阅读说明：本技术 一种单双向飞轮及其调节系统 (Unidirectional and bidirectional flywheel and adjusting system thereof ) 是由 刘志 毛世昌 付鹏举 吴维彬 丁先锋 于 2020-11-20 设计创作，主要内容包括：本发明提供一种单双向飞轮及其调节系统,属于健身器材领域,单双向飞轮包括飞轮本体、中轴以及联轴器,飞轮本体的轴心处嵌设有单向轴承,中轴穿过所述单向轴承设置,联轴器可移动套设在所述中轴上,以实现与所述飞轮本体的啮合、分离。单双向飞轮调节系统包括：单双向飞轮和拨档组件,拨档组件包括弹簧拨叉、调节手柄和拨档拉线,弹簧拨叉设置在所述联轴器上,调节手柄可转动设置；拨档拉线用于将所述弹簧拨叉和调节手柄连接,以通过调节手柄控制所述弹簧拨叉的放松收紧,进而带动联轴器沿中轴移动。本发明通过调节系统可以实现单双向飞轮单向模式和双向模式的切换,即可以通过一台健身车实现两种运动方式,使用方便且能降低成本。(The invention provides a unidirectional and bidirectional flywheel and an adjusting system thereof, belonging to the field of fitness equipment. The unidirectional and bidirectional flywheel regulating system comprises: the shifting assembly comprises a spring shifting fork, an adjusting handle and a shifting stay wire, the spring shifting fork is arranged on the coupler, and the adjusting handle can be arranged in a rotating mode; the shifting stay wire is used for connecting the spring shifting fork with the adjusting handle, so that the spring shifting fork is controlled to be loosened and tightened through the adjusting handle, and the coupler is driven to move along the middle shaft. The invention can realize the switching between the unidirectional mode and the bidirectional mode of the unidirectional and bidirectional flywheels through the adjusting system, namely, two movement modes can be realized through one exercise bicycle, the use is convenient, and the cost can be reduced.)

1. A uni-directional and bi-directional flywheel, comprising:

the flywheel comprises a flywheel body, wherein a one-way bearing is embedded in the axis of the flywheel body;

the middle shaft penetrates through the one-way bearing;

and the coupling is movably sleeved on the middle shaft so as to realize engagement and separation with the flywheel body.

2. The unidirectional and bidirectional flywheel of claim 1, wherein a plurality of protrusions are annularly distributed on the end surface of the coupler, a plurality of grooves are formed in the end surface of the flywheel body opposite to the coupler at the axis, and the grooves correspond to the protrusions one to realize the engagement of the coupler and the flywheel body.

3. The uni-directional flywheel of claim 1 further comprising:

and the supporting mechanism is formed by a left supporting plate and a right supporting plate and is used for supporting the middle shaft.

4. A uni-directional flywheel according to claim 3 further comprising:

and the electromagnet is fixed between the left support plate and the right support plate through a support rod and is positioned on the outer side of the flywheel body.

5. A unidirectional and bidirectional flywheel modulation system comprising: a gear shifting assembly and the unidirectional/bidirectional flywheel of any of claims 1-4, the gear shifting assembly comprising:

the spring shifting fork is arranged on the coupler and used for shifting the coupler to move;

the adjusting handle is rotatably arranged and is used for being operated by a user;

and the shifting stay wire is used for connecting the spring shifting fork with the adjusting handle so as to control the loosening and tightening of the spring shifting fork through the adjusting handle and further drive the coupler to move along the middle shaft.

6. The unidirectional and bidirectional flywheel adjusting system of claim 5, wherein an annular clamping groove is formed in the outer wall of the coupler, and the spring shifting fork is clamped in the annular clamping groove through a U-shaped groove formed in the end portion of the spring shifting fork;

the material of spring shift fork is the spring steel, when the spring shift fork is in the relaxed state, the spring shift fork pushes down the shaft coupling makes it mesh with the flywheel body, when the spring shift fork is in the tightened-up state, the spring shift fork stirred the shaft coupling and makes it and flywheel body separation.

7. The unidirectional and bidirectional flywheel modulation system of claim 5, further comprising a brake assembly, the brake assembly comprising:

the brake pad is rotatably arranged on the outer side of the flywheel body;

and the reset torsion spring is arranged on the rotating shaft of the brake pad to drive the brake pad to return.

8. The unidirectional/bidirectional flywheel adjustment system of claim 7, wherein the shift cable is a U-shaped structure, and a U-shaped bent portion of the shift cable is fixed to the brake pad so as to rotate the brake pad via the adjustment handle.

9. The unidirectional/bidirectional flywheel adjustment system of claim 7, wherein a brake cable is connected to the brake pad, and a brake handle is connected to an end of the brake cable, which is far away from the brake pad, so that the brake pad is rotated by the brake handle.

10. The unidirectional/bidirectional flywheel regulating system of claim 7, wherein the shift cable is composed of a cable A and a cable B, one end of the cable A is connected with the regulating handle, the other end of the cable A is fixed on the steering wheel, one end of the cable B is connected with the spring shifting fork, and the other end of the cable B is fixed on the steering wheel;

the brake cable is connected to the brake pad, and the end, far away from the brake pad, of the brake cable is fixed to the steering wheel.

Technical Field

The invention belongs to the field of fitness equipment, particularly relates to a unidirectional and bidirectional flywheel, and further relates to a unidirectional and bidirectional flywheel adjusting system.

Background

The existing exercise bicycle can be divided into a vertical exercise bicycle, a horizontal exercise bicycle and a spinning bicycle according to different exercise modes. The vertical exercise bicycle and the horizontal exercise bicycle adopt unidirectional flywheels, namely, the flywheels can only rotate in one direction, and when the feet stop driving, the flywheels can still continue to rotate by inertia; the spinning uses the two-way flywheel, and the flywheel can positive and negative two directions rotation, and when the foot stops driving, the flywheel can drive the foot to continue to move because of inertial rotation.

The unidirectional flywheel exercise bicycle (vertical exercise bicycle or horizontal exercise bicycle) can not drive the shaft and the pedal to continue moving when the feet stop driving because the inertia of the flywheel can not be transferred to the shaft, so that the bicycle can not be jumped on the unidirectional flywheel exercise bicycle or a lot of exercise actions can not be performed; when the bidirectional flywheel exercise bicycle (spinning) needs to stop rotating immediately, the shaft and the feet can be continuously driven to move due to inertia, and the risk of human body injury is caused.

In addition, when the two exercise modes are to be achieved, the user needs two exercise devices, which is not only inconvenient but also increases the exercise cost.

Disclosure of Invention

Based on the background problems, the invention aims to provide a unidirectional and bidirectional flywheel, which can realize the switching between a unidirectional flywheel mode and a bidirectional flywheel mode, further realize two movement modes through one exercise bicycle, is convenient to use and can reduce the cost; it is a further object of the present invention to provide a regulating system comprising the unidirectional and bidirectional flywheel described above.

In order to achieve the above object, in one aspect, the embodiment of the present invention provides a technical solution:

a uni-directional and bi-directional flywheel comprising:

the flywheel comprises a flywheel body, wherein a one-way bearing is embedded in the axis of the flywheel body;

the middle shaft penetrates through the one-way bearing;

and the coupling is movably sleeved on the middle shaft so as to realize engagement and separation with the flywheel body.

In one embodiment, a plurality of protrusions are annularly distributed on the end face of the coupler, a plurality of grooves are formed in the end face of the flywheel body, opposite to the coupler, at the axis of the flywheel body, and the grooves correspond to the protrusions one to one, so that the coupler is meshed with the flywheel body.

In one embodiment, the uni-directional flywheel further comprises:

and the supporting mechanism is formed by a left supporting plate and a right supporting plate and is used for supporting the middle shaft.

Preferably, the uni-directional flywheel further comprises:

and the electromagnet is fixed between the left support plate and the right support plate through a support rod and is positioned on the outer side of the flywheel body.

On the other hand, an embodiment of the present invention further provides a unidirectional/bidirectional flywheel adjustment system, including: the single-direction and bidirectional flywheel comprises a gear shifting assembly and the single-direction and bidirectional flywheel, wherein the gear shifting assembly comprises:

the spring shifting fork is arranged on the coupler and used for shifting the coupler to move;

the adjusting handle is rotatably arranged and is used for being operated by a user;

and the shifting stay wire is used for connecting the spring shifting fork with the adjusting handle so as to control the loosening and tightening of the spring shifting fork through the adjusting handle and further drive the coupler to move along the middle shaft.

In one embodiment, the outer wall of the coupler is provided with an annular clamping groove, and the spring shifting fork is clamped in the annular clamping groove through a U-shaped groove arranged at the end part;

the material of spring shift fork is the spring steel, when the spring shift fork is in the relaxed state, the spring shift fork pushes down the shaft coupling makes it mesh with the flywheel body, when the spring shift fork is in the tightened-up state, the spring shift fork stirred the shaft coupling and makes it and flywheel body separation.

In one embodiment, the unidirectional and bidirectional flywheel adjustment system further comprises a brake assembly, the brake assembly comprising:

the brake pad is rotatably arranged on the outer side of the flywheel body;

and the reset torsion spring is arranged on the rotating shaft of the brake pad to drive the brake pad to return.

In one embodiment, the shift pulling wire is of a U-shaped structure, and a U-shaped bending part of the shift pulling wire is fixed with the brake pad so as to drive the brake pad to rotate through the adjusting handle.

In one embodiment, the brake pad is connected with a brake cable, and the end part of the brake cable far away from the brake pad is connected with a brake handle so as to drive the brake pad to rotate through the brake handle.

In one embodiment, the gear shifting pull wire consists of a pull wire A and a pull wire B, one end of the pull wire A is connected with the adjusting handle, the other end of the pull wire A is fixed on the steering wheel, one end of the pull wire B is connected with the spring shifting fork, and the other end of the pull wire B is fixed on the steering wheel; the brake cable is connected to the brake pad, and the end, far away from the brake pad, of the brake cable is fixed to the steering wheel.

Compared with the prior art, the invention has the following effects:

1. the invention provides a unidirectional and bidirectional flywheel, which can be engaged with and separated from a flywheel body by moving a coupler, wherein when the coupler is engaged with the flywheel body, the bidirectional flywheel mode is adopted, and when the coupler is separated from the flywheel body, the unidirectional flywheel mode is adopted; the unidirectional and bidirectional flywheel can realize the switching between the unidirectional flywheel and the bidirectional flywheel, so that two movement modes can be realized through one exercise bicycle, the use is convenient, and the cost can be reduced.

2. The invention provides a unidirectional and bidirectional flywheel adjusting system, which can realize the movement of a coupler through a gear shifting assembly, wherein the gear shifting assembly comprises a spring shifting fork, a gear shifting stay wire and an adjusting handle, the adjusting handle is operated to drive the gear shifting stay wire to pay off and take up, and further the spring shifting fork is loosened and tightened, so that the coupler is driven to move, the engagement and separation of the coupler and a flywheel body are realized, only the adjusting handle needs to be pressed or pulled up during operation, and the adjustment is convenient.

3. The invention also comprises a brake component, the brake component comprises a brake pad and a reset torsion spring, the brake pad and the shift pulling wire are fixed, the switching of the unidirectional and bidirectional modes and the braking of the flywheel body can be realized by using an adjusting handle and a group of shift pulling wires, the use is convenient, and the cost can be reduced.

4. The shifting pull wire is of a U-shaped structure, the U-shaped bent part of the shifting pull wire is fixed with the brake pad, when the adjusting handle is pressed, the shifting pull wire is pulled, the shifting pull wire drives the brake pad to rotate clockwise, the spring shifting fork is loosened, the coupler moves rightwards to be meshed with the flywheel body, a middle shaft and the flywheel body are connected into a whole, and at the moment, a bidirectional flywheel mode is adopted; the adjusting handle is continuously pressed, and the brake pad can continuously rotate clockwise to rub the outer edge of the flywheel body, so that the braking effect is achieved; after the adjusting handle is pulled up, the brake pad loses acting force and can rebound under the action of the reset torsion spring, the brake pad rotates anticlockwise, the spring shifting fork is pulled to tighten up, the coupler is shifted leftwards, the coupler is separated from the flywheel body, and the unidirectional flywheel mode is realized at the moment.

Drawings

In order to more clearly illustrate the technical solutions in the embodiments of the present invention, the drawings used in the description of the embodiments will be briefly introduced below.

Fig. 1 is a schematic structural view of a unidirectional/bidirectional flywheel in embodiment 1 of the present invention (a coupling is engaged with a flywheel body);

FIG. 2 is an exploded view of a unidirectional/bidirectional flywheel according to embodiment 1 of the present invention;

FIG. 3 is a front view of a unidirectional/bidirectional flywheel according to embodiment 1 of the present invention;

fig. 4 is a schematic structural view of a coupler and a middle shaft in embodiment 1 of the present invention;

fig. 5 is a schematic connection diagram of the coupling and the middle shaft in embodiment 1 of the present invention;

FIG. 6 is a schematic structural diagram of a unidirectional/bidirectional flywheel modulation system according to embodiment 2 of the present invention;

FIG. 7 is an exploded view of a unidirectional/bidirectional flywheel modulation system according to embodiment 2 of the present invention;

FIG. 8 is another exploded view of a unidirectional/bidirectional flywheel modulating system in accordance with embodiment 2 of the present invention;

fig. 9 is a schematic structural view of a unidirectional/bidirectional flywheel in embodiment 2 of the present invention (with the coupling separated from the flywheel body);

fig. 10 is a schematic structural diagram of a unidirectional/bidirectional flywheel regulating system in embodiment 4 of the present invention.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present invention clearer, the technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are some, but not all, embodiments of the present invention. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

In the description of the present invention, it should be noted that the terms "center", "top", "bottom", "left", "right", "vertical", "horizontal", "inner", "outer", "front", "rear", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings of the specification, and are only for convenience in describing the present invention and simplifying the description, but do not indicate or imply that the referred device or element must have a specific orientation, be constructed in a specific orientation, and be operated, and thus, should not be construed as limiting the present invention.

Example 1

A unidirectional and bidirectional flywheel is shown in figures 1-3 and comprises a flywheel body 1, a middle shaft 2, a coupling 3 and a supporting mechanism.

In the present embodiment, as shown in fig. 2, rolling bearings 101 are disposed on both left and right sides of the flywheel body 1, and in the present embodiment, the rolling bearings 101 are deep groove ball bearings, but are not limited thereto; the axle center of the flywheel body 1 is embedded with a one-way bearing 102, and the one-way bearing 102 in this embodiment is a one-way needle bearing, but is not limited thereto.

The middle shaft 2 penetrates through the axis of the flywheel body 1 and penetrates through the rolling bearing 101 and the one-way bearing 102, and two ends of the middle shaft 2 are supported by the supporting mechanism.

In the embodiment, the supporting mechanism is composed of a left supporting plate 4-1 and a right supporting plate 4-2, the left supporting plate 4-1 and the right supporting plate 4-2 are further fixed through at least two connecting rods 4-3, and the left supporting plate 4-1 and the right supporting plate 4-2 are respectively arranged on the left side and the right side of the flywheel body 1.

Specifically, as shown in fig. 2, the present embodiment further includes a first bearing seat 103 and a second bearing seat 104, the first bearing seat 103 is sleeved on the left rolling bearing 101, the second bearing seat 104 is sleeved on the right rolling bearing 101, and for supporting the rolling bearing 101, through holes for the rolling bearing 101 to pass through are formed in both the left support plate 4-1 and the right support plate 4-2.

In this embodiment, the coupler 3 is sleeved on the center shaft 2 and can move left and right along the center shaft 2, when the coupler 3 moves right until the right end surface of the coupler 3 is connected with the left end surface of the axle center of the flywheel body 1, the coupler 3 is meshed with the flywheel body 1, and at this time, the flywheel body 1 and the center shaft 2 are connected into a whole, can synchronously rotate and are in a bidirectional wheel mode; when the coupler 3 moves leftwards to be disengaged from the left end face of the axle center of the flywheel body 1, the coupler 3 is separated from the flywheel body 1, at the moment, the flywheel body 1 and the middle axle 2 can be separated in an overrunning manner, and only under the action of the one-way bearing 102, the flywheel body 1 and the middle axle 2 synchronously rotate in a one-way mode.

Specifically, as shown in fig. 4, the left side of the center shaft 2 is a stepped shaft, specifically a square stepped shaft, for transmitting power, the coupler 3 is provided with a square hole 3-1, the coupler 3 is sleeved on the square stepped shaft on the left side of the center shaft 2 through the square hole 3-1, when the coupler 3 is engaged with the flywheel body 1, since the coupler 3 is sleeved on the square stepped shaft of the center shaft 2 through the square hole 3-1, the middle shaft 2 can drive the flywheel body 1 to rotate synchronously through the coupler 3 when rotating.

In order to facilitate the engagement of the coupler 3 and the flywheel body 1, as shown in fig. 2 and 5, a plurality of protrusions 3-2 are annularly distributed on the right end face of the coupler 3, a plurality of grooves 1-1 are formed in the left end face of the axle center of the flywheel body 1, the grooves 1-1 correspond to the protrusions 3-2 one by one, and when the coupler 3 is engaged with the flywheel body 1, the protrusions 3-2 are embedded into the grooves 1-1. The engagement manner of the coupling 3 and the flywheel body 1 is not limited to the above-described configuration.

In this embodiment, as shown in fig. 1 to 3, the unidirectional/bidirectional flywheel further includes an electromagnet 5, the electromagnet 5 can provide an electromagnetic field, the flywheel body 1 generates an induced current when operating, and the induced current prevents a relative movement in the magnetic field, i.e., provides resistance to the operation of the flywheel body 1, so as to achieve the purpose of leg exercise, and the magnetic field strength can be changed according to the magnitude of the current when in specific use. As shown in fig. 2, the electromagnet 5 is fixed between the left support plate 4-1 and the right support plate 4-2 by a plurality of support rods 501, and the electromagnet 5 is located outside the flywheel body 1.

In the embodiment, as shown in fig. 2 and 3, a belt pulley 6 is further connected to the right end of the central shaft 2, the belt pulley 6 is disposed on the right side of the right support plate 4-2, and the belt pulley 6 is a part of a transmission mechanism and can transmit force to the central shaft 2.

Example 2

A unidirectional and bidirectional flywheel adjusting system comprises a gear shifting assembly, a brake assembly and the unidirectional and bidirectional flywheel in embodiment 1.

As shown in fig. 6-8, the shifting assembly includes: a spring shifting fork 7, an adjusting handle 8 and a shifting pull wire 9.

In the present embodiment, as shown in fig. 7 and 8, the spring fork 7 is disposed on the coupling 3 for shifting the coupling 3. As shown in fig. 4, an annular clamping groove 3-3 is formed in the outer wall of the coupler 3, a U-shaped groove 7-1 is concavely formed in the top end of the spring shifting fork 7, the radian of the U-shaped groove 7-1 is matched with the radian of the annular clamping groove 3-3, so that the spring shifting fork 7 can be clamped in the annular clamping groove 3-3 through the U-shaped groove 7-1, and as shown in fig. 3, the bottom of the spring shifting fork 7 is fixed to the left support plate 4-1 through a bolt.

It should be noted that the connection mode of the spring fork 7 and the coupler 3 is not limited to this, and in other embodiments, a connector may be directly disposed at an end of the spring fork 7, and the spring fork 7 is sleeved on the annular slot 3-3 of the coupler 3 through the connector.

As shown in fig. 7, the adjusting handle 8 is rotatably disposed for being operated by a user, and the shift cable 9 is used for connecting the spring fork 7 and the adjusting handle 8, so as to control the releasing and tightening of the spring fork 7 through the adjusting handle 8, and further drive the shaft coupling 3 to move along the central shaft 2.

Specifically, the material of spring shift fork 7 is the spring steel, and spring shift fork 7 is the spring steel sheet promptly, and during initial condition, when spring shift fork 7 was in the state of relaxing, spring shift fork 7 pushed down shaft coupling 3 makes it mesh with flywheel body 1, works as when adjustment handle 8 was through dialling shelves 9 pulling spring shift fork 7, when spring shift fork 7 was in the state of tightening up, spring shift fork 7 stirred shaft coupling 3 and made it and flywheel body 1 separation.

As shown in fig. 7, the brake assembly includes: a brake pad 10 and a return torsion spring 11.

In this embodiment, the brake pad 10 has an arc-shaped structure, the brake pad 10 is rotatably disposed on the left side of the flywheel body 1, and in order to realize the rotatable disposition of the brake pad 10, specifically, as shown in fig. 8, in this embodiment, a rotating shaft 10-1 is rotatably disposed between the left support plate 4-1 and the right support plate 4-2, and the bottom end of the brake pad 10 is fixed to the rotating shaft 10-1. The rotatable structure of the brake pad 10 is not limited to this, and in other embodiments, the rotating shaft 10-1 may be fixed and fixed, and a sleeve may be disposed at the bottom end of the brake pad 10, and the brake pad may be rotatably connected to the rotating shaft 10-1 through the sleeve.

As shown in fig. 7, the reset torsion spring 11 is disposed on the rotating shaft 10-1, and one end of the reset torsion spring is fixed to the brake pad 10, so that the reset torsion spring 11 is squeezed when the brake pad 10 rotates clockwise, and the reset torsion spring 11 drives the brake pad 10 to return to the initial position when the brake pad 1 loses acting force.

In order to realize the structure simplification, the embodiment simultaneously realizes the switching of the unidirectional and bidirectional modes and the braking of the flywheel body 1 through the adjusting handle 8 and the gear shifting pull wire 9. Specifically, as shown in fig. 6 to 8, the shift cable 9 is a U-shaped structure, the right end of the shift cable 9 is connected to the adjustment handle 8, the U-shaped bent portion of the shift cable 9 is connected to the brake pad 10, and the left end of the shift cable 9 passes through the left support plate 4-1 and is connected to the spring fork 7.

In order to facilitate the connection between the shift cable 9 and the brake pad 10, as shown in fig. 6-8, in this embodiment, a fixing seat 10-2 is disposed at the top of the brake pad 10, the fixing seat 10-2 is an L-shaped structure, and at this time, the U-shaped bending portion of the shift cable 9 is fixed to the fixing seat 10-2. In this embodiment, the brake pad 10 is a cow leather brake pad, which can be directly adhered to the fixing base 10-2, but the brake pad 10 is not limited thereto.

In order to protect the shift cable 9, as shown in fig. 6, in this embodiment, a protective casing 901 is further sleeved on the shift cable 9, a casing support 902 is disposed on the left supporting plate 4-1, and a left end of the protective casing 901 is fixed to the casing support 902.

The working principle of the embodiment is as follows:

when the adjusting handle 8 is pressed, the tail end (the end connected with the adjusting handle 8) of the gear shifting pull wire 9 is pulled, the gear shifting pull wire 9 drives the brake pad 10 to rotate clockwise through the fixed seat 10-2, the front end (the end connected with the spring shifting fork 7) of the gear shifting pull wire 9 is paid off, so that the spring shifting fork 7 is loosened, the coupler 3 moves rightwards to be meshed with the flywheel body 1, the middle shaft 2 is further connected with the flywheel body 1 into a whole, and the bidirectional flywheel mode is adopted at the moment.

And the adjusting handle 8 is continuously pressed, and the fixed seat 10-2 continuously drives the brake pad 10 to rotate clockwise to rub the outer edge of the flywheel body 1, so that the braking effect is achieved.

After the adjusting handle 8 is pulled up, the brake pad 10 loses acting force and rebounds under the action of the reset torsion spring 11, namely, the brake pad 10 rotates anticlockwise, the front end of the shifting pull wire 9 is wound up, the spring shifting fork 7 is pulled to tighten, and the coupler 3 is shifted leftwards, so that the coupler 3 is separated from the flywheel body 1, as shown in fig. 9, the mode is a one-way flywheel mode.

Example 3

The present embodiment provides a unidirectional and bidirectional flywheel adjustment system, which is different from embodiment 2 in that the adjustment of the gear shifting assembly and the brake assembly are separately arranged.

Specifically, the fixed seat 10-2 is directly connected with a brake cable, the end part of the brake cable far away from the brake pad 10 is connected with a brake handle, the brake pad 10 is driven to rotate through the brake handle, the gear shifting stay wire 9 can be set to be a straight line at the moment, the tail end of the gear shifting stay wire 9 is connected with the adjusting handle 8, the front end of the gear shifting stay wire is connected with the spring shifting fork 7, and the unidirectional and bidirectional mode of the flywheel is adjusted through the adjusting handle 8.

Example 4

Unlike the embodiment 2 in which the adjustment of the shift lever assembly and the brake assembly is controlled by the adjusting handle 8, the embodiment provides a single-direction and two-direction flywheel adjusting system, in which a steering wheel 12 is disposed on the left support plate 4-1, as shown in fig. 10.

The gear shifting pull wire 9 consists of a pull wire A9-1 and a pull wire B9-2, the right end of the pull wire A9-1 is connected with the adjusting handle 8, the left end of the pull wire A9-1 is fixed on the steering wheel 12, the right end of the pull wire B9-2 is connected with the spring shifting fork 7, and the left end of the pull wire B9-2 is fixed on the steering wheel 12; the fixed seat 10-2 of the brake pad 10 is connected with a brake cable 13, and the right end of the brake cable 13 is fixed on the steering wheel 12.

Specifically, the fixed points of the pull wire A9-1 and the pull wire B9-2 on the steering wheel 12 are adjacent and are positioned at the top of the right half part of the steering wheel 12, so that when the adjusting handle 8 is pressed, the pull wire A9-1 drives the steering wheel 12 to rotate clockwise, at the moment, the right end of the pull wire B9-2 is paid off, the spring shifting fork 7 is loosened, the coupler 3 moves rightwards to be meshed with the flywheel body 1, the middle shaft 2 and the flywheel body 1 are connected into a whole, and the bidirectional flywheel mode is adopted.

When the pull wire A9-1 drives the steering wheel 12 to rotate clockwise, the brake cable 13 drives the brake pad 10 to rotate clockwise until the brake pad rubs with the outer edge of the flywheel body 1, so that the brake function is achieved.

When the adjusting handle 8 is lifted, the pull wire A9-1 can drive the steering wheel 12 to rotate anticlockwise, the right end of the pull wire B9-2 takes up the wire, the spring shifting fork 7 is tightened, and the coupler 3 is shifted leftwards to separate the coupler 3 from the flywheel body 1, and at the moment, the unidirectional flywheel mode is adopted. When the brake is released, the brake pad 10 returns to the initial position under the action of the reset torsion spring 11.

It should be noted that, for those skilled in the art, various changes and modifications can be made without departing from the inventive concept of the present invention, and these changes and modifications belong to the protection scope of the present invention.