioner suitable for their physique because the distance between the working arms is fixed.

The present invention has been made to solve the above problems, the compression of the spring member that provides the elastic force to the tensioner to improve the strength of the elastic force provided to the tensioner to solve the problem that the spring connection is broken while the user to his own strength It is an object of the present invention to provide a force that can adjust the force.

Another object of the present invention is to provide a tensioner that can adjust the distance between the working arms of the tensioner to fit the user's physique.

The present invention to achieve the above object, a pair of operating arms that are connected to each other by the rotational portion to enable the movement; A compression spring disposed between the pair of operating arms in an inclined direction and configured to provide an elastic force in the direction in which the operating arms are spaced apart from each other by compression deformation that the length contracts when the operating arms approach each other; And the compression spring is installed above the operating arm of any one of the pair of operating arms such that one end of the compression spring is movable up and down along the operating arm adjacent to an imaginary arc centered on the other end. Provides a tensioner including a strength and weakening control portion that allows to adjust the strength of the elastic force to provide.

Preferably, the compression spring is a cylindrical tube containing a compressible gas therein and a tube connection portion, and one end is located inside the tube is moved up and down while being guided by the inside of the tube and the tube connection portion Consists of a gas spring consisting of a rod having a rod connection on the opposite side, it is configured to provide an elastic force while the gas is compressed when the length of the gas spring is contracted.

Preferably, the compression spring is made of a coil spring, the coil spring, a first body supporting one end of the coil spring and connected to any one of the pair of working arms, and the coil in the first body A first guide member having a first guide rod extending along a spring extending direction and having a guide groove formed therein; A second body which supports the other end of the coil spring and is connected to the other of the pair of operating arms, and extends along the extension direction of the coil spring in the second body and is inserted into the guide groove to extend the path of the guide groove; Interposed between the second guide member having a second guide rod to move along the configuration is configured to be guided in the longitudinal deformation direction.

In addition, the present invention is a pair of operating arms that are rotatably coupled to each other to the mutually accessible and spaced movement to both ends of the rotating portion; A strength and weakness control unit installed in the rotation unit and including a movable body movable in an up and down direction; One end is supported on each of the pair of operating arms and the other end is supported on the movable body, and the elastic force can be provided in a direction in which the operating arms are spaced apart from each other by compressive deformation that the length contracts when the operating arms approach each other. To provide a configured tensioner including a pair of compression springs.

Preferably, the compression spring is a cylindrical tube having a tube connection for receiving a compressible gas therein and connected to the movable body, and one end is located inside the tube to guide the movement by the inside of the tube. A rod having a rod connection portion which is lowered and connected to each of the operation arms on opposite sides of the tube connection portion, and the pair of operation arms are spaced apart from each other by an elastic force provided while the gas is compressed during length contraction. Consists of a gas spring to provide force.

Preferably, the compression spring is made of a coil spring, the coil spring, a first body supporting one end of the coil spring and connected to any one of the pair of operating arms, and in the first body A first guide member having a first guide rod extending in an extension direction of the coil spring and having a guide groove formed therein; A second body which supports the other end of the coil spring and is connected to the other of the pair of operating arms, and extends along the extension direction of the coil spring in the second body and is inserted into the guide groove to extend the path of the guide groove; Interposed between the second guide member having a second guide rod to move along the configuration is configured to be guided in the longitudinal deformation direction.

In addition, the present invention, a pair of working arms that are rotatably coupled to each other to the mutually accessible and spaced movement to both ends of the rotating portion; Both ends are located in one direction and the middle portion is bent to form an arch having a curved portion, one end of which is located upwards is supported by the rotating part and rotatably coupled to the rotating part, the other end is connected to the operating arm. Curved arm coupled while extending in the cross direction; A compression spring installed between the curved portion of the curved arm and the pivoting portion to provide an elastic force in a direction in which the pair of working arms are spaced apart from each other; And installed in the rotational portion to support the one end of the compression spring by providing a resilient control unit including a strength adjustment portion to adjust the strength of the elastic force provided by the compression spring by allowing the vertical movement.

Preferably, it further comprises a distance adjusting unit for adjusting the separation distance between the operating arm by changing the engagement position of the other end of the curved arm and the operating arm.

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

1 is a front view of a tensioner according to the first embodiment of the present invention, Figure 2 is an exploded perspective view of the tensioner according to the first embodiment of the present invention, Figure 3 is another tensioner according to the first embodiment of the present invention Is a cross-sectional view of.

1 to 3, the tensioner according to the first embodiment of the present invention is operated between a pair of operating arms (10,30) and a pair of operating arms that are rotatably coupled by a pivoting unit. It includes a gas spring (50) which is a compression spring for providing an elastic force in the direction in which the arms (10,30) are spaced apart from each other, and a strength control unit (70) for adjusting the strength of the elasticity provided to the gas spring (50) Preferably, it comprises a distance adjusting unit 90 to change the separation distance between the operating arms.

The actuating arms 10 and 30 are formed of a long rectangular rod, and each end is provided with gripping portions 10a and 30a for gripping by the user. In general, the holding portions (10a, 30a) is made of a non-slip anti-slip pad (not shown) is attached, the anti-slip pad is generally used a rubber pad so that the user's fingers can be easily placed The holding groove (not shown) is formed in a structure formed.

The actuating arms 10 and 30 are rotatably coupled to each other to allow mutual movement and separation by the pivot. As shown in the figure, a hinge portion 14 in which a pin hole 12 is formed is provided at an upper end of the first operating arm 10 having an elongated rod shape. A rotating part 35 is provided at an upper end of the second working arm 30 having an elongated shape, and a hinge bracket 34 having a pin hole 32 is formed at a side end of the rotating part 35. The hinge portion 14 of the first operating arm 10 is inserted into the hinge bracket 34 of the second operating arm 30 and the hinge pins 2 are fixed through the pin holes 12 and 32 so that the first operating arm is fixed. (10) and the second operating arm (30) are rotatably coupled to allow mutual access and separation.

Between the first operating arm 10 and the second operating arm 30, a gas spring 50 for providing an elastic force in the spaced apart direction is disposed to be inclined. The gas spring 50 exerts an elastic force by using a compressible gas volume change inside the tube 54 as the rod 52 moves, and one end of the rod 52 moves in the tube 54. The rod 52 is moved up and down as the movement is guided by the inside of the tube. Thus, even when the gas spring 50 is formed to have a long length, the gas spring 50 may be provided with an elastic force while the length is contracted and stretched without bending in one direction. At the ends of the rod 52 and the tube 54 of the gas spring, connecting portions 53 and 55 having pin holes 53 'and 55' are formed, so that the sliders of the strength control unit 70 and the distance control unit 90 ( It is inserted into the hinge brackets 76, 96 of 75, 95 and is rotatably coupled by the pivot pins 4, 4 '.

1 to 3 illustrate a case where the gas spring 50 is used as the compression spring, it is possible to use a compression coil spring, and in this case preferably in FIG. As shown, it is preferable to further include a guide member which can prevent the bending of the compression coil spring.

Referring to FIG. 4, in the extending direction of the coil spring in the first body 58a and the first body 58a, which supports one end of the coil spring 57 and is connected to any one of the pair of operating arms. The first guide member 58 and the other end of the coil spring 57 having the first guide rod 58b extending along and formed with the guide groove 58c are supported and connected to the other of the pair of operating arms. The second body 59a and the second body 59a extend along the extension direction of the coil spring 57 and are inserted into the guide groove 58c to move along the extension path of the guide groove 58c. Including the second guide member 59 including a second guide bar (59b) to hold the coil spring 57 by the first guide member 58 and the second guide member 59 in the longitudinal direction The deformation is configured to be guided.

Referring back to FIGS. 1 to 3, the distance adjusting part 90 formed downward of the first operating arm 10 is installed in the lower side of the first operating arm 10 so as to be capable of forward and reverse rotation and threaded on an outer circumferential surface thereof. The rotating shaft bolt 92 and the rotating shaft bolt 92 is integrally coupled to adjust the forward and reverse rotation of the rotating shaft bolt 92 and a part of the rotating shaft bolt 92 is exposed to the outside of the first operating arm 10 through the user Rotation knob 94 to adjust the rotation of the rotary shaft bolt 92, and the slider 95 is fastened to the rotary shaft bolt 92 by the forward and reverse rotation of the rotary shaft bolt. A hinge bracket 96 formed with a pin hole 96 'is formed at the side of the slider 95 so that the hinge bracket 96 protrudes from the side of the first operating arm 10 so that the rod 52 of the gas spring 50 can be formed. Connecting portion 53 formed at the end of the () is inserted and rotatably coupled by the rotation pin (4). A fixing block 20 for supporting the end of the rotating shaft bolt 92 is installed inside the first operating arm 10, and pins are provided in the pin block through-holes 21 formed on the plate surface of the first operating arm 10. The block 23 is inserted to allow the rotating shaft bolt 92 to rotate in position.

The strength adjustment part 70 formed on the upper side of the second operation arm 30 is installed on the upper side of the second operation arm 30 so as to be rotated forward and backward and has a screw shaft formed on an outer circumferential surface thereof, and a rotation shaft bolt. Combining integrally with the 72 can adjust the forward and reverse rotation of the rotating shaft bolt 72 and a portion of the rotating shaft bolt 72 is exposed to the outside of the second operating arm 30 through the opening 36 to allow the user to rotate the rotating shaft bolt 72 Rotation knob 74 that can be adjusted, and the slider 75 is fastened to the rotation shaft bolt 72 is moved up and down by the forward and reverse rotation of the rotation shaft bolt. A hinge bracket 76 having a pin hole 76 ′ protrudes from the side of the slider 75, and the hinge bracket 76 protrudes from the side of the second operating arm 30 to form a tube 54 of the gas spring 50. Connecting portion 55 formed at the end of the () is inserted and rotatably coupled by the rotation pin (4 '). A fixing block 31 supporting the end of the rotating shaft bolt 72 is installed inside the second operating arm 10, and pins are provided in the pin block through-holes 33 formed on the plate surface of the first operating arm 30. A block 37 is inserted to allow the rotating shaft bolt 72 to rotate in position.

Hereinafter, the operation of the armature according to the first embodiment of the present invention with reference to the drawings.

5 is a view for explaining an example of the strength and weakness adjustment of the tensioner according to the first embodiment of the present invention. Referring to the drawings, in order to adjust the strength of the user to the strength of the dashed state to match the user's strength, such as children with weak muscles in the state shown in the dotted line by rotating the rotary knob 74 of the strength control unit 70 to one side The slider 75 is moved upward. Since the strength and weakness adjustment part 70 is formed above the second operation arm 30, the slider will be described with reference to the pivoting pin 4, which is a coupling portion of the distance adjustment part 90 and the gas spring 50. The movement path of 75 is approximated with the rotation path of the other end of the gas spring 50 in a state where the operation arms 10 and 30 are spaced apart from each other. Accordingly, when the rotary knob 74 is rotated, the slider 75 moves upward, and the other end of the gas spring 50 is located on the rotation path centering on the pivot pin 4. It moves upward along the rotating shaft bolt (72). The strength of the elasticity provided to the tensioner is the strength of the elasticity provided when the working arms 10 and 30 are close to each other and are determined according to the displacement amount of the gas spring 50. As shown in the figure, when the other end of the gas spring 50 moves upward along the rotating shaft bolt 72 of the strength adjustment part 70, it is the gas spring 50 when the operating arms 10, 30 are close to each other. ) Results in a change in the amount of displacement that is compressed, and consequently, means that the force required during the exercise using the force reducer becomes smaller. Therefore, according to the tensioner according to the first embodiment of the present invention, the user is able to exercise by adjusting the elasticity of the tensioner in accordance with his strength.

In the first embodiment of the present invention, the elasticity provided in the tensioner can be adjusted using the compression displacement amount of the spring. When the compression coil spring is used in the tensioner, the coil spring may be bent in the lateral direction and bend during the contraction and restoration of the coil spring, thereby preventing elasticity from being provided. According to the present invention, however, the end of the rod inserted into the tube is guided by the inner surface of the tube, thereby preventing the bending of the rod in the longitudinal direction. By using the elastic force generated when compressing the gas in the spring connection can be solved the problem of breakage.

6 is a view for explaining an example of the distance adjustment of the armature according to the first embodiment of the present invention. Referring to the drawings, in the state shown in a solid line, a user, such as a child with a small physique having a short arm length, shoulder width, etc. in order to adjust the distance of the working arm in a dotted line state to fit his / her physique. ) Rotates the rotary knob 94 to one side to move the slider (95) downward. Since the distance adjusting part 90 is formed below the first operating arm 10, the distance adjusting part 90 looks at the pivot pin 4 ′, which is a hinge coupling part of the strength and weakness adjusting part 70 and the gas spring 50. The movement path of the slider 95 intersects with the rotation path of one end of the gas spring 50. Therefore, when the slider 95 is moved as the rotary knob 94 is rotated, one end of the gas spring 50 is changed in position, which is viewed from the first operating arm 10 based on the second operating arm 30. ) Will move away or close. Accordingly, when the rotary knob 94 of the distance adjusting unit 90 is rotated to one side and the slider 95 is rotated downward, the first operating arm 10 is first rotated based on the second operating arm 30. 2 will be close to the working arm (30). Therefore, according to the armature according to the first embodiment of the present invention, the user can exercise by adjusting the distance of the arm of the armature to fit his or her body in consideration of his arm length and shoulder width.

Accordingly, the tensioner according to the first embodiment of the present invention can be used in accordance with the user's physique and strength by adjusting the distance between the strength and weakness and the working arm. In addition, the resilient device according to the first embodiment of the present invention is small in the "c" shape in the folded state to ensure the convenience of portability.

7 and 8 are perspective views of the armature according to the second embodiment of the present invention, Figure 9 is a partially exploded perspective view according to a second embodiment of the present invention. The second embodiment of the present invention shows an embodiment in which a tensioner is constructed using two compression springs.

7 to 9, the resilient device according to the second embodiment of the present invention is a pair of operating arm pivotally coupled to the rotating part 110 and the side of the rotating part so as to be approached and spaced apart from each other ( 120 and 130, the strength and weakness control unit 140 installed in the pivoting unit 110, and the gas spring 160, which is a compression spring installed between the pair of operating arms 120 and 130 and the strength and weakness control unit 140. It includes, and preferably comprises a distance adjusting unit 170.

The gas spring 160 exerts an elastic force by using a volume change of the compressible gas inside the tube as the rod moves. As one end of the rod moves in the tube, the rod is guided by the inside of the tube. Descends. Accordingly, even when the gas spring 160 is formed to have a long length, the gas spring 160 may provide elastic force while the length is contracted and stretched without bending in one direction. 7 to 9 illustrate a case where the gas spring 160 is used as the compression spring, it is possible to use a compression coil spring, in which case it is preferable to be identical to the configuration shown in FIG. While the coil spring is held by the first guide member and the second guide member, the longitudinal deformation is guided.

The operation arms 120 and 130 are formed of long, rectangular rods, and gripping parts 122 and 132 are provided at each end thereof, and gripping pads (not shown) having gripping grooves formed at the gripping parts so that a user's finger can be easily disposed. Is attachable.

Hinge portions 122 and 132 formed with pin holes 123 and 133 are formed at upper ends of the operating arms 120 and 130, and are rotatable by hinge coupling portions 112 and 114 and pivot pins 101 and 102 formed at both side ends of the pivoting portion 110. Combined.

The rotating unit 110 includes hinge coupling portions 112 and 114 having pin holes formed at both ends of the body 111, and hinge portions 122 and 132 of the hinge coupling portions 112 and 114 and the operating arms 120 and 130 are connected to the rotating pins 101 and 102. Rotatingly coupled to form a rotatable coupling portion. Strength adjustment unit 140 is provided under the imaginary line connecting the rotation coupling unit.

The strength adjustment unit 140 is configured to be movable up and down by supporting the other end of the gas spring 160 fixed to the operation arms 120 and 130 to adjust the strength of the compression spring. The gas spring 160 exerts elastic force by using a gas volume change inside the tube 166 according to the movement of the rod 162, and a pin hole is formed at an end of the rod 162 and the tube 166 of the gas spring 160. Connection portions 163 and 167 having 163 'and 167' are formed. Connections 163 and 167 of rod 162 and tube 166 are coupled with actuating arms 120 and 130 and strength adjustment 140.

According to the embodiment shown in Figures 7 to 9, the strength adjustment unit 140 includes a moving body 142 which is moved up and down by supporting the connecting portion 167 of the tube 166 of the gas spring 160. A pair of fixing pieces 144 having a pin hole 141 formed at the lower end of the movable body 142 is formed. The tube 166 connecting portion 167 of the other end of the gas spring 160 is inserted between the fixing pieces 144 and is rotatable by the rotation pin 169 inserted through the pin hole 141 of the fixing piece 144. Is supported. An installation groove 143 through which the adjustment knob 146 is installed is formed in the body of the movable body 142. A moving groove 152 is formed along the longitudinal direction of the body 111 of the rotating unit 110, and a plurality of fixing grooves 154 are formed along the extension path of the moving groove 152. The adjusting knob 146 is installed through the moving groove 152 and the installation groove 143 of the body 111, and includes a circular shaft 147 and a handle portion 149 attached to the end thereof. Notches 148 are formed on each of the opposing surfaces so as to be movable along the moving grooves 152 on both sides of the circular shaft 147. Therefore, when the handle 149 is turned upright, the notch 148 formed on the circular shaft 147 is erected in the longitudinal direction, and the circular shaft 147 is movable along the moving groove 152. Accordingly, it is possible to move up and down of the movable body 142 in the state in which the adjustment knob 146 is installed, the notch 148 is positioned in the vertical direction when the knob 149 is turned in the fixing groove 154 that provides the desired elasticity. While the circular shaft 147 is fixed to the fixing groove 154, the movable body 142 shangdong is regulated.

The connecting portion 163 of the rod 162 of the gas spring 160 is coupled to the lower side of the working arms (120, 130). A plurality of fixing holes 172 are formed in the lower portion of the operation arms 120 and 130 to which the connecting portion 163 of the rod 162 of the gas spring 160 disposed to be inclined is coupled in the longitudinal direction. The connecting portion 163 formed at the end of the rod 162 of the gas spring 160 is fixed by the fixing pin 175 passing through the fixing hole 172 and the pin hole 163 'of the connecting portion 163, As the fixing hole 172 coupled to the connecting portion 163 is changed, it is possible to adjust the separation distance between the working arms 120 and 130.

Hereinafter will be described the operation according to the second embodiment of the present invention.

Another tensioner in the second embodiment of the present invention is a tensioner configured using two compression springs, which illustrate the case where the gas spring 160 is used. Therefore, the elasticity provided to the tensioner when exercising while gripping, approaching and separating the operating arms 120 and 130 of the tensioner depends on the amount of compression displacement of the compression spring. Therefore, it is possible to solve the problem that the stress is broken by the concentration of the spring connection.

Referring to FIGS. 8 and 9, the strength adjustment operation of the tensioner according to the second embodiment of the present invention, the connecting portion 167 of the tube 166 of the gas spring used as the compression spring 160 is the rotary pin 169. The strength of the elasticity is increased when moving downward along the movable body 142 in a state in which it is freely fixed to the movable body 142, and the strength of the elasticity is weakened when moving upward. Looking at the movement of the moving body 142, first turning the handle 149 of the adjustment knob 146, the notch 148 formed on both sides of the circular shaft 147 is parallel to the extending direction of the moving groove 152 Grasp the handle 149 and move the movable body downward or upward. Both ends of the moving groove 152 are guided by the notch 148 to move the moving body 142. After adjusting the elasticity as intended, hold the handle 149 at the position where the fixing groove 154 is formed and rotate the adjusting knob 146. When the circular shaft 147 rotates, the notch 148 crosses the extending direction of the moving groove 152, so that the circular shaft 147 cannot be moved along the moving groove 152, and the moving body 142 is moved. It is supported in the fixing groove 154 position.

On the other hand, looking at the separation distance control process of the operation arm (120,130), after removing the fixing pin 175, the connection portion 163 of the rod 162 is separated from the operation arm (120,130) and then the connection portion 163 before removal After moving to the connection portion 163 to the fixing hole 172 located below the fixed fixing hole 172 is coupled to the fixing pin 175 again. In this way, when the position of the fixing hole 172 of the operation arm (110,130) coupled to the connecting portion 163 of the rod 162 moves downward, the distance between the operation arm (120,130) is narrowed, and the position is upward When moving, the distance between the working arms (120, 130) is widened.

According to the method described above, the user of the armature according to the second embodiment of the present invention can use the distance between the strength and the operating arm according to their muscle strength and physique.

10 is an exploded perspective view showing a tensioner according to a third embodiment of the present invention, Figure 11 is a cross-sectional view of the tensioner according to a third embodiment of the present invention. The third embodiment of the present invention shows another embodiment of the tensioner using two compression springs.

10 and 11, the tensioner according to the third embodiment of the present invention is a pair of pivoting units that rotate to allow the approaching and separating movement to each other at both sides of the pivoting portion 210 and the pivoting portion 210. The operating arm 220 and the curved arm 240, the strength adjustment unit 260 installed on the rotating unit 210, and the compression spring 280 is installed between the strength adjustment unit 260 and the operation arm 209. It is configured by.

The operation arm 220 is formed of a long rod, the end of the operation arm 220 is provided with a gripping portion 221, the gripping portion 221 is a sliding groove formed with a gripping groove so that the user's fingers can be easily disposed A prevention pad (not shown) is attachable.

A hinge portion 222 having a pin hole 223 is formed at an upper end of the operating arm 220, and is rotatably coupled to the hinge bracket 214 formed at both side ends of the pivot portion 210 by a pivot pin 201. do.

Rotating portion 210 is composed of a hinge coupling portion 214 formed with a pin hole 212 at both ends and a body 216 having a fixing member 215, the strength adjustment portion 260 to the lower side of the fixing member 215. ) Is installed.

The curved arm 240 is formed in a bow shape in which both ends are located in one direction and the middle portion is bent. One end portion 241 positioned upward is supported in contact with the upper surface of the fixing member 215, the hinge coupling portion 242 is formed with a pin hole 242 'is formed on the side. The pivot pin 201 is engaged with the hinge portion 222 of the operating arm 220, the hinge coupling portion 214 of the pivoting portion 210, and the hinge coupling portion 242 of the curved arm 240 overlapping each other. To be assembled.

Curved arm 240 extends to one side, the middle portion is bent to form a curved portion 245, the direction is changed and extends in one direction again, the other extension portion to the arc-shaped support 225 formed on the operation arm 220 Correspondingly extending in an arc shape. A plurality of fixing holes 247 are formed in the arc-shaped extension part 246 formed on the other side of the curved arm 240, and formed above the supporting part 225 of the fixing hole 247 and the operation arm 220. Through the fixing hole 227, the fixing pin 204 is coupled so that the curved arm 240 is supported by the operating arm 220. Although described in detail below, it is possible to adjust the distance between the working arms 220 according to the position of the fixing hole 247 of the arcuate extension 246 coupled by the fixing pin 204. The coupling of the extension portion 246 of the curved arm 240 and the operation arm 220 has been described using the fixing pin 204 as an example in the present embodiment, but is not limited thereto and is formed in a sliding manner. It is apparent that such modifications are naturally understood to be within the scope of the present invention.

The strength and weakening portion 260 formed on the rotating part 210 is fixed to the lower end of the rotating shaft bolt 262, the upper end of the rotating shaft bolt 262 is rotatably supported by the fixing member 215 (the rotating shaft bolt ( 262 and the rotating knob 264 and the rotating shaft bolt 262 is fastened to the front and rear of the body 216 is adjustable to allow the user to adjust the rotation of the rotating shaft bolt 262 The slider 265 moves up and down according to the forward and reverse rotation of the rotation shaft bolt 262. The rotating shaft bolt 262 is supported by the pin block 302 to be rotatable in place.

A compression spring 280 is installed between the slider 265 and the curved arm 240, and one end of the compression spring 280 is supported by the slider 265 so that the compression spring 280 moves as the slider 265 moves. The strength of the force is adjusted as one end of the machine moves up and down.

Compression spring 280 may be a gas spring, coiled coil spring (285), etc., the gas spring is a cylindrical tube that receives the compressible gas therein and has a tube connection, and the inside of the tube One end portion is located in the rod is moved up and down while being guided by the inside of the tube consists of a rod provided with a rod connection to the opposite side of the tube connection. When the coil spring 285 is used as the compression spring 280, it is preferable to include a guide member 290 for guiding the compression direction of the coil spring 285.

The guide member 290 has a first body 295 and the first body 295 formed so as to be supported by one end of the coil spring 285 rotatably rotatable and the other end of the guide member 290 in contact with the curved portion 245 formed in a hemispherical shape. A first guide member 291 formed of a first guide rod 298 extending from the other end of the coil spring 285 to an inner side of the coil spring 285 and having a guide groove 296 movable thereon while the second guide rod 308 is guided to the center thereof. And a second body 305 and a second body 305 rotatably rotatable in contact with the curved portion 266 formed at the side of the slider 265 and the other end supporting the other end of the coil spring 285. Consists of a second guide member 301 extending from the other end of the coil spring 285 to the inside of the second guide rod 308 is inserted into the guide groove 296 of the first guide rod 298 and moves The coil springs 285 are installed on the first body 295 and the second body 305.

In the case of using a compression spring as an elastic member providing elasticity to the tensioner, it is possible to solve a problem in that stress is concentrated at both ends of the connection when broken. However, when the coil spring 285 is used as the compression spring, the coil spring 285 may be compressed and bent to one side when the operating arm repeatedly approaches and spaces in the tensioner. However, when the guide member 290 is moved as in the third embodiment of the present invention, since the deformation of the coil spring 285 is guided by the guide member 290, the problem that the coil spring 285 is bent is fundamentally solved. It will be possible.

11 and 12, the operation of the armature according to the third embodiment of the present invention will be described.

First, referring to FIG. 11, when a user who is relatively weak in muscle wants to use the tensioner according to the third embodiment of the present invention, the rotary knob 264 of the rotating shaft bolt 262 shown in FIG. 9 is rotated to one side. The slider 265 is moved upward. When the slider 265 moves upward, one end of the coil spring 285 moves upward, thereby increasing the strength of elasticity acting on the tensioner.

On the other hand, when a relatively strong user wants to use the tensioner according to the third embodiment of the present invention, the rotary knob of the rotary shaft bolt 267 is rotated in the opposite direction to move the slider 265 downward. When the slider 265 moves downward, one end of the coil spring 285 moves downward, thereby reducing the strength of elasticity acting on the tensioner.

12 is a view for explaining the distance adjusting operation of the tensioner according to the second embodiment of the present invention, the solid line shows a case in which the separation distance between the working arm 220 is long, the point is the working arm 220 The case where the separation distance between them is short is shown.

If the user has a large arm length and a large distance between the shoulders and the user wants to use the armature, the armature may be used in a state where the separation distance between the working arms is long as shown by the solid line. In this state, to narrow the distance between the working arms of the tensioner, first, the fixing pin 204 fixing the extension 246 of the curved arm 240 and the working arm 220 is removed. Thereafter, the fixing holes 227 of the curved arm 240 and the fixing holes 227 of the operating arm 220 coincide with each other and then fixed with the fixing pin 204. By adjusting in this way, the separation distance between the working arm 220 is small, such as a dotted line, so that a person with a small physique can comfortably use the armature.

Although the present invention described above has been described in detail with reference to specific preferred embodiments, various modifications may be made by those skilled in the art to which the present invention pertains without departing from the spirit or scope of the present invention. . The appended claims are intended to cover such various modifications as well as the above-described embodiments.

According to the present invention, a compression spring can be used as an elastic member that provides elasticity to the tensioner. This makes it possible to solve the problem of breakage of stress that is concentrated in the spring connection, thereby providing a durable resilient force.

In addition, the user can arbitrarily adjust the strength of the elasticity, the distance between the operating arms can be arbitrarily adjustable to provide a tensioner that can be used by adjusting the distance of the operating arm to suit their physique.

Claims (17)

A pair of actuating arms which are connected to each other by rotatable parts so as to allow mutual access and separation movement; A compression spring disposed between the pair of operating arms in an inclined direction and configured to provide an elastic force in the direction in which the operating arms are spaced apart from each other by compression deformation that the length contracts when the operating arms approach each other; And The compression spring is provided by being installed above the operating arm of any one of the pair of operating arms such that one end of the compression spring is movable up and down along the operating arm adjacent to an imaginary arc centered on the other end. A resilience device comprising a strength and weakness control unit for adjusting the strength and strength of the elastic force. The method of claim 1, The compression spring, A cylindrical tube containing a compressible gas therein and having a tube connection portion, and a rod having one end portion positioned inside the tube and being moved up and down while being guided by the inside of the tube, and having a rod connection portion opposite to the tube connection portion. Consisting of a configured gas spring, The tensioner, characterized in that configured to provide an elastic force while the gas is compressed when the length of the gas spring is contracted. The method of claim 1, The compression spring is made of a coil spring The coil spring, A first body supporting one end of the coil spring and connected to any one of the pair of operating arms, and a first guide rod extending from the first body along an extension direction of the coil spring and having a guide groove formed therein; A first guide member; A second body which supports the other end of the coil spring and is connected to the other of the pair of operating arms, and extends along the extension direction of the coil spring in the second body and is inserted into the guide groove to extend the path of the guide groove; The tensioner, characterized in that the deformation direction in the longitudinal direction is interposed between the second guide member having a second guide rod moving along the guide. The method of claim 1, It is installed below the other arm of the pair of operating arms, and is supported by the other end of the compression spring to move up and down, And a distance adjuster for adjusting a distance on the pair of operating arms. The method of claim 4, wherein Each of the intensity control unit and the distance control unit A rotating shaft bolt received in the working arm and rotatably installed at a predetermined position; A rotary knob coupled to the rotary shaft bolt to adjust the rotation of the rotary shaft bolt; And Screwed to the rotating shaft bolt is moved up and down in accordance with the rotation of the rotating shaft bolt, and comprises a slider formed with a hinge bracket, And a tube connecting portion and a rod connecting portion of the gas spring are coupled to the hinge brackets of the sliders of the strength adjusting part and the distance adjusting part by a rotation pin. A pair of actuating arms pivotally coupled to both ends of the pivot to enable mutual access and separation; A strength and weakness control unit installed in the rotation unit and including a movable body movable in an up and down direction; One end is supported on each of the pair of operating arms and the other end is supported on the movable body, and the elastic force can be provided in a direction in which the operating arms are spaced apart from each other by compressive deformation that the length contracts when the operating arms approach each other. A tensioner, characterized in that it comprises a pair of compression springs configured to. The method of claim 6, wherein the compression spring, A cylindrical tube having a tube connection portion for receiving a compressible gas therein and connected to the movable body, and having one end positioned inside the tube, being moved up and down while being guided by the inside of the tube, and opposite to the tube connection portion; It includes a rod having a rod connecting portion connected to each of the working arms, the gas spring for providing a force in the direction in which the pair of working arms are spaced apart from each other by the elastic force provided as the gas is compressed when the length contracted Featuring a tensioner. The method of claim 6, The compression spring is made of a coil spring The coil spring, A first body supporting one end of the coil spring and connected to any one of the pair of operating arms, and a first guide rod extending from the first body along an extension direction of the coil spring and having a guide groove formed therein; A first guide member; A second body which supports the other end of the coil spring and is connected to the other of the pair of operating arms, and extends along the extension direction of the coil spring in the second body and is inserted into the guide groove to extend the path of the guide groove; The tensioner, characterized in that the deformation direction in the longitudinal direction is interposed between the second guide member having a second guide rod moving along the guide. The method of claim 6, The intensity control unit A moving groove formed along a vertical direction of the body of the rotating part and a plurality of fixing grooves formed along the extension path; The movable body is rotatably supported by the tube connecting portion of the gas spring to the fixed piece formed at the lower end to be movable up and down, the installation groove is formed through, And a control knob including a circular shaft having a notch extending through the movable groove of the body and the installation groove of the movable body and movable along the movable groove on both sides thereof, and a handle formed at the end of the circular shaft. And the circular shaft is movable up and down along the moving groove in a state in which the circular shaft is towed the movable body according to the rotation of the handle of the adjusting knob, and is fixed in the fixing groove. The method of claim 6, One end of the compression spring It is installed on the operating arm, the tensioner, characterized in that coupled to the distance adjuster to adjust the position of one end of the compression spring along the operation arm. The method of claim 10, The distance adjusting unit is a tensioner, characterized in that composed of a plurality of fixed holes are formed along the longitudinal direction of the working arm, and any one of the fixing hole and the fixing pin for freely rotating the rod connecting portion of the gas spring. A pair of actuating arms pivotally coupled to both ends of the pivot to enable mutual access and separation; Both ends are located in one direction and the middle portion is bent to form an arch having a curved portion, one end of which is located upwards is supported by the rotating part and rotatably coupled to the rotating part, the other end is connected to the operating arm. Curved arm coupled while extending in the cross direction; A compression spring installed between the curved portion of the curved arm and the pivoting portion to provide an elastic force in a direction in which the pair of working arms are spaced apart from each other; And And a strength control unit installed in the rotating unit to support one end of the compression spring to move upward and downward to adjust the strength of the elastic force provided by the compression spring. The method of claim 12, wherein the intensity control unit, A rotating shaft bolt rotatably installed to the rotating part; A rotary knob coupled to the rotary shaft bolt of the rotating unit to adjust the rotation of the rotary shaft bolt; The screw is fastened to the rotating shaft bolt is capable of vertical movement according to the rotation of the rotary knob and a tensioner comprising a slider for supporting one end of the compression spring. The method of claim 12, Compression spring is installed between the curved portion of the curved arm and the slider of the strength adjustment portion is made of a coil spring, The coil spring, One end of which is freely supported on the curved portion of the curved arm and the other end includes a first body for supporting one end of the coil spring, and a first guide rod extending from the body along an extension direction of the coil spring and having a guide groove formed therein. A first guide member; One end is freely supported by the curved portion formed by the side of the slider, the other end is a second body for supporting the other end of the coil spring, and extends along the extension direction of the coil spring in the body and the guide groove is inserted into the guide groove The armature is guided by a second guide member having a second guide rod that moves along the extension path of the. The method of claim 12, The compression spring is A cylindrical tube containing a compressible gas therein and having a tube connection portion, and a rod having one end portion positioned inside the tube and being moved up and down while being guided by the inside of the tube, and having a rod connection portion opposite to the tube connection portion. A tensioner, characterized in that the configured gas spring. The method of claim 12, And a distance adjuster configured to adjust a separation distance between the actuating arm by changing a coupling position of the other end of the curved arm and the actuating arm. The method of claim 16, wherein the distance adjusting unit, Any one of a fixed hole formed in the extending direction in the arc-shaped extension portion extending to form the other end of the curved arm, a fixing hole formed corresponding to the arc-shaped extension portion on the working arm, and a fixing hole of the arc-shaped extension portion Consists of one and a fixed pin fixed through the fixing hole of the working arm, And a distance between the actuating arms according to the position of the fixing hole of the arc-shaped extension part coupled to the fixing hole of the working arm by the fixing pin.

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