KR101807935B1 - vibration alarm method of health care chairs - Google Patents

Abstract

A sensing step of sensing a signal in the control unit 140 by generating a signal at a sensing unit 120 installed on a chair body 110 of a user sitting on a chair body 110 of the healthcare chair 100; A conversion step of converting the signal detected in the sensing step into sensing data in the controller 140; A vibration step of causing the control unit 140 to vibrate the vibration unit 150 provided on the chair body 110 according to the converted sensing data; And a control unit,
In the vibration alarm method of the present invention, the sensing unit of the healthcare chair senses the user's attitude, and the control unit adjusts the vibration intensity of the vibrating unit according to the sensed data to intuitively inform the user of the attitude Has a remarkable effect.

Description

[0001] The present invention relates to a vibration alarm method of health care chairs,

The present invention relates to a vibration alarm method for a health care chair, and more particularly, to a vibration monitoring method for a health care chair, which detects a user's posture state in a sensing unit of a healthcare chair, adjusts vibration intensity of a vibration unit in a control unit according to sensed sensed data, To a user by intuitively notifying the user of the vibration by vibration.

Generally, people who work mainly in indoor areas such as students and office workers spend a lot of time sitting on their chairs, and the people work on their own chairs in a comfortable habit position, and those who have habits that are not in good posture, And the like.

Also, those sitting in a chair need a lot of effort to correct their posture, and can not confirm their exact state needed for posture correction.

In a chair-type sitting posture and a distraction accuracy calibration system using a 3-load cell disclosed in Japanese Unexamined Patent Application Publication No. 10-2015-0094316, three load cells are attached between an upper unit and a lower unit of a chair, A weight measuring unit for measuring a weight signal according to a weight change from the load cells, a timer for calculating a temporal change amount of the measured weight signal, A signal transmitter for converting attitude information of the controller into a communication signal and transmitting the communication signal; And a terminal device for monitoring the posture or distraction degree of the seated person with the posture information transmitted from the signal transmission unit. [0002] The present invention relates to a chair-type seating posture and a distraction accuracy calibration system using a three-load cell.

As another conventional technique, a user interface method based on biometric information obtained from a chair of a patent publication No. 10-2014-0003820 is applied to a living body signal acquiring sensor and a pressure sensor provided on an armrest, A user interface method for acquiring a user's bio-signal, determining a health state, a stress or an emotional state of the user from the bio-signal, and feeding back the user's signal to the user through the user terminal, A first process of determining a health state, a stress state, and an emotional state of a user from a bio-signal obtained from a sensor; A second step of determining a posture of the user from the pressure signals of the respective sensors obtained from the pressure sensor; A third step of displaying on the screen of the user terminal a health state, a stress state, an emotion state, and a sitting posture state of the user obtained from the first and second processes; A fourth step of displaying a change state of the user's health state, stress state, emotional state, and sitting posture state obtained by the first and second processes by time, date, week, or month; A fifth step of providing feedback information classified into an image or voice according to the stress state and the emotion state determined in the first step through the user terminal; And a sixth step of providing screen and voice information through the user terminal so as to correct the posture of the user determined in the second step. User interface method.

However, in the conventional method as described above, there is a disadvantage in that, when data of the chair body is detected by the healthcare chair sensing unit, the user can not pay attention to the user when vibrating.

Therefore, through the vibration alarm method of the health care chair according to the present invention, the user's posture state is sensed by the sensing unit of the healthcare chair, and the control unit adjusts the vibration intensity of the vibrating unit according to the sensed sensed data, It is intended to provide a vibrating alarm method of a health care chair which gives an intuitive notification with care.

A sensing step of sensing a signal by a control unit 140 by generating a signal by a sensing unit 120 installed on a chair body 110 of a user sitting on the chair body 110 of the health care chair 100; A conversion step of converting the signal detected in the sensing step into sensing data in the controller 140; A vibration step of causing the control unit 140 to vibrate the vibration unit 150 provided on the chair body 110 according to the converted sensing data; And a control unit.

In the vibration alarm method of the present invention, the sensing unit of the healthcare chair senses the user's attitude, and the control unit adjusts the vibration intensity of the vibrating unit according to the sensed data to intuitively inform the user of the attitude Has a remarkable effect.

1 is a flowchart of a vibration alarm method of the present invention health care chair
FIG. 2 is a view showing a vibration part of the vibration controller of the health care chair according to the present invention.
3 is a block diagram of a health care chair of the vibration alarm method of the present invention.
FIG. 4 is a block diagram of a sensing part and a vibrating part example embodiment installed on a chair body of the vibration alarm method of the healthcare chair of the present invention
FIG. 5 is a block diagram showing an example of a vertical movement of the chair body neck support in the vibrating alarm method of the healthcare chair of the present invention
6 is a data communication conceptual diagram of the vibration alarm method of the present invention health care chair.
FIG. 7 is an exploded isometric view and a right side view of a stationary health care chair of the health care chair structure of the present invention
8 is a right side view of a stationary type health care chair of the present invention health care chair structure.
9 is a front view and a rear view of an embodiment of a stationary health care chair of the health care chair structure of the present invention
10 is a rear view of an embodiment of a stationary health care chair of the health care chair structure of the present invention
FIG. 11 is a view showing an application main screen of a method of operating a smartphone application for a health care chair according to the present invention
FIG. 12 is a graph showing a statistical screen of application items according to a method of operating a smartphone application for a health care chair according to the present invention
13 is a diagram showing an application alarm setting screen of a smartphone application operating method for a health care chair according to the present invention
14 is a view showing an application medical information screen of a method of operating a smartphone application for a healthcare chair according to the present invention
FIG. 15 is a view showing an application automatic off screen of a method of operating a smartphone application for a health care chair according to the present invention

A sensing step of sensing a signal by a control unit 140 by generating a signal by a sensing unit 120 installed on a chair body 110 of a user sitting on the chair body 110 of the health care chair 100; A conversion step of converting the signal detected in the sensing step into sensing data in the controller 140; A vibration step of causing the control unit 140 to vibrate the vibration unit 150 provided on the chair body 110 according to the converted sensing data; And a control unit.

The converting step or the vibrating step may include a communication step of transmitting sensed data of the controller 140 to the smartphone 200 through the chair communication unit 130; And further comprising:

Further, the vibration unit 150 is characterized by using a vibration motor.

The present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is a flowchart of a vibration alarm method of the present invention. FIG. 2 is a conceptual diagram of a vibration motor used in the vibrating alarm method of the healthcare chair according to the present invention. FIG. 4 is a conceptual diagram of a sensing unit and a vibration unit installed on a chair body of a vibration alarm method of the health care chair of the present invention. FIG. 5 is a conceptual diagram of a sensing unit and a vibration unit of the health care chair. 6 is a data communication conceptual diagram of the vibration alarm method of the present invention health care chair, Fig. 7 is an exploded isometric view and a right side view of the stationary health care chair of the present invention health care chair structure, and Fig. Fig. 9 is a view showing the arrangement of a resting-type healthcare chair of the present invention having a structure of a healthcare chair according to the present invention. Fig. Fig. 10 is a rear view of the embodiment of the present invention, Fig. 10 is a rear view of an embodiment of a stationary health care chair of the present invention health care chair structure, Fig. 11 is an application main screen of a smartphone application operating method for the health care chair of the present invention, FIG. 13 shows an application alarm setting screen of the method for operating the smartphone application for the health care chair according to the present invention, FIG. 14 shows the application alarm setting screen for the smartphone application for the healthcare chair according to the present invention 15 is an application automatic shutdown screen of the smartphone application operating method for a health care chair according to the present invention.

The structure of the healthcare chair 100 in which the sensing unit 120 is installed is as follows.

The health care chair 100 includes a chair body 110 having a sensing unit 120 installed on a front surface thereof; A controller 140 for converting a signal sensed by the sensing unit 120 installed in the chair body 110 into data; A chair communication unit 130 for communicating the converted data to the control unit 140 with the smartphone; A vibration unit 150 for generating a vibration modulated in accordance with the converted data to the controller 140; .

The chair body 110 is a stationary chair or a stationary chair that can be mounted on a chair.

The chair body 110 of the integral chair can be seated by a user made up of a backrest 111, a neck base 112 and a seating part 113. The chair body 110 includes a backrest 111, A sensing unit 120 including a plurality of sensors is installed on a front surface of the housing 112.

The chair body 110 can separate and engage the neck support 112. The sensor of the sensing unit 120 installed on the neck support 112 when the neck support 112 is detached is not used .

The chair body 110 of the integral chair is such that the neckrest 112 is manually moved by the user or vertically moved by the control unit 140 automatically.

The neckrest 112 of the chair body 110 using the automatic method is vertically moved by the control unit 140 of the healthcare chair 100.

The neck support connection part connecting the neck support 112 is a rod-shaped geargear. A back support connection part vertically passing through the back support part is vertically passed through and a pinion gear is installed inside.

The pinion gear is rotated in the forward and reverse directions by a common electric motor (step motor) capable of both forward and reverse rotation.

When the pinion gear is rotated, a neck support connection part serving as a gear which is in contact with one side is moved up and down. When the user senses a predetermined time (3 seconds) at the back sensor 121 of the sensing part 120 The control part 140 of the chair body 110 rotates the pinion gear to move the neck support connection part upward and sends a signal to the control part 140 when the user's neck touches the pressure sensor of the neck part, The movement of the neck support connection stops.

After a predetermined time (5 minutes) after the user is not detected by the backrest, the controller 140 reversely rotates the pinion gear to move the neckrest connecting portion in the downward direction.

Further, the chair body 110 of the stationary chair is a stationary type which is mounted on a chair as shown in Figs.

The chair body 110 is a stationary chair on which a user can sit by resting on a chair composed of a backrest 111 and a seating part 113. The chair body 110 includes a plurality of sensors A sensing unit 120 and a vibration unit 150 are installed.

In addition, the chair body 110 is integrally formed with a seating portion 113, which is under the heap of the user, and a back 111, which is in contact with the user's back.

A curved line for inserting a user's hip rear portion is formed in a lower portion of the backrest 111. An inflection point of curve curvature is formed at an upper portion and a lower center of the backrest 111 so that the curvature is changed vertically, The sensor of the sensing unit 120 is protruded forward by a spring or a magnet inside. When the sensor of the sensing unit 120 is pressed by the user, the controller 120 140, and the signal is transferred to the control unit.

8, the backrest 111 is adjustable in height, and the backrest 111 includes a lower backrest 111-b integrally formed with the seating portion 113, and a lower backrest 111- And a length adjuster installed between the lower and upper backrests 111-b and 111-b so as to move the upper and lower backrests 111-b up and down, And a vibration part 150 and a sensing part 120 are installed on the front of the upper back part 111-b.

The sensing unit 120 is a plurality of sensors provided on the chair body 110 and determines whether the sensing unit 120 is in contact with the subject's body or not. A piezoelectric sensor, a pressure sensor, a proximity sensor, or a magnetic sensor.

The sensing unit 120 senses the position of the chair body 110 through a pressure sensor on the back of the chair body 110 and a pressure sensor on the front surface of the neck of the chair body 110. [ And the sensed data sensed by the sensing unit 120 is transmitted from the chair communication unit 130 to the smart phone 200 through Bluetooth communication.

The sensing unit 120 includes a neck sensing unit 122 provided on the neck support 112 and a back sensing unit 121 provided on the backrest 111. [

The sensor of the collar portion 122 senses the user's neck and the sensor of the backlight sensing portion 121 senses the backlight of the user 10. When the user 10 sits on the chair body 110 And a neck part 122 provided on the front surface of the neck support 112 where the neck of the user 10 is in contact with the back part of the backrest 111, The controller 10 senses the pressure of the user 10 and sends a signal to the controller 140.

The pressure sensor converts the pressure signal into an electric signal when a pressure is applied by a user to detect a pressure. The pressure sensor mainly uses a load cell. The proximity sensor detects an approaching position of an object and converts it into an electric signal The presence or absence of a user is confirmed, and the magnetic sensor senses a magnetic field, which is a magnetic signal, to confirm presence or absence of a user.

The neck portion 122 of the sensing unit 120 is installed with two pressure sensors vertically spaced apart from the center of the front surface of the neck base 112 so that the upper and lower pressure sensors A total of six pressure sensors are provided on the front surface of the neck support 112 and the back sensing unit 121 of the sensing unit 120 is mounted on the back support surface The pressure sensor detects a part of the body. A part of the pressure sensor sensed through the neck part 122 is the neck of the user. The part sensed by the back sensor 121 Lt; / RTI >

The chair communication unit 130 transmits the sensed data sensed by the sensing unit 120 to the smart phone 200 that has executed the application through a transmission scheme. The transmission scheme includes Bluetooth communication, , Or a wired communication method in which a cable is directly connected and communicated.

In one embodiment of the transmission method, the transmission method uses Bluetooth communication among short-range wireless communication methods, and the smart phone 200 and the health care chair 100 executing the application can communicate with each other to transmit / receive data will be.

The vibration unit 150 vibrates in response to the intensity of the sensed data generated by the controller 140. The controller 140 senses the sensor of the sensor 130, The vibration intensity is increased or decreased according to the quantity of the sensor which is not sensed among the sensors of the sensing unit 140 extracted.

The vibration intensity of the vibration unit 150 increases with an increase in the number of undetected sensors, and decreases with an increase in the number of undetected sensors.

The vibration motor 150 may be a vibration motor. The vibration motor may be installed on the front surface of the chair body 110 so that the vibration motor can be felt by a user sitting on the chair body. And the vibrating motor generates the pseudo vibration energy on the entire surface of the body 110 to transmit the vibration to the seated user.

The vibration unit 150 increases or decreases the vibration intensity Hz according to rpm, which is the number of revolutions per minute during the physical rotation. When the rpm, which is the number of revolutions per minute, increases, Hz as the vibration intensity increases through physical rotation. As the number of rpm decreases, the physical rotation decreases and the vibration strength, Hz, becomes weaker.

The vibration alarm method of the present invention is as follows.

A sensing step of sensing a signal by a control unit 140 by generating a signal by a sensing unit 120 installed on a chair body 110 of a user sitting on the chair body 110 of the health care chair 100; A conversion step of converting the signal detected in the sensing step into sensing data in the controller 140; A vibration step of causing the control unit 140 to vibrate the vibration unit 150 provided on the chair body 110 according to the converted sensing data; .

When the user of the health care chair 100 sits on the chair body 110, the sensing unit 120 installed on the chair body 110 is pressed to generate a signal by the movement of the user, The control unit 140 detects the control signal.

In addition, the converting step converts the sensed signal into a standardized method by the control unit 140 to generate sensed data, and the generated sensed data has an identifier that can be distinguished in order. The identifier includes a generation number, Time, and so on.

In order to use the standardized method in two or more devices rather than managing the data in one, the transmission method and the receiving method such as the data length, the data sending order, and the data signal pattern should be standardized and used. The user can process the data in a desired manner through the data in one state.

As an embodiment, if the standardization is not performed, the identifiers of the nine sensors of the sensing unit are recognized and signals are received at the same time. If only the signals of the sensors 1 to 5 are inputted to the control unit from the nine sensors having the respective identifiers, In order to standardize the signal values received from sensor # 1 to sensor # 9 according to the identification value, it is necessary to set the time at 02:03:04:56:18, 2001 and the signal value from sensor # 1 to sensor # 9 And the number of the left nine digits 111110000, which is the signal value from the sensor 1 to the sensor 9, is extracted from the standardized data, and the number of zeros that the user does not touch The control unit sends a signal to the vibration unit using the vibration motor to rotate the vibration motor at 2500 rpm The vibration is generated in proportion to the rotation speed.

The vibrating step vibrates the vibrating part 150 through the sensing data converted in the converting step and the vibrating part 150 is installed on the chair body 110 and the control part 140 detects The controller 140 determines the number of undetected sensors based on the data and increases or decreases the vibration intensity of the vibration unit 150 installed on the chair body 110 in proportion to the number of undetected sensors.

The control unit 140 controls the intensity of the vibration of the vibration unit 150. The control unit 140 detects the sensed data and extracts the number of sensors not sensed in the sensing data among the sensors, The vibration intensity of the vibration unit 150 is increased or decreased according to the number of undetected sensors. And the sensed data is stored by time sequence.

That is, all the sensors of the sensing unit 130 sense a signal, convert the sensed signal into sensed data in the control unit 140, and check whether each sensor is sensed by the control unit 140 through the sensed data And the vibration intensity of the vibration unit 150 is adjusted according to the number of the detection sensors in a state where the detection is not detected.

If all of the sensors of the sensing unit 130 do not sense the user, the controller 140 determines that the user is not seated and does not vibrate the vibration unit 150.

As an embodiment, the controller 140 detects a sensor that is not sensed among all the sensors of the sensing unit 130, and does not vibrate the vibration unit 150 when the sensor is zero.

If one sensor is not detected, the number of revolutions of the vibrating part becomes 1000 rpm. When the number of revolutions increases, vibration is generated and the user is warned. When the number of undetected sensors increases by one, the number of revolutions of the vibrating part is increased by 500 rpm To more intuitively inform the user sitting on the body of the body of the degree of vibration intensity.

If all the sensors are not detected, it is determined that the user is not seated and the vibration unit 150 is not operated.

The vibrating step may include a controlling step of controlling the chair body 110 by the control unit 140 through the converted sensing data; As shown in FIG.

The control unit 140 controls the neckrest 111 of the chair body 110 upwards and downwards by checking sensed data over time.

The converting step or the vibrating step may include a communication step of transmitting sensed data of the controller 140 to the smartphone 200 through the chair communication unit 130; As shown in FIG.

Soon, the communication step may be executed immediately after the conversion step, or may be executed after the conversion step and the vibration step.

Preferably, the communication step takes a lot of execution time, so it is appropriate to execute after the latter conversion step and the vibration step.

In the communication step, the sensing data of the standardized method is sent to the smartphone 200 through the chair communication unit 130, and the processed data is output to the display unit by the smart phone 200.

The configuration of the smart phone 200 of the present invention is as follows.

The smartphone 200 includes a smartphone communication unit 210 for communicating data; A central processing unit 220 for computing and processing status information through data received from the smartphone communication unit 210; A display unit 230 for outputting data processed by the central processing unit 220; .

The application installed in the smartphone 200 is application software that outputs data to be executed to the display unit 230 in the central processing unit 220.

The central processing unit 220 of the smartphone 200 includes an arithmetic unit for performing an arithmetic operation and a logical operation, a register for storing data, and a controller for instructing operation of the arithmetic unit, The device 220 computes and processes the data transmitted from the chair communication unit 130 as status information so that the user 10 can confirm the data, and outputs the processed data to the display unit 230.

The display unit 230 may include a screen for selecting a time unit or a body part so that the user 10 can select touch data to be sensed by the display unit 230 of the smart phone 200 .

An application operation method of the smartphone 200 according to the present invention is as follows.

The smartphone 200 of the present invention transmits sensing data transmitted from the chair communication unit 130 of the smartphone 200 to the sensing data through the smartphone communication unit 210 of the smart phone 200, A receiving step of receiving the data; A processing step of calculating reception data received by the central processing unit 220; An output step of outputting the data calculated in the processing step to a corresponding screen of the display unit 230; .

The sensing data is data on whether or not each sensor senses a user on a predetermined time basis. The sensing data may include sensed time data and whether or not each sensor 123 of the sensing unit 120 senses the body according to the time data.

The receiving step receives sensed data transmitted from the chair communication unit 130 of the smart phone 200 through the smart phone communication unit 210 of the smart phone 200 in which the application is executed, .

In the processing step, the central processing unit 220 preliminarily computes sensed data as data to be output on the screen.

In the output step, the central processing unit 220 processes the calculated sensed data according to an initial selection or a selection item selected by the user, and outputs the image and text to the display unit 230.

The display unit 130 outputs sensor data for each sensor corresponding to the time of real-time, that is, recently received from the sensor data stored in the central processing unit 220, In percent (%) as text.

In addition, the display unit 130 outputs sensed data for a selected whole body or a body part in units of a predetermined time, and outputs a maximum value / a minimum value / an average value per unit time at the time of output in the unit of time in the central processing unit 220 And displayed on the display unit 230 as a graph.

The body part output to the display unit 230 is a whole body, back and neck, and one of the body parts can be selected by the user. The body part information corresponding to the body part is detected by the neck part 122 of the sensing part, And detection information detected through the back light sensing unit 121 of the sensing unit.

On the other hand, the time unit output to the display unit 230 is one day, one week, one month, and one of the time units can be selected by the user.

If the selected time unit is one day, 24 hours are divided into time units, and the sensed data is displayed as a graph on the display unit 230. In the case of one week, And in case of one month, the body information of each sensor is converted into an average value for each body part in the sensed data accumulated for one month, and the site information is outputted as a percentage (%).

In the embodiment of the present invention, the body sensor of the sensor is calibrated as 0, which means that the user is not sensed, and 1, which senses the user, (30 days) from the sum of the detection of the body during one month (to be described as 30 days) in the neck detection information excluding the data sensed by the back light sensing unit 121 among the sensed data detected per second 1 second) * The equation (1), which is the number of sensors in the neck part,

[Expression (1)]

The sum of the detection of six sensors in the neck area per unit of sensation per month for a month / (30 * 24 * 60 * 60 * 6) = Neck sensor average value

The central processing unit 220 can calculate the average value of the neck sensor 100. If the back sensor 121 uses the same method and the number of sensors of the back sensor 121 is 9, 2)

[Expression (2)]

(30 * 24 * 60 * 60 * 9) = the average of detection of 9 sensors in a unit of 1 second per month for a month

The central processing unit 220 can calculate an average value of the back sensors.

A screen displayed on the display unit 230 through the smartphone application of the present invention will be described below.

11, the main screen includes a title layout under the top notification bar; A real-time sensor layout under the title layout; A statistical layout under the real-time sensor layout; Lt; / RTI >

In the center of the title layout, 'Main' is outputted as text so that the name of the screen can be intuitively recognized. On the left side, a Bluetooth-linked state is outputted as a switch icon, and on the right side, a menu icon for outputting a menu screen is outputted .

In the right upper end of the real-time sensor layout, there is an image direction list view for selecting the position of the human image and the sensor as the rear output, the side output, and the front output. On the left side of the real-time sensor layout, And the image is output to the image with a difference in color between the black which is detected and the red which is not detected, and the image of the person such as a straight person or a tilted person is displayed according to the detected position.

That is, when the user selects the rear output in the image direction list view of the real-time sensor layout outputted on the main screen, the human image and sensor image detected from the rear are displayed on the left side of the real-time sensor layout, When the sensor on the upper right side of the neck part determines that the user can not be detected, the shape of the human image is outputted to the left side of the neck, and the side image is output when the side image is output. The front surface shape of the person and the sensor unit is output.

On the right side of the real-time sensor layout, an average value of the detection rate corresponding to the neck or waist (or the like) is output as a percentage text and a waist text.

Referring to the drawings, the central processing unit confirms whether the six sensors corresponding to the neck are detected in real time on the right side of the title text, and 83% of the five sensors are detected. In this case, 83% 100% * The number of sensors detected is 5 / the rounding value of decimal point first digit of total sensor number of 6. In addition, it outputs red so that the user can intuitively judge that the output value is not 100% because the output value is not 100%. The right side of the waist text indicates whether the nine sensors corresponding to the back (or waist) The central processing unit confirms whether the 9 sensors corresponding to the sensor are detected in real time, and outputs 100% of the detected 9 sensors. In this case, 100% is 100% * 9 / The number of the sensor, the decimal point of 9, is rounded to the first digit. In addition, since the output value is 100%, it is outputted in black so that the user can intuitively judge that the whole is detected.

The number of sensors to be sensed is not more than the number of sensors installed and varies depending on the seating state of the user. .

Below the real-time sensor layout, it is output as text so that the user can understand whether or not the sensor is being detected.

In addition, a time list view for selecting a time unit is displayed on the right upper side of the statistical layout, and when Day and Weeks are selected in the time unit list view, a body part list view And if Months is selected, the body part list view disappears, and at the bottom, the average value of the sensed data per unit time is output as a graph or text according to the selection of the time unit list view and the body part list view.

When Day is selected in the time unit list view, a body part list view is generated in a state in which the body part list view is set as a whole, and a state in which the body part list view is full displays a time- If you select Weeks in the time unit list view and then select the waist in the body part list view, you can display the highest, lowest, and average values of the detection data of the circumference of the waist in one day. If you select Months in the time unit list view, The left and right arrows and the sensed data of the neck and waist in the month are output as a percentage of the total average.

In addition, when a menu icon of the title layout of the main screen is pressed, a menu screen is generated so as to cover a certain portion of the main screen in front of the main screen, and the shape of the person is displayed as an image view on the upper left of the menu screen, A name of the environment setting icon is output as a name text, an environment setting icon button for changing the setting is outputted on the right side of the image view, a refresh icon button is displayed on the right side of the environment setting icon, Icon button is displayed, and under the user name, a square button is used to output the notification cycle, date display, statistics, medical information, auto off, information sharing, data backup, help, and program end.

12, a notification cycle screen for selecting an alarm is output. In the notification cycle screen, a title text having a center text changed to a 'notification cycle' is displayed under the notification bar at the top, layout; An icon button layout which is output under the title layout and in which a notification addition icon and a more icon are generated; An alarm list view below the icon button layout; The alarm list view can be changed to an alarm generation view to add an alarm. If the icon icon is clicked, alarms displayed in the alarm list view can be input, sorted in date and time order The user can select the time, the day of the week, the notification method, the alarm sound, and the sound volume level in the alarm generation view and press the OK button at the bottom to save the alarm in the alarm list. A check mark is displayed on each list in the list view to confirm that the alarm has ended.

When the user sets an alarm through a touch on the smartphone in the alarm setting screen, the central processing unit 220 sounds an alarm with vibration or sound at predetermined intervals of the alarm set.

As shown in FIG. 13, when the medical information button is pressed, a medical information screen for outputting and searching medical information related to the vertebra is output. The medical information screen includes a function of the spine, a configuration of the spine, And a bookmark icon button at the upper left corner to change to a favorite screen for storing the selected information and a search icon on the right side of the book icon button to search for desired contents It is. In addition, in the favorite screen, deletion icon buttons for storing the selection information and storing the selection information in a list are generated on the right side of the book shape icon button.

14, an automatic ending screen which can be set to end the power supply of the healthcare chair is output at a predetermined time, and the automatic ending screen displays the title text of the title layout as 'automatic ending' Quot ;, and a screen is displayed which allows the power supply of the healthcare chair to be reserved and terminated.

When the statistic button is pressed, a statistical screen for outputting total usage time, total number of days of use, daily use time, main usage time, and measurement result is output as shown in FIG. 15, and the statistical screen is displayed on the uppermost notification bar Below is the title layout with the central text changed to 'Statistics'; An icon button layout which is output under the title layout and in which a statistic icon and a more icon are generated; A statistical view below the icon button layout; Wherein the total usage time is displayed at the top of the statistical view, the number of days of use is displayed below the total usage time, the daily usage time of the day used for the day is displayed below the total usage time, Below, the main usage time of the main use is displayed, and the measurement result is output according to the detection data under the main usage time.

When the information sharing button is pressed, an information sharing screen that can be shared by various social members is displayed. The information sharing screen displays various social icons such as Facebook, Twitter, and KakaoTalk. When a social icon is clicked, Chair usage information is uploaded.

If you press the data backup button, you can select the means to back up the data such as device, SD card, USIM, etc., and output the data backup screen to export or import.

When the program end button is pressed, the application of the smart phone is terminated.

Therefore, according to the vibration alarm method of the present invention, the sensing unit of the health care chair senses the user's posture state, and the control unit adjusts the vibration intensity of the vibrating unit according to the sensed data to intuitively There is a remarkable effect to tell.

10: User
100: Health care chair 110: Chair body
111: backrest 111-a: upper backrest
111-b: lower backrest 111-c:
112: neckrest
113:
120: sensing unit 130: chair communication unit
140: control unit 150:
200: smart phone 210: smart phone communication part
220: central processing unit 230: display unit

Claims (4)

A sensing step of generating a signal by a sensing unit 120 installed on a chair body 110 and sensing a signal by a control unit 140 when a user sitting on the chair body 110 of the health care chair 100 is sensed; A conversion step of converting the signal detected in the sensing step into sensing data in the controller 140; A vibration step of causing the control unit 140 to vibrate the vibration unit 150 provided on the chair body 110 according to the converted sensing data; A method for shaking a vibration of a health care chair,
The converting step or the vibrating step may include a communication step of transmitting sensed data of the controller 140 to the smartphone 200 through the chair communication unit 130; Further comprising:
The vibration unit 150 uses a vibration motor,
The chair body 110 is a stationary chair or a stationary chair that can be mounted on a chair,
The chair body 110 is integrally formed with a seat portion 113 to which a bottom portion of the user's hips is touched and a back portion 111 to which the user's back comes into contact. Curves are formed at the upper and lower centers of the backrest 111 and the curvature of curvature is changed in the upper and lower portions of the backrest 111. The sensing unit 120 is formed on the upper surface of the backrest 111, A sensor of the sensor unit 120 is forwardly protruded by an internal spring or a magnet. When a sensor of the sensor unit 120 is pressed by the user, a signal is generated by the controller 140 and the signal is transferred to the controller.
The backrest 111 is adjustable in height up and down. The backrest 111 includes a lower backrest 111-b integrally formed with the seating portion 113 and an upper backrest 111-a disposed on the upper side of the lower backrest And a length adjuster 111-c installed between the lower and upper backrests 111-b and 111-b to move the upper backrest 111-b up and down, A vibration unit 150 and a sensing unit 120 are installed on the front surface of the upper backrest 111-b,
The sensing unit 120 includes a neck sensing unit 122 provided on the neck support 112 and a back sensing unit 121 provided on the backrest 111,
The vibration unit 150 vibrates to adjust the strength through the sensing data generated by the controller 140. The controller 140 controls the sensing unit 130 to detect the quantity data The vibration intensity of the vibration unit 150 increases with an increase in the number of sensors that are not sensed, and the vibration intensity of the vibration unit 150 increases as the number of sensors that are not sensed increases. The vibration of the chair is reduced.
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