WO2019225769A1

WO2019225769A1 - Suprahyoid muscle exercise system

Info

Publication number: WO2019225769A1
Application number: PCT/KR2018/005777
Authority: WO
Inventors: 박준후; 박동휘
Original assignee: (재)대구포교성베네딕도수녀회
Priority date: 2018-05-21
Filing date: 2018-05-21
Publication date: 2019-11-28
Also published as: KR102000397B1

Abstract

The present invention relates to a suprahyoid muscle exercise system. The suprahyoid muscle exercise system, according to one embodiment of the present invention, comprises an exercise assistance apparatus worn on the head of a user, wherein the exercise assistance apparatus comprises: an exercise assistance part which is worn so as to cover the mandibular bone part of the user, is provided so that at least one area thereof makes contact with the area where the suprahyoid muscles are positioned between the chin and the neck, and assists an eccentric contraction exercise of the suprahyoid muscles; and a sensor which is positioned at the exercise assistance part, and is capable of detecting the exercise level of the suprahyoid muscles.

Description

[Revision 29.05.2018 by Rule 26]

The present invention relates to a iliac muscle exercise system, and more particularly, to a iliac muscle exercise system that can perform exercise while stretching the hyoid bone effectively.

Difficult to swallow (Dysphagia) is a symptom of a problem in the passage of food from the oral cavity to the esophagus and the inability to eat food. Swallowing muscles are involved in swallowing. The hyoid bone is a muscle that rises from the skull and sticks to the hyoid bone. The hyoid bone is a small bone showing a U-shape between the mandible and the sternum. The hyoid bone causes the hyoid bone to rise during the swallowing process, preventing aspiration symptoms from entering the airways. Therefore, when the hyoid bone does not move smoothly in the swallowing operation, food or water is sucked into the airways due to insufficient elevation of the hyoid bone. Therefore, people who have aspiration due to the deterioration of the iliac muscles need exercise to strengthen the hyoid bones.

The present invention is to provide a ulnar muscle exercise system that can effectively exercise the ulnar muscles.

In addition, it is to provide a iliac muscle exercise system that can perform the iliac muscle exercise in the form of stretch contraction.

In addition, it is to provide a ulnar muscle exercise system that can effectively measure the exercise state of the ulnar muscle.

In addition, it is to provide a ulnar muscle exercise system that can effectively manage the exercise of the ulnar muscles.

According to an aspect of the present invention, in the hyoid bone muscle exercise system to assist the movement of the hyoid bone, the hyoid bone exercise system includes an exercise assisting device worn on a user's head, and the exercise assisting device includes: An exercise aid that is worn to surround the jawbone portion and is provided to contact at least a portion of the jaw muscle with the region where the hyoid muscle is located; And located in the exercise aid, there can be provided a hyoid bone exercise system comprising a sensor for sensing the degree of exercise of the hyoid bone.

In addition, the sensor may be provided as a pressure sensor.

In addition, the exercise assisting device may be provided in the form of a headset, and may further include a wearable part that can be covered by a user's head, and both ends of the exercise assisting part may be fixed to the wearable part.

In addition, the iliac muscle exercise system is connected to the sensor, the difference between the relaxation signal value received when the upper iliac muscle is relaxed and the contraction signal value received when the iliac muscle is stretched out of the signals provided by the sensor It may further include a management device for calculating the exercise intensity value through.

In addition, the management device, the processing unit for processing the signal received from the sensor to calculate the exercise intensity value; And a memory configured to store the exercise intensity value as exercise history data, wherein the management device has a limit error greater than the maximum value of the exercise intensity value of the exercise history data. If the value is larger than the value or smaller than the minimum error value than the minimum value of the exercise intensity value of the exercise history data, it may be determined that the exercise assisting device is in an incorrectly worn state.

In addition, the management device, the processing unit for processing the signal received from the sensor to calculate the exercise intensity value; And a memory configured to store a misdetection detection value, which is a criterion for determining whether the exercise assisting device is properly worn, and wherein the management device has an exercise intensity value calculated through a signal received from the sensor. If it is out of the wear detection value, it may be determined that the exercise assisting device is incorrectly worn.

In addition, the sensor is provided to be located in an area symmetrically on both sides with respect to the area connecting the chin and the neck when the exercise assisting device is properly worn, the management device is the difference value of the signal received from each sensor is set value If it exceeds, it may be determined that the exercise assisting device may be in an incorrectly worn state.

According to an embodiment of the present invention, the hyoid bone muscle exercise system that can effectively exercise the hyoid bone muscle may be provided.

In addition, according to an embodiment of the present invention, there may be provided a iliac muscle exercise system that can perform the iliac muscle exercise in the form of stretch contraction.

In addition, according to an embodiment of the present invention, it is possible to provide a iliac muscle exercise system that can effectively measure the exercise state of the ulnar muscles.

In addition, according to an embodiment of the present invention, it is possible to provide a hyoid bone exercise system that can effectively manage the exercise of the hyoid bone.

1 is a block diagram showing the hyoid bone exercise system according to an embodiment of the present invention.

2 is a view showing the exercise assisting device of FIG. 1 according to an embodiment of the present invention.

3 is a view illustrating a state in which the exercise assisting apparatus of FIG. 2 is worn on a user's head.

4 is a diagram illustrating a connection relationship between sensors.

5 and 6 are diagrams schematically showing a state in which the hyoid bone is exercised.

7 is a diagram illustrating a signal sensed by the sensor when the hyoid bone is exercised.

8 is a block diagram showing the configuration of the management apparatus of FIG.

9 is a diagram illustrating an output screen of an output unit, according to an exemplary embodiment.

10 is a diagram illustrating a state in which a signal received from a sensor is managed.

Hereinafter, embodiments of the present invention will be described in more detail with reference to the accompanying drawings. The embodiments of the present invention can be modified in various forms, and the scope of the present invention should not be construed as being limited to the following embodiments. This embodiment is provided to more completely explain the present invention to those skilled in the art. Therefore, the shape of the elements in the drawings are exaggerated to emphasize a more clear description.

Referring to FIG. 1, the hyoid bone muscle exercise system 1 may include an exercise assisting device 10 and a management device 20.

The hyoid bone exercise system 1 assists the user in exercising the suprahyoid muscles. Swallowing occurs when a person puts food in his mouth and then passes food to the esophagus. Swallowing muscles are involved in swallowing. The hyoid bone is a muscle that rises from the skull and sticks to the hyoid bone. The hyoid bone is a small bone showing a U-shape between the mandible and the sternum. The hyoid bone causes the hyoid bone to rise during the swallowing process, preventing aspiration symptoms from entering the airways. People with impaired swallowing behavior, such as stroke patients and neuromuscular diseases, often have food or water aspirated into the airways due to insufficient hyoid elevation during swallowing due to placebo in the hyoid bone. Therefore, people with aspiration symptoms during swallowing need exercise to strengthen the hyoid bone.

2 is a view showing the exercise assisting device of FIG. 1 according to an embodiment of the present invention, Figure 3 is a view showing a state in which the exercise assisting device of Figure 2 is worn on the user's head.

2 and 3, the exercise assisting device 10 may include a wearing unit 110, an exercise assisting unit 130, and a sensor 140.

The exercise assisting device 10 is worn on the user's head to assist the user in effectively performing the exercise of the hyoid bone.

The wearing unit 110 may allow the exercise assisting device 10 to be fixed to the user's head. For example, the wearing unit 110 may be provided in the form of a headset, and may be provided to be worn in the form of being covered on the head of the user.

The wearing part 110 has a set width and a set length, and one side may be provided in a shape corresponding to the outer circumference of the head of the person. For example, the wearing unit 110 may be provided in a shape corresponding to a portion facing down from the top of the human head, and may be provided to be worn in a form covered from the top to the bottom of the user's head. In addition, the wearing part 110 is provided in a shape corresponding to an inclined portion of the upper portion set to the front or the rear with respect to the portion facing down from the top of the human, can be worn in the form of being obliquely covered on the user's head. May be provided. The wearing part 110 may be provided with a synthetic resin or the like so as to be elastically deformable. The wearing part 110 may be provided to be in close contact with both sides of the user's head when the user's head is covered.

An auxiliary wearing part 120 may be connected to one side of the wearing part 110. The auxiliary wearing part 120 may be worn on the user's head to allow the exercise assisting device 10 to be aligned at a predetermined position on the user's head. The auxiliary wearing part 120 has a set width and a set length, and one side may be provided in a shape corresponding to the outer circumference of the head of the person. One side or both ends of the auxiliary wearing part 120 is connected to the wearing part 110, the longitudinal direction of the auxiliary wearing part 120 may be provided at an angle set to the longitudinal direction of the wearing part 110. For example, when the exercise assisting device 10 is worn by the user, the auxiliary wearing part 120 may be provided to pass over the forehead portion of the user. An end of the auxiliary wearing part 120 may be connected to an end of the wearing part 110.

The exercise assisting unit 130 may be worn to surround the lower jaw portion of the user, and at least some areas may be provided to contact the area where the hyoid muscle is located between the chin and the neck. Both ends of the exercise relief part 130 may be fixed to the wearing part 110.

The exercise assistant 130 may include a support part 131 and a fixing part 132.

The support part 131 may be located in the central area of the exercise assisting part 130. When the exercise assisting device 10 is worn on the user's head, the support 131 may be provided such that at least a part of the exercise assisting device is in contact with the area where the hyoid bone is located. The support 131 may be provided to have a length corresponding to the region where the hyoid bone is located. For example, the support 131 may be provided to have a length corresponding to the distance between the jaw lines on both sides with respect to the region where the hyoid bone is located. Accordingly, when the exercise assisting unit 130 is worn on the user's face, the region where the hyoid bone is located between both jaw lines may be in contact with the support unit 131.

The fixing part 132 may be provided to extend with a set length at both ends of the support part 131. The fixing part 132 may be provided such that its longitudinal direction is toward the longitudinal direction of the support part 131. In addition, the fixing part 132 may be provided such that its longitudinal direction is inclined at a set angle with the longitudinal direction of the support part 131. Both ends of the fixing part 132 may be connected to the wearing part 110. For example, both ends of the fixing part 132 may be connected to an end of the wearing part 110.

The exercise assistant 130 may be provided to have a variable length and elasticity. For example, the support 131 may be provided to have an elasticity and to be variable in length. For example, the support 131 may be provided as a band of a material such as fabric fiber, synthetic fiber, silicon, latex, etc., and may be provided to have elasticity and vary in length. In addition, the support part 131 may be provided with different materials for each region. For example, the support part 131 is provided with a different material from the folding surface (inner side) and the inner side (outer side) of the user's skin, and the inner side portion and the outer side portion are attached to each other. Can be provided. Accordingly, the support 131 may be provided to be elastically deformable and to prevent deformation due to an increase in the number of times of use and to improve durability.

As another example, the fixing part 132 may be provided to be elastic and variable in length. For example, the fixing part 132 may be provided as a band of a material such as fabric fiber, synthetic fiber, silicone, latex, etc., and may be provided to have a variable length and elasticity. In addition, the fixing part 132 may be provided with different materials for each region. For example, the fixing part 132 may be provided in a form in which the folding surface (inner side) of the user's skin and the opposite side (outer side) of the inner side are each made of different materials, and the inner side and the outer side are attached to each other. Can be. Accordingly, the fixing part 132 may be provided to be elastically deformable and to prevent deformation due to an increase in the number of times of use and to improve durability.

In addition, the support part 131 and the fixing part 132 may be provided to be elastic and variable in length. At this time, the materials of the support part 131 and the fixing part 132 may be the same or different.

At least one sensor 140 may be located in the exercise assistant 130. 3 illustrates an example in which two sensors 140 are positioned in the exercise assisting unit 130. However, this is exemplary and one sensor 140 may be provided to the exercise assisting unit 130 or three or more sensors.

The sensor 140 may detect the exercise degree of the hyoid bone, while the user performs the exercise of the hyoid bone, using the exercise assisting device 10. For example, the sensor 140 may be provided to the pressure sensor 140. Accordingly, when the user applies a force to the exercise assisting unit 130 in the process of performing the exercise of the hyoid bone using the exercise assisting device 10, the sensor 140 may detect this. The sensor 140 may be connected to the management device 20 to provide a detected signal to the management device 20.

4 is a diagram illustrating a connection relationship between sensors.

Referring to FIG. 4, the sensor 140 may be provided to include a variable resistor. The variable resistor may be provided to be connected in series with the distribution resistor 141. The distribution resistor 141 may be connected to ground. The power supply unit 142 may be connected to both ends of the variable resistor and the distribution resistor 141 to apply a voltage to the variable resistor and the bonsai resistor.

The power supply unit 142 may be provided in the form of a battery, and may be provided in a form accommodated on one side of the exercise assisting device 10. For example, the power supply unit 142 provided in the form of a battery may be provided in a form accommodated on one side of the wearing unit 110. The battery may be provided in a replacement type, a charging type or a replaceable and chargeable type. As another example, the power source may be located outside the exercise assisting device 10, and the power supply unit 142 may be located at one side of the exercise assisting device 10 and may be provided as a conductor connecting the power source and the sensor 140.

The node to which the sensor 140 and the distribution resistor 141 are connected may be provided as an output terminal and connected to the management device 20. An amplifier 143 may be provided at an output terminal of the sensor 140. The amplifier 143 may amplify the signal output from the sensor 140 and provide it to the management device 20. As an example, the amplifier 143 may be configured to have negative feedback.

When pressure acts on the sensor 140, the resistance value of the sensor 140 changes. Accordingly, the ratio of the distribution resistor 141 to the sum of the sensor 140 and the distribution resistor 141 is changed, so that the magnitude of the voltage applied to both ends of the distribution resistor 141 is changed. The pressure applied to the sensor 140 may be derived through the magnitude of the voltage applied to the distribution resistor 141. For example, the sensor 140 may be provided such that the resistance value is small when the pressure is applied. In addition, the sensor 140 may be provided such that the resistance value becomes small in the form of a straight line or a curve when the working pressure is increased. Accordingly, the pressure applied to the sensor 140 may be sensed through the degree that the voltage applied to both ends of the distribution resistor 141 increases.

As another example, the sensor 140 may be provided to increase the resistance value when pressure is applied. Accordingly, the pressure applied to the sensor 140 can be sensed by the degree that the voltage applied to both ends of the bonsai resistor becomes small.

5 and 6 are diagrams schematically showing a state in which the hyoid bone is exercised, and FIG. 7 is a diagram illustrating a signal detected by a sensor when the hyoid bone is exercised.

5 is a view showing a state in which the user has left the upper hyoid bone, and FIG. 6 is a view showing a state in which the user contracts the upper hyoid bone.

5 to 7, the user may perform an exercise while wearing the exercise assisting device 10.

When the user wears the exercise assisting device 10, the exercise assisting device 10 is fixed to the user's head by the wearing unit 110, and the exercise assisting unit 130 covers the lower part of the user's head while between the chin and the neck. In contact with the part where the hyoid muscle is located. At this time, since the exercise assisting unit 130 is elastically and variably provided, the user may feel that the exercise assisting unit 130 gently pushes the portion where the hyoid bone is located.

The user may perform the exercise of the hyoid bone while performing the contraction and relaxation of the hyoid muscle of the hyoid bone while wearing the exercise assisting device 10 at least one or more times. At this time, the user can allow the hyoid muscles to be exercised while performing an elongated contraction (eccentric contraction). Stretchable contraction is contraction in an elongated state with a length of muscle. Extensible contractions can result in as much muscle contraction as possible when doing stretch contractions. Accordingly, when the hyoid bone muscle exercise is performed in the form of stretch contraction, the exercise effect can be improved. To this end, the user can bulge downward between the jaw and the neck in a convex manner so that the degree of opening of the mouth does not change, so that the hyoid muscles can be elongated contraction. For example, the user may stretch the systolic muscles while keeping the mouth closed. Later, when the power is removed from the upper extremity, the upper extremity can be relaxed. The user may perform the exercise of the hyoid bone while repeating such an operation.

While the hyoid humerus is being exercised, the exercise assisting unit 130 maintains contact with the part where the hyoid humerus is located. Accordingly, the user consciously performs the exercise of the hyoid bone while recognizing a portion of the exercise assisting unit 130, thereby improving the efficiency of the exercise. In addition, during exercise, the exercise assisting unit 130 exerts a force on the upper extremity of the hyoid bone, thereby increasing the force necessary for the user to stretch the upper extremity of the hyoid bone, thereby improving exercise efficiency.

The sensor 140 may detect the exercise state of the hyoid bone during exercise. If the sensor 140 is provided to the pressure sensor 140 according to an embodiment of the present invention, the sensor 140 may directly detect the exercise state of the hyoid bone. Specifically, when the hyoid muscle is exercised while stretching the renal contraction, the part between the user's chin and neck comes down and goes up. Accordingly, when the hyoid humerus is stretched and contracted, the force applied to the exercise aid 130 is increased, and when the hyoid humerus is relaxed, the force applied to the exercise aid 130 is reduced. Accordingly, the sensor 140 may directly detect the state of contraction and relaxation of the hyoid humerus.

Alternatively, sensor 140 may be an EMG sensor. The EMG sensor 140 may detect a signal generated from a nerve connected to the muscle. The signal detected by the EMG sensor 140 senses a nerve signal for moving the hyoid bone, not the motor state of the hyoid bone. However, the degree of muscle response in response to nerve signals of the same size varies from person to person. In addition, depending on the relative position between the EMG sensor 140 and the portion where the actual nerve passes, the magnitude of the signal detected by the EMG sensor 140 may be different even though the magnitude of the signal generated by the actual nerve is the same. Accordingly, in the case of the EMG sensor 140, there is a limit in that it is not possible to effectively detect the exercise state of the hyoid bone, and the measurement result is different depending on whether the sensor 140 is positioned at an appropriate place according to the level of skill.

Referring to FIG. 8, the management device 20 may include a processing unit 210, a memory 220, an output unit 230, and an input unit 240.

The management device 20 may assist the user in performing an effective hyoid bone exercise on the basis of a signal received from the exercise assisting device 10. For example, the management device 20 may be a computer such as a laptop, desktop, laptop, or the like. In addition, the management device 20 may be provided as a portable terminal such as a smartphone, and the portable terminal may be in a state where a setting program for operating as the management device 20 is installed. In addition, the management device 20 may be provided in the form of a dedicated terminal constituting the hyoid bone muscle exercise system (1). The management device 20 may be connected to the exercise assisting device 10 in a wired or wireless manner. When the management device 20 receives a signal regarding the exercise state of the hyoid bone from the sensor 140, the management device 20 may provide the user with information for determining whether the exercise assisting device 10 is properly worn. In addition, the management device 20 may store a signal received from the sensor 140 and provide the user with information about the improved state of the hyoid bone.

The processor 210, the memory 220, the output 230, and the input 240 may be physically separated from each other, or one or more of them may be integrated. Here, the processor 210 may control the memory 220, the output unit 230, and the input unit 240, may process a signal input from the sensor 140, and may process the memory 220 according to a predetermined program. It can be understood as a processor capable of reading and processing data stored in the.

The processor 210 may execute a program stored in the memory 220 and apply the stored data and a signal received from the sensor 140 to the program. The processor 210 may allow the signal received from the sensor 140 to be displayed on the output unit 230 in a set form or stored in the memory 220. In addition, the processor 210 may process the signal received from the sensor 140 as exercise history data and then store the result in the memory 220 or output the output unit 230. In addition, the processor 210 may determine whether the exercise assisting device 10 is properly worn by using the signal received from the sensor 140.

The memory 220 may store a signal received from the sensor 140, data processed by the processor 210, and a program for processing and managing the signal received from the sensor 140. In addition, a misdetected detection value may be stored in the memory 220. Here, the memory 220 may be referred to collectively as a nonvolatile storage device that maintains stored information even when power is not supplied.

The output unit 230 may display the data processed by the processor 210 in a form that can be recognized by a person. For example, the output unit 230 may be a display that outputs data in a visually recognizable form. In addition, the output unit 230 may be a speaker for outputting a setting message to the user in an audible form.

The input unit 240 may enable a user to input data for operating the management device 20. For example, the input unit 240 may be provided in the form of a touch screen or a keyboard.

9 is a diagram illustrating an output screen of an output unit according to an exemplary embodiment, and FIG. 10 is a diagram illustrating a state in which a signal received from a sensor is managed.

9 and 10, the management device 20 may display the signal received from the sensor 140 so that the user can recognize it. For example, the management device 20 may provide a signal received from the sensor 140 in the form of a graph. The horizontal axis of the graph may be time and the vertical axis may be the strength of the signal. In the graph, the section where the vertical axis value is located below is the signal value of the sensor 140 in the state where the hyoid bone is relaxed (hereinafter, referred to as the relaxation signal value), and the section located above is the state where the hyoid bone is stretched and contracted. Is a signal value of the sensor 140 (hereinafter, referred to as a shrinkage signal value). Accordingly, the user may visually recognize how much the hyoid bone is stretched contractively through the difference between the relaxation signal value and the contraction signal value (hereinafter, referred to as the exercise intensity value).

The relaxation signal value may indicate that the pressure applied to the sensor 140 is not zero. This may be due to the exercise assisting unit 130 being provided to contact the face of the user even when the hyoid bone is relaxed. In addition, the relaxation signal value may vary whenever the same user wears or as the user changes. This is because when the exercise assisting device 10 is worn, the upper extremity of the hyoid bone is relaxed due to the fact that the alignment relationship between the user's face and the exercise assisting device 10 is not exactly the same, and the shape of the face differs for each user. The pressure applied to the exercise assisting unit 130 in the state may be due to a different point or the like. Accordingly, the management device 20 may bias and display the relaxation signal value so that the relaxation signal value is at the set position on the vertical axis of the graph. For example, the management device 20 may bias the relaxation signal value to be located at 0 on the vertical axis, and display the signal received by the sensor 140.

As another example, the management device 20 may process a signal received from the sensor 140 so that the exercise intensity value is directly expressed in the form of a number, a graph, or the like.

In addition, the management device 20 may process a signal received from the sensor 140 each time and manage it in the form of exercise history data. For example, the exercise history data may include information about a time at which a signal is received from the sensor 140 (for example, a date of exercise), a maximum value of the exercise intensity value during the exercise, a minimum value of the exercise intensity value, Exercise duration, and the like. In addition, the management device 20 may display all or part of the exercise history data on the output unit 230. In addition, the management device 20 may allow the output unit 230 to display a selected item of the exercise history data by a user's manipulation. Accordingly, the user may check whether the user continuously performs the exercise through the history of the date of the exercise and the duration of the exercise. In addition, the change in the exercise intensity value can determine how the effect of the exercise is exhibited.

In addition, the management device 20 may separately manage exercise history data for two or more users. For example, the management device 20 may create an account for the user to manage the exercise history data, and select an account in which the signal provided by the sensor 140 is stored as the exercise history data when the exercise assisting device 10 is used. Can be provided. Accordingly, two or more users may individually create an account for managing their exercise history data. Thereafter, the user may select his or her account from two or more accounts so that the signal transmitted from the sensor 140 is stored as exercise history data.

In addition, the management device 20 may detect a wearing state of the exercise assisting device 10 by using a signal received from the sensor 140. For example, when the exercise assisting device 10 is used in a state of being correctly worn on the head of a person, the exercise intensity value detected through the sensor 140 may be designed to be measured within a setting range. In addition, the management device 20 may be provided with a misdetected detection value. The misdetection detection value may be set corresponding to the design of the exercise assisting device 10. For example, the misdetection detection value may correspond to the exercise intensity value detected when the exercise assisting device 10 is used in a correctly worn state. The misdetection detection value may be set to a set upper limit value. And, when the exercise assisting device 10 is used, if the exercise intensity value by the signal received from the sensor 140 is more than or more than the misunderstanding detection value, the management device 20 is wrong with the exercise assisting device 10 It may be determined that it may be in a worn state. In addition, the misdetection detection value may be set to a set lower limit value. And, when the exercise assisting device 10 is used, if the exercise intensity value by the signal received from the sensor 140 is less than or less than the misunderstanding detection value, the management device 20 is worn by the exercise assisting device 10 incorrectly It may be determined that the state may be in a closed state. In addition, the misdetection detection value may be set to a setting range having an upper limit value and a lower limit value. In addition, when the exercise assisting device 10 is used, when the exercise intensity value due to the signal received from the sensor 140 is out of the misdetection detection value, the management device 20 is worn with the exercise assisting device 10 incorrectly. It may be determined that the state may be. If it is determined that the exercise assisting device 10 may be in an incorrectly worn state, the management device 20 may output a message indicating that the exercise wearer is in a wrong wearing state. Such a misalignment state may be a state in which the exercise assistant 130 is deviated toward the chin side or the neck side from the position where the exercise assistant 130 is to be worn, or the exercise assistant 130 is twisted or folded.

As another example, the management device 20 may detect a wearing state of the exercise assisting device 10 using exercise history data. For example, when the same user uses the exercise assisting apparatus 10 two or more times, the management apparatus 20 may compare the signal received from the sensor 140 with the exercise history data. In addition, the management apparatus 20 may determine that the exercise assisting device 10 may be in an incorrectly worn state if the exercise intensity value exceeds the limit error value greater than the maximum value of the exercise intensity value on the exercise history data. . The marginal error value can be set greater than zero. In addition, the management device 20 may determine that the exercise assisting device 10 may be in an incorrectly worn state if the exercise intensity value is smaller than the minimum error value of the exercise intensity value on the exercise history data. . The marginal error value can be zero or greater than zero. In addition, the management apparatus 20 may be in a state in which the exercise assisting device 10 may be worn incorrectly when the exercise intensity value deviates between the maximum value and the minimum value of the exercise intensity value on the exercise history data by more than the limit error value. You can judge. At this time, the limit error value for the maximum value and the limit error value for the minimum value may be set to be the same or different. When there are two or more days of exercise on the exercise history data, the minimum, maximum, or minimum and maximum values that the management device 20 uses for detecting the wearing state of the exercise assisting device 10 are the most recent date. One, the most recent date, or between the earliest date and the most recent date may be used. Also, the minimum and maximum values may be on the same date or on different dates.

As another example, when a plurality of sensors 140 are provided, the management device 20 may detect a wearing state of the exercise assisting device 10 by using a signal received from each sensor 140.

When a plurality of sensors 140 are provided, each sensor 140 may be provided to be located in an area symmetrically on both sides with respect to the area connecting the chin and the neck when the exercise assisting device 10 is correctly worn. In addition, the management device 20 may determine that the exercise assisting device 10 may be in an incorrectly worn state when the difference in the signal received from each sensor 140 exceeds a set value. For example, the management device 20 may determine that the exercise assisting device 10 may be in an incorrectly worn state when the difference between the relaxation signal values in the signals received from the respective sensors 140 exceeds a set value. have. In addition, the management device 20 may determine that the exercise assisting device 10 may be in an incorrectly worn state when the difference between the contraction signal values in the signals received from the respective sensors 140 exceeds a set value. . In addition, the management device 20 may determine that the exercise assisting device 10 may be in an incorrectly worn state when the difference between the exercise intensity values in the signals received from the respective sensors 140 exceeds a set value. have. In addition, the management device 20 considers two or more of the relaxation signal value, the contraction signal value, and the exercise intensity value in the signal received from each sensor 140, and calculates the value of the signal received from each sensor 140. If at least one or more of the difference between the relaxation signal values, the difference between the contraction signal values, and the difference between the exercise intensity values exceeds the set value, it may be determined that the exercise assisting device 10 may be in an incorrectly worn state.

The foregoing detailed description illustrates the present invention. In addition, the above-mentioned contents show preferred embodiments of the present invention, and the present invention can be used in various other combinations, modifications, and environments. That is, changes or modifications may be made within the scope of the concept of the invention disclosed in the present specification, the scope equivalent to the disclosures described above, and / or the skill or knowledge in the art. The described embodiments illustrate the best state for implementing the technical idea of the present invention, and various modifications required in the specific application field and use of the present invention are possible. Thus, the detailed description of the invention is not intended to limit the invention to the disclosed embodiments. Also, the appended claims should be construed to include other embodiments.

10: exercise assistance device 20: management device

110: wearing part 120: auxiliary wearing part

130: exercise aid 140: sensor

210: processor 220: memory

230: output unit 240: input unit

Claims

In the hyoid bone exercise system that assists the exercise of the hyoid bone,

The hyoid bone exercise system includes an exercise assisting device worn on the user's head,

The exercise assisting device,

An exercise aid which is worn to surround the lower jaw portion of the user, the at least a portion of which is provided to be in contact with the region where the hyoid muscle is located between the jaw and the neck, and assists the stretch contraction movement of the hyoid bone; And

Located in the exercise aid, the hyoid bone exercise system comprising a sensor for detecting the degree of movement of the hyoid bone.
The method of claim 1,

The sensory humeral muscle system provided by the pressure sensor.
The method of claim 1,

The exercise assisting device,

It is provided in the form of a headset, further comprising a wearable portion that can be put on the user's head,

Both sides of the exercise aid is a hyoid bone exercise system is fixed to the wearing portion.
The method of claim 1,

The hyoid humerus exercise system is connected to the sensor, and the exercise is performed through a difference between a relaxation signal value received when the hyoid bone is relaxed among the signals provided by the sensor and a contraction signal value received when the hyoid bone is stretched and contracted. The hyoid bone exercise system further comprising a management device for calculating the intensity value.
The method of claim 4, wherein

The management device,

A processor configured to process the signal received from the sensor to calculate the exercise intensity value; And

A memory for storing the exercise intensity value as exercise history data,

The management device may determine that the exercise intensity value calculated through the newly received signal from the sensor is greater than the maximum error value of the exercise intensity value of the exercise history data, or is greater than the minimum value of the exercise intensity value of the exercise history data. The hyoid bone exercise system, which is determined to be in a state in which the exercise aid is incorrectly worn when the limit error value is smaller than the threshold error value.
The method of claim 4, wherein

The management device,

A processor configured to process the signal received from the sensor to calculate the exercise intensity value; And

And a memory configured to store a misdetection detection value, which is a criterion for determining whether the exercise assisting device is properly worn.

And the management device determines that the exercise assisting device is incorrectly worn when the exercise intensity value calculated through the signal received from the sensor deviates from the misdetection detection value.
The method of claim 4, wherein

The sensor is provided to be located in an area symmetrically on both sides with respect to the area connecting the chin and neck when the exercise assisting device is properly worn,

And the management device determines that the exercise assisting device may be in an incorrectly worn state if the difference between the signals received from each sensor exceeds a set value.