CN116763256A - Healthy physical building monitoring equipment and student physical examination method - Google Patents

Abstract

The invention aims to provide healthy sports building monitoring equipment, which can test the horizontal balance capacity of 2 testers simultaneously, realize comprehensive evaluation of body coordination and lower limb stability of the testers, increase test interest through manual combination type driving, and has a rotating speed protection property. The device comprises a frame, a driving device, a first horizontal testing device and a second horizontal testing device, wherein the driving device, the first horizontal testing device and the second horizontal testing device are all connected with the frame, and the driving device is connected with the first horizontal testing device and the second horizontal testing device.

Description

Healthy physical building monitoring equipment and student physical examination method

Technical Field

The invention relates to the field of sports, in particular to healthy sports building monitoring equipment and a student physical examination method.

Background

Based on the education form and method of China, a certain attention is lacking in physical exercise in the past, and with the comprehensive popularization of the De-body education, the physical quality of students is estimated and a training plan is formulated in a scientific method.

For example: the invention discloses CN116077028A, a lower limb reaction and balance test and training device, which comprises a transmission chassis, wherein one end of the transmission chassis is provided with computer equipment, the top of the transmission chassis is fixedly connected with a central device, the central device comprises a central block and a pedal, the top of the transmission chassis is fixedly connected with the bottom end of the central block, the top of the central block is fixedly connected with a plurality of uniformly distributed first sensors, and the top of each first sensor is fixedly connected with a stabilizing block and a first spring. Through connecting block and vertical piece one that sets up, when the circumstances of focus skew appears, the connecting block can produce the swing, and it will give the two external force of vertical piece of both sides, and under the effect of second spring, vertical piece one also can receive the external force of equidimension, and sensor one all can receive pressure at whole in-process, and sensor one and sensor two all can collect data and feed back to computer equipment in real time on, do benefit to computer equipment and calculate and draw balanced condition. The training method is only aimed at lower limb training, cannot directly correct the whole body training and the core training, is tedious, and has a structure which is a conventional mechanism which can be adjusted according to the actual practice by a person skilled in the art.

For example: the invention discloses a sports equipment balance testing device and a method thereof, and discloses a sports equipment balance testing device and a method thereof, relating to the technical field of sports equipment balance testing. The invention comprises a testing mechanism, wherein the testing mechanism comprises a base, a testing frame, electric telescopic rods and clamping plates, the middle position of the top of the base is fixedly provided with the testing frame, the left side surface and the right side surface of the testing frame are respectively fixedly provided with the electric telescopic rods, and the connecting ends of the two electric telescopic rods are respectively connected with the clamping plates; the storage mechanism comprises a qualified storage rack and a disqualified storage rack. According to the invention, the self-contained pad frame on the test frame can adjust the height of the barbell according to the size of the end part of the barbell, so that the barbell test device is suitable for barbell detection of different sizes, and the self-contained barbell with qualified balance degree detection and the barbell with unqualified balance degree detection on two sides of the test mechanism are convenient for timely classifying and storing the qualified barbells of different sizes and the unqualified barbells of different sizes, and in addition, the test mechanism can intuitively display detection data on a display screen during detection. The testing method is only suitable for part of equipment, no safety protection structure exists in the testing process, the mechanism is simple and impractical to set, and the structure is a conventional mechanism which can be adjusted according to the actual practice by a person skilled in the art.

Disclosure of Invention

The invention aims to provide healthy physical building monitoring equipment and a student physical examination method, which can simultaneously test the horizontal balance capacity of 2 testers, realize comprehensive evaluation of body coordination and lower limb stability of the testers, increase test interest through manual combination type driving, and have rotating speed protection property.

The aim of the invention is achieved by the following technical scheme:

a healthy sports building monitoring device, characterized by: the device comprises a frame, a driving device, a first horizontal testing device and a second horizontal testing device, wherein the driving device, the first horizontal testing device and the second horizontal testing device are all connected with the frame, and the driving device is connected with the first horizontal testing device and the second horizontal testing device.

As a further optimization of the technical scheme, the health sports building monitoring equipment comprises a frame, a sensor A and a sensor B, wherein the panel A, the panel B, the top plate A, the handle, the shaft seat A, the sensor A and the sensor B are fixedly connected with the frame.

As a further optimization of the technical scheme, the invention relates to healthy sports building monitoring equipment, which comprises a connecting rod A, a shaft sleeve B, a shaft A, a toothed ring assembly A, a connecting chuck A, a three-way eccentric wheel, a gear A, a gear B, a gear C, a connecting chuck B, a double-gear connecting assembly A, a double-gear connecting assembly B, a double-gear connecting assembly C, a double-gear connecting assembly D, a double-gear connecting assembly E and a gear D, wherein the connecting rod A, the connecting rod B, the connecting rod D and the connecting rod E are respectively and rotatably connected with the shaft sleeve A, the connecting rod A is rotatably connected with an arc-shaped rack A, the connecting rod D is rotatably connected with the arc-shaped rack B, the connecting rod G is rotatably connected with the arc-shaped rack C, the connecting rod B, the connecting rod E and the connecting rod H are respectively and rotatably connected with the shaft sleeve B through a connecting rod C, a connecting rod F and a connecting rod I, the gear ring assembly A is fixedly connected with the connecting chuck A, the connecting chuck A is fixedly connected with the tee eccentric wheel, the gear A, the gear B and the gear C are respectively connected with the gear ring A in a meshed manner, the connecting chuck B is connected with the gear A, the gear B and the gear C, the connecting chuck B is rotationally connected with the gear ring A, the gear ring A is fixedly connected with the connecting cylinder, the connecting cylinder is rotationally connected with the limit sleeve, the connecting cylinder is fixedly connected with the double-gear connecting assembly A, the double-gear connecting assembly A is connected with the double-gear connecting assembly B in a meshed manner, the double-gear connecting assembly B is connected with the double-gear connecting assembly C in a meshed manner, the double-gear connecting assembly D is connected with the double-gear connecting assembly E in a meshed manner, the double-gear connecting assembly E is connected with the gear D in a meshed manner, the double-gear connecting assembly A, the double-gear connecting assembly B, the double-gear connecting assembly C, the double-gear connecting assembly D, the double-gear connecting assembly E and the gear D are all in rotary connection with the shaft seat B, the gear D and the belt wheel A are both in fixed connection with the shaft B, and the belt wheel A is in rotary connection with the belt wheel B through a belt.

As a further optimization of the technical scheme, the first horizontal testing device comprises a shaft seat C, a groove cam, an X-shaped groove cylinder, a supporting chuck and a sensor C, wherein the groove cam, the X-shaped groove cylinder and a connecting rod assembly are all in rotary connection with the shaft seat C, the groove cam is fixedly connected with a flange, an optical axis A, an optical axis B, an arc connecting rod A and an arc connecting rod B are all in fixed connection with the flange, the optical axis A, the optical axis B, the arc connecting rod A and the arc connecting rod B are all in fixed connection with the X-shaped groove cylinder, the X-shaped groove cylinder is connected with a supporting upright column, the supporting upright column is in rotary connection with the connecting rod assembly, the connecting rod assembly is connected with the groove cam through a sliding block, the supporting upright column is fixedly connected with the supporting chuck, and the supporting chuck is fixedly connected with the sensor C.

As a further optimization of the technical scheme, the healthy sports building monitoring equipment is characterized in that the parts contained in the second horizontal testing device are the same as those of the first horizontal testing device, the assembly mode and the sequence of the second horizontal testing device are the same as those of the first horizontal testing device, and the operation sequence and the implementation function of the second horizontal testing device are the same as those of the first horizontal testing device.

The physical examination method of students, realize through a kind of health sports building monitoring equipment in the above claims 1-5 specifically, can implement the horizontal balance ability test to 2 testers at the same time, realize the comprehensive assessment to tester's physical harmony and low limbs stability, increase the test interest through the drive of the manual combination form, and the structure possesses the rotational speed protection property, include the following steps:

s1, in the current education mode, a large proportion of the education mode focuses on the culture level culture of students, and the problems about physical and psychological health and the like are often ignored by parents and teachers, and the physical constitution of part of the students is different from that of the same-age people under the background of complex foods filled with science and technology, so that the physical constitution check of the students in all ages is particularly important, and the problems presented by the above points are solved. The specific implementation details are that the frame 1 is lifted to a test place through the handles 105 at four corners, and as the first horizontal testing device 3 and the second horizontal testing device 4 have the same assembly mode and sequence and the same operation sequence and the same implementation function, the first horizontal testing device 3 is taken as an example for illustration, a test student stands in the supporting chuck 312, two legs straddles and have the same width with shoulders, two arms are opened outwards naturally, then the rest students sequentially lift the connecting rod C205, the connecting rod F209 and the connecting rod I213 upwards under the guidance of relevant staff, the structure is designed to be a cooperative driving mode, the aim is to increase the interest of using the device through the curiosity of the students, increase the coordination among the students through the driving mode of cluster cooperation, the connecting rod C205 drives the shaft sleeve A201 to slide upwards along the shaft A215 through the connecting rod B204 when the lifting, when the connecting rod F209 is lifted, the shaft sleeve A201 is driven to slide upwards along the shaft A215 by the connecting rod E208, when the connecting rod I213 is lifted, the shaft sleeve A201 is driven to slide upwards along the shaft A215 by the connecting rod H212, wherein any one of the connecting rod C205, the connecting rod F209 and the connecting rod I213 can drive the other two parts to work simultaneously when being lifted upwards, the three parts are integrated, when the shaft sleeve A201 slides upwards, the arc-shaped rack A203, the arc-shaped rack B207 and the arc-shaped rack C211 are respectively driven to expand outwards by the connecting rod A202, the connecting rod D206 and the connecting rod G210, lifting of the connecting rod C205, the connecting rod F209 and the connecting rod I213 is stopped until the connecting rod C is completely meshed with the toothed ring assembly A216, when the arc-shaped rack A203, the arc-shaped rack B207 and the arc-shaped rack C211 are meshed with the toothed ring on the inner wall of the toothed ring assembly A216, the shaft sleeve A201 slides upwards to be contacted with the shaft sleeve B214, the shaft sleeve B214 forms an upper limit of the height, and then students hold the connecting rod C205, the connecting rod F209, the connecting rod I213 and the connecting rod I, the connecting rod I213 rotates clockwise, the arc-shaped rack A203, the arc-shaped rack B207 and the arc-shaped rack C211 drive the toothed ring assembly A216 to rotate, the toothed ring assembly A216 drives the connecting chuck A217 to rotate, in order to prevent students from generating potential safety hazards to test students when initially exerting force, the connecting chuck A217 drives the three-way eccentric wheel 218 to rotate when rotating, the three-way eccentric wheel 218 drives the gear A219, the gear B220 and the gear C221 to rotate along the toothed ring A223 in an engaged way due to the eccentric reason, the connecting chuck B222 drives the toothed ring A223 to rotate when rotating, thereby forming a cycloidal speed reducing effect, the force of the front rotating rod C205, the connecting rod F209 and the connecting rod I213 of the students is firstly reduced, the students being tested are protected from the source, the rotating difficulty of the students is increased due to the primary speed reduction, the final rotating speed of the test students can be within a standard and safe test range, the final rotation speed of the test students is increased to a certain extent through the differential speed increasing mechanism, double guarantee of driving safety and personnel safety is finally formed, the connecting cylinder 224 is driven to rotate when the toothed ring A223 rotates, the connecting cylinder 224 rotates to drive the double-gear connecting assembly A226 to rotate, the double-gear connecting assembly A226 drives the double-gear connecting assembly B227 to rotate, the double-gear connecting assembly B227 drives the double-gear connecting assembly C228 to rotate, the double-gear connecting assembly C228 drives the double-gear connecting assembly D229 to rotate, the double-gear connecting assembly D229 drives the double-gear connecting assembly E230 to rotate, the double-gear connecting assembly E230 drives the gear D231 to rotate, and the double-gear connecting assembly A226, the double-gear connecting assembly B227, the double-gear connecting assembly C228, the double-gear connecting assembly D229 and the double-gear connecting assembly E230 are all in the combined form of big gears and small gears, the continuous acceleration between the pinion and the large gear is combined with a front deceleration mechanism to change the original driving effect, the purpose of the device is to synthesize an integral rotation mechanism, students with the front rotation slightly take effort to rotate the connecting rod C205, the connecting rod F209 and the connecting rod I213, the output of the rear gear D231 is smooth, the combined design is to avoid the excessive effort or the too easy realization of the test of the balance force of the students, the stable control of the test personnel and operators through the combined mechanism is ensured, the rotation of the gear D231 drives the shaft B233 to rotate, the shaft B233 drives the belt wheel A234 to rotate, and the belt wheel A234 drives the belt wheel B236 to rotate through the belt 235;

s2, when the belt wheel B236 rotates, the groove cam 302 in the first horizontal testing device 3 is driven to rotate, the groove cam 302 drives the flange 303 to rotate, the flange 303 drives the optical axis A304, the optical axis B305, the arc-shaped connecting rod A306 and the arc-shaped connecting rod B307 to rotate, when the optical axis A304 or the optical axis B305 rotates along the flange 303, the shaft end of the optical axis corresponds to the spiral groove of the X-shaped groove barrel 308, the optical axis continuously rotates, the shaft end slides along the groove in the X-shaped groove barrel 308, the X-shaped groove barrel 308 is driven to rotate, the X-shaped groove barrel 308 drives the supporting upright post 309 to rotate, the rotation angle is 180 DEG, when the groove cam 302 rotates, the connecting rod assembly 310 is driven to rotate along the shaft seat C301 by sliding in the cam-shaped groove of the sliding block 311, the connecting rod assembly 310 is driven to push upwards along the X-shaped groove barrel 308 when the connecting rod assembly 310 rotates, the time for pushing the top end is consistent with the time for the optical axis to drive the X-shaped groove drum 308 to rotate 180 degrees, namely, when the groove cam 302 rotates to 0-180 degrees, the supporting upright post 309 rotates clockwise to push upwards, when the groove cam 302 rotates to 180-360 degrees, the supporting upright post 309 rotates anticlockwise and retracts downwards, so that the balance capacity of a student is circularly tested, the tested student completes the test of the balance capacity under the full supervision of peripheral staff, test data is comprehensively evaluated by the on-site screen recording and the degree of outward stretching of limbs, the most main evaluation data is the accumulated rotation degree of the tested student straddling on the supporting chuck 312, the degree record is mapped by the sensor A107 and the sensor B108, and the core capacity and the balance capacity of the student are comprehensively evaluated by combining whether the lower limbs move during retest of the student and the movement range and frequency and the like.

The health sports building monitoring equipment has the beneficial effects that:

the health sports building monitoring equipment has the beneficial effects that: 1. 2 testers can be tested for horizontal balance capacity at the same time, so that comprehensive evaluation of body coordination and lower limb stability of the testers is realized; 2. the test interest is increased through the manual combination type driving, and the structure has the rotating speed protection property.

Drawings

The invention will be described in further detail with reference to the accompanying drawings and detailed description.

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

FIG. 2 is a schematic diagram of the overall structure of the present invention;

FIG. 3 is a schematic view of a frame structure of the present invention;

FIG. 4 is a schematic diagram of a rack structure of the present invention;

FIG. 5 is a schematic diagram of a driving apparatus according to the present invention;

FIG. 6 is a schematic diagram of a driving apparatus according to a second embodiment of the present invention;

FIG. 7 is a schematic diagram of a driving apparatus according to the third embodiment of the present invention;

FIG. 8 is a schematic diagram of a driving apparatus according to the present invention;

FIG. 9 is a schematic diagram of a first horizontal testing apparatus according to the present invention;

FIG. 10 is a schematic diagram of a first horizontal testing apparatus according to the present invention;

in the figure: a frame 1; a frame 101; a panel a102; a panel B103; top plate a104; a handle 105; axle seat a106; sensor a107; sensor B108; a driving device 2; sleeve a201; connecting rod a202; arc rack a203; connecting rod B204; connecting rod C205; a connecting rod D206; arc rack B207; a connecting rod E208; a link F209; a connecting rod G210; arc rack C211; a connecting rod H212; connecting rod I213; sleeve B214; axis a215; toothed ring assembly a216; connecting a chuck A217; a three-way eccentric 218; gear a219; gear B220; gear C221; connect chuck B222; toothed ring a223; a connecting cylinder 224; a stop collar 225; dual gear connection assembly a226; double gear connection assembly B227; dual gear connection assembly C228; dual gear connection assembly D229; a dual gear connection assembly E230; gear D231; axle seat B232; an axis B233; pulley a234; a belt 235; pulley B236; a first horizontal testing device 3; axle seat C301; a grooved cam 302; a flange 303; an optical axis a304; an optical axis B305; arc link a306; arc-shaped link B307; an X-shaped grooved drum 308; support posts 309; a linkage assembly 310; a slider 311; a support chuck 312; sensor C313; a second level testing device 4.

DETAILED DESCRIPTION OF EMBODIMENT (S) OF INVENTION

The invention is described in further detail below with reference to the accompanying drawings.

First embodiment:

the following describes the present embodiment with reference to fig. 1 to 10, a health sports building monitoring device includes a frame 1, a driving device 2, a first horizontal testing device 3, and a second horizontal testing device 4, where the driving device 2, the first horizontal testing device 3, and the second horizontal testing device 4 are all connected with the frame 1, and the driving device 2 is connected with the first horizontal testing device 3 and the second horizontal testing device 4.

Specific embodiment II:

in the following, the present embodiment will be further described with reference to fig. 1-10, where the operation principle of the rack 1 is that the comprehensive carriers of the embodiment 3, the embodiment 4, and the embodiment 5 form a reasonable and effective layout.

Third embodiment:

in the following description of the embodiment with reference to fig. 1-10, the driving device 2 further illustrates the operation principle of the embodiment, in which, under the guidance of related staff, the connecting rod C205, the connecting rod F209 and the connecting rod I213 are sequentially lifted upwards, when the connecting rod C205 is lifted, the shaft sleeve a201 is driven to slide upwards along the axis a215 by the connecting rod B204, when the connecting rod F209 is lifted, the shaft sleeve a201 is driven to slide upwards along the axis a215 by the connecting rod E208, when the connecting rod I213 is lifted, the shaft sleeve a201 is driven to slide upwards along the axis a215 by the connecting rod H212, wherein, when any one of the connecting rod C205, the connecting rod F209 and the connecting rod I213 is lifted upwards, the other two parts can be simultaneously driven to work, the three parts are in an integrated design, when the shaft sleeve a201 slides upwards, the arc-shaped rack a203, the arc-shaped rack B207 and the arc-shaped rack C211 are respectively driven to expand outwards by the connecting rod a202, the connecting rod D206 and the connecting rod G210, when the arc racks A203, B207 and C211 are meshed with the inner wall of the toothed ring assembly A216, the shaft sleeve A201 slides upwards to be in contact with the shaft sleeve B214, the shaft sleeve B214 forms an upper limit of the height, then students hold the connecting rod C205, the connecting rod F209 and the connecting rod I213 respectively and rotate clockwise, the arc racks A203, B207 and C211 drive the toothed ring assembly A216 to rotate, the toothed ring assembly A216 drives the connecting chuck A217 to rotate, so that when the connecting chuck A217 rotates, the three-way eccentric wheel 218 drives the gears A219, B220 and C221 to rotate along the toothed ring A223 respectively due to the eccentricity, and when the connecting chuck A222 rotates, the connecting chuck B222 drives the toothed ring A223 to rotate to form a cycloid speed reduction effect, the front end rotating rod C205 of students, the force of the connecting rod F209 and the force of the connecting rod I213 are reduced firstly, the connecting cylinder 224 is driven to rotate when the toothed ring A223 rotates, the connecting cylinder 224 rotates to drive the double-gear connecting assembly A226 to rotate, the double-gear connecting assembly A226 drives the double-gear connecting assembly B227 to rotate, the double-gear connecting assembly B227 drives the double-gear connecting assembly C228 to rotate, the double-gear connecting assembly C228 drives the double-gear connecting assembly D229 to rotate, the double-gear connecting assembly D229 drives the double-gear connecting assembly E230 to rotate, the double-gear connecting assembly A226, the double-gear connecting assembly B227, the double-gear connecting assembly C228, the double-gear connecting assembly D229 and the double-gear connecting assembly E230 are all in a large-gear and small-gear combined structure, the continuous speed increasing mechanism between the small gears and the large gears is combined with the front speed reducing mechanism, the original driving effect is changed, the purpose is to synthesize the integral rotating mechanism, students with slightly laborious front end rotating rotate the connecting rod C205, the connecting rod F209 and the connecting rod I213, the output of the rear gear D231 rotates smoothly, the gear D231 drives the shaft B231 to rotate, and the belt pulley B233 drives the pulley A234 to rotate smoothly, and the pulley B234 rotates smoothly.

Fourth embodiment:

in the following description of the embodiment with reference to fig. 1-10, the operation principle of the first horizontal testing device 3 is that, when the pulley B236 rotates, the groove cam 302 in the first horizontal testing device 3 is driven to rotate, the groove cam 302 drives the flange 303 to rotate, the flange 303 drives the optical axis a304, the optical axis B305, the arc-shaped connecting rod a306 and the arc-shaped connecting rod B307 to rotate, when the optical axis a304 or the optical axis B305 rotates along the flange 303, the shaft end of the optical axis corresponds to the spiral groove of the X-shaped groove drum 308, the optical axis continuously rotates, the shaft end slides along the groove in the X-shaped groove drum 308, the X-shaped groove drum 308 is driven to rotate, the supporting upright post 309 is driven to rotate when the X-shaped groove drum 308 rotates, the rotation angle is 180 °, when the groove cam 302 rotates, the sliding block 311 slides along the cam-shaped groove of the self, the connecting rod assembly 310 is driven to rotate along the shaft seat C301, the time when the connecting rod assembly 310 rotates, the supporting upright post 309 is driven to push upwards along the X-shaped groove drum 308, the time of pushing the optical axis is consistent with the time when the optical axis a 180 ° of driving the X-shaped groove drum 308 to rotate 180 °, and the upright post is driven to rotate clockwise when the cam 302 rotates to rotate to the clockwise, and the supporting upright post to rotate to the upright to 180 ° to rotate to the clockwise, and the supporting upright post to rotate to the upright to rotate 309 when the supporting cam to rotate to the clockwise, and rotate to the upright to rotate to the supporting upright, and to rotate 309, and to rotate clockwise, and to rotate to support 309.

Fifth embodiment:

in the following description of the present embodiment with reference to fig. 1 to 10, the operation principle of the second horizontal testing device 4 is that the components contained in the second horizontal testing device are the same as those of the first horizontal testing device 3, the assembly mode and the sequence of the second horizontal testing device are the same as those of the first horizontal testing device 3, and the operation sequence and the implementation function of the second horizontal testing device are the same as those of the first horizontal testing device 3.

Claims (6)

1. A healthy sports building monitoring device, characterized by: the device comprises a frame (1), a driving device (2), a first horizontal testing device (3) and a second horizontal testing device (4), wherein the driving device (2), the first horizontal testing device (3) and the second horizontal testing device (4) are connected with the frame (1), and the driving device (2) is connected with the first horizontal testing device (3) and the second horizontal testing device (4).

2. A healthy sports building monitoring device according to claim 1, wherein: the rack (1) comprises a frame (101), a sensor A (107) and a sensor B (108), wherein the panel A (102), the panel B (103), the top plate A (104), the handle (105), the shaft seat A (106), the sensor A (107) and the sensor B (108) are fixedly connected with the frame (101).

3. A healthy sports building monitoring device according to claim 1, wherein: the driving device (2) comprises a connecting rod A (202), a shaft sleeve B (214), a shaft A (215), a toothed ring assembly A (216), a connecting chuck A (217), a tee eccentric wheel (218), a gear A (219), a gear B (220), a gear C (221), a connecting chuck B (222), a double-gear connecting assembly A (226), a double-gear connecting assembly B (227), a double-gear connecting assembly C (228), a double-gear connecting assembly D (229) and a double-gear connecting assembly E (230) and a gear D (231), wherein the connecting rod A (202), the connecting rod B (204), the connecting rod D (206) and the connecting rod E (208) are all in rotary connection with the shaft sleeve A (201), the connecting rod A (202) is in rotary connection with an arc-shaped rack A (203), the connecting rod D (206) is in rotary connection with the arc-shaped rack B (207), the connecting rod G (210) is in rotary connection with the arc-shaped rack C (211), the connecting rod B (204), the connecting rod E (208) and the connecting rod H (212) are respectively in rotary connection with the shaft sleeve B (214) through the connecting rod C (205), the connecting rod F (213) and the shaft sleeve A (214), the shaft sleeve A (214) and the toothed ring assembly A (216) are all in rotary connection, tooth ring assembly A (216) is fixedly connected with connecting chuck A (217), connecting chuck A (217) is fixedly connected with tee bend eccentric wheel (218), gear A (219), gear B (220), gear C (221) are all in meshed connection with tooth ring A (223), connecting chuck B (222) is connected with gear A (219), gear B (220), gear C (221), connecting chuck B (222) is in rotary connection with tooth ring A (223), tooth ring A (223) is in fixed connection with connecting cylinder (224), connecting cylinder (224) is in rotary connection with stop collar (225), connecting cylinder (224) is in fixed connection with double-gear connecting assembly A (226), double-gear connecting assembly A (226) is in meshed connection with double-gear connecting assembly B (227), double-gear connecting assembly B (227) is in meshed connection with double-gear connecting assembly C (228), double-gear connecting assembly C (228) is in meshed connection with double-gear connecting assembly D (226), double-gear assembly D (230) is in meshed connection with double-gear assembly E (230), double-gear assembly E (230) is in meshed connection with double-gear assembly E (230) The double-gear connecting assembly C (228), the double-gear connecting assembly D (229), the double-gear connecting assembly E (230) and the gear D (231) are rotationally connected with the shaft seat B (232), the gear D (231) and the belt wheel A (234) are fixedly connected with the shaft B (233), and the belt wheel A (234) is rotationally connected with the belt wheel B (236) through a belt (235).

4. A healthy sports building monitoring device according to claim 1, wherein: the first horizontal testing device (3) comprises a shaft seat C (301), a groove cam (302), an X-shaped groove cylinder (308), a support chuck (312) and a sensor C (313), wherein the groove cam (302), the X-shaped groove cylinder (308) and a connecting rod assembly (310) are all rotationally connected with the shaft seat C (301), the groove cam (302) is fixedly connected with a flange (303), an optical axis A (304), an optical axis B (305), an arc-shaped connecting rod A (306) and an arc-shaped connecting rod B (307) are all fixedly connected with the flange (303), the optical axis A (304), the optical axis B (305), the arc-shaped connecting rod A (306) and the arc-shaped connecting rod B (307) are all connected with the X-shaped groove cylinder (308), the X-shaped groove cylinder (308) is connected with a support column (309), the support column (309) is rotationally connected with the connecting rod assembly (310), the connecting rod assembly (310) is fixedly connected with the groove cam (302) through a sliding block (311), the support column (309) is fixedly connected with the support chuck (312), and the support chuck (312) is fixedly connected with the sensor C (313).

5. A healthy sports building monitoring device according to claim 1, wherein: the components contained in the second horizontal testing device (4) are the same as those in the first horizontal testing device (3), the assembly mode and the sequence of the second horizontal testing device are the same as those in the first horizontal testing device (3), and the operation sequence and the implementation function of the second horizontal testing device are the same as those in the first horizontal testing device (3).

6. The physical examination method of students, realize through a kind of health sports building monitoring equipment in the above claims 1-5 specifically, can implement the horizontal balance ability test to 2 testers at the same time, realize the comprehensive assessment to tester's physical harmony and low limbs stability, increase the test interest through the drive of the manual combination form, and the structure possesses the rotational speed protection property, include the following steps:

s1, lifting a rack (1) to a test place through handles (105) at four corners, wherein the first horizontal testing device (3) and the second horizontal testing device (4) are the same in assembly mode and sequence and have the same operation sequence and function, so the first horizontal testing device (3) is taken as an example for illustration, a test student stands in a supporting chuck (312), legs straddle and shoulders are wider, two arms are opened outwards naturally, then the rest students sequentially lift a connecting rod C (205), a connecting rod F (209) and a connecting rod I (213) upwards under the guidance of related staff, the structural design is a cooperative driving mode, the aim is to increase the interest of using the device through the curiosity of the student, increase the coordination between the students through a driving mode of cluster cooperation, the connecting rod C (205) drives a shaft sleeve A (201) to slide upwards along a shaft A (215) during lifting, the connecting rod F (209) drives the shaft sleeve A (201) to slide upwards along the shaft A (215) through a connecting rod E (208) during lifting, the connecting rod F (213) drives the connecting rod C (205) to slide upwards along the shaft A (215), the rest of the connecting rod F (213) can slide upwards through the connecting rod F (213) simultaneously, the rest of the connecting rod C (213) can be designed to slide upwards, and the rest parts (213) can be simultaneously and all parts (213) are upwards and upwards, the shaft sleeve A (201) drives the arc racks A (203), B (207) and C (211) to expand outwards through the connecting rod A (202), the connecting rod D (206) and the connecting rod G (210) respectively when sliding upwards until the arc racks A (202), the connecting rod D (206) and the connecting rod G (210) are completely meshed with the toothed ring assembly A (216), the connecting rod C (205), the connecting rod F (209) and the connecting rod I (213) are stopped to be lifted, when the arc racks A (203), B (207), C (211) and the connecting chuck A (216) are meshed with the toothed ring on the inner wall of the toothed ring assembly A (216), the shaft sleeve A (201) slides upwards to be contacted with the shaft sleeve B (214), the shaft sleeve B (214) forms an upper limit of a height, then students hold the connecting rod C (205), the connecting rod F (209) and the connecting rod I (213) respectively, and rotate clockwise, the arc racks A (203), the arc racks B (207) and the arc racks C (211) drive the toothed ring assembly A (216) to rotate, and the connecting chuck A (217) to rotate, so that the connecting chuck A (217) is driven to rotate, and the eccentric gear (218) is prevented from rotating, and the eccentric gear (218) is driven by the eccentric gear (218) to rotate respectively, and the eccentric gear (220) is driven by the eccentric gear (218) to rotate respectively, and the eccentric gear (218) is driven by test reasons of eccentric mechanism (219) and test respectively The gear C (221) is meshed with the toothed ring A (223) to rotate, the toothed ring A (223) is driven to rotate through the connecting chuck B (222) during rotation, a cycloid speed reducing effect is formed, the force of a front-end rotating rod C (205), a connecting rod F (209) and a connecting rod I (213) of students is reduced, the students under test are protected from the source, the rotating difficulty of the students can be increased by considering one-taste speed reduction, the final rotating speed of the students can be enabled to be within a standard and safe test range, the final rotating speed of the students is increased to a certain extent through a differential speed increasing mechanism, double guarantee of driving safety and personnel safety is finally formed, the connecting cylinder A (224) is driven to rotate during rotation of the toothed ring A (223), the connecting cylinder (224) drives the double-gear connecting assembly A (226) to rotate, the double-gear connecting assembly A (226) is driven to rotate, the double-gear connecting assembly B (227) drives the double-gear connecting assembly C (228) to rotate, the double-gear connecting assembly C (228) is driven to rotate, the double-gear connecting assembly C (229) drives the double-gear connecting assembly D (229) to rotate, and the double-gear connecting assembly E (230) drives the double-gear connecting assembly D (226) to rotate, and the double-gear assembly E (226) to rotate, and the double-gear assembly (226) to drive the double-gear connecting assembly (230) to rotate, and the double-gear assembly (226) to rotate The double-gear connecting assembly E (230) is of a combined structure of a large gear and a small gear, the original driving effect is changed by continuously increasing the speed between the small gear and the large gear and combining with a front speed reducing mechanism, the aim is to synthesize an integral rotating mechanism, the front end rotating students slightly laborious to rotate a connecting rod C (205), a connecting rod F (209) and a connecting rod I (213), the output of a rear gear D (231) is smoother, the combined design is to prevent the students from excessively laborious or excessively relaxed realization of balance force test of the students, ensure that the testers and operators can be stably controlled through the combined mechanism, the gear D (231) drives a shaft B (233) to rotate when rotating, the shaft B (233) drives a belt wheel A (234) to rotate, and the belt wheel A (234) drives the belt wheel B (236) to rotate through a belt (235);

s2, when the belt wheel B (236) rotates, the groove cam (302) in the first horizontal testing device (3) is driven to rotate, the groove cam (302) drives the flange (303) to rotate, the flange (303) drives the optical axis A (304), the optical axis B (305), the arc-shaped connecting rod A (306) and the arc-shaped connecting rod B (307) to rotate, when the optical axis A (304) or the optical axis B (305) rotates along the flange (303), the shaft end of the optical axis corresponds to a spiral groove of the X-shaped groove barrel (308), the optical axis continuously rotates, the shaft end slides along the groove in the X-shaped groove barrel (308) to drive the X-shaped groove barrel (308) to rotate, the X-shaped groove barrel (308) rotates, the supporting upright post (309) is driven to rotate when the groove cam (302) rotates, the rotation angle is 180 DEG, the connecting rod assembly (310) is driven to push upwards through sliding in the cam-shaped groove of the sliding block (311) along the self, when the groove cam (302) rotates, the time of pushing upwards is 180 DEG, the supporting upright post (308) is driven to rotate clockwise, and the supporting upright post (180 DEG is driven to rotate when the groove (308) is rotated 180 DEG to rotate clockwise when the groove (180 DEG is pushed upwards, the method is characterized in that the balance capacity of the students is circularly tested, the tested students finish the balance capacity test under the full supervision of surrounding staff, test data are comprehensively evaluated by means of on-site screen recording and the degree of outward extension of limbs, the most main evaluation data are accumulated rotation of the tested students on a supporting chuck (312), degree records are mapped by a sensor A (107) and a sensor B (108), and the core capacity and the balance capacity of the students are comprehensively evaluated by combining whether lower limbs move, the movement range and the frequency and the like during retest of the students based on the balance capacity.