WO2020116956A1 - Dynamic balancer control system - Google Patents

Abstract

The present invention includes: a dynamic balancer which measures body balancing ability; and a terminal which receives measured body balancing ability data from the dynamic balancer and outputs the received body balancing ability data as a graphic image, wherein the terminal provides a user with at least one function among a dynamic balancer usage guiding function, an SNS linking function, and a usage result checking function.

Description

Dynamic balancer control system

The present invention relates to a dynamic balancer control system, and more specifically, to establish body-specific standardized data related to health management through measurement of body balance ability (exercise evaluation) and body mass index (BMI) in various postures. It relates to a dynamic balancer that enables the collection of specific information about the body type required for measurement.

According to a survey by the Korea Employment Agency for the Disabled at the end of December 2016, the number of registered disabled people in Korea was 2,511,051 as of December 2016. This is an increase of about 162.1% from 958,000 at the end of December 2000, and is increasing at an annual average of 10.1% due to the influx of new disabled people and aging population. In particular, rather than congenital disorders, those with a disability who cannot live a normal daily life due to accidents or various diseases are rapidly increasing to account for 90% of the disabled. Among those with acquired disabilities, most cases of disability due to diseases such as traffic accidents, industrial accidents, diabetes, high blood pressure, or stroke, and unlike physical disability mainly caused by accidents after their 20s, brain lesions have occurred Is frequently caused by Here, one of the most common sequelae due to stroke or other brain damage is hemiplegia symptoms, and people with hemiplegia disorders are limited in their daily lives due to sudden impairment as well as deterioration or loss of physical function. This can cause additional problems. For example, fall due to communication problems such as lack of understanding or recognition by fall, need for physical assistance and judgment errors, inability to perceive danger, inability to perceive the dangerous environment, and overestimation of one's safety ability against movement, loss of language The risk for increases. As such, the community environment to which they belong acts as a factor that threatens the body's ability to balance, such as unexpected work, improper handling due to errors in judgment or inability to recognize obstacles, or beyond the limits of balance and performance. In order to re-acquire functional movement performance according to and to learn to maintain the balance of body segments, intensive and diverse body balance training and education should always be an important rehabilitation goal. On the other hand, modern people now take the same position for a long time, such as sitting at a desk for a long time or driving. As such, if the incorrect posture persists for a long time when the same posture is taken for a long time, a fatal imbalance appears in the human body, and such a body imbalance is bound to adversely affect the daily life of modern people. In addition, if the ability to maintain balance is reduced due to the imbalance of the body, there is a risk of falling. In addition, since the human body affects each other organically, if any body part is abnormally developed or poor, it may affect other body parts. Therefore, it is necessary to develop the ability to maintain balance in order to maintain a normal and safe life. In this regard, through Korean Patent Registration No. 10-1668428, a dynamic balancer capable of measuring a user's balance maintaining ability in various postures and having a sensor for more accurate measurement has been disclosed. The dynamic balancer includes a central footrest unit composed of a pressure sensor and a foot support; A first footrest part having a guideline and a pressure sensor in front of the center footrest part; A second footrest part and a third footrest part having a guideline and a pressure sensor at the rear of the center footrest part; Consists of; a control unit for electrically connecting the first to third scaffolding. Accordingly, the first footrest of the first footrest, the second footrest of the second footrest, and the fourth footrest of the third footrest are pushed as much as possible by using one foot while the measurement target is on the central footrest. My body measures the body's balance-keeping ability based on the balance-keeping ability in various postures. However, the first to third guide lines of the first to third foot portions in the form of elongated bars toward the left and right rear portions of the center foot portion are simply directed toward the left and right rear portions of the center foot portion, and the direction It cannot be adjusted. For this reason, it is only necessary to measure the ability to maintain body balance in a limited posture, and it is difficult to measure the customized body balance ability of people with different body structures for each body type and constitution, so there is great room for improvement in terms of the accuracy of measurement data analysis. . In addition, structurally, technology implementation that maximizes space utilization through volume reduction has not been achieved, so storage and movement of the corresponding equipment is not easy when not in use.

[Advanced technical literature]

[Patent Document]

KR 10-1668428 B1

The object of the present invention is to solve the above-mentioned problems, and a body mass index measurement module is provided on a stepping board where a person to be measured stands on one foot to measure weight and weight movement using various sensors. The aim is to provide a dynamic balancer that enables more precise measurement of body balance maintenance ability through customized exercise evaluation for each measurement target. Another object of the present invention, the guide bar (second guide bar) extended to the left and right side rear of the stepping plate is made of a rotational folding structure, the rotational folding toward the guide bar (first guide bar) extended forward of the stepping plate It is to provide a dynamic balancer that improves storage (spatial utilization) and mobility (convenience) when the equipment is not in use by keeping them in close contact with each other and maintaining mutual contact through restraint of the guide bars using a plurality of movable plates.

In order to achieve the above object, the present invention, a dynamic balancer for measuring body balance ability; And a terminal that receives the measured body balance ability data from the dynamic balancer and outputs the received body balance ability data as a graphic image, wherein the terminal uses the dynamic balancer usage guide function, SNS interworking function, and checks the result of use. Provide at least one of the functions to the user. At this time, the dynamic balancer usage guide function provided by the terminal may output at least one content of a video, an image, and a text message that guides how to use the dynamic balancer as a graphic image. In addition, the method of using the dynamic balancer includes a method for measuring the length of the leg, and the content for guiding the method for measuring the length of the leg includes a column for inputting a length of the leg, a video for measuring the length of the leg, and a text message explaining the process of measuring the die length. May be included. In addition, in order to provide a function for confirming the result of the use of the dynamic balancer, the terminal is interlocked with the dynamic balancer through short-range wireless communication, the user receives usage information using the dynamic balancer, and the body is based on the dynamic balancer usage information. A record of balance ability can be calculated, and the calculated body balance ability record can be output as a graphic image. In addition, the terminal may collect the records of the body balance ability, calculate it as daily, weekly, and monthly records, and provide the calculated daily, weekly, and monthly records. In addition, the terminal may provide a workout fitness function that provides a target amount of use of the dynamic balancer, receives the usage information of the dynamic balancer, and determines and outputs whether the target amount of use is reached. In addition, the terminal may continuously monitor and accumulate the usage information of the dynamic balancer, calculate the body balance ability record, and determine and output whether the body balance ability is improved. In addition, the terminal may provide a dynamic sharing function in which a sharing amount is accumulated based on the usage amount of the dynamic balancer and a donation of the accumulated amount is made for social contribution. In addition, the dynamic balancer is a stepping step that allows a person who wants to measure the body balance ability to stand on one foot and a stepped stepping step, and in the state of stepping on the stepping step, the other foot is pushed forward. One first guide bar extended in front of the stepping board, and in the state of stepping on the stepping board, the other foot is extended diagonally to the left and right sides of the stepping board to take a posture with the other foot sideways. A plurality of extended second guide bars, a first movable mill plate provided on the first guide bar, and a stepped-up step plate so that a measurement target standing on the stepped plate can push one foot forward and push it out The second measurement bar may include a plurality of second movable mill plates which are assembled to each of the second guide bars so that the target of the line measurement can push one foot toward the rear side. In addition, the dynamic balancer, the stepping plate, has a length and width suitable for placing one foot of the measurement target, the first and second guide bar to insert the tip and form a thickness capable of embedding the measurement module, At the front end in the longitudinal direction, an insertion space is formed through which one end of the first guide bar can be fitted and engaged, and the left and right sides of the insertion space are fitted with hinge fittings at one end of each of the second guide bars. And a plurality of rotation spaces providing a rotational range in the hinged state, the hinge coupling of the second guide bars and the rotational movement to the hinged state, by means of a hinge formed vertically in the rotational space. It may be possible.

The dynamic balancer control system according to the present invention can easily measure a user's body balance ability through a dynamic balancer, and at this time, various functions that help or encourage the use of the dynamic balancer by interlocking the dynamic balancer with a terminal are effectively used. Can provide. And the dynamic balancer of the present invention, through the provision of a body mass index measurement module in the stepping plate, the effect of knowing clearly how to measure the current body balance ability of the measurement target and develop a lack of body parts based on this, also The amount of muscles related to body type and constitution by quantifying the correlation between balance and body mass index, and the effect that can measure the exact body type and constitution of the measurement subject and measure the appropriate body balance ability based on the data In the area of body and body control, you can expect the effect of effective equipment implementation to manage both management contents, problem analysis, and solutions. In addition, it is possible to reduce the volume of the equipment according to the rotational folding of the second guide bars extending to the left and right sides of the stepping plate, thereby exhibiting the effect of maximizing space utilization and convenience of movement when the equipment is not in use. At the same time, the evaluator records the measured value on the evaluation sheet, displays the corresponding level of balance ability on the graph, and observes the balance ability performed by the measurement target on the analog measurement equipment by the evaluator, and checks each distance It is not a method of recording and recording, but it can be evaluated by one person to be measured, and the data can be recorded and stored and the management system of the measurement results of the performance results can be checked in real time with an automated system. Also, Bluetooth, Wi-Fi, etc. The effect of transmitting data to a smart phone or a portable recording device through the grafting of the wireless transmission system, so that the central change of body weight can be closely measured based on the precise movement distance measurement of the moving plate using a sensor In the process of measuring the physical balance maintenance ability, it is possible to perform a clear exercise evaluation as it becomes possible, and provides appropriate exercise prescriptions to improve the balance maintenance ability based on the measurement results. As a leader in healthcare equipment that provides convergence measurement, analysis, and rehabilitation for each body structure of a measurement vehicle, along with measurement, diagnosis, and inspection of body balance maintaining ability, such as being able to increase convenience and accuracy, it deteriorates into a disability. It is a very useful invention that can greatly contribute to the development and activation of the related medical industry and related medical technologies, as well as medical effects such as greatly assisting in improving the body balance ability.

1 and 2 are a perspective view and a plan view showing a configuration structure of a dynamic balancer according to the present invention.

3 is an enlarged view of main parts showing a configuration relationship between a stepping plate and a plurality of guide bars and a rotational relationship between first and second guide bars in the dynamic balancer according to the present invention.

Figure 4 (a) (b) is a working example showing the folded state of the guide bar in the dynamic balancer according to the present invention.

5A and 5B are main part perspective views showing various configuration relationships of the moving platen in the dynamic balancer according to the present invention.

6 is in the dynamic balancer according to the present invention, a plurality using a moving mill

This is an example of action showing the restraint of the guide bar.

7 to 8f is an example of use showing the measurement relationship of the body balance ability using a dynamic balancer according to the present invention.

9 is an exemplary view showing a relationship of use of the body mass index measurement module in the dynamic balancer according to the present invention.

10 is an exemplary view showing a communication pattern between a dynamic balancer and a smart terminal according to the present invention.

11 is an exemplary view showing an implementation guide of a specific posture by an indicator in the dynamic balancer according to the present invention.

12 is an internal block diagram of a terminal according to the present invention.

13 is a flowchart illustrating a control method of a terminal interworking with a dynamic balancer according to an embodiment of the present invention.

14 is a dynamic balancer application launcher execution screen according to an embodiment of the present invention.

15 is a dynamic balancer service member registration screen according to an embodiment of the present invention.

16 is a screen for providing information on the use of a dynamic balancer according to an embodiment of the present invention.

17 shows a data synchronization screen according to an embodiment of the present invention.

18 shows a state in which a dynamic balancer and a terminal according to an embodiment of the present invention are connected through wireless communication.

19 is a screen displaying a balance capability value calculated based on the dynamic balancer usage information according to an embodiment of the present invention.

20 is a screen displaying a balance capability value calculated based on the use information of a dynamic balancer according to an embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art to which the present invention pertains can easily implement the present invention. First, it should be noted that in adding reference numerals to the components of the drawings, the same components have the same reference numerals as possible even though they are displayed on different drawings. In addition, in describing the present invention, when it is determined that detailed descriptions of related well-known structures or functions may obscure the subject matter of the present invention, detailed descriptions thereof will be omitted. 1 and 2 of the accompanying drawings are a perspective view and a plan view showing a structural structure of a dynamic balancer according to the present invention, and FIG. 3 is a structural relationship between a stepping plate and a plurality of guide bars and a first and second in the dynamic balancer according to the present invention Fig. 4(a)(b) is an exemplary view showing the folded state of the guide bar in the dynamic balancer according to the present invention, and Figs. 5a and 5b show the present invention. Fig. 6 is a perspective view showing various components of the moving platen in the dynamic balancer according to the present invention, and Fig. 6 is a working example showing a restraining state of a plurality of guide bars using the moving platen in the dynamic balancer according to the present invention. Is an example of use showing the measurement relationship of the body balance ability using the dynamic balancer according to the present invention, Figure 9 is an exemplary view showing the relationship of use of the body mass index measurement module in the dynamic balancer according to the present invention, Figure 10 is An exemplary view showing a communication pattern between a dynamic balancer and a smart terminal according to the present invention, and FIG. 11 is an exemplary view showing an implementation guide of a specific posture by an indicator in the dynamic balancer according to the present invention. 1 and 2, the dynamic balancer (A) according to the present invention, the stepping step (1), and the stepping step, which allows a person who wants to measure the body balance ability to stand on one foot and stand up (1) One step guide bar (2) extended in front of the stepping foot (1) so as to take a posture of pushing the other foot forward while standing on top of the stepped foot (1) A plurality of second guide bars (3) (3') and the stepping plate (1), which are each extended diagonally to the left and right sides of the stepping foot so as to take a posture of extending the other foot sideways in the state, and push backward The first moving mill plate (4) assembled on the first guide bar (2) and the measurement target stepped up on the stepping plate (1) so that the subject to climb on and push out one foot forward and push it out It is configured to include a plurality of second moving mill plate (5) (5') that is assembled to each of the second guide bar (3) (3') to be able to push out one foot to the rear side. Stepping board (1) is a body mass index (BMI), along with the acquisition of weight transfer information when the subject to be measured is taking a certain posture to measure the body balance ability while being a stepping-up on one foot. ) Personalized body balance maintenance ability for each subject through simultaneous acquisition of information As a means of acquiring information for precise measurement of the valuation of exercise, it has an appropriate length and width to place one foot of the subject, It is preferable that the first and second guide bars 2, 3, 3'form a thickness capable of inserting the tip and embedding the measurement module. To this end, as illustrated in FIG. 3, at the longitudinal front end, an insertion space 10-1 is formed in which one end of the first guide bar 2 can be fitted and engaged. In addition, the left and right sides of the insertion space (10-1), the second guide bar (3) (3'), a plurality of fitting hinge hinges at one end of each side, and a plurality of rotational ranges in the hinged state are provided. A rotation space 10-2 is provided. This minimizes the overall volume of the equipment through the rotational folding of the second guide bar (3) (3') to each side of the first guide bar (2) when the equipment is not in use, thereby storing and moving the equipment. This is to facilitate. Here, the hinge coupling of the second guide bar (3) (3') and the rotational movement to the hinge coupling state, the hinge portion (10-) formed vertically (up and down) in the rotation space (10-2) 21). In addition, a position image 11 for positioning is printed (or imprinted) on the upper surface so that the measurement target can accurately place his stepping feet on the correct position, and specific posture is performed on other parts of the upper surface. A guiding indicator 12 is provided. In addition, the body mass index measurement module 13, the indicator 12 and the pressure sensor required for the above-described body mass index (BMI) measurement, including a pressure sensor (not shown) for detecting the weight and weight movement of the subject to be measured, and A microcomputer (not shown) for driving the body mass index measuring module 13 and executing a preset program is incorporated. The indicator 12 is a light emitting diode (LED) that produces a small number of carriers (electrons or holes) injected using a pn junction structure of a semiconductor and emits light by recombination of them, to be measured. For stepping step (1) to step up on one foot and in one state in order to induce the posture practice of selectively pushing the first and second movable mills (4) (5) (5') Consists of a total of four bars, one stepped light emitting diode for induction of stepping plate (1) stepping is placed in the center, and the first and second guide bars (2) (3) and (3') are advanced. Three light emitting diodes are arranged in proximity to each predetermined position along the direction. The pressure sensor is a strain gauge type, and it is preferable to use one that senses that the electrical resistance changes when the sensor deforms due to pressure, but this is only one embodiment and various embodiments It is possible. The microcomputer controls each electronic module based on a preset program, and it is preferable to add a main memory, peripheral circuits, interfaces with input/output devices, etc., using a microprocessor as a central element, but this also It is only one embodiment and various embodiments are possible. The first guide bar (2) and the second guide bar (3) (3'), the first and second movable mill plate (4) (5) (5) in a state standing on the stepping foot (1) with one foot ') It is a means for guiding specific posture and straightening the movement of each of the first and second movable plates (4)(5)(5') so that they can be pushed to the front or the left and right sides with the other foot as much as possible. , When the measurement target is raised on the stepping plate 1, either one of the first moving mill plate 4 or the second moving foot plate 5, 5'is pushed as much as possible using one foot. It is preferable that the first and second moving feet 4, 5, 5'of the square pipe having a length suitable for position movement and smooth movement. On the other hand, as shown in Figure 4 (a) (b), the first and second guide bars (2) (3) (3'), the main bar 21, which is connected to the stepping plate (1) ( 31), the main bar (21) (31) can be divided into a folding bar (21-1) (31-1) (31-1') from the outer end, and the main bar (21) (31) The foldable bars 21-1 and 31-1 can achieve a structure in which one-sided folding is possible by a hinge member (hinged / not shown) at the part where they are mutually joined. This is to maximize the space utilization by reducing the length of the first and second guide bars (2), (3) and (3') when the equipment is not used as described above. In addition, at the outer ends of the first and second guide bars 2, 3 and 3', finishing shoes 22 and 32 for maintaining a horizontal state with the ground are provided along with the ends of the corresponding ends. Can be combined. The first movable tread plate 4 and the second movable tread plate 5, 5', the body balance in the process of stepping on the stepping plate 1 with one foot and maximally pushing the other to the other foot As a means of performing posture for grasping how much can be pushed out while maintaining the, as shown in FIGS. 5A to 6, the left and right are wide while the front and rear widths are relatively narrow and the upper and lower widths are slim. It is desirable to form one block. In addition, when the equipment is used, the first and second guide bars (2), (3) and (3') for inserting the first through holes (41, 51) are formed to penetrate the center part before and after, and when the equipment is not in use The first guide bar (2) and three second through holes (42) for maintaining mutual contact through the simultaneous penetration of the second guide bars (3) (3') that are folded and folded to both sides thereof ) 52 is formed through and arranged on the side surface so as to cross the first through hole (41, 51). At the same time, the rear side end portion facing the stepping plate 1 is provided with detectors 43 and 53 for grasping the movement distance as much as the target is pushed with the foot. As shown in Fig. 5a, a distance sensor (distant sensor, 431) 531 that detects a distance by measuring the time until the reflected wave from the object is received by transmitting ultrasonic waves with sharp directivity to the object It is preferred. In addition, as shown in Figure 5b, the first and second guide bars (2) (3) (3') wheel sensor that can grasp the moving distance by calculating the number of revolutions when moving along the longitudinal direction (wheel sensor, 432) (532). However, the present invention is not necessarily limited to this, and it is possible to employ any number of other methods as long as they exhibit the same functions and functions as described above. Unexplained reference numerals (131) are internal to the stepping plate and are measured by the user with both hands when measuring body mass index, and (m) and (p) are the present invention for wirelessly transmitting and receiving measurement information. It is a mobile device or/and related equipment that is paired with (wireless connection). When explaining in detail the action of the dynamic balancer (A) according to the present invention having the configuration as described above are as follows. First, the dynamic balancer (A) of the present invention configured as described above is installed on the floor of a place where the body balance maintaining ability is to be measured with reference to FIGS. 1 and 2. Thereafter, after the measurement target rises above the dynamic balancer (A) of the present invention, the first moving mill plate (4) or the second guide foot assembled on the first guide bar (2) using one foot (3) (3') Assess the exercise by measuring the body balance in the process of taking the various postures pushing the second movable mill plate (5)(5') assembled and provided to the outside as much as possible. valuation of exercise). More specifically, several (specific) postures as shown in FIGS. 7 to 8F are subject to be measured, and the ability to maintain body balance in the process can be measured with the dynamic balancer (A) of the present invention ( See Figure 11). First, as shown in FIG. 7, the subject to be measured stepped up on the stepping plate 1 with one foot, placed on the cover line image 11, and placed the foot as the stepping axis for maintaining the body balance. In, in a state where the corresponding foot is the stepping axis for maintaining the balance of the body, the other one is provided with the first moving bar (4) assembled in the first guide bar (2) to take a specific position to push forward as much as possible And by measuring the extent to which the first movable foot 4 is pushed while maintaining the body balance, it is possible to grasp the ability to maintain balance before and after the body of the measurement object. Here, when the stepping axis is used as the left foot, one foot taking a posture uses the right foot, and when the stepping axis is used as the right foot, one foot taking a posture uses the left foot. And, as shown in Figures 8a to 8c, the subject to be measured stepped up on the stepping plate (1) with one foot (left foot), but it is precisely positioned on the cover line image (11) to climb and maintain the balance of the foot In the state where the stepping axis is used, the second moving mill plate 5 assembled on the second guide bar 3 among the second guide bars 3 and 3'with the other foot (right foot) is moved to the rear right side. By measuring the extent to which the second movable foot 5 is pushed while taking a specific posture to push as much as possible and maintaining body balance, it is possible to grasp the body's left and right balance maintaining ability. In addition, the second guide bar (3) (3') of the second guide bar (3') provided with the assembled second movable plate (5') to take the other specific posture to push the rear as far as possible While maintaining the body balance, by measuring the extent to which the second movable foot 5'is pushed out, it is possible to grasp the body's left and right balance maintaining ability. In addition, as shown in Figures 8d to 8f, the subject to be measured stepped on the stepping plate (1) with one foot (right foot), but accurately positioned on the cover line image (11) to climb and balance the foot body In the state of being used as the stepping axis of the holding, the second moving mill plate 5'assembled with the second guide bar 3'among the second guide bars 3 and 3'with the other foot (left foot) is used. By measuring the extent to which the second movable footrest 5'is pushed while taking a specific posture to push the left rear as far as possible and maintaining the body balance, the ability to maintain the balance of the left and right body of the subject to be measured can be further grasped. Can be. In addition, the second guide bar (3) (3') among the second guide bar (3) of the assembled second movable plate (5) to the right rear to take as much as possible to take another specific posture and balance the body While maintaining the, by measuring the extent to which the second movable foot (5') is pushed, it is possible to further grasp the body's left and right balance maintaining ability of the measurement target. At the same time, referring to FIG. 9, when both feet are placed on the stepping plate 1, the body mass index (EMI) estimates the amount of fat by using the height and weight of the subject to be measured by the body mass index measurement module 13 ( BMI) is measured, and accordingly, it is possible to collect specific information on the type of measurement target required for building standardized data customized for each life cycle in relation to health management. Particularly, the measurement target is placed on the stepping plate 1, and with it, the measurement handle 131 in the stepping plate 1 is pulled out and the body mass index is measured in a state to be held with both hands. After completion of this, the measurement handle 131 can be stored again by inserting it into the stepping plate 1, and the rotating action of the wire winding roll is made to automatically rotate in one direction by the spring reaction force in the stepping plate 1 By this, the measuring handle 131 can be automatically inserted into the stepping plate 1. In addition, as described above, the first and second moving mill plates assembled to each of the first and second guide bars (2), (3) and (3') in a state in which the measurement target stepped up on the stepping plate (1). (4)(5)(5') The collection of information on the weight transfer action in the process of taking a specific posture that pushes out as much as possible is possible by measuring by the pressure sensor described above. In addition, in the process of taking the specific posture as described above, the first and second movable mill plates 4, 5 and (4) (5) are assembled in each of the first and second guide bars (2) (3) and (3'). How much 5') is pushed, the stepping plate 1 and the first and second moving mill plates by the distance sensors 431, 531 or wheel sensors 432, 532 of the detectors 43, 53 ( 4)(5)(5') It is possible to measure according to the determination of the variation in the separation distance between each other. In addition, the specific position of the measurement target pushes one step on the stepping plate (1) or pushes the first and second movable mill plates (4)(5)(5') with the other foot in the state. Inducing them to be taken is possible by directly confirming the process of lighting the four light emitting diodes constituting the indicator 12 provided on the stepping plate 1 with the eyes or by an inspector after confirming. For reference, by placing the stand-type safety guards (not shown) on both sides of the dynamic balancer A so that the safety guards can be held when the body balance is lost, the measurement target takes a specific attitude according to the above-described process. In the process, you should be prepared for the occurrence of safety accidents due to loss of balance and falling. As described above, it is possible to maintain the body balance of the measurement target through all the processes described so far, and after using the equipment, when storing the dynamic balancer (A) of the present invention, the volume of the equipment is reduced to maximize space utilization. In addition, it is possible to increase the mobility efficiency. That is, after separating the first and second movable mill plates 4, 5 and 5'from each of the first and second guide bars 2, 3 and 3', referring to FIG. After the second guide bar (3) (3') is rotationally folded to the first guide bar (2) so as to be in close contact with each other, as shown in FIG. 6, the first and second movable mill plates (4) described above (5) By inserting the first and second guide bars (2), (3) and (3') into the second through holes (42, 52) of (5'), the first and second guide bars ( 2)(3)(3'). In addition, as shown in Figure 4, the structure of the first and second guide bar (2) (3) (3') is divided into a main bar (21) (31) and the folding bar (21-1) , Through the one-way rotational folding of the folding bar (21-1) using a hinge member coupled to these joints, so that the length of the first and second guide bars (2) (3) (3') is shortened It is also possible to reduce the length of the equipment. In addition, as shown in FIG. 10, related equipment, such as a terminal (m) or a computer paired with the dynamic balancer (A) of the present invention, measures the body balance ability and body mass index acquisition measurement information of the measurement object described so far. It can be wirelessly transmitted to (p), and it is possible to easily grasp the measurement target and use it as data for health management afterwards. In summary, according to the dynamic balancer (A) according to the present invention, it is possible to know how to develop a lacking body part only by clearly measuring the current body balance ability of the measurement target, and through this, the exact body shape and It is possible to measure the constitution and measure whether or not an appropriate body balance ability is based on this. By quantifying the correlation between the balance and the body mass index and applying the correlation, the management of muscle mass and body control related to body shape and constitution can be controlled. Efficient equipment implementation that can manage both contents and problem analysis and solutions can be achieved. The dynamic balancer (A) can interwork with the terminal (M), and the terminal (M) interlocked with the dynamic balancer (A) guides the user to the use of the dynamic balancer (A), SNS interlocking function and function check function, etc. It may provide a service using a dynamic balancer (A). In detail, the terminal (M) according to the embodiment, the mobile terminal (M) installed with an application that can be wirelessly interlocked with the dynamic balancer (A) to perform data communication with the dynamic balancer (A) and provide a service using the dynamic balancer (A) Can be The mobile terminal M includes a smart phone, a mobile phone, a laptop computer, a terminal for digital broadcasting (M), personal digital assistants (PDA), portable multimedia player (PMP), navigation, and a tablet PC (tablet). PC), an ultrabook (ultrabook), a wearable device (wearable device), a glass-type terminal (M) (smart glass), and the like may be included. In addition, the terminal M according to the embodiment may include an input unit 220, a communication unit 210, an interface unit, a memory 240, a display unit 230, and a processor 250, and the processor 250 May control each unit based on an application to provide a service using a dynamic balancer (A). First, the terminal M may include an input unit 220 that detects a user's input. For example, the input unit 220 may detect an execution input for turning on/off the power of the terminal M, settings for various functions of the terminal M, execution input, and the like. . The input unit 220 includes a gesture input unit 220 (eg, an optical sensor) for detecting a user gesture, a touch input unit 220 for sensing a touch (eg, a touch sensor, a touch key) (touch key), a push key (mechanical key, etc.), and at least one of a microphone (microphone) for detecting a voice input, it is possible to detect the user input. In addition, the terminal M may include a dynamic balancer A, a communication unit 210 for wireless communication with an external server, and the like. In an embodiment, the communication unit 210 may wirelessly communicate with an external server to exchange data according to the use result of the dynamic balancer (A), and to exchange data required to execute the application related to the dynamic balancer (A). For example, the communication unit 210 may include technology standards or communication methods for mobile communication (eg, Global System for Mobile Communication (GSM), Code Division Multi Access (CDMA), High Speed Downlink Packet Access (HSDPA)) , High Speed Uplink Packet Access (HSUPA), Long Term Evolution (LTE), Long Term Evolution-Advanced (LTE-A), etc. It can transmit and receive. In addition, the communication unit 210 may acquire the location (or current location) of the terminal M, and a representative example thereof may acquire a location using a GPS (Global Positioning System) module or a WiFi (Wireless Fidelity) method. Can be. In addition, the terminal M may include an interface unit that receives data from the dynamic balancer A or transmits a signal processed or generated by the processor 250 to the dynamic balancer A. In an embodiment, the interface unit may transmit/receive body balance information or BMI information measured by the dynamic balancer (A) in a wireless signal through a wired/wireless communication method. In detail, the interface unit may serve as a passage with various types of external devices connected to the terminal M. The interface unit includes a wired/wireless headset port, an external charger port, a wired/wireless data port, a memory 240 card port, and a port for connecting a device equipped with an identification module. (port), an audio input/output (I/O) port, a video input/output (I/O) port, and an earphone port. In the terminal M, in response to an external device being connected to the interface unit, appropriate control related to the connected external device can be performed. In addition, the terminal M may include a memory 240 that stores data supporting various functions of the terminal M. In detail, the memory 240 may store dynamic balancer (A) application programs (application programs), data for operation of the terminal M, and commands that are driven in the terminal M. In addition, the application program is stored in the memory 240 and is installed on the terminal M, and may be driven by the processor 250 to perform an operation (or function) of the terminal M. In addition, the memory 240 may be various storage devices such as a ROM, RAM, EPROM, flash drive, hard drive, etc. in hardware, and the memory 240 stores the storage function of the memory 240 on the Internet. It may be a web storage to be performed. In addition, the terminal M may include an output unit, and the output unit is for generating output related to visual, auditory or tactile senses, and includes at least one of a display unit 230, an audio output unit, a hap tip module, and an optical output unit. It may include. In detail, the display unit 230 may form a mutual layer structure with the touch sensor or may be integrally formed to implement a touch screen. The touch screen functions as a user input unit 220 that provides an input interface between the terminal M and the user, and at the same time, can provide an output interface between the terminal M and the user. The display 230 includes a liquid crystal display (LCD), a thin film transistor-liquid crystal display (TFT LCD), an organic light-emitting diode (OLED), and a flexible display It may include at least one of a (flexible display), a three-dimensional display (3D display), an electronic ink display (e-ink display). It may include a processor 250 for controlling the overall operation of each unit. These processors 250 include application specific integrated circuits (ASICs), digital signal processors (DSPs), digital signal processing devices (DSPDs), programmable logic devices (PLDs), field programmable gate arrays (FPGAs), controllers, micros It may be implemented using at least one of controllers (micro-controllers), microprocessors (microprocessors), and electrical units for performing other functions. The processor 250 controls the overall operation of the terminal M, in addition to the operations related to the application program. The processor 250 may provide or process appropriate information or functions to the user by processing signals, data, information, etc. input or output through the above-described components or by driving an application program stored in the memory 240. At least some of the components may operate in cooperation with each other to implement the operation, control, or control method of the terminal M according to various embodiments described below. In detail, referring to FIG. 13, when the processor 250 receives a user input and receives a dynamic balancer (A) application execution input, the processor 250 may drive the application through launcher execution. (S101) Next, the processor 250 checks whether there is a preset member login information, and if there is no login information, an interface through which the user can sign up for the dynamic balancer (A) using service, and a dynamic balancer after registering (A) It is possible to provide an interface for logging in to the service used. (S102) In detail, the processor 250, as shown in FIG. 14, through a touch interface in which the display unit 230 and the touch input unit 220 are combined, a mobile phone number (ID), name, which is an item required for membership registration, It can provide a member registration interface that allows you to enter at least one of the following: nickname (using nickname), gender, date of birth, height, height, weight, area (country/city designation function), password, password confirmation, and personal information agreement have. In addition, referring to FIG. 15, the processor 250 may log in to the service using the dynamic balancer A by inputting a mobile phone number (or ID) and a password. When the first login is completed, the processor 250 may provide educational content for teaching how to use the dynamic balancer (A). (S103) In detail, the processor 250 may provide a user to learn how to use the dynamic balancer A through various contents through a video, an image, and a text message to guide how to use the dynamic balancer A. . In addition, the processor 250 may provide the leg length measurement method guide content in order to receive leg length information, which is necessary information before using the dynamic balancer (A). In detail, referring to FIG. 16, the leg length measurement method guide content displays a text box for inputting a leg length, a video for measuring the leg length, and a text message explaining the process of measuring the leg length, making it easy for beginners to understand. Education through a variety of content. In addition, the processor 250 may provide a fun function through interworking with an SNS by interworking with a server or/and an SNS server providing a service using the dynamic balancer (A) through the communication unit 210. In detail, as shown in FIG. 17, the processor 250 may transmit/receive data from a server by interlocking a mobile phone number through a communication unit 210 with data obtained by a user using the dynamic balancer A and synchronization. Next, the processor 250 may receive records calculated based on data used by the dynamic balancer (A) of others from the server, compare the records of others with the user, and provide ranking. At this time, the processor 250 further improves the fun factor by providing a regional comparison function (eg, 1st in Busan area / 18th in Korea), and a comparison function by profession (eg, 1st in high school baseball / 2nd in amateur badminton). I can do it. In addition, the processor 250, when the server and the event of the dynamic balance is held at a specific point in time through the linkage with the server, and outputs the match / event holding information, to increase the motivation for the user to use the dynamic balancer (A) Can be. Meanwhile, the processor 250 may interwork with the dynamic balancer A to receive usage information measured by the dynamic balancer A sensor from the dynamic balancer A. (S104) In detail, the processor 250 may interwork with the dynamic balancer (A) through short-range wireless communication, for example, Bluetooth™, Radio Frequency Identification (RFID), Infrared Data Association (IrDA) ), UWB (Ultra Wideband), ZigBee, NFC (Near Field Communication), Wi-Fi (Wireless-Fidelity), Wi-Fi Direct, Wireless USB (Wireless Universal Serial Bus) using at least one of the dynamic balancer ( A). In addition, the processor 250 may provide a guide message to the user through the touch screen to confirm the linkage as shown in FIG. 18 when the linkage through the short-range wireless communication with the dynamic balancer A is completed. Next, the processor 250 may monitor usage information of the dynamic balancer A by receiving usage information measured by the dynamic balancer A through wireless communication with the dynamic balancer A. (S105) In detail, the processor 250 receives the usage information including distance information between each footrest and the center footrest measured by the dynamic balancer A through the communication unit 210, and the user's dynamic balancer A ) Can monitor usage. Next, the processor 250 may calculate a record based on the usage information and guide the user. (S106) In detail, the processor 250 may display usage information and a record based on the usage information through the display unit 230, for example, as shown in FIG. 19, confirming my dynamic balance record, profile picture, nickname setting Through the function, it can be emphasized that it is a program for me, and it can provide daily, weekly, and monthly data verification functions. In addition, referring to FIG. 19, the processor 250 may provide a function for checking the ranking of each region and each code through the display unit 230 or a service for changing colors such as green when the balance is good and red when the balance is good. . In addition, the processor 250 provides a workout fitness program using a dynamic balance, provides a target amount in front, back, and rear, receives usage information, and interlocks the target filling amount (ANT 1/10 , 2/10, 3/10…. )can do. Further, the processor 250 may calculate a record based on the use information, wherein the use information is a plurality of distance information and the record may be a user's balance capability value calculated from the distance information. In addition, the processor 250 may continuously monitor and accumulate the calculated balance ability value, thus indicating whether the user's balance ability value is improved, or provide a ranking as shown in FIGS. 19 and 20, and the color. Through this, it can be provided to confirm the good or bad of the balance ability value. In addition, the processor 250 may guide link connection information, such as a space for studying dynamic balance-related information or materials, blogs, YouTube, and the like, and may further provide thesis content related to balance, dynamic balance journal content, and the like. have. In addition, the processor 250 may provide a dynamic sharing function in conjunction with a server, in which a sharing amount is accumulated when exercising through dynamic balance, and a donated amount can be donated for social contribution.

The present invention relates to a dynamic balancer control system, and more specifically, to establish body-specific standardized data related to health management through measurement of body balance ability (exercise evaluation) and body mass index (BMI) in various postures. It relates to a dynamic balancer that enables the collection of specific information about the body type required for measurement.

Claims (11)

1. A dynamic balancer measuring body balance ability; And

   And a terminal that receives the measured body balance ability data from the dynamic balancer and outputs the received body balance ability data as a graphic image,

   The terminal,

   A dynamic balancer control system that provides a user with at least one of the dynamic balancer usage guidance function, SNS interlocking function, and usage result checking function.
2. According to claim 1,

   The use of the dynamic balancer guide function provided by the terminal,

   A dynamic balancer control system that outputs at least one content of a video, image, and text message that guides how to use the dynamic balancer as a graphic image.
3. According to claim 2,

   The method of using the dynamic balancer includes a method for measuring leg length,

   The content that guides the method for measuring the leg length,

   A dynamic balancer control system that includes a space for entering the leg length, a video of how to measure the leg length, and a text message explaining the process of measuring the die length.
4. According to claim 1,

   In order to provide a function for confirming the result of using the dynamic balancer, the terminal,

   It is interlocked with the dynamic balancer through short-range wireless communication, and a user receives usage information using the dynamic balancer,

   Based on the use information of the dynamic balancer calculates a record for the body balance ability,

   A dynamic balancer control system that outputs the calculated body balance ability record as a graphic image.
5. The method of claim 4,

   The terminal,

   Collect the records for the body balance ability, calculate the daily, weekly and monthly records,

   Dynamic balancer control system that provides to check the calculated daily, weekly and monthly records.
6. The method of claim 5,

   The terminal,

   A dynamic balancer control system that provides a workout fitness function that provides the target amount of use of the dynamic balancer and determines and outputs whether the target amount of use is reached by receiving the usage information of the dynamic balancer.
7. The method of claim 6,

   The terminal,

   A dynamic balancer control system that continuously monitors and accumulates the usage information of the dynamic balancer, calculates the body balance ability record, and determines and outputs whether the body balance ability is improved.
8. According to claim 1,

   The terminal,

   A dynamic balancer control system that provides a dynamic sharing function in which a sharing amount is accumulated based on the amount of use of the dynamic balancer and a donation of the accumulated amount can be made for social contribution.
9. According to claim 1,

   The dynamic balancer,

   A stepped footboard that allows a person who wants to measure the body balance ability to stand on one foot and stand up on the stepped footstep, and extends forward in front of the stepped foot so as to take a posture to push the other foot forward. One first guide bar, and a plurality of second guide bars extending diagonally to the left and right sides of the stepping boards so as to take a posture of spreading the other foot to the side while standing on the stepping board, and to extend backwards , The first moving mill plate is assembled on the first guide bar so that the measurement target standing on the stepped step can push one foot forward and push it out, and the measurement target on the stepped foot step A dynamic balancer control system including a plurality of second moving mill plates which are provided and assembled to each of the second guide bars so as to be pushed out to the rear side.
10. The method of claim 9,

    The dynamic balancer,

    The stepping plate has a length and width suitable for placing one foot of the measurement object, and forms a thickness capable of inserting the tip portions of the first and second guide bars and embedding the measurement module, but at the front end in the longitudinal direction, the Insertion spaces for fitting and engaging one end of the first guide bar are formed, and to the left and right of the insertion space, the fitting hinges of the one end of each of the second guide bars are coupled to the hinged state. A plurality of rotation spaces for providing a rotation range are provided,

    A dynamic balancer control system capable of hinge coupling of the second guide bars and rotational movement to the hinge coupling state is possible by a hinge formed vertically in the rotation space.
11. The method of claim 10,

    In the stepping plate, a dynamic balancer control system in which a position image for positioning is output from an indicator on the top one surface so that a measurement target can accurately place his stepping step in the correct position.

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