CN116392791B - Device for training hand-eye coordination and working method thereof - Google Patents

Abstract

The invention discloses a device for training hand-eye coordination and a working method thereof, and relates to the field of hand-eye coordination training equipment. Solves the problems that the prior hand-eye coordination training device has relatively complex result and lacks functionality, which causes that training staff is difficult to continue with higher interest after using for a period of time. The device comprises a leg training mechanism, a first flow mechanism and a second flow mechanism are sequentially arranged above the leg training mechanism from back to front, target mechanisms are fixedly connected to the second flow mechanism and the outer cambered surface of the first flow mechanism, an energy storage mechanism is rotatably connected to the surface of the power transmission mechanism, a shooting tool is carried on the energy storage mechanism, and an atomization mechanism is further arranged at the top of the energy storage mechanism. According to the invention, through changing the flowing track of the target card, the training items are diversified, the training personnel are prevented from being tedious, and the training personnel are facilitated to be full of interests for a long time.

Description

Device for training hand-eye coordination and working method thereof

Technical Field

The invention relates to the field of hand-eye coordination training equipment, in particular to a device for training hand-eye coordination and a working method thereof.

Background

With the improvement of the technical level of trainers and the development of scientific technology, trainers begin to pay more and more attention to the training of hand-eye coordination ability, and various hand-eye coordination devices are appeared in the field in recent years, so that the requirements of users are better met.

The hand-eye coordination training device in the prior art has relatively complex results, lacks functionality, cannot quickly make training staff throw in whole body and mind, further can influence the training effect, and lacks certain challenges and stimulations, so that the training staff is difficult to continue to have higher interests after using for a period of time.

Disclosure of Invention

Aiming at the problems, the invention provides a device for training hand-eye coordination and a working method thereof, which solve the problems that the existing hand-eye coordination training device has relatively complex result, lacks functionality, cannot quickly throw training staff into the whole body, further influences the training effect, and lacks certain challenges and stimulations, so that the training staff is difficult to continue to have higher interest after using for a period of time.

The technical scheme includes that the leg training mechanism comprises a leg training mechanism 1, a first flow mechanism 3 and a second flow mechanism 4 are sequentially arranged above the leg training mechanism 1 from back to front, a power transmission mechanism 2 is arranged among the first flow mechanism 3, the second flow mechanism 4 and the leg training mechanism 1, target mechanisms 5 are fixedly connected to the second flow mechanism 4 and the outer cambered surface of the first flow mechanism 3, an energy storage mechanism 6 is rotatably connected to the surface of the power transmission mechanism 2, a shooting tool 8 is mounted on the energy storage mechanism 6, and an atomization mechanism 7 is further arranged at the top of the energy storage mechanism 6.

A leg training mechanism;

The leg training mechanism 1 comprises a frame 101, a plurality of transmission roll shafts 102 which are rotatably connected to the frame 101 and are arranged in a linear arrangement, and a transmission belt 103 which surrounds the plurality of transmission roll shafts 102;

The transmission roller shaft 102 is driven to rotate by the movement of the transmission belt 103, so that a user can drive the transmission roller shaft to rotate when walking or running on the transmission belt 103 to output power;

The bottom of the frame 101 is fixedly connected with a threaded connection column 104, a spherical hoop groove formed in the bottom end of the threaded connection column 104 is rotationally connected with a rolling ball 106, a threaded connection cylinder 105 is sleeved on the periphery of the rolling ball 106, and the threaded connection cylinder 105 is in threaded connection with the threaded connection column 104. Therefore, after the threaded connecting cylinder 105 is rotated to ascend, the rolling beads 106 can be exposed so as to facilitate the whole transportation of the equipment, and after the threaded connecting cylinder 105 is rotated to descend, the stand can be supported to play a role of stable support.

Regarding the power transmission mechanism;

The power transmission mechanism 2 comprises a connecting box 201, wherein the connecting box 201 is clamped at the end part of the frame 101, one transmission roll shaft 102 in the leg training mechanism 1 extends into the connecting box 201, a driving wheel 202 is fixedly connected to the transmission roll shaft 102, a transverse connecting shaft 205 is rotatably connected to the connecting box 201, a driven wheel 204 is fixedly connected to the transverse connecting shaft 205, and the driving wheel 202 is kept linked with the driven wheel 204 through a linkage belt 203, so that the transverse connecting shaft 102 can be driven to rotate after the transmission roll shaft rotates;

The power transmission mechanism 2 further comprises a supporting tubular barrel 209 which is vertically arranged and fixedly connected to the connection box 201, wherein a vertical connection shaft 208 is rotatably connected in the supporting tubular barrel 209, a first drive bevel gear 206 is fixedly connected to the horizontal connection shaft 205, a first driven bevel gear 207 is fixedly connected to the vertical connection shaft 208, and the first drive bevel gear 206 and the first driven bevel gear 207 are meshed, so that the vertical connection shaft 208 can be driven to rotate after the horizontal connection shaft 102 rotates;

The middle part of the supporting tubular cylinder 209 is rotatably connected with two driving wheels 212 for driving the first flow mechanism 3 and the second flow mechanism 4 respectively, the vertical connecting shaft 208 is fixedly connected with a second drive bevel gear 210, one end of the driving wheel 212 extending into the supporting tubular cylinder 209 is fixedly connected with a second driven bevel gear 211, and the two second driven bevel gears 211 are symmetrically arranged along the center of the second drive bevel gear 210 and are meshed with the second drive bevel gear 210. So that the rotation of the vertical coupling shaft 208 can simultaneously rotate the two driving wheels 212 and the rotation of the two driving wheels 212 is reversed.

With respect to the first flow mechanism and the second flow mechanism;

the first flow mechanism 3 and the second flow mechanism 4 have the same structure and are symmetrically arranged, and the first flow mechanism 3 comprises a bracket and a flow soft belt 301;

The support is fixedly connected to a supporting tubular cylinder 209 in the power transmission mechanism 2, a plurality of connecting supporting rollers 303 distributed in an annular array are rotatably connected to the support, a connecting groove body 302 is formed in the end face of the flowing soft belt 301, the connecting supporting rollers 303 extend into the connecting groove body 302, and the flowing soft belt 301 is kept in contact with a driving wheel 212 in the power transmission mechanism 2, so that the flowing soft belt 301 in the first flowing mechanism 3 and the second flowing mechanism 4 can be directly driven to move when the driving wheel 212 rotates;

The support comprises a plurality of telescopic rods which are fixedly connected, wherein each telescopic rod comprises an external telescopic sleeve 305, an internal telescopic shaft 304, a coupling sleeve 306 and a locking screw 307, the external telescopic sleeves 305 in the telescopic rods are fixedly connected with the supporting tubular cylinder 209, and the coupling type supporting roller 303 is rotatably connected on the internal telescopic shaft 304;

The inner telescopic shaft 304 is inserted into the outer telescopic sleeve 305, a plurality of threaded holes are formed in the inner telescopic shaft 304 and uniformly distributed along the length direction of the inner telescopic shaft, the connecting sleeve 306 is fixedly connected to the outer telescopic sleeve 305 and sleeved outside the inner telescopic shaft 304, and the locking screw 307 is in threaded connection with the connecting sleeve 306 and is also in threaded connection with one threaded hole in the inner telescopic shaft 304. Thereby enabling the length of the telescopic rod to be adjustable.

The built-in telescopic shafts symmetrically distributed in the first flow mechanism 3 and the second flow mechanism 4 are fixedly connected through a linkage shaft 10, the external telescopic sleeve in the first flow mechanism 3 and the external telescopic sleeve in the second flow mechanism 4 are fixedly connected through a bridge type connecting frame, and the bottom of the bridge type connecting frame is fixedly connected to the top of the supporting tubular barrel.

Regarding the target mechanism;

The target mechanism 5 comprises a fixed connecting seat 501, and the fixed connecting seat 501 is fixedly connected to a flow soft belt in the first flow mechanism 3 or the second flow mechanism 3;

The upper hinge of fixed connecting seat 501 has switching formula cutting ferrule 502, it has built-in plug connector 504 to peg graft in the switching formula cutting ferrule 502, fixedly connected with target card 503 on the one side that built-in plug connector 504 deviates from fixed connecting seat 501, set up telescopic spread groove 505 on the terminal surface of built-in plug connector 504, sliding connection has telescopic locating pin 506 in the telescopic spread groove 505, the one end of telescopic locating pin 506 is connected with the inboard terminal surface of telescopic spread groove 505 through first supporting spring 508, the tank bottom of telescopic connecting groove 505 and the end of telescopic locating pin 506 are connected to the both ends of first supporting spring 508 respectively fixed connection, the other end of telescopic locating pin 506 is located the telescopic locating groove 507 of seting up on the inside wall of switching formula cutting ferrule 502.

Regarding the energy storage mechanism;

The energy storage mechanism 6 comprises a switching type coupling sleeve 601, the switching type coupling sleeve 601 is rotationally connected above the frame 101, a telescopic coupling seat 602 is sleeved in the switching type coupling sleeve 601, a piston seat 603 is slidably connected in the telescopic coupling seat 602, a second supporting spring 604 is arranged between the top of the piston seat 603 and the telescopic coupling seat 602, a lower-layer wedge seat 605 is fixedly connected to the top of the piston seat 603, an upper-layer wedge seat 606 attached to the lower-layer wedge seat 605 is arranged on the lower-layer wedge seat 605, a steering coupling shaft 607 is fixedly connected to the top of the upper-layer wedge seat 606, and the steering coupling shaft 607 is rotationally connected to the telescopic coupling seat 602;

The steering connecting shaft 607 is sleeved with a torsion spring, one end of the torsion spring is fixedly connected to the surface of the steering connecting shaft, the other end of the torsion spring is fixedly connected to the top of the inner side of the telescopic connecting seat, and the top end of the steering connecting shaft is provided with a shooting tool 8.

The bottom of the adaptor-type coupling sleeve 601 is also equipped with an electromagnetic plate.

Regarding the atomizing mechanism;

The atomization mechanism 7 comprises a tubular support 701, the bottom end of the tubular support 701 is fixedly connected to the telescopic connecting seat 602, an atomization nozzle 702 is assembled on the tubular support 701, an input port of the atomization nozzle 702 is communicated with a cavity above the piston seat 603 in the telescopic connecting seat 602 through a wall climbing pipe, the wall climbing pipe is attached to the tubular support 701, a suction pipe is further clamped on the side end face of the telescopic connecting seat 602, and the suction pipe and the wall climbing pipe are both provided with one-way valves.

A method of operating a device for training hand-eye coordination comprising the steps of:

s1, training personnel stand on a conveying belt in a leg training mechanism 1 to walk or run, and the conveying belt is driven to drive a transmission roller shaft to rotate;

S2, the transmission roll shaft passes through a transverse connecting shaft and a vertical connecting shaft in the power transmission mechanism 2 in the rotating process, and finally drives the two driving wheels to synchronously and reversely rotate;

S3, respectively acting on the built-in flow soft belt of the first flow mechanism and the built-in flow soft belt of the second flow mechanism in the process of rotating the two driving wheels, wherein the flow directions of the two built-in flow soft belts are reciprocal, the two flow soft belts respectively drive corresponding target cards to perform corresponding transmission actions at the stage, the target cards at the rear side serve as shooting objects, and the target cards at the front side serve as barriers to shield the shooting objects;

S4, rotating the switching type connecting sleeve to adjust the included angle between the switching type connecting sleeve and the rack, pulling the piston seat to perform corresponding telescopic action in the switching type connecting sleeve, and adjusting the interval between the shooting tool and the shooting object;

S5, adjusting the length of each telescopic rod in the first flow mechanism and the second flow mechanism, and changing the form of the flow soft belt after the adjustment work is completed;

S6, in the shooting aiming process, the steering connecting shaft is continuously twisted along with training personnel, and in the rotating process of the steering connecting shaft, the piston seat is driven to frequently perform piston movement, in the process, the suction pipe continuously extracts liquid, and the wall climbing pipe continuously releases the liquid into the atomizing nozzle.

The beneficial effects of the invention are as follows:

1. According to the invention, when a training person operates the shooting tool to shoot shooting objects, shooting can be successful only when a group of adjacent shooting objects and obstacles are misplaced, so that the stress response capability of the training person can be trained, the eye concentration of the training person is required, and meanwhile, the auxiliary operation of the hand of the training person is also required, so that the training person has good interestingness, is beneficial to the overall physical and psychological investment of the training person, and therefore, the training effect can be improved to a higher degree, and the aims of stimulating teaching and training are fulfilled.

2. According to the invention, the space between the shooting tool and the shooting object is adjusted, the training difficulty is improved by changing the space between the shooting tool and the shooting object, the challenge in the training process is increased, in this state, on one side, training personnel can perform shooting training, on the other hand, friends or families can perform running exercise on the transmission belt, in the running exercise process of the friends or families, the running speed of the first flow mechanism built-in flow soft belt and the running speed of the second flow mechanism built-in flow soft belt can be adjusted at any time by changing the running speed, so that the challenge difficulty is further increased, a certain interaction effect is achieved, interaction is performed with the families and friends, the interestingness is increased, and the cultivation of friends and relatives is facilitated.

3. According to the invention, the form of the flowing soft belt is changed, and the flowing track of the target card is changed, so that the training items are diversified, the training personnel are prevented from being tedious, and the training personnel are benefited to be full of interests for a long time.

4. According to the invention, in the shooting aiming process, a training person continuously twists the steering connecting shaft, the steering connecting shaft drives the upper wedge-shaped seat and the lower wedge-shaped seat to move relatively in the rotating process, the special characteristics of the surface structures of the upper wedge-shaped seat and the lower wedge-shaped seat are utilized, and the elastic supporting effect of the second supporting spring is used for assisting, so that the piston seat can be driven to frequently perform piston movement, in the process, the suction pipe continuously extracts liquid, the wall climbing pipe continuously releases the liquid into the atomizing spray head, so that the liquid is sprayed above the training person in an atomized form, and the air refreshing effect is achieved.

Drawings

FIG. 1 is a schematic diagram of the overall structure of the present invention;

FIG. 2 is a schematic view of a first flow mechanism according to the present invention;

FIG. 3 is an enlarged schematic view of the structure of FIG. 2A;

FIG. 4 is a schematic view of a combination of a first flow mechanism and a second flow mechanism according to the present invention;

FIG. 5 is a schematic diagram of a split structure of the target mechanism according to the present invention;

FIG. 6 is a schematic view of another view of the leg training mechanism of the present invention;

FIG. 7 is a schematic view of a power transmission mechanism according to the present invention;

FIG. 8 is a schematic cross-sectional view of an energy storage mechanism according to the present invention;

FIG. 9 is a schematic diagram showing the combined structure of the lower wedge-shaped seat and the upper wedge-shaped seat according to the present invention.

Legend description:

1-leg training mechanism, 101-frame, 102-transmission roll shaft, 103-transmission belt, 104-screw connection column, 105-screw connection cylinder and 106-rolling ball;

2-power transmission mechanism, 201-connection box, 202-driving wheel, 203-linkage belt, 204-driven wheel, 205-transverse connection shaft, 206-first driving bevel gear, 207-first driven bevel gear, 208-vertical connection shaft, 209-supporting tubular barrel, 210-second driving bevel gear, 211-second driven bevel gear, 212-driving wheel;

3-a first flow mechanism, 301-a flow soft belt, 302-a connection groove body, 303-a connection supporting roller, 304-an internal telescopic shaft, 305-an external telescopic sleeve, 306-a connection sleeve, 307-a locking screw and 308-a through connection port;

4-a second flow mechanism;

5-target mechanism, 501-fixed connecting seat, 502-adapter card sleeve, 503-target card, 504-built-in plug connector, 505-telescopic connecting slot, 506-telescopic locating pin, 507-telescopic locating slot, 508-first supporting spring;

6-energy storage mechanism, 601-switching type coupling sleeve, 602-telescopic coupling seat, 603-piston seat, 604-second supporting spring, 605-lower wedge seat, 606-upper wedge seat, 607-steering connecting shaft;

7-atomization mechanism, 701-tubular bracket, 702-atomization nozzle, 8-shooting tool, 9-timer and 10-linkage shaft.

Detailed Description

In order to clearly illustrate the technical features of the present patent, the following detailed description will make reference to the accompanying drawings.

The invention is shown in figures 1-9, a device for training hand-eye coordination, which comprises a leg training mechanism 1, wherein a first flow mechanism 3 and a second flow mechanism 4 are sequentially arranged above the leg training mechanism 1 from back to front, the second flow mechanism 4 is fixedly connected with the first flow mechanism 3 through a linkage shaft 10, a power transmission mechanism 2 is assembled among the first flow mechanism 3, the second flow mechanism 4 and the leg training mechanism 1, a target mechanism 5 is fixedly connected on the outer cambered surfaces of the second flow mechanism 4 and the first flow mechanism 3, the surface of the power transmission mechanism 2 is rotatably connected with an energy storage mechanism 6, a shooting tool 8 is carried on the energy storage mechanism 6, and an atomization mechanism 7 is also assembled at the top of the energy storage mechanism 6.

Specifically, as shown in fig. 1, the leg training mechanism 1 comprises two parallel racks 101, opposite surfaces of the two racks 101 are rotatably connected with a plurality of transmission roll shafts 102 which are linearly arranged, the transmission roll shafts 102 are transmitted through a transmission belt 103, the bottom of the rack 101 is fixedly connected with a threaded connection column 104, a spherical hoop groove formed at the bottom end of the threaded connection column 104 is rotationally connected with a rolling bead 106, the periphery of the rolling bead 106 is sleeved with a threaded connection cylinder 105, and the threaded connection cylinder 105 is in threaded connection with the surface of the threaded connection column 104;

The power transmission mechanism 2 comprises a coupling box 201 and a supporting tubular barrel 209 fixedly connected to the coupling box 201, the coupling box 201 is clamped at the end part of the frame 101, one of the transmission roll shafts 102 is also rotationally connected to the corresponding surface of the coupling box 201, a driving wheel 202 is fixedly connected to the surface of the transmission roll shaft 102 at a position corresponding to the inside of the coupling box 201, the driving wheel 202 is kept linked with a driven wheel 204 through a linkage belt 203, the driven wheel 204 is fixedly connected to the surface of a transverse coupling shaft 205, one end of the transverse coupling shaft 205 is rotationally connected to the end surface of the inner side of the coupling box 201 through a bearing, the other end of the transverse coupling shaft 205 is fixedly connected with a first driving bevel gear 206, the surface of the first driving bevel gear 206 is meshed with a first driven bevel gear 207, the first driven bevel gear 207 is fixedly connected to the bottom end of a vertical coupling shaft 208, and the surface of the vertical coupling shaft 208 is rotationally connected to the bottom of the supporting tubular barrel 209 through a bearing. The top end of the vertical coupling shaft 208 is fixedly connected with a second driving bevel gear 210, the surface of the second driving bevel gear 210 is meshed with a second driven bevel gear 211, the surface of the second driven bevel gear 211 is meshed with two symmetrically arranged second driven bevel gears 211, the second driven bevel gear 211 is fixedly connected to a roll shaft of a driving wheel 212, and the roll shaft of the driving wheel 212 is rotatably connected to the inner cylinder wall of the supporting tubular cylinder 209 through a bearing.

When the device is used, a training person stands on the transmission belt 103 to perform running movement, so that the transmission belt 103 can be driven to move on the transmission roller shaft 102, meanwhile, the transmission roller shaft 102 can be driven to perform rotating movement, the transmission roller shaft 102 connected to the coupling box 201 can transmit torsion on the transmission roller shaft 102 to the transverse coupling shaft 205 by utilizing linkage effects among the driving wheel 202, the linkage belt 203 and the driven wheel 204 in the rotating process, the transverse coupling shaft 205 can transmit the torsion again by utilizing linkage effects between the first driving bevel gear 206 and the first driven bevel gear 207, and the vertical coupling shaft 208 can disperse and act on the two driving wheels 212 at the same time by utilizing linkage effects between the second driving bevel gear 210 and the second driven bevel gear 211, and the steering directions of the two driving wheels 212 are reversed.

Specifically, as shown in fig. 1, the first flow mechanism 3 and the second flow mechanism 4 have the same structure, the first flow mechanism 3 comprises a flow soft belt 301, a connecting groove body 302 is formed on the front side end surface of the flow soft belt 301, a plurality of connecting supporting rollers 303 arranged in an annular array are connected in a rolling manner in the connecting groove body 302, an inner telescopic shaft 304 is connected on the end surface of the connecting supporting rollers 303 in a rotating manner, an outer telescopic sleeve 305 is sleeved on the surface of the inner telescopic shaft 304, one ends, close to the outer telescopic sleeve 305, of the inner telescopic shaft 304 are fixedly connected, a connecting sleeve 306 fixedly connected with the outer telescopic sleeve is sleeved on the surface of the outer telescopic sleeve 305, a locking screw 307 is connected on the surface of the connecting sleeve 306 in a threaded manner, and the end part of the locking screw 307 penetrates through a through connecting port 308 formed on the front side end surface of the outer telescopic sleeve 305 and is connected in a threaded hole formed on the front side end surface of the inner telescopic shaft 304 in a threaded manner, and a plurality of threaded holes uniformly distributed along the length direction of the inner telescopic shaft 304 are formed in the inner telescopic shaft 304;

During adjustment, the locking screw 307 is twisted to loosen the coupling sleeve 306 from the built-in telescopic shaft 304, then the built-in telescopic shaft 304 is pulled or pushed to perform corresponding telescopic action in the external telescopic sleeve 305, after the adjustment work is completed, the locking screw 307 is twisted again to fasten the coupling sleeve 306 and the built-in telescopic shaft 304, further the form of the flowing soft belt 301 can be changed, the flowing track of the target card 503 is changed, the diversification of training projects is avoided, the training personnel are prevented from producing tedious and the training personnel are benefited to be full of interests for a long time.

The opposite surfaces of the internal coupling type supporting roller 303 of the first flow mechanism 3 and the internal coupling type supporting roller 303 of the second flow mechanism 4 are fixedly connected through the coupling shaft 10, an external telescopic sleeve 305 included in the first flow mechanism 3 and an external telescopic sleeve 305 included in the second flow mechanism 4 are fixedly connected through a bridge type connecting frame, and the bottom of the bridge type connecting frame is fixedly connected to the top of the supporting tubular barrel 209.

When the device is used, two driving wheels 212 respectively act on the built-in flowing soft belts 301 of the first flowing mechanism 3 and the built-in flowing soft belts 301 of the second flowing mechanism 4 in the rotating process, the flowing directions of the two built-in flowing soft belts 301 are reversed, the two flowing soft belts 301 respectively drive corresponding target cards 503 to perform corresponding actions at the stage, the target cards 503 positioned at the rear side serve as shooting objects, the target cards 503 positioned at the front side serve as barriers to shield the shooting objects, so that when a training person operates the shooting tool 8 to shoot the shooting objects, shooting can be successful only when a group of adjacent shooting objects and barriers are misplaced, stress reaction capacity of the training person can be exercised, eye concentration of the training person is needed, meanwhile, auxiliary operation of hands of the training person is also needed, good interestingness is achieved, full-body investment of the training person is facilitated, and therefore, the training effect can be improved to a higher degree, and the purposes of stimulating teaching and training are achieved.

Specifically, as shown in fig. 1, the target mechanism 5 includes a fixed connection seat 501, the fixed connection seat 501 is fixedly connected to an outer arc surface of the built-in flow soft belt 301 of the first flow mechanism 3 or the built-in flow soft belt 301 of the second flow mechanism 4, a switching type clamping sleeve 502 is rotatably connected to an outer end surface of the fixed connection seat 501 through a spring hinge, a built-in plug 504 is plugged into the switching type clamping sleeve 502, a target card 503 is fixedly connected to a surface of the built-in plug 504, which faces away from the fixed connection seat 501, a telescopic connection groove 505 is formed in an end surface of the built-in plug 504, a telescopic positioning pin 506 is slidably connected to the telescopic connection groove 505, one end of the telescopic positioning pin 506 is connected to an end surface inside the telescopic connection groove 505 through a first support spring 508, two ends of the first support spring 508 are respectively fixedly connected to a groove bottom of the telescopic connection groove 505 and an end of the telescopic positioning pin 506, and the other end of the telescopic positioning pin 506 is located in a telescopic positioning groove 507 formed in an inner side wall of the switching type clamping sleeve 502.

Specifically, as shown in fig. 1, the energy storage mechanism 6 includes a switching type coupling sleeve 601, the switching type coupling sleeve 601 is rotationally connected to the surface of the supporting tubular barrel 209, a telescopic coupling seat 602 is sleeved in the switching type coupling sleeve 601, a piston seat 603 is slidably connected in the telescopic coupling seat 602, the top of the piston seat 603 is fixedly connected with a lower wedge seat 605 through a second supporting spring 604 and the top of the inner side of the telescopic coupling seat 602, an upper wedge seat 606 is slidingly connected on the inclined surface of the lower wedge seat 605, the top of the upper wedge seat 606 is fixedly connected with a steering connecting shaft 607, the steering connecting shaft 607 is rotationally connected to the top of the inner side of the telescopic connecting seat, a torsion spring is sleeved on the surface of the steering connecting shaft 607, one end of the torsion spring is fixedly connected to the surface of the steering connecting shaft 607, the other end of the torsion spring is fixedly connected to the top of the inner side of the telescopic coupling seat 602, a steering shaft is rotationally connected to a steering shaft in a steering groove formed in the top of the steering connecting shaft 607, one end of the torsion spring is fixedly connected to the surface of the steering shaft, and the other end of the torsion spring is fixedly connected to the end of the steering shaft 607 on the inner side of the steering shaft is provided with a steering tool 8.

The atomizing mechanism 7 comprises a tubular bracket 701, the bottom end of the tubular bracket 701 is fixedly connected to the top of the telescopic connecting seat 602, an atomizing nozzle 702 is assembled on the tubular bracket 701, an input port of the atomizing nozzle 702 is communicated with the side end face of the telescopic connecting seat 602 through a wall climbing pipe, the wall climbing pipe is attached to the tubular bracket 701, a suction pipe is also clamped on the side end face of the telescopic connecting seat 602, check valves are assembled on the suction pipe and the wall climbing pipe, and a timer 9 is assembled on the tubular bracket 701.

In the shooting aiming process, a training person continuously twists the steering connecting shaft 607, the steering connecting shaft 607 drives the upper wedge-shaped seat 606 and the lower wedge-shaped seat 605 to move relatively in the rotating process, the specificity of the surface structures of the upper wedge-shaped seat 606 and the lower wedge-shaped seat 605 is utilized, the bottom of the upper wedge-shaped seat 606 is wedge-shaped, the middle of the top surface of the lower wedge-shaped seat 605 is sunken downwards, the elastic supporting effect of the second supporting spring 604 is assisted, the piston seat 603 can be driven to frequently perform piston movement, in the process, the suction pipe continuously extracts liquid, the wall climbing pipe continuously releases the liquid into the atomizing nozzle 702, the liquid is sprayed above the training person in an atomized form, the effect of air refreshing is achieved, and the suction pipe and the wall climbing pipe are provided with one-way valves.

A method of training a hand-eye coordination device, the method comprising the steps of:

s1, training personnel stand on the transmission belt 103 to do running movement, so that the transmission belt 103 can be driven to do transmission movement on the transmission roll shaft 102, and meanwhile, the transmission roll shaft 102 can be driven to do rotation movement;

S2, the torque on the transmission roll shaft 102 is transmitted to the transverse connecting shaft 205 by utilizing the linkage effect among the driving wheel 202, the linkage belt 203 and the driven wheel 204 in the rotating process of the transmission roll shaft 102, the torque is transmitted again by the transverse connecting shaft 205 by utilizing the linkage effect between the first driving bevel gear 206 and the first driven bevel gear 207, and the torque is dispersed and acted on the two driving wheels 212 simultaneously by utilizing the vertical connecting shaft 208 by utilizing the linkage effect between the second driving bevel gear 210 and the second driven bevel gear 211, and the steering directions of the two driving wheels 212 are reversed;

s3, in the process of rotating action, the two driving wheels 212 respectively act on the built-in flow soft belts 301 of the first flow mechanism 3 and the built-in flow soft belts 301 of the second flow mechanism 4, the flow directions of the two built-in flow soft belts 301 are reciprocal, the two flow soft belts 301 respectively drive the corresponding target cards 503 to perform corresponding actions at the stage, the target cards 503 positioned at the rear side serve as shooting objects, and the target cards 503 positioned at the front side serve as barriers to shield the shooting objects, so that when a training person operates the shooting tool 8 to shoot the shooting objects, the training person needs to shoot successfully when a group of adjacent shooting objects and barriers are misplaced, and further stress reaction capability of the training person can be exercised;

S4, an electromagnetic plate is assembled at the bottom of the switching type coupling sleeve 601, so that after the switching type coupling sleeve 601 rotates 90 degrees, the stability of the switching type coupling sleeve 601 after angle adjustment can be ensured, the piston seat 603 is pulled to perform corresponding telescopic action in the switching type coupling sleeve 601, and the distance between the shooting tool 8 and a shooting object can be adjusted;

S5, twisting the locking screw 307 to loosen the coupling sleeve 306 and the built-in telescopic shaft 304, then pulling or pushing the built-in telescopic shaft 304 to perform corresponding telescopic action in the external telescopic sleeve 305, and twisting the locking screw 307 again to fasten the coupling sleeve 306 and the built-in telescopic shaft 304 after the adjustment work is completed, so that the form of the flowing soft belt 301 can be changed;

s6, in the shooting aiming process, a training person continuously twists the steering connecting shaft 607, the steering connecting shaft 607 drives the upper wedge-shaped seat 606 and the lower wedge-shaped seat 605 to move relatively in the rotating process, the special characteristics of the surface structures of the upper wedge-shaped seat 606 and the lower wedge-shaped seat 605 are utilized, the elastic supporting effect of the second supporting spring 604 is used for assistance, and then the piston seat 603 can be driven to frequently perform piston movement, in the process, the suction pipe continuously extracts liquid, and the wall climbing pipe continuously releases the liquid into the atomizing spray head 702.

Working principle, when in use:

The training personnel stand on the transmission belt 103 to do running movement, so that the transmission belt 103 can be driven to do transmission movement on the transmission roller shaft 102, and meanwhile, the transmission roller shaft 102 can be driven to do rotation movement;

The transmission roll shaft 102 will transmit the torsion on the transmission roll shaft 102 to the transverse connecting shaft 205 by utilizing the linkage effect among the driving wheel 202, the linkage belt 203 and the driven wheel 204 in the rotation process, and the transverse connecting shaft 205 transmits the torsion again by utilizing the linkage effect between the first driving bevel gear 206 and the first driven bevel gear 207, and the vertical connecting shaft 208 disperses and acts on the two driving wheels 212 at the same time by utilizing the linkage effect between the second driving bevel gear 210 and the second driven bevel gear 211, and the steering directions of the two driving wheels 212 are reversed;

In the process of rotating, the two driving wheels 212 respectively act on the built-in flowing soft belt 301 of the first flowing mechanism 3 and the built-in flowing soft belt 301 of the second flowing mechanism 4, the flowing directions of the two built-in flowing soft belts 301 are reciprocal, the two flowing soft belts 301 respectively drive the corresponding target cards 503 to perform corresponding transmission actions at the stage, the target cards 503 at the rear side serve as shooting objects, the target cards 503 at the front side serve as barriers to shield the shooting objects, so that when a shooting tool 8 is operated to shoot the shooting objects, a training person needs to shoot successfully when a group of adjacent shooting objects and barriers are misplaced, stress reaction capacity of the training person can be exercised, eye concentration of the training person is needed, meanwhile, auxiliary operation of hands of the training person is needed, good interestingness is achieved, full body and mind investment of the training person is facilitated, and therefore, the purposes of stimulating and training are achieved to a higher degree;

The bottom of the transfer type coupling sleeve 601 is provided with an electromagnetic plate, after the transfer type coupling sleeve 601 rotates by 90 degrees, 1 can ensure the stability of the transfer type coupling sleeve 601 after angle adjustment, the piston seat 603 is pulled to carry out corresponding telescopic actions in the transfer type coupling sleeve 601, further, the distance between the shooting tool 8 and a shooting object can be adjusted, the difficulty of modifying training can be improved by changing the distance between the shooting tool 8 and the shooting object, the challenge of the training process is increased, in this state, one side is used for shooting training by training staff, on the other hand, running exercise can be carried out on the transmission belt 103 by friends or family members, in the running exercise process of friends or family members, the running speed of the first running mechanism 3 and the running soft belt 301 can be adjusted by changing the running speed at any time, so that the challenge can be further increased, a certain interaction effect is achieved, the interaction with friends and relatives is carried out, the interest is increased, and the training difficulty of friends and relatives is facilitated;

Twisting the locking screw 307 to loosen the coupling sleeve 306 and the built-in telescopic shaft 304, then pulling or pushing the built-in telescopic shaft 304 to perform corresponding telescopic action in the external telescopic sleeve 305, and twisting the locking screw 307 again to fasten the coupling sleeve 306 and the built-in telescopic shaft 304 after finishing the adjustment work, thereby changing the form of the flowing soft belt 301, enabling the training items to be diversified by changing the flowing track of the target card 503, avoiding the generation of tedious training personnel, and being beneficial to the training personnel to be full of interest for a long time;

In the process of shooting aiming, a training person can continuously twist the steering connecting shaft 607, the steering connecting shaft 607 can drive the upper wedge-shaped seat 606 and the lower wedge-shaped seat 605 to move relatively in the process of rotating, the special characteristics of the surface structures of the upper wedge-shaped seat 606 and the lower wedge-shaped seat 605 are utilized, the elastic supporting effect of the second supporting spring 604 is further utilized, and then the piston seat 603 can be driven to frequently perform piston movement, in the process, the suction pipe continuously extracts liquid, the wall climbing pipe continuously releases the liquid into the atomizing nozzle 702, so that the liquid is sprayed above the training person in an atomized form, and the effect of refreshing air is achieved.

While there have been described what are believed to be the preferred embodiments of the present invention, it will be apparent to those skilled in the art that many more modifications are possible without departing from the principles of the invention.

Claims (8)

1. A device for training hand-eye coordination, characterized in that it comprises a leg training mechanism (1), wherein a first flow mechanism (3) and a second flow mechanism (4) are arranged above the leg training mechanism (1) from back to front in sequence, a power transmission mechanism (2) is arranged between the first flow mechanism (3), the second flow mechanism (4) and the leg training mechanism (1), a target mechanism (5) is fixedly connected to the outer arc surface of the second flow mechanism (4) and the first flow mechanism (3), an energy storage mechanism (6) is rotatably connected to the surface of the power transmission mechanism (2), a shooting tool (8) is mounted on the energy storage mechanism (6), and an atomization mechanism (7) is also arranged on the top of the energy storage mechanism (6); The first flow mechanism (3) and the second flow mechanism (4) have the same structure and are symmetrically arranged. The first flow mechanism (3) comprises a bracket and a flow soft belt (301); The bracket is fixedly connected to a supporting tubular tube (209) in the power transmission mechanism (2), and a plurality of coupling support rollers (303) distributed in a ring array are rotatably connected to the bracket, a coupling groove body (302) is provided on the end surface of the flow soft belt (301), and a plurality of coupling support rollers (303) extend into the coupling groove body (302), and the flow soft belt (301) also maintains contact with a driving wheel (212) in the power transmission mechanism (2); The support comprises a plurality of fixedly connected telescopic rods, wherein the telescopic rods comprise an external telescopic sleeve (305), an internal telescopic shaft (304), a connecting sleeve (306) and a locking screw (307); the external telescopic sleeves (305) of the plurality of telescopic rods are all fixedly connected to the supporting tubular tube (209), and the connecting support roller (303) is rotatably connected to the internal telescopic shaft (304); The built-in telescopic shaft (304) is inserted into the external telescopic sleeve (305), and the built-in telescopic shaft (304) is provided with a plurality of threaded holes evenly distributed along its length direction; the connecting sleeve (306) is fixedly connected to the external telescopic sleeve (305) and is sleeved outside the built-in telescopic shaft (304); the locking screw (307) is threadedly connected to the connecting sleeve (306) and is also threadedly connected to a threaded hole on the built-in telescopic shaft (304); The symmetrically distributed internal telescopic shafts in the first flow mechanism (3) and the second flow mechanism (4) are fixedly connected via a linkage shaft (10), and the external telescopic sleeve in the first flow mechanism (3) and the external telescopic sleeve in the second flow mechanism (4) are fixedly connected via a bridge-type connecting frame, the bottom of the bridge-type connecting frame being fixedly connected to the top of the supporting tubular tube. 2. A device for training hand-eye coordination according to claim 1, characterized in that the leg training mechanism (1) comprises a frame (101), a plurality of linearly arranged transmission rollers (102) rotatably connected to the frame (101), and a transmission belt (103) surrounding the plurality of transmission rollers (102); The conveyor roller shaft (102) is driven to rotate by the movement of the conveyor belt (103); The bottom of the frame (101) is also fixedly connected to a threaded connection column (104), a rolling ball (106) is rotatably connected in a spherical hoop groove provided at the bottom of the threaded connection column (104), a threaded connection tube (105) is provided on the outer periphery of the rolling ball (106), and the threaded connection tube (105) is threadedly connected to the threaded connection column (104). 3. A device for training hand-eye coordination according to claim 1, characterized in that the power transmission mechanism (2) comprises a coupling box (201), the coupling box (201) is clamped at the end of the frame (101), and a driving roller (102) in the leg training mechanism (1) extends into the coupling box (201), a driving wheel (202) is fixedly connected to the driving roller (102), a transverse coupling shaft (205) is rotatably connected to the coupling box (201), a driven wheel (204) is fixedly connected to the transverse coupling shaft (205), and the driving wheel (202) is linked with the driven wheel (204) through a linkage belt (203); The power transmission mechanism (2) further comprises a supporting tubular tube (209) vertically arranged and fixedly connected to the coupling box (201); a vertical coupling shaft (208) is rotatably connected to the supporting tubular tube (209); a first driving bevel gear (206) is fixedly connected to the transverse coupling shaft (205); a first driven bevel gear (207) is fixedly connected to the vertical coupling shaft (208); the first driving bevel gear (206) and the first driven bevel gear (207) are meshed; The middle part of the supporting tubular tube (209) is rotatably connected to two driving wheels (212) for driving the first flow mechanism (3) and the second flow mechanism (4) respectively; the vertical connecting shaft (208) is fixedly connected to a second active bevel gear (210); one end of the driving wheel (212) extending into the supporting tubular tube (209) is fixedly connected to a second driven bevel gear (211); the two second driven bevel gears (211) are symmetrically arranged along the center of the second active bevel gear (210) and are both meshed with the second active bevel gear (210). 4. A device for training hand-eye coordination according to claim 1, characterized in that the target mechanism (5) comprises a fixed connection seat (501), and the fixed connection seat (501) is fixedly connected to the mobile soft belt in the first mobile mechanism (3) or the second mobile mechanism (3); The fixed connection seat (501) is hinged with an adapter sleeve (502) on the top, and a built-in connector (504) is inserted in the adapter sleeve (502). A target card (503) is fixedly connected to the surface of the built-in connector (504) facing away from the fixed connection seat (501). A telescopic connection groove (505) is provided on the end surface of the built-in connector (504), and a telescopic positioning pin (503) is slidably connected in the telescopic connection groove (505). 506), one end of the telescopic positioning pin (506) is connected to the inner end surface of the telescopic connecting groove (505) through a first supporting spring (508), and the two ends of the first supporting spring (508) are respectively fixedly connected to the bottom of the telescopic connecting groove (505) and the end of the telescopic positioning pin (506), and the other end of the telescopic positioning pin (506) is located in the telescopic positioning groove (507) opened on the inner wall of the adapter sleeve (502). 5. A device for training hand-eye coordination according to claim 1, characterized in that the energy storage mechanism (6) comprises an adaptable coupling sleeve (601), the adaptable coupling sleeve (601) is rotatably connected to the upper part of the frame (101), a telescopic coupling seat (602) is sleeved in the adaptable coupling sleeve (601), a piston seat (603) is slidably connected in the telescopic coupling seat (602), a second supporting spring (604) is provided between the top of the piston seat (603) and the telescopic coupling seat (602), a lower wedge seat (605) is fixedly connected to the top of the piston seat (603), an upper wedge seat (606) abutting against the lower wedge seat (605) is provided on the lower wedge seat (605), a steering shaft (607) is fixedly connected to the top of the upper wedge seat (606), and the steering shaft (607) is rotatably connected to the telescopic coupling seat (602); A torsion spring is sleeved on the steering coupling (607), one end of the torsion spring is fixedly connected to the surface of the steering coupling, and the other end of the torsion spring is fixedly connected to the top of the inner side of the telescopic coupling seat. The top end of the steering coupling is equipped with a shooting tool (8). 6. A device for training hand-eye coordination according to claim 5, characterized in that an electromagnetic plate is also installed at the bottom of the transitional coupling sleeve (601). 7. A device for training hand-eye coordination according to claim 5, characterized in that the atomizing mechanism (7) comprises a tubular support (701), the bottom end of the tubular support (701) is fixedly connected to the telescopic coupling seat (602), the tubular support (701) is equipped with an atomizing nozzle (702), the input port of the atomizing nozzle (702) is connected to the cavity above the piston seat (603) in the telescopic coupling seat (602) through a wall-climbing tube, the wall-climbing tube is attached to the tubular support (701), and a suction tube is clamped on the side end surface of the telescopic coupling seat (602), and both the suction tube and the wall-climbing tube are equipped with a one-way valve. 8. A method for operating the device for training hand-eye coordination according to claim 1, characterized in that it comprises the following steps: S1: The trainee stands on the conveyor belt in the leg training mechanism (1) and walks or runs, driving the conveyor belt to drive the transmission roller to rotate; S2: During the rotation process, the transmission roller shaft passes through the horizontal connecting shaft and the vertical connecting shaft in the power transmission mechanism (2), and finally drives the two driving wheels to rotate synchronously in opposite directions; S3: During the rotation, the two driving wheels will act on the built-in flow soft belt of the first flow mechanism and the built-in flow soft belt of the second flow mechanism respectively, and the flow directions of the two built-in flow soft belts are opposite to each other. At this stage, the two flow soft belts will respectively drive the corresponding target cards to perform corresponding transmission actions. The target card at the rear side serves as the shooting object, and the target card at the front side serves as an obstacle to block the shooting object. S4: rotating the transfer sleeve to adjust the angle between the transfer sleeve and the frame, pulling the piston seat to perform corresponding telescopic action in the transfer sleeve, and adjusting the distance between the shooting tool and the shooting object; S5: adjusting the length of each retractable rod in the first flow mechanism (3) and the second flow mechanism (4), and changing the shape of the flow soft belt after the adjustment is completed; S6: During the process of shooting and aiming, the trainee will continuously twist the steering coupling, which will drive the piston seat to frequently perform piston movements during the rotation. During this process, the suction tube will continuously extract liquid, and the wall-climbing tube will continuously release the liquid into the atomizing nozzle.