KR102631519B1 - Magnetic-based resistance adjustment module and resistance adjustment method - Google Patents

Abstract

The present invention relates to a resistance adjustment module for controlling the resistance of an exercise device, comprising: a housing having a groove on the upper side; a cable flowing out through the groove; and a fastening protrusion provided on the lower side of the housing and coupled to the exercise mechanism. As a result, it is not only easy to carry, but can also be easily installed on exercise equipment, and can provide the user's desired resistance.

Description

Magnetic-based resistance adjustment module and resistance adjustment method {MAGNETIC-BASED RESISTANCE ADJUSTMENT MODULE AND RESISTANCE ADJUSTMENT METHOD}

The present invention relates to a magnetic-based resistance control module and a resistance control method, and more specifically, to a magnetic-based resistance control module and a resistance control method for controlling the resistance of an exercise device that provides resistance.

As social distancing to prevent COVID-19 group infections has been implemented globally, interest in personal exercise and home training has increased as it has become difficult to use public gyms and sports facilities.

In order to perform fitness exercise, equipment for fitness exercise is required, but general fitness equipment has a problem of being difficult to carry because it is bulky or has a high weight.

In addition, since fitness equipment can only be used in specific spaces, there is a problem that exercise to improve health can only be performed in a limited way during normal times.

In addition, conventional exercise equipment can only exercise against a certain preset load, which makes it difficult to meet the needs of users who want greater exercise effects or who want to exercise with relatively low resistance.

Therefore, a device that is not only easy to carry, but can also be easily installed on exercise equipment, and can provide the resistance desired by the user is needed.

Korean Patent Publication No. 10-2010-0061984

The present invention was created to solve the above problems, and the purpose of the present invention is to provide a magnetic-based resistance control module that is not only easy to carry, but can also be easily installed on exercise equipment, and can provide the user's desired resistance. It provides a method of controlling resistance.

A resistance adjustment module for adjusting the resistance of an exercise device according to an embodiment of the present invention for achieving the above object includes a housing having a groove on the upper side; a cable flowing out through the groove; and a fastening protrusion provided on the lower side of the housing and coupled to the exercise mechanism.

And a resistance adjustment knob provided on one side of the housing and operated to adjust resistance; a rotation spring located inside the other side of the housing and rotating according to the moving direction of the cable; a cable pulley located between the rotation spring and the resistance adjustment knob inside the housing and around which the cable is wound; And located between the cable pulley and the resistance adjustment knob inside the housing, moves coaxially with the cable pulley according to the operation of the resistance adjustment knob, and is applied to the cable pulley according to the contact area with the cable pulley. It may further include a magnetic portion that adjusts the resistance provided to the user by changing the strength of the magnetic force.

It may also further include a bush that moves coaxially with the cable pulley and is located between the cable pulley and the magnetic portion.

And the magnetic part may include a magnet inserted into the cable pulley or spaced apart from the cable pulley according to the operation of the resistance adjustment knob; And it may include a bearing that is respectively inserted into one side and the other side of the magnet and rotates in a single direction.

Additionally, a magnetic force blocking cover provided between the rotation spring and the cable pulley; and a screw shaft connected to the resistance adjustment knob and penetrating the magnetic portion so that the magnetic portion moves coaxially with the cable pulley.

Meanwhile, a resistance control method according to an embodiment of the present invention for achieving the above object is a resistance control module for controlling the resistance of an exercise equipment, comprising a housing provided with a groove on the upper side, a cable flowing out through the groove, and A fastening protrusion provided on the lower side of the housing and coupled to the exercise mechanism, a resistance adjustment knob provided on one side of the housing and operated to adjust resistance, a rotation spring located inside the other side of the housing and rotating according to the moving direction of the cable, A cable pulley located between the rotation spring and the resistance adjustment knob inside the housing and around which the cable is wound, and a cable pulley located between the cable pulley and the resistance adjustment knob inside the housing, according to the operation of the resistance adjustment knob. providing a resistance adjustment module including a cable pulley and a magnetic portion moving coaxially; adjusting the resistance as the contact area between the magnetic part and the cable pulley changes when the resistance adjustment knob rotates in a predetermined direction; and providing resistance when the cable is released from the cable pulley.

And in the step of adjusting the resistance, when the resistance adjustment knob rotates in the first direction, the magnetic part moves so that part or all of the magnetic part is inserted into the cable pulley, and the contact area increases so that the cable pulley As the magnetic force applied increases, the resistance may increase.

Additionally, in the step of adjusting the resistance, when the resistance adjustment knob rotates in the second direction, the magnetic portion moves so that part or all of the magnetic portion is separated from the inside of the cable pulley, and the contact area is reduced to prevent the cable pulley from moving. As the magnetic force applied to decreases, the resistance may decrease.

According to one aspect of the present invention described above, by providing a magnetic-based resistance control module and a resistance control method, it is not only easy to carry, but can also be easily installed on exercise equipment, and can provide the user's desired resistance.

1 is a perspective view illustrating a resistance adjustment module according to an embodiment of the present invention;
Figure 2 is an exploded perspective view for explaining the configuration of a resistance adjustment module according to an embodiment of the present invention;
Figures 3 and 4 are diagrams for explaining how resistance is adjusted in the resistance control module of Figure 2;
Figure 5 is a diagram for explaining how the resistance control module of Figure 1 is coupled to an exercise device, and
FIG. 6 is a flowchart for explaining a resistance control method in the resistance control module of FIG. 1.

The detailed description of the present invention described below refers to the accompanying drawings, which show by way of example specific embodiments in which the present invention may be practiced. These embodiments are described in sufficient detail to enable those skilled in the art to practice the invention. It should be understood that the various embodiments of the present invention are different from one another but are not necessarily mutually exclusive. For example, specific shapes, structures and characteristics described herein may be implemented in one embodiment without departing from the spirit and scope of the invention. Additionally, it should be understood that the location or arrangement of individual components within each disclosed embodiment may be changed without departing from the spirit and scope of the invention. Accordingly, the detailed description that follows is not intended to be taken in a limiting sense, and the scope of the invention is limited only by the appended claims, together with all equivalents to what those claims assert, if properly described. Similar reference numbers in the drawings refer to identical or similar functions across various aspects.

The components according to the present invention are components defined by functional division rather than physical division, and can be defined by the functions each performs. Each component may be implemented as hardware or program code and processing units that perform each function, and the functions of two or more components may be included and implemented in one component. Therefore, the names given to the components in the following embodiments are not intended to physically distinguish each component, but are given to suggest the representative function performed by each component, and the names of the components refer to the present invention. It should be noted that the technical idea is not limited.

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

Figure 1 is a perspective view for explaining the resistance adjustment module 10 according to an embodiment of the present invention.

The resistance adjustment module 10 (hereinafter referred to as module) according to an embodiment of the present invention is provided to adjust the resistance of an exercise equipment, and can provide the resistance desired by a user exercising.

To this end, the module 10 according to this embodiment includes a housing 110, a cable 120, and a fastening protrusion 130, as shown in FIG. 1.

The housing 110 is an element that makes up the exterior of the module 10, protects various internal components for adjusting resistance, and allows the user to easily install or dismantle the module 10 on exercise equipment or carry it. .

Additionally, the housing 110 may be provided with a groove 111 on the upper side, and a fastening protrusion 130 may be located on the lower side.

The groove 111 is provided to allow a portion of the cable 120 to flow out to the outside.

One end of the cable 120 is connected to the cable pulley 160, which will be described later, and can be wound around the cable pulley 160 through external force by the user.

And the other end of the cable 120 may be connected to a handle held by the user.

Meanwhile, the fastening protrusion 130 is provided to couple the module 10 with the exercise device, and may be provided on the lower side of the housing 110. Specifically, the fastening protrusion 130 may be provided at a position opposite to the groove 111 on the lower side of the housing 110.

The resistance adjustment knob 140 is provided to adjust the degree of resistance provided to the user. And the resistance adjustment knob 140 is provided on one side of the housing 110 and can be operated by the user.

Additionally, the inside of the resistance adjustment knob 140 may be connected to the screw shaft 200.

Figure 2 is an exploded perspective view to explain the configuration of the resistance adjustment module 10 according to an embodiment of the present invention.

The module 10 according to this embodiment is located inside the housing 110 to control resistance and includes a rotation spring 150, a cable pulley 160, a magnetic portion 170, a bush 180, and a magnetic force. It may include a blocking cover 190 and a screw shaft 200.

The rotation spring 150 may be located on the other side of the housing 110 and connected to the cable pulley 160.

And the rotation spring 150 may be provided to allow the cable 120 to be released or wound from the cable pulley 160.

Specifically, when the user pulls the cable 120, the rotation spring 150 rotates the cable pulley 160 in a predetermined direction to wind the spring, and when the external force that causes the cable 120 to be released is released, the spring returns to its original state. By being restored to its shape, the cable 120 that was unwound from the cable pulley 160 can be wound again.

In the case of the rotation spring 150 according to this embodiment, since it can be implemented using generally known technology to transmit or stop rotational motion depending on the direction of rotation, detailed description will be omitted.

Additionally, the rotation spring 150 may have a through hole formed in the center so that the screw shaft 200 passes through it. For convenience of explanation, hereinafter, one side of the housing 110 where the resistance adjustment knob 140 is located will be described as the front, and the other side of the housing 110 will be described as the rear.

A magnetic force blocking cover 190 may be located in front of the rotation spring 150 to block the magnetic force generated between the magnetic portion 170 and the cable pulley 160.

Meanwhile, the cable pulley 160 may be connected to one end of the cable 120 to allow the cable 120 to be wound. This cable pulley 160 may be located between the rotation spring 150 and the resistance adjustment knob 140.

In addition, the cable pulley 160 includes a hollow interior, so that the magnetic portion 170 can be inserted into the hollow according to the operation of the resistance adjustment knob 140.

Through this, the contact area of the cable pulley 160 with the magnetic portion 170 may vary. And the cable pulley 160 may be made of a metal material that can be affected by the magnetic force of the magnetic portion 170.

Therefore, when the cable 120 is released from the cape pulley 160 by the user's external force, resistance can be provided to the user by the magnetic force of the magnetic portion 170.

In addition, the cable pulley 160 may include a through hole through which the screw shaft 200 passes so as to be positioned coaxially with the magnetic portion 170.

Meanwhile, the magnetic portion 170 may adjust the resistance by changing the contact area with the cable pulley 160 based on the operation of the resistance adjustment knob 140.

Specifically, the magnetic portion 170 may be inserted into the hollow of the cable pulley 160 or separated from the hollow of the cable pulley 160 depending on the rotation direction and degree of rotation of the resistance adjustment knob 140. Accordingly, the area where the magnetic portion 170 contacts the cable pulley 160 may be changed, and the strength of the magnetic force applied to the cable pulley 160 may vary depending on the contact area. Through this magnetic portion 170, the module 10 according to this embodiment can adjust the degree of resistance provided to the user.

For this purpose, the magnetic portion 170 is located between the cable pulley 160 and the resistance adjustment knob 140 and can move coaxially with the cable pulley 160 through the screw shaft 200, and the magnetic portion 171 and the bearing ( 173) may be included.

The magnet 171 is intended to generate magnetic force, and can be moved rearward and inserted into the cable pulley 160 or moved forward to be spaced apart from the cable pulley 160 according to the operation of the resistance adjustment knob 140.

In addition, in the module 10 according to this embodiment, it is shown that a single magnet 171 is provided to generate magnetic force, but it is not limited to this and a plurality of magnets 171 may be provided.

Additionally, the magnet 171 is provided in a tube shape so that the bearing 173 and the screw shaft 200 can be inserted therein. And the magnet 171 may be provided as, for example, an industrial neodymium magnet.

Meanwhile, the bearings 173 are provided to move the magnet 171 forward or backward, and may be provided in plural numbers as shown in FIG. 2.

The plurality of bearings 173 may be inserted into one side and the other side of the magnet 171, respectively, and may rotate in a single direction.

In addition, the plurality of bearings 173 may include a through hole through which the screw shaft 200 passes to move the magnet 171.

Meanwhile, the bush 180 is provided to move the magnetic portion 170, and may be located between the cable pulley 160 and the magnetic portion 170.

Additionally, the bush 180 may be provided to move coaxially with the cable pulley 160 through the screw shaft 200.

In addition, the bush 180 is made of a material that allows the magnetic field, that is, magnetic force, generated between the cable pulley 160 and the magnetic portion 170 to pass through the contact area of the cable pulley 160 and the magnetic portion 170. You can. For example, the bush 180 is an oil-free bush and may be provided as an acetal bush.

And the bush 180 may be provided in a tube shape so that the magnetic portion 170 including the magnet 171 and the bearing 173 can be inserted therein.

The outer diameter of the bush 180 may be set to a diameter corresponding to the inner diameter of the cable pulley 160, and the inner diameter of the bush 180 may be set to a diameter corresponding to the outer diameter of the magnet 171.

Meanwhile, the magnetic force blocking cover 190 may be provided to prevent the magnetic force generated according to the contact area between the cable pulley 160 and the magnetic portion 170 from being transmitted to the rotation spring 150.

This magnetic blocking cover 190 may be located between the rotation spring 150 and the cable pulley 160. Additionally, the magnetic force blocking cover 190 may include a through hole through which the screw shaft 200 passes.

The screw shaft 200 is connected to the resistance adjustment knob 140 and the rotation spring 150, and the magnetic part 170, the bush 180, and the magnetic force are used so that the magnetic part 170 moves coaxially with the cable pulley 160. It may penetrate the blocking cover 190.

Meanwhile, FIGS. 3 and 4 are diagrams for explaining how resistance is adjusted in the resistance adjustment module 10 of FIG. 2.

3 shows a state in which the entire magnetic portion 170 is completely inserted into the cable pulley 160 through manipulation of the resistance adjustment knob 140 so that the contact area between the magnetic portion 170 and the cable pulley 160 is maximized. . In the case of the module 10 shown in FIG. 3, the strength of the magnetic force can be maximized to provide the highest resistance when the cable 120 is pulled by the user.

Figure 4 shows a state in which the contact area is reduced by separating the magnetic portion 170 and the cable pulley 160 so that only a portion of the magnet 171 is inserted into the cable pulley 160 by manipulating the resistance adjustment knob 140. In the case of the module 10 shown in FIG. 4, the strength of the magnetic force is reduced from that provided in FIG. 3, so that when the cable 120 is pulled by the user, less resistance can be provided than when the contact area is at its maximum. there is.

FIG. 5 is a diagram illustrating the resistance adjustment module 10 of FIG. 1 coupled to an exercise device.

The exercise equipment (M) in which the module 10 of the present invention is installed may be provided with a fastening groove (H) into which an accessory module 10 such as the module 10 according to this embodiment can be coupled.

Therefore, the fastening protrusion 130 provided on the lower side of the module 10 can be coupled to the fastening groove H provided on the exercise device M.

More specifically, the fastening protrusion 130 may be provided in a shape corresponding to the fastening groove (H). Through this, while the fastening protrusion 130 is seated in the fastening groove (H), the module 10 is rotated clockwise or counterclockwise so that the fastening protrusion 130 is fastened to the fastening groove (H), thereby attaching the module 10 to the fastening groove (H). This can be fixed to the exercise equipment (M).

Meanwhile, FIG. 6 is a flowchart for explaining the resistance adjustment method in the resistance adjustment module 10 of FIG. 1.

The resistance adjustment method according to this embodiment includes the step of providing the resistance adjustment module 10 (S110), the step of adjusting the resistance (S130), and the step of providing the resistance (S150).

In the step of providing a resistance adjustment module (S110), a resistance adjustment module 10 may be provided to adjust the resistance of the exercise equipment.

The resistance adjustment module 10 prepared in the step of preparing the resistance adjustment module (S110) is the same as or can be sufficiently inferred from the resistance adjustment module 10 shown in FIGS. 1 to 5 described above, and detailed description is omitted. I decided to do it.

Meanwhile, the resistance adjustment step (S130) may be a step in which the resistance is adjusted as the contact area between the magnetic portion 170 and the cable pulley 160 changes when the resistance adjustment knob 140 rotates in a predetermined direction. .

In the resistance adjustment step (S130), when the resistance adjustment knob 140 rotates in the first direction (eg, clockwise), the direction in which part or all of the magnetic portion 170 is inserted into the cable pulley 160 The magnetic part 170 can move. Through this, the contact area between the magnetic portion 170 and the cable pulley 160 increases, so that resistance may increase as the magnetic force applied to the cable pulley 160 increases.

Additionally, in the resistance adjustment step (S130), when the resistance adjustment knob 140 rotates in the second direction (e.g., counterclockwise), part or all of the magnetic portion 170 is separated from the inside of the cable pulley 160. The magnetic portion 170 may move in the desired direction. Through this, the contact area between the magnetic portion 170 and the cable pulley 160 is reduced, thereby reducing the magnetic force applied to the cable pulley 160, thereby reducing resistance.

Meanwhile, the step S150 in which resistance is provided is a step in which resistance is provided when the cable 120 is unwound from the cable pulley 160.

Specifically, in the step S150 where resistance is provided, when the cable 120 is unwound from the cable pulley 160, the contact area between the magnetic portion 170 and the cable pulley 160 adjusted in the step S130 where the resistance is adjusted. Accordingly, resistance may be provided to the user equal to the strength of the magnetic force applied to the cable pulley 160.

Although various embodiments of the present invention have been shown and described above, the present invention is not limited to the specific embodiments described above, and may be used in the technical field to which the invention pertains without departing from the gist of the invention as claimed in the claims. Of course, various modifications can be made by those skilled in the art, and these modifications should not be understood individually from the technical idea or perspective of the present invention.

10: Resistance adjustment module 110: Housing
111: groove 120: cable
130: coupling protrusion 140: resistance adjustment knob
150: rotation spring 160: cable pulley
170: magnetic part 171: magnetic
173: Bearing 180: Bush
190: Magnetic blocking cover 200: Screw shaft
M: Exercise equipment H: Fastening groove

Claims (8)

A resistance control module for controlling the resistance of exercise equipment,
A housing with a groove on the upper side;
a cable flowing out through the groove; and
It includes a fastening protrusion provided on the lower side of the housing and coupled to the exercise mechanism,
a resistance adjustment knob provided on one side of the housing and operated to adjust resistance;
a rotation spring located inside the other side of the housing and rotating according to the moving direction of the cable;
a cable pulley located between the rotation spring and the resistance adjustment knob inside the housing and around which the cable is wound; and
It is located between the cable pulley and the resistance adjustment knob inside the housing, moves coaxially with the cable pulley according to the operation of the resistance adjustment knob, and magnetic force applied to the cable pulley according to the contact area with the cable pulley. It further includes a magnetic portion that adjusts the resistance provided to the user by changing the intensity of
The resistance adjustment knob, rotation spring, cable pulley and magnetic portion are located on the same axis,
The magnetic part,
Resistance adjustment module including a magnet that is inserted into the cable pulley on the coaxial axis or moves forward toward the resistance adjustment knob to be spaced apart from the cable pulley according to the operation of the resistance adjustment knob. delete According to paragraph 1,
Resistance adjustment module further comprising a bush that moves coaxially with the cable pulley and is located between the cable pulley and the magnetic portion. According to paragraph 1,
The magnetic part,
A resistance control module further comprising bearings that are respectively inserted into one side and the other side of the magnet and rotate in a single direction. According to paragraph 1,
A magnetic force blocking cover provided between the rotation spring and the cable pulley; and
Resistance adjustment module further comprising a screw shaft connected to the resistance adjustment knob and penetrating the magnetic portion so that the magnetic portion moves coaxially with the cable pulley. A resistance control module for adjusting the resistance of an exercise device, comprising a housing provided with a groove on the upper side, a cable flowing to the outside through the groove, a fastening protrusion provided on the lower side of the housing and coupled to the exercise device, and one side of the housing. A resistance adjustment knob is provided and operated to adjust the resistance, a rotation spring located inside the other side of the housing and rotating according to the moving direction of the cable, located between the rotation spring and the resistance adjustment knob inside the housing and the cable is wound. providing a resistance adjustment module including a cable pulley and a magnetic portion located between the cable pulley and the resistance adjustment knob inside the housing and moving coaxially with the cable pulley according to manipulation of the resistance adjustment knob;
adjusting the resistance as the contact area between the magnetic part and the cable pulley changes when the resistance adjustment knob rotates in a predetermined direction; and
providing resistance when the cable is released from the cable pulley,
The magnetic part,
Adjusting the resistance provided to the user by changing the strength of the magnetic force applied to the cable pulley according to the contact area with the cable pulley,
The resistance adjustment knob, rotation spring, cable pulley and magnetic portion are located on the same axis,
The magnetic part,
A resistance adjustment method comprising a magnet that is inserted into the cable pulley on the coaxial axis or moves forward toward the resistance adjustment knob to be spaced apart from the cable pulley according to the operation of the resistance adjustment knob. According to clause 6,
In the stage where the resistance is adjusted,
When the resistance adjustment knob rotates in the first direction, the magnetic portion moves so that part or all of the magnetic portion is inserted into the cable pulley, and the contact area increases, thereby increasing the magnetic force applied to the cable pulley. A resistance control method characterized by increasing resistance. According to clause 6,
In the stage where the resistance is adjusted,
When the resistance adjustment knob rotates in the second direction, the magnetic portion moves so that part or all of the magnetic portion is separated from the inside of the cable pulley, and the contact area decreases, thereby reducing the magnetic force applied to the cable pulley. A resistance control method characterized by reducing resistance.