CN105920783A - Screen-self-adapting running machine and realizing method thereof - Google Patents

Abstract

The invention relates to the technical field of running machines, and provides a screen-self-adapting running machine and a realizing method of the screen-self-adapting running machine. According to the screen-self-adapting running machine, a large-screen intelligent display is fixed on a display bracket, and a bracket servo system is arranged in a body of the running machine; the display bracket is positioned on the two sides of the body of the running machine in a symmetric manner, a base of the display bracket is arranged inside the body of the running machine, and allows the bracket servo system to move forwards and backwards; each side of the display bracket is composed of at least one main bearing rod, an auxiliary bearing rod, a first hydraulic lifting pillar and a second hydraulic lifting pillar, the first hydraulic lifting pillar and the second hydraulic lifting pillar are connected with the bracket servo system and are controlled by the bracket servo system. According to the embodiment of the invention, the bracket servo system controls the display bracket and the base of the display bracket, so that the self-adaptive change of the height and angle of the display screen is realized, therefore, the screen-self-adapting running machine is suitable for use by people with different body heights and in different age groups, and also can provide different running experience, thus the functions of the running machine are enriched, and finally, the user experience is promoted.

Description

Screen-adaptive treadmill and implementation method thereof

[ technical field ] A method for producing a semiconductor device

The invention relates to the technical field of running machines, in particular to a screen self-adaptive running machine and an implementation method thereof.

[ background of the invention ]

Traditionally, athletes using treadmills are moving in a monotonous environment (e.g., gym and bedroom), and there are few places that provide a situational exercise environment. Also, in the prior art, in which the treadmill is a horizontal transmission belt driving the axles of the treadmill, as shown in the schematic diagram of the prior art treadmill shown in fig. 1, the athlete 10 may hold the handrail 11 of the treadmill to run on a transmission belt 13 and set the treadmill speed switch on a panel 100, and the front axle 15a and the rear axle 15b actively drive the transmission belt 13 to enable the athlete 10 to run thereon; the athlete 10 may also move forward in a running or walking motion. Due to the friction between the shoes and the transmission belt 13, the transmission belt 13 drives the front axle 15a and the rear axle 15b which can rotate freely, thereby achieving the effect of the treadmill in the prior art.

In another prior art, although the patent CN02143304.6 relates to a virtual reality screen, the screen is implemented in a fixed manner, and cannot provide a suitable screen display manner for people with different heights, ages, and motion states.

In view of the above, overcoming the drawbacks of the prior art is an urgent problem in the art.

[ summary of the invention ]

The invention aims to provide a screen self-adaptive treadmill and an implementation method thereof.

The invention adopts the following technical scheme:

in a first aspect, an embodiment of the present invention provides a screen adaptive treadmill, including a treadmill track, a transmission system thereof, and a treadmill body, where the treadmill track covers an area on the treadmill body for providing a user with exercise; track drive system is located inside the treadmill organism, screen self-adaptation's treadmill still includes big screen intelligent display, display support and support servo, and is specific:

the large-screen intelligent display is fixed on the display support, and the support servo system is arranged in the treadmill body; the display support is symmetrically arranged on two sides of the treadmill body, and a base of the display support is arranged in the treadmill body and can receive a support servo system to finish the back-and-forth movement;

the display bracket on each side is composed of at least one main bearing rod, one auxiliary bearing rod, a first hydraulic lifting column and a second hydraulic lifting column, and the first hydraulic lifting column and the second hydraulic lifting column are connected with the bracket servo system for control; one end of the main bearing rod is connected to a base of the display support, the other end of the main bearing rod is connected with a first hydraulic lifting column, and the other end of the first hydraulic lifting column is connected with a display screen; the auxiliary bearing rod is connected with the display screen and the main bearing rod and forms a deformable quadrilateral structure with the large-screen intelligent display, the first hydraulic lifting column and the main bearing rod; one end of the second hydraulic lifting column is fixed on the base of the display support, the other end of the second hydraulic lifting column is connected with the main bearing rod, and the second hydraulic lifting column, the base of the large-screen intelligent display support and the main bearing rod form a deformable triangular structure.

Preferably, one end of the second hydraulic lifting column is fixed on the base of the display support, and the implementation is as follows:

one end of the second hydraulic lifting column is provided with a positioning hole, a base of the display support is provided with a hollow column with a positioning hole, and the second hydraulic lifting column is fixed on the hollow column through a positioning pin.

Preferably, the other end is connected with the main bearing rod, and the method can be specifically realized as follows:

the other end of the second hydraulic lifting column is connected with a supporting arm through a rotating shaft structure, and the supporting arm is used for supporting one side of the main bearing rod; or,

the other end of the second hydraulic lifting column is connected with a pipe barrel through a rotating shaft structure, the pipe barrel is sleeved on the main bearing rod, and a bearing is arranged on the inner side of the pipe barrel.

Preferably, the one end of main carrier bar is connected on the base of display support, and first hydraulic lifting post is connected to the other end, the display screen is connected to the first hydraulic lifting post other end, specifically realizes to be:

the connection structure of the first hydraulic lifting column and the main bearing rod is a rotating shaft structure; the other end of the first hydraulic lifting column is also connected with a display screen through a rotating shaft structure. A

In a second aspect, an embodiment of the present invention provides a screen adaptive treadmill, including a treadmill track, a transmission system thereof, and a treadmill body, wherein the treadmill track covers an area of the treadmill body for providing a user with exercise; track drive system is located inside the treadmill organism, screen self-adaptation's treadmill still includes big screen intelligent display, display support and support servo, and is specific:

the large-screen intelligent display is fixed on the display support, and the support servo system is arranged in the treadmill body; the display support is symmetrically arranged on two sides of the treadmill body, and a base of the display support is arranged in the treadmill body and can receive a support servo system to finish the back-and-forth movement;

the intelligent display comprises a display base, a display support and a plurality of intelligent displays, wherein the display support on each side is composed of at least one main bearing rod and a hydraulic lifting column, one end of the main bearing rod is used for fixing the intelligent display, and the other end of the main bearing rod is connected to the display base after being connected with the hydraulic lifting column in series; the hydraulic lifting column is connected with a support servo system and is controlled by the support servo system to complete the stretching and retracting actions.

In a third aspect, an embodiment of the present invention provides an implementation method of a screen adaptive treadmill, where the screen adaptive treadmill structure according to the first aspect is used, and the implementation method includes:

the large-screen intelligent display receives parameter information input by a user, wherein the parameter information comprises height information of sports personnel, running speed simulated by a running machine, climbing angle simulated by the running machine and one or more of virtual scene types displayed by the display screen;

the large-screen intelligent display adjusts the running speed of the treadmill, the angle of the treadmill and the position of the large-screen intelligent display according to the parameter information input by the user; wherein, the specific position of adjustment large-size screen intelligent display includes:

determining the proper height of the large-screen intelligent display according to the height information of the user, and inputting a control instruction to the support servo system so that the support servo system controls the second hydraulic lifting column to complete the height adjustment of the large-screen intelligent display; and controlling the first hydraulic lifting column to complete the vertical angle adjustment of the large-screen intelligent display after the height adjustment.

Preferably, if the large-screen smart display receives a control request, the implementation method further includes:

the large-screen intelligent display transmits a control signal to the support servo system;

and the support servo system adjusts the front and rear positions of the display base according to the control signal, and adjusts the intelligent display to a proper distance away from a user.

Preferably, if the virtual scene type is specifically a chase type, the implementation method further includes:

the tracked target is set with an initial speed, and the intelligent display calculates the distance difference according to the respective speeds of the user and the tracked target;

when the distance difference between the user and the tracked target is smaller than a preset threshold value, the intelligent display sends a control signal to the support servo system, so that the support servo system controls the display base, the intelligent display moves towards the direction of the user, and the user interacts with the tracked target through the intelligent display.

Preferably, the running speed simulated by the treadmill is of a user adaptive type, and the implementation method further includes:

the crawler self-adapts to the running speed of a user and adjusts the conveying speed of the user, and the conveying speed is fed back to the intelligent display by a crawler transmission system of the user;

and the intelligent display adjusts the speed effect of the display picture in the display according to the change of the transmission rate.

In a fourth aspect, an embodiment of the present invention provides an implementation method of a screen-adaptive treadmill, where the screen-adaptive treadmill structure according to the second aspect is used, and the implementation method includes:

the large-screen intelligent display receives parameter information input by a user, wherein the parameter information comprises height information of sports personnel, running speed simulated by a running machine, climbing angle simulated by the running machine and one or more of virtual scene types displayed by the display screen;

the large-screen intelligent display adjusts the running speed of the treadmill, the angle of the treadmill and the position of the large-screen intelligent display according to the parameter information input by the user; wherein, the specific position of adjustment large-size screen intelligent display includes:

and determining the proper height of the large-screen intelligent display according to the height information of the user, and inputting a control instruction to the support servo system so that the support servo system controls the hydraulic lifting column to complete the height adjustment of the large-screen intelligent display.

Compared with the prior art, the invention has the beneficial effects that: according to the embodiment of the invention, the self-adaptive change of the height and the angle of the display screen can be realized by controlling the display bracket and the base thereof through the bracket servo system, so that the self-adaptive treadmill can be suitable for users with different heights and different age groups, further different running experiences can be provided, the functions of the treadmill are enriched, and the user experience is improved.

[ description of the drawings ]

FIG. 1 is a schematic view of a prior art treadmill according to an embodiment of the present invention;

FIG. 2 is a schematic structural diagram of a screen-adaptive treadmill according to an embodiment of the present invention;

FIG. 3 is a schematic diagram of another screen adaptive treadmill according to an embodiment of the present invention;

FIG. 4 is a partial structure enlarged view of a screen adaptive treadmill according to an embodiment of the present invention;

FIG. 5 is a schematic diagram illustrating a partial structure of a screen adaptive treadmill according to an embodiment of the present invention;

FIG. 6 is a partial structure enlarged view of a screen adaptive treadmill according to an embodiment of the present invention;

FIG. 7 is a partial structure enlarged view of a screen adaptive treadmill according to an embodiment of the present invention;

FIG. 8 is a schematic view of another screen adaptive treadmill according to an embodiment of the present invention;

FIG. 9 is a schematic diagram illustrating the effect of using a screen adaptive treadmill according to an embodiment of the present invention;

FIG. 10 is a flow chart of a screen adaptive treadmill implementation provided by an embodiment of the present invention;

FIG. 11 is a flow chart of another screen adaptive treadmill implementation consistent with embodiments of the present invention.

[ detailed description ] embodiments

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention is described in further detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.

In addition, the technical features involved in the embodiments of the present invention described below may be combined with each other as long as they do not conflict with each other.

In each embodiment of the invention, the direction description language 'front and back' is the direction description which is made by taking the treadmill as a main body when the user faces the direction of the large-screen intelligent display; the "left and right" are described with reference to the "front and rear" directions.

In the embodiments of the present invention, the large-screen intelligent display refers to a display integrating a computer CPU, a large-size display screen, and a control panel, and is somewhat similar to an all-in-one machine in the PC field. The frame of the common large screen display can be provided with control buttons, the high-level large screen display can be provided with a local touch screen design, and the top-level large screen display can be provided with a full-screen touch function.

Example 1:

the embodiment of the present invention provides a screen adaptive treadmill, as shown in fig. 2, including a treadmill track 21 and a transmission system thereof (not a core invention point of the present invention, but referring to the prior art, not shown in the figures), a treadmill body 22, wherein the treadmill track 21 covers an area of the treadmill body 22 for providing a user with exercise; the track transmission system is located inside the treadmill body 22, and is characterized in that the screen adaptive treadmill further includes a large screen intelligent display 23, a display support 24, and a support servo system 25, specifically:

the large-screen intelligent display 23 is fixed on the display bracket 24, and the bracket servo system 25 is arranged in the treadmill body 22; wherein, the display bracket 24 is symmetrically arranged at both sides of the treadmill body 22, and the base 245 of the display bracket 24 is arranged inside the treadmill body 22 and can receive the bracket servo system 25 to complete the back and forth movement.

The moving implementation mode of the base 245 can refer to the existing bilateral symmetry guide rails, wherein the left side and the right side of the base 245 are provided with guide shafts embedded into the guide rails, and the moving implementation mode is further matched with a gear to conduct the power required by moving.

Wherein, each side display bracket 24 is composed of at least one main bearing rod 241, one auxiliary bearing rod 242, a first hydraulic lifting column 243 and a second hydraulic lifting column 244, and the first hydraulic lifting column 243 and the second hydraulic lifting column 244 are connected with the bracket servo system 25 for control; one end of the main bearing rod 241 is connected to a base 245 of the display bracket 24, the other end of the main bearing rod is connected to a first hydraulic lifting column 243, and the other end of the first hydraulic lifting column 243 is connected to a display screen; the auxiliary bearing rod 242 is connected with the large-screen intelligent display and the main bearing rod 241, and forms a deformable quadrilateral structure with the large-screen intelligent display 23, the first hydraulic lifting column 243 and the main bearing rod 241; one end of the second hydraulic lifting column 244 is fixed on the base 245 of the display bracket 24, and the other end is connected with the main bearing rod 241, and forms a deformable triangle structure with the base 245 and the main bearing rod 241 of the display bracket 24.

The embodiment of the invention provides a screen self-adaptive treadmill, which can realize self-adaptive change of the height and the angle of a display screen by controlling a display bracket 24 and a base 245 thereof through a bracket servo system 25, thereby being suitable for users with different heights and different age groups, further providing different running experiences, enriching the functions of the treadmill and improving the user experience.

In the embodiment of the present invention, one end of the second hydraulic lifting column 244 is fixed on the base 245 of the display bracket 24, and there is a preferred specific implementation, as shown in fig. 3 and 4, which includes:

one end of the second hydraulic lifting/lowering column 244 is provided with a positioning hole, a base 245 of the display bracket 24 is provided with a hollow column 246 with a positioning hole, and the second hydraulic lifting/lowering column 244 is fixed on the hollow column 246 by using a positioning pin 247.

This embodiment can further increase the size of the adjustable space of the large-screen intelligent display 23 of the treadmill, and the higher the second hydraulic lifting column 244 is fixed relative to the hollow column 246, the higher the maximum height of the large-screen intelligent display 23 can be adjusted.

With the embodiment of the present invention, there is a preferred implementation scheme for the structure that the other end is connected to the main carrier bar 241, which can be specifically implemented as follows:

in a first mode, as shown in fig. 5, the other end of the second hydraulic lifting column 244 is connected to a supporting arm 248 by a rotating shaft structure, and the supporting arm 248 is used for supporting one side of the main bearing rod 241.

In a second mode, as shown in fig. 6 and 7, the other end of the second hydraulic lifting column 244 is connected to a pipe barrel 249 in a rotating shaft structure (a structure indicated by 251 in the figure), the pipe barrel is sleeved on the main carrier bar 241, and a bearing 250 is arranged inside the pipe barrel. The bearing 250 is used for converting the extension or contraction force of the second hydraulic lifting column 244 to the torsion of the main load bearing rod 241 under the condition of low resistance when the second hydraulic lifting column extends or contracts.

In combination with the embodiment of the present invention, one end of the main bearing rod 241 is connected to the base 245 of the display bracket 24, the other end of the main bearing rod is connected to the first hydraulic lifting column 243, and the other end of the first hydraulic lifting column 243 is connected to the large-screen intelligent display 23, there is an optimal implementation manner, specifically:

the connection structure of the first hydraulic lifting column 243 and the main bearing rod 241 is specifically a rotating shaft structure; the other end of the first hydraulic lifting column 243 is also connected with the large-screen intelligent display 23 by using a rotating shaft structure.

Example 2:

the embodiment of the invention provides a simple screen-adaptive treadmill in addition to a relatively complex screen-adaptive treadmill as disclosed in embodiment 1. The treadmill comprises a treadmill crawler belt 21, a transmission system thereof and a treadmill body 22, wherein the treadmill crawler belt 21 covers the treadmill body 22 and is used for providing a user with a sport area; the track transmission system is located inside the treadmill body 22, and is characterized in that the screen adaptive treadmill further includes a large screen intelligent display 23, a display support 24, and a support servo system 25, specifically:

the large-screen intelligent display 23 is fixed on the display bracket 24, and the bracket servo system 25 is arranged in the treadmill body 22; wherein, the display bracket 24 is symmetrically arranged at two sides of the treadmill body 22, and the base 245 of the display bracket 24 is arranged inside the treadmill body 22 and can receive the bracket servo system 25 to complete the back and forth movement;

the display bracket 24 on each side is composed of at least one main bearing rod 241 and a hydraulic lifting column 26, one end of the main bearing rod 241 is used for fixing the large-screen intelligent display 23, and the other end of the main bearing rod is connected to the display base 245 after being connected with the hydraulic lifting column 26 in series; the hydraulic lifting column 26 is connected to the support servo system 25 and is controlled by the support servo system 25 to perform the extending and retracting actions.

Compared with the embodiment 1, the screen adaptive treadmill provided by the embodiment has a simpler structure and is more convenient to use, but the angle that the screen can present is also fixed compared with the treadmill provided by the embodiment 1. For the multifunctional running machine, for example, the multifunctional running machine with additional functions such as sit-up or rowing can be performed, at this time, the scheme provided by embodiment 2 cannot well meet the user requirements. As shown in fig. 9, with the structure given in embodiment 1, it is possible to provide a more suitable angle for viewing and operating a large-screen smart display for a user doing sit-up.

Example 3:

an embodiment of the present invention further provides an implementation method of a screen adaptive treadmill, where the screen adaptive treadmill structure described in embodiment 1 is used, as shown in fig. 10, the implementation method includes:

in step 201, the large-screen smart display 23 receives parameter information input by a user, where the parameter information includes one or more of height information of an athlete, a running speed simulated by the treadmill, a climbing angle simulated by the treadmill, and a virtual scene type displayed by the large-screen smart display 23.

In step 202, the large-screen intelligent display adjusts the running speed of the treadmill, the angle of the treadmill and the position of the large-screen intelligent display 23 according to the parameter information input by the user; wherein, adjusting 23 concrete positions of large-size screen intelligent display includes:

in step 203, determining a suitable height of the large-screen intelligent display 23 according to the height information of the user, and inputting a control instruction to the support servo system 25, so that the support servo system 25 controls the second hydraulic lifting column to complete the height adjustment of the large-screen intelligent display 23; and controls the first hydraulic lifting column to complete the vertical angle adjustment of the large-screen intelligent display 23 after the height adjustment.

With reference to the embodiment of the present invention, there is also a preferred implementation scheme, where if the large-screen smart display 23 receives a control request, the implementation method further includes:

the large-screen intelligent display 23 transmits a control signal to the support servo system 25; the support servo system 25 adjusts the front and rear positions of the display base 245 according to the control signal, and adjusts the large-screen intelligent display 23 to be at a proper distance from the user.

With reference to the embodiment of the present invention, there is also a preferred implementation scheme, where the virtual scene type is specifically a chase type, and the implementation method further includes:

the chased object is set with an initial speed, and the large-screen intelligent display 23 calculates the distance difference according to the respective speeds of the user and the chased object; when the distance difference between the user and the tracked target is smaller than a preset threshold value, the large-screen intelligent display 23 sends a control signal to the support servo system 25, so that the support servo system 25 controls the display base 245, and the large-screen intelligent display 23 moves towards the user, so that the user interacts with the tracked target through the large-screen intelligent display 23. The interaction includes clicking on an on-screen capture button, clicking on an on-screen win button, clicking on an on-screen call button, and the like.

In combination with the embodiment of the present invention, there is also a preferred implementation scheme, where the running speed simulated by the treadmill is user adaptive, and the implementation method further includes:

the crawler tracks are adaptive to the running speed of the user and adjust the conveying speed of the user, and the conveying speed is fed back to the large-screen intelligent display 23 through a crawler track transmission system;

the large-screen intelligent display 23 adjusts the speed effect of the display picture in the display according to the change of the transmission rate.

Example 4:

an embodiment of the present invention further provides an implementation method of a screen-adaptive treadmill, where the screen-adaptive treadmill structure described in embodiment 2 is used, as shown in fig. 11, and the implementation method includes:

in step 301, the large-screen smart display 23 receives parameter information input by a user, wherein the parameter information includes one or more of height information of an athlete, a running speed simulated by the treadmill, a climbing angle simulated by the treadmill, and a virtual scene type displayed by the display screen.

In step 302, the large-screen intelligent display 23 adjusts the running speed of the treadmill, the angle of the treadmill and the position of the large-screen intelligent display 23 according to the parameter information input by the user; wherein, adjusting 23 concrete positions of large-size screen intelligent display includes:

in step 303, the appropriate height of the large-screen intelligent display 23 is determined according to the height information of the user, and a control instruction is input to the support servo system 25, so that the support servo system 25 controls the hydraulic lifting column 26 to complete the height adjustment of the large-screen intelligent display 23.

It should be noted that, because the contents of information interaction, execution process, and the like between the modules and units in the device are based on the same concept as the processing method embodiment of the present invention, specific contents may refer to the description in the method embodiment of the present invention, and are not described herein again.

Those of ordinary skill in the art will appreciate that all or part of the steps of the various methods of the embodiments may be implemented by associated hardware as instructed by a program, which may be stored on a computer-readable storage medium, which may include: read Only Memory (ROM), Random Access Memory (RAM), magnetic or optical disks, and the like.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the invention, and any modifications, equivalents and improvements made within the spirit and principle of the present invention are intended to be included within the scope of the present invention.

Claims (10)

1. A screen self-adaptive treadmill comprises a treadmill crawler belt, a transmission system thereof and a treadmill body, wherein the treadmill crawler belt covers an area on the treadmill body for providing a user with exercise; inside the treadmill organism, its characterized in that, screen self-adaptation's treadmill still includes big screen intelligent display, display support and support servo, specific:

the large-screen intelligent display is fixed on the display support, and the support servo system is arranged in the treadmill body; the display support is symmetrically arranged on two sides of the treadmill body, and a base of the display support is arranged in the treadmill body and can receive a support servo system to finish the back-and-forth movement;

the display bracket on each side is composed of at least one main bearing rod, one auxiliary bearing rod, a first hydraulic lifting column and a second hydraulic lifting column, and the first hydraulic lifting column and the second hydraulic lifting column are connected with the bracket servo system for control; one end of the main bearing rod is connected to a base of the display support, the other end of the main bearing rod is connected with a first hydraulic lifting column, and the other end of the first hydraulic lifting column is connected with a display screen; the auxiliary bearing rod is connected with the display screen and the main bearing rod and forms a deformable quadrilateral structure with the large-screen intelligent display, the first hydraulic lifting column and the main bearing rod; one end of the second hydraulic lifting column is fixed on the base of the display support, the other end of the second hydraulic lifting column is connected with the main bearing rod, and the second hydraulic lifting column, the base of the large-screen intelligent display support and the main bearing rod form a deformable triangular structure.

2. The screen-adaptive treadmill of claim 1, wherein one end of the second hydraulic lifting column is fixed to a base of the display support, embodied as:

one end of the second hydraulic lifting column is provided with a positioning hole, a base of the display support is provided with a hollow column with a positioning hole, and the second hydraulic lifting column is fixed on the hollow column through a positioning pin.

3. The screen-adaptive treadmill of claim 1, wherein the other end is connected to a main load bar, embodied as:

the other end of the second hydraulic lifting column is connected with a supporting arm through a rotating shaft structure, and the supporting arm is used for supporting one side of the main bearing rod; or,

the other end of the second hydraulic lifting column is connected with a pipe barrel through a rotating shaft structure, the pipe barrel is sleeved on the main bearing rod, and a bearing is arranged on the inner side of the pipe barrel.

4. The screen-adaptive treadmill of claim 1, wherein one end of the main bearing rod is connected to the base of the display support, the other end of the main bearing rod is connected to a first hydraulic lifting column, the other end of the first hydraulic lifting column is connected to the display screen, and the screen-adaptive treadmill is implemented as follows:

the connection structure of the first hydraulic lifting column and the main bearing rod is a rotating shaft structure; the other end of the first hydraulic lifting column is also connected with a display screen through a rotating shaft structure.

5. A screen self-adaptive treadmill comprises a treadmill crawler belt, a transmission system thereof and a treadmill body, wherein the treadmill crawler belt covers an area on the treadmill body for providing a user with exercise; inside the treadmill organism, its characterized in that, screen self-adaptation's treadmill still includes big screen intelligent display, display support and support servo, specific:

the large-screen intelligent display is fixed on the display support, and the support servo system is arranged in the treadmill body; the display support is symmetrically arranged on two sides of the treadmill body, and a base of the display support is arranged in the treadmill body and can receive a support servo system to finish the back-and-forth movement;

the intelligent display comprises a display base, a display support and a plurality of intelligent displays, wherein the display support on each side is composed of at least one main bearing rod and a hydraulic lifting column, one end of the main bearing rod is used for fixing the intelligent display, and the other end of the main bearing rod is connected to the display base after being connected with the hydraulic lifting column in series; the hydraulic lifting column is connected with a support servo system and is controlled by the support servo system to complete the stretching and retracting actions.

6. A method for implementing a screen-adaptive treadmill, wherein the screen-adaptive treadmill structure of any one of claims 1-4 is used, the method comprising:

the large-screen intelligent display receives parameter information input by a user, wherein the parameter information comprises height information of sports personnel, running speed simulated by a running machine, climbing angle simulated by the running machine and one or more of virtual scene types displayed by the display screen;

the large-screen intelligent display adjusts the running speed of the treadmill, the angle of the treadmill and the position of the large-screen intelligent display according to the parameter information input by the user; wherein, the specific position of adjustment large-size screen intelligent display includes:

determining the proper height of the large-screen intelligent display according to the height information of the user, and inputting a control instruction to the support servo system so that the support servo system controls the second hydraulic lifting column to complete the height adjustment of the large-screen intelligent display; and controlling the first hydraulic lifting column to complete the vertical angle adjustment of the large-screen intelligent display after the height adjustment.

7. The method of claim 6, wherein the large-screen smart display receives a manipulation request, and further comprising:

the large-screen intelligent display transmits a control signal to the support servo system;

and the support servo system adjusts the front and rear positions of the display base according to the control signal, and adjusts the intelligent display to a proper distance away from a user.

8. The method of claim 6, wherein the virtual scene type is a chase type, and the method further comprises:

the tracked target is set with an initial speed, and the intelligent display calculates the distance difference according to the respective speeds of the user and the tracked target;

when the distance difference between the user and the tracked target is smaller than a preset threshold value, the intelligent display sends a control signal to the support servo system, so that the support servo system controls the display base, the intelligent display moves towards the direction of the user, and the user interacts with the tracked target through the intelligent display.

9. The screen-adaptive treadmill implementation of claim 6, wherein the simulated running speed of the treadmill is user-adaptive, the implementation further comprising:

the crawler self-adapts to the running speed of a user and adjusts the conveying speed of the user, and the conveying speed is fed back to the intelligent display by a crawler transmission system of the user;

and the intelligent display adjusts the speed effect of the display picture in the display according to the change of the transmission rate.

10. A method for implementing a screen-adaptive treadmill, wherein the screen-adaptive treadmill structure of claim 6 is used, the method comprising:

the large-screen intelligent display receives parameter information input by a user, wherein the parameter information comprises height information of sports personnel, running speed simulated by a running machine, climbing angle simulated by the running machine and one or more of virtual scene types displayed by the display screen;

the large-screen intelligent display adjusts the running speed of the treadmill, the angle of the treadmill and the position of the large-screen intelligent display according to the parameter information input by the user; wherein, the specific position of adjustment large-size screen intelligent display includes:

and determining the proper height of the large-screen intelligent display according to the height information of the user, and inputting a control instruction to the support servo system so that the support servo system controls the hydraulic lifting column to complete the height adjustment of the large-screen intelligent display.