KR102294958B1 - Electronic device and electronic system for guiding posture correction - Google Patents

Abstract

The technical idea of the present invention relates to an electronic device for guiding posture correction and an electronic system thereof. The device comprises: a cushion; an internal sensor module that is located inside the cushion and includes a substrate including a plurality of sensor units positioned in a left-right symmetrical form concerning a gaze direction of the seated person and positioned in an asymmetrical front-to-rear shape concerning the gaze direction; an internal processing module located inside the cushion and transmitting posture data through a communication unit based on a sensing signal output from the internal sensor module; and an external operation module located outside the cushion and including an input unit for controlling a power state of the internal processing module.

Description

Electronic device and electronic system for guiding posture correction

The technical idea of the present disclosure relates to an electronic device for guiding posture correction and an electronic system thereof, and in particular, a sensor module and a processing module are included inside the cushion, and a manipulation module is included on the outside of the cushion for user operation convenience. It relates to a posture correction electronic device and an electronic system thereof.

With the increase in computer and smartphone usage time, the number of patients with spinal diseases in Korea increased by 900,000 over 5 years. In particular, students or office workers maintain sitting for a long time in their studies and work in a posture that places strain on their neck, back, and spine. hard to do
In view of the above problems, a cushion including a weight sensor has been disclosed, but the conventional cushion does not accurately predict a sitting posture due to a sensor arrangement that does not consider the seated person's posture. Such is the case in Korean Patent Laid-Open Publication No. 10-2016-0034128. In addition, since the operation module is provided integrally with the cushion, as the cushion shape of the cushion is deformed by seating, the load of the seated person is applied to the operation module, so the possibility of damage to the operation module is high.

The problem to be solved by the technical idea of the present disclosure is an electronic device for guiding posture correction, including an internal sensor module of the cushion that accurately senses the seated posture of a seated person, and an external sensor module of the cushion for maximizing user convenience and reducing the possibility of damage and to provide an electronic system thereof.

In order to achieve the above object, in an electronic device for guiding posture correction according to an aspect of the technical idea of the present disclosure, a cushion is located inside the cushion, and is located in a symmetrical form with respect to the gaze direction of a seated person An internal sensor module including a substrate including a plurality of sensor units positioned in a front and rear asymmetric shape with respect to the gaze direction, positioned inside the cushion, and transmitting posture data based on a sensing signal output from the internal sensor module to a communication unit It may include an internal processing module that transmits through and an external manipulation module that is located outside the cushion and includes an input unit for controlling the power state of the internal processing module.
In addition, the internal sensor module may include a first row sensor group including some of the plurality of sensor units, a second row sensor group including another part of the plurality of sensor units, and among the plurality of sensor units. a third row sensor group including another part; and a fourth row sensor group including the rest of the plurality of sensor units, wherein a separation distance between the first row sensor group and the second row sensor group is determined by the second row sensor group and the third row sensor group The separation distance of the group may be greater than the separation distance between the second row sensor group and the third row sensor group, and the separation distance between the third row sensor group and the fourth row sensor group may be substantially the same. .
In addition, the number of the plurality of sensor units included in the first row sensor group and the fourth row sensor group is the same, and the number of the plurality of sensor units included in the second row sensor group and the third row sensor group is The number may be characterized as being equal to each other.
Also, the number of the plurality of sensor units included in the first row sensor group may be smaller than the number of the plurality of sensor units included in the second row sensor group.
In addition, the first row sensor group is located on the frontmost side among the plurality of row sensor groups, and the second row sensor group is located in a rearward direction from the first row sensor group, The third row sensor group may be positioned in a rear direction than the second row sensor group, and the fourth row sensor group may be positioned at the rearmost surface among the plurality of row sensor groups.
On the other hand, one end of each of the plurality of sensor units located on the left half surface of the internal sensor module is electrically connected by a first channel, and one end of each of the plurality of sensor units positioned on the right half surface of the internal sensor module The end may be electrically connected by a second channel, and the other end of each of the plurality of sensor units may output sensing signals through a plurality of different channels.
On the other hand, the cushion includes a pocket into which the external manipulation module located on the left side or the right side can be inserted, and the external manipulation module includes a locking member provided to be fixed to the cushion is formed on the lower surface of the case, The input unit and the display unit may be formed on an upper surface of the case opposite to the lower surface.
In addition, the external manipulation module may further include a display unit for indicating the power state and the communication state of the communication unit.
Meanwhile, the internal processing module may further include a vibration unit, and when it is identified that the posture of the seated person is an incorrect posture based on the sensing signal, it may be characterized in that the vibration notification is given to the seated person by driving the vibration unit. .

In the electronic device according to an exemplary embodiment of the present disclosure, since the external manipulation module is located outside the cushion and is connected to the internal processing module through a wire, even if the occupant is seated on the cushion including the electronic device, the external manipulation module is damaged And it is possible to prevent disconnection of the wire.
In addition, the power state and communication state of the electronic device can be controlled through an external manipulation module located outside the cushion, or the power state and communication state can be identified through the display unit, thereby increasing user convenience.
In addition, by arranging a relatively large number of sensor units in the hip region of the seated person to which the load of the seated person is applied the greatest, it is possible to perform precise sensing. By arranging fewer sensor units in the thigh region of the seated person, to which the body pressure of the seated person is applied, an efficient circuit design can be achieved, and the cost can be reduced and the sensing efficiency can be improved.

1 is a diagram for describing an electronic system for posture correction according to an exemplary embodiment of the present disclosure.
2 is a block diagram for explaining in detail an electronic device according to an exemplary embodiment of the present disclosure.
3 is a diagram for describing an internal sensor module according to an exemplary embodiment of the present disclosure.
4 is for explaining an internal sensor module according to a comparative example.
5A, 5B and 6 are for explaining the structure of an external manipulation module according to an exemplary embodiment of the present disclosure.

Hereinafter, embodiments of the present disclosure will be described in detail with reference to the accompanying drawings. The embodiments of the present invention are provided to more completely explain the present invention to those of ordinary skill in the art. Since the present invention can have various changes and can have various forms, specific embodiments are illustrated in the drawings and described in detail. However, this is not intended to limit the present invention to the specific disclosed form, it should be understood to include all modifications, equivalents and substitutes included in the spirit and scope of the present invention. In describing each figure, like reference numerals are used for like elements. In the accompanying drawings, the dimensions of the structures are enlarged or reduced than the actual size for clarity of the present invention.
The terms used in the present disclosure are used only to describe specific embodiments, and are not intended to limit the present invention. The singular expression includes the plural expression unless the context clearly dictates otherwise. In the present disclosure, terms such as “comprise” or “have” are intended to designate that a feature, number, step, operation, component, part, or combination thereof described in the specification is present, but one or more other features It is to be understood that it does not preclude the possibility of the presence or addition of numbers, steps, operations, components, parts, or combinations thereof. Ordinal expressions such as "first ~" and "second ~" used in the present disclosure do not limit that "first ~" precedes "second ~", and are understood to be expressed differently in similar configurations. should be
Unless defined otherwise, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. Terms such as those defined in a commonly used dictionary should be interpreted as having a meaning consistent with the meaning in the context of the related art, and should not be interpreted in an ideal or excessively formal meaning unless explicitly defined in the present application. does not
1 is a diagram for describing an electronic system for posture correction according to an exemplary embodiment of the present disclosure.
Referring to FIG. 1 , an electronic system 1000 may include an electronic device 10 , a cushion 20 , and a user terminal 30 . The electronic device 10 may include an internal sensor module 100 , an internal processing module 200 , and an external manipulation module 300 . To drive the electronic device 10 , the electronic device 10 may include a battery, and the battery may be charged by an external power source. For example, the external power source may charge the battery through the external manipulation module 300 .
According to an exemplary embodiment of the present disclosure, the internal sensor module 100 and the internal processing module 200 may be included in the cushion 20 .
The internal sensor module 100 is included in the cushion 20, and is positioned in a left-right symmetrical form with respect to the gaze direction of the seated person, and a substrate including a plurality of sensor units positioned in an asymmetrical front-to-rear shape based on the gaze direction. may include Hereinafter, the seated person may also be referred to as a user.
The internal sensor module 100 may include a plurality of sensor units for detecting the posture of the seated person, and the plurality of sensor units may include a pressure sensor. For example, at least some of the plurality of sensor units may be Force Sensitive Resistor (FSR) sensors. The FSR sensor can output the pressure level as an analog or digital signal in various stages when pressure is applied.
In the internal sensor module 100 , the density of the plurality of sensor units located at the rear side with respect to the gaze direction may be greater than the density of the plurality of sensor units located at the front side based on the gaze direction of the seated person. When the seated person sits on the cushion 20 , the pressure from the head to the buttocks of the seated person may be applied to the rear surface of the internal sensor module 100 , and the pressure by the thigh may be applied to the front of the internal sensor module 100 . When the seated person takes an incorrect posture, such as a turtle neck posture or a left and right tilted posture, since the amount of change in the pressure applied from the seated person's buttocks (that is, the pressure applied to the rear of the internal sensor module 100) is larger, The density of the plurality of sensor units located on the rear side of the internal sensor module 100 according to the exemplary embodiment of the present disclosure may be greater.
The internal sensor module 100 may output a sensing signal sensing the pressure applied as the seated person is seated. For example, when the seated person takes the so-called turtle neck posture, a plurality of sensor units located in front of the internal sensor module 100 may sense a greater pressure than when the seated person takes the upright posture. As another example, when the seated person takes a left-leaning posture, a plurality of sensor units located on the left side of the internal sensor module 100 may sense a greater pressure than when the seated person takes a straight posture.
The internal processing module 200 may be included in the cushion 20 , and may generate posture data based on a sensing signal output from the internal sensor module 100 . The posture data may be data processed by the internal processing module 200 based on a sensing signal. For example, the sensing signal may be an analog signal, and the posture data may include digital data. As another example, the posture data may be data identified as one of a plurality of pre-stored posture data based on a sensing signal.
The internal processing module 200 may guide the occupant to correct posture through vibration and/or sound based on the sensing signal.
According to an embodiment of the present disclosure, the internal processing module 200 may identify the identified posture data as a correct posture or an incorrect posture. For example, the plurality of posture data may include an identifier indicating an upright posture or an incorrect posture. Identifiers may include, for example, flags, which are predefined bits (or several bits).
According to another embodiment of the present disclosure, the internal processing module 200 transmits the posture data to the user terminal 30 , and the user terminal 30 may identify whether the received posture data is an upright posture or an incorrect posture. The user terminal 30 may transmit the identified data (eg, data indicating an incorrect posture) to the internal processing module 200 .
The internal processing module 200 may guide the occupant to correct the posture by driving a vibrator and/or a sound output unit in response to identifying or receiving data indicating an incorrect posture.
The external manipulation module 300 is located outside the cushion 20 and may include an input unit 310 for controlling the power state of the internal processing module 200 . In addition, the internal processing module 200 may include a display unit 320 indicating at least one of the power state of the internal processing module 200 and the communication state of the communication unit ( FIG. 2 220 ) included in the internal processing module 200 . may be For example, the input unit 310 may be implemented as a push button switch, and the display unit 320 may be implemented as at least one light emitting diode.
According to an exemplary embodiment of the present disclosure, the external manipulation module 300 may receive various types of user inputs through the input unit 310 . For example, in response to the user pressing the input unit 310 once equal to or shorter than the preset time, the external manipulation module 300 activates the vibrator ( 241 in FIG. 2 ) included in the internal processing module 200 . Or you can disable it. As another example, in response to a user pressing the input unit 310 once longer than a preset time, the power of the electronic device 10 may be turned on or off, and thereafter, the internal processing module 200 included The communication unit ( 220 of FIG. 2 ) may enter a pairing mode. When the pairing condition is satisfied, a wireless communication connection between the internal processing module 200 and the user terminal 30 may be established.
According to an exemplary embodiment of the present disclosure, the external manipulation module 300 may display the power state of the internal processing module 200 through the display unit 320 . For example, when all the batteries included in the internal processing module 200 are fully charged, the power state of the internal processing module 200 is stable, so that the display unit 320 may maintain a lit state. As another example, when the battery included in the internal processing module 200 is lower than a preset voltage level, since the power state of the internal processing module 200 is unstable, the display unit 320 may blink for shorter than a preset period. As another example, when the battery included in the internal processing module 200 is being charged, the display unit 320 may blink longer than a preset period.
According to an exemplary embodiment of the present disclosure, the external manipulation module 300 may display the communication state of the communication unit ( 220 of FIG. 2 ) of the internal processing module 200 through the display unit 320 . For example, the display unit 320 may display the communication state in different ways for each state in which the internal processing module 200 is in a state in which a connection with the user terminal 30 is established and a state in the pairing mode.
On the other hand, examples of the input unit 310 and the display unit 320 are not limited to the above-described examples, and various input means that the user can input for various operations and control of the electronic system 1000 and the power state and communication to the user are provided. It may include a display means capable of displaying the status.
The external manipulation module 300 may supply power supplied from an external power source to a battery included in the internal processing module 200 . For example, the external manipulation module 300 may receive power supplied from an external power source through a USB terminal from a travel adapter to charge the battery.
According to an exemplary embodiment of the present disclosure, the cushion 20 may include a pocket 21 on the left side or the right side, and the external manipulation module 300 may be inserted into the pocket 21 . At this time, the external manipulation module 300 has a locking member provided to be fixed to the cushion 20 is formed on the lower surface of the external manipulation module 300, and the input unit 310 and the display unit 320 are the case opposite to the lower surface. may be formed on the upper surface of In this regard, it will be described later in detail with reference to FIGS. 5 and 6 .
Specifically, in order to control the power state or communication state of the electronic device 10 , the external manipulation module 300 exposed to the outside of the cushion 20 may include an input unit 310 . In addition, the external manipulation module 300 exposed to the outside of the cushion 20 may include a display unit 320 so that the external manipulation module 300 can easily grasp the power state or communication state of the electronic device 10 . have.
In addition, the external manipulation module 300 may be connected to the internal processing module 200 through a wire 330 rather than being directly structurally connected thereto. Specifically, the internal processing module 200 and the external manipulation module 300 may not be formed on a single substrate, but may be formed as separate substrates. That is, the internal processing module 200 may be formed on a first substrate and include a first connector, and the external manipulation module 300 may be formed on a second substrate and include a second connector, and the wire 330 . may be interconnected with the first connector and the second connector to transmit power and transmit/receive data. Accordingly, even if a seated person applies a large pressure by sitting on the electronic device 10 , damage and disconnection of the internal processing module 200 and the external manipulation module 300 may be prevented.
2 is a block diagram for explaining in detail an electronic device according to an exemplary embodiment of the present disclosure. Hereinafter, it will be described together with reference numerals in FIG. 1 .
Referring to FIG. 2 , the internal processing module 200 may include a power management unit 210 , a communication unit 220 , a multiplexer 230 , a driving unit 240 , and a processor 250 .
The power management unit 210 may include a charging circuit 211 , a voltage regulator 212 , a battery 213 and a voltage detector 214 , and the communication unit 220 includes an antenna 221 . ) and a communication module 222 , and the driving unit 240 may include a vibrating unit 241 and a sound output unit 242 .
The power management unit 210 may receive power supplied from an external power source. For example, the power management unit 210 may receive the power provided by the external manipulation module 300 from an external power source through the wire 330 . As another example, the power management unit 210 may directly receive power supplied from an external power source. For example, the external power source may be a travel adapter.
According to an embodiment of the present disclosure, the power management unit 210 may charge the battery 213 using power supplied from an external power source. While the electronic device 10 is electrically connected to an external power source, for example, the battery 213 may supply power to the electronic device 10 , and as another example, the charging circuit 211 may receive power supplied from the external power source. Power may be directly supplied to the electronic device 10 , or as another example, the battery 213 and the charging circuit 211 may supply power to the electronic device 10 together. For example, battery 213 may be a lithium ion battery.
According to another embodiment of the present disclosure, while the electronic device 10 and an external power source are not electrically connected, the battery 213 may supply power to the electronic device 10 .
The voltage regulator 212 may maintain a voltage of power supplied to the processor 250 at a constant level. For example, the voltage of the power provided from the battery 213 may be output by limiting the range of the preset level, and the range of the preset level may be 3.0 volts or more and 3.3 volts or less.
Also, the voltage regulator 212 may reduce the voltage level so that the electronic device 10 consumes a minimum current in a standby mode. For example, the voltage regulator 212 may supply power of a preset voltage level to the processor 250 in response to receiving a signal indicating the standby mode from the processor 250 .
The voltage detector 214 may detect an output voltage of the battery 213 . For example, the voltage detector 214 may provide the processor 250 with a result of detecting that the output voltage of the battery 213 is reduced below a preset voltage level. The processor 250 may indicate that the battery 213 is in a low voltage state through the display unit 320 .
Meanwhile, the voltage detector 214 may block the voltage output from the battery 213 when the output voltage of the battery 213 is reduced below a preset voltage level. That is, it may operate as a protection circuit of the battery 213 .
In addition, the voltage sensor 214 may adjust the output voltage of the battery 213 to maintain the torque and/or the speed of the motor included in the driving unit 240 . For example, the voltage detector 214 may detect that the output voltage of the battery 213 is insufficient to drive the driving unit 240 , boost the output voltage of the battery 213 and provide it to the processor 250 .
The communication unit 220 may perform data transmission/reception between the user terminal 30 and the electronic device 10 .
The antenna 221 may be provided to receive data from the user terminal 30 or to transmit data from the electronic device 10 to the user terminal 30 . Here, the data may include sitting data indicating a seating posture, a seating position, and a seating angle of a seated person. Alternatively, the data may include a sensing signal detected from the internal sensor module 100 . For example, the sensing signal may be data regarding pressure sensed from at least one of a plurality of sensor sensor modules.
The communication module 222 may support various short-distance or long-distance communication methods. For example, it may include Bluetooth, Bluetooth Low Energy (LBE), ZigBee, Wi-Fi, and infrared (IR) schemes, and may include cellular communication schemes such as 3G, LTE, LTE-A and 5G. However, the present invention is not limited thereto, and may further include a wired or wireless communication method capable of transmitting and receiving seating data, sensing signals, and other various types of data.
The multiplexer 230 may transmit a sensing signal received from the internal sensor module 100 to the processor 250 . For example, the internal sensor module 100 may output sensing signals as many as the number of the plurality of channels through the plurality of channels. The multiplexer 230 may sequentially provide the received sensing signals to the processor 250 . For example, the first sensing signal received from the first channel may be first output to the processor 250 , and then a switching operation may be performed, and then the second sensing signal received from the second channel may be output to the processor 250 . .
The driving unit 240 may include a vibrating unit 241 that generates vibration under the control of the processor 250 . When the processor 250 identifies that the seated person's posture is an incorrect posture based on the sensing signal, the processor 250 may drive the vibrator 241 to give a vibration notification to the seated person, and the sound output unit 242 can be activated to give a sound notification to the user. For example, the vibrator 241 and the sound output unit 242 may oscillate at a frequency of an audible region, an ultrasonic frequency, and a low frequency, respectively.
The processor 250 may control the electronic device 10 as a whole.
The processor 250 may manage the power state of the electronic device 10 based on a period (or time point) at which a sensing signal is received from the internal sensor module 100 . Here, the power state of the electronic device 10 may include a standby mode, a sleep mode, and a power off mode.
The standby mode refers to a power state in which the electronic device 10 receives a rated voltage from the battery 213 and can perform all functions that the electronic device 10 can perform according to the control of the processor 250 .
The sleep mode refers to a state in which power consumption of the battery 213 is less than that of the standby mode, and refers to a power state in which the electronic device 10 can perform a limited function. For example, in the sleep mode, the communication module 222 may perform only a minimal function with lower power than in the standby mode.
The power-off mode refers to a state in which the electronic device 10 performs only a minimum function or a current is not conducted to internal components of the electronic device 10 until a turn-on operation is received from the input unit 310 . .
As an example, the processor 250 may control the electronic device 10 to a sleep mode when a sensing signal is not input for the first time. Thereafter, if the sensing signal is not input for a second time period longer than the first time period, the processor 250 may control the power-off mode. Meanwhile, when a first operation (eg, an operation of pressing the input unit 310 shorter than a preset time) is input through the input unit 310 in the sleep mode, the processor 250 controls the electronic device 10 to the standby mode. can In addition, when a second manipulation (eg, an operation of long pressing the input unit 310 for a preset time) is input through the input unit 310 in the sleep mode, the processor 250 controls the electronic device 10 to the standby mode. can
The processor 250 may display the power state of the electronic device 10 through the display unit 320 . For example, the display unit 320 may be an RGB light emitting diode.
For example, the processor 250 may maintain a state in which the display unit 320 is lit in the first color in the standby mode. As another example, the processor 250 may turn off the display unit 320 in the sleep mode and the power off mode.
The processor 250 may identify the communication state of the electronic device 10 based on the communication module 222 . The processor 250 may display the identified communication state through the display unit 320 . For example, the communication state may include a pairing mode for connecting one of the electronic device 10 and an external device, and a connection mode in which the electronic device 10 and the user terminal 30 are connected to each other. have. Meanwhile, the processor 250 may enter the pairing mode when a third manipulation (eg, pressing twice for shorter than a preset time) is input through the input unit 310 .
For example, the processor 250 may maintain a state in which the display unit 320 is flickered in the second color in the pairing mode. As another example, the processor 250 may maintain a state in which the display unit 320 is lit with the second color in the connection mode for a preset time. For example, when the power state of the electronic device 10 is the standby mode and the communication state enters the connection mode, the display unit 320 may be maintained in the second color for a preset time and then may be controlled in the first color. .
According to an embodiment of the present disclosure, the processor 250 may receive a sensing signal from the internal sensor module 100 . The processor 250 may generate seating data based on the received sensing signal. Hereinafter, the electronic device 10 may include a memory inside or outside the processor 250 . Here, the memory may include a lookup table capable of identifying the sensing signal as an upright posture or an incorrect posture.
The processor 250 may identify the seated person's posture as an upright posture or an incorrect posture based on the sensing signal.
According to an embodiment of the present disclosure, when the posture of the seated person is an incorrect posture, the processor 250 may control the vibrator 241 and/or the sound output unit 242 to oscillate. As another example, when the posture of the seated person is an incorrect posture, the processor 250 may transmit sitting data indicating the incorrect posture to the user terminal 30 .
Meanwhile, according to an embodiment of the present disclosure, when the seated person's posture is a normal posture, the processor 250 may control the vibrator 241 and/or the sound output unit 242 not to oscillate. As another example, if the seated person's posture is an incorrect posture, the processor 250 may transmit seated data indicating that the seated person is an upright posture to the user terminal 30 .
In addition, according to an embodiment of the present disclosure, the processor 250 may transmit seating data to the user terminal 30 , but may also transmit a sensing signal received from the internal sensor module 100 to the user terminal 30 . . In this case, the user terminal 30 may identify the posture of the seated person based on the sensing signal. The user terminal 30 may display the identified posture or inform the occupant that the posture is incorrect through video and/or audio.
3 is a diagram for describing an internal sensor module according to an exemplary embodiment of the present disclosure.
Referring to FIG. 3 , the internal sensor module 100 may include a plurality of sensor units S1 to S32 included in the substrate ST. For example, the substrate ST may be a flexible printed circuit board FPCB, and the plurality of sensor units S1 to S32 may be printed or deposited on the FPCB.
Also, the internal sensor module 100 may output a sensing signal from the plurality of sensor units S1 to S32 through a channel to the connector CN. Here, the channel may be printed on an upper surface, a lower surface, or an intermediate layer of the substrate ST, and may be a conducting wire through which each of the sensor units S1 to S32 transmits a sensing signal sensing a pressure.
The internal sensor module 100 may include a plurality of row sensor groups SA to SD. That is, the internal sensor module 100 may include a first row sensor group SA, a second row sensor group SB, a third row sensor group SC, and a fourth row sensor group SD. can
In each of the plurality of row sensor groups SA to SD, some of the sensor units S1 to S32 form one row and may be arranged in a column direction.
According to an embodiment of the present disclosure, the first row sensor group SA is located on the frontmost side among the plurality of row sensor groups SA to SD, and the second row sensor group SB is The first row sensor group SA is positioned in a rearward direction, the third row sensor group SC is positioned in a rearward direction than the second row sensor group SB, and the fourth row sensor group SD is arranged in a plurality of rows. It may be located on the rearmost surface of the sensor groups SA to SD.
According to an embodiment of the present disclosure, the internal sensor module 100 includes a first row sensor group SA including some of the plurality of sensor units S1 to S32, and a plurality of sensor units S1 to S32. ) of the second row sensor group SB including another part, the third row sensor group SC including another part of the plurality of sensor units S1 to S32, and the plurality of sensor units S1 to A fourth row sensor group SD including the rest of S32) may be included.
In this case, the separation distance between the first row sensor group SA and the second row sensor group SB may be greater than the separation distance between the second row sensor group SB and the third row sensor group SC, and The separation distance between the second row sensor group SB and the third row sensor group SC may be substantially the same as the separation distance between the third row sensor group SC and the fourth row sensor group SD. Accordingly, it is possible to precisely sense the hip region of the seated person to which the body pressure of the seated person is applied with the same number of sensor units. Conversely, by arranging fewer sensor units in the thigh region of the seated person, to which the body pressure of the seated person is applied, an efficient circuit design can be achieved, and the cost can be reduced and the sensing efficiency can be improved. Meanwhile, the separation distance between the row sensor groups means the shortest distance between each of the two row sensor groups in the row direction.
According to an embodiment of the present disclosure, the number of sensor units included in the first row sensor group SA and the fourth row sensor group SD is the same, and the second row sensor group SB and the third row The number of sensor units included in the sensor group SC may be the same. As an example, each of the sensor units included in the first row sensor group SA and the fourth row sensor group SD may be three, and each of the sensor units in the second row sensor group SB and the third row sensor group SC may have three. The number of included sensor units may be 5 each. Accordingly, by locating a relatively large number of sensor units in the sensor groups SB and SC located relatively centrally in the internal sensor module 100 , cost reduction and sensing efficiency may be increased.
According to an embodiment of the present disclosure, one end of each of the plurality of sensor units (S1 to S3, S7 to S11, S17 to S21, S27 to S29) located on the left half of the internal sensor module 100 is a first channel One end of each of the plurality of sensor units (S4~S6, S12~S16, S22~S26, S30~S32) located on the right half of the internal sensor module is electrically connected by (CH1) and has a second channel (CH2) ), and the other end of each of the plurality of sensor units S1 to S32 may output sensing signals through a plurality of different channels.
For example, the internal sensor module 100 may include a plurality of channels including a first channel CH1 and a second channel CH2 . When the plurality of sensor units S1 to S32 are 32, one end of each is connected to the first channel CH1 and the second channel CH2, and the other end is connected to each other by a plurality of different channels. Connected. Accordingly, the internal sensor module 100 may include 34 channels. In other words, the internal sensor module 100 may include two more channels than the number of the plurality of sensor units S1 to S32 .
4 is for explaining an internal sensor module according to a comparative example.
Referring to FIG. 4 , the internal sensor module 100 ′ according to the comparative example may include sensor units SU that do not consider body pressure that is distributed when the occupant sits on a cushion. In this case, even though body pressure in the thigh region of the seated person is not applied to the internal sensor module 100 ′, since many sensor units SU are disposed, an increase in cost and a decrease in sensing efficiency may occur.
However, according to an exemplary embodiment of the present disclosure, when a occupant sits on the cushion 20, a plurality of sensor units S1 to S32 are arranged in the internal sensor module 100 in consideration of the body pressure that is dispersed, thereby providing an efficient sensor. It is possible to reduce the cost due to the use of the unit and increase the sensing efficiency.
5A, 5B and 6 are for explaining the structure of an external manipulation module according to an exemplary embodiment of the present disclosure.
5A and 6 , the cushion 20 may include a pocket 21 into which the external manipulation module 300 located on the left or right side can be inserted. The external manipulation module 300 may further include a locking member 340 . Here, the locking member 340 may be formed on the lower surface of the case of the external manipulation module 300 so as to be fixed to the outside (outer surface) of the pocket 21 . In addition, the input unit 310 and the display unit 320 may be formed on the upper surface of the case opposite to the lower surface of the case.
5B and 6, the cushion 20 may further include a locking groove 22 on the left side or the right side. A description of the same or similar configuration as that of FIG. 5A will be omitted. The engaging member 340 may be seated in the engaging groove 22 , and the external manipulation module 300 may be fixed to the left or right side of the cushion 20 . Unlike FIG. 5A , since the wire 330 is not twisted, durability may be improved. In addition, when the engaging member 340 is not seated in the engaging groove 22 , the external manipulation module 300 may be seated in the pocket 21 .
On the other hand, the locking groove 22 may be implemented in the form of a pocket in which the upper surface is perforated and the remaining surfaces are closed, and the upper and lower surfaces are perforated and the other side surfaces are blocked. In addition, the locking groove 22 may be implemented with the same material as the outer shell of the cushion 20, but is not limited thereto.
According to an exemplary embodiment of the present disclosure, the external manipulation module 300 is electrically connected to the cushion 20 and spaced apart through the internal processing module 200 and the wire 330 . Accordingly, even if the shape of the cushion 20 is deformed by the seated person sitting on the cushion 20 , the body pressure of the seated person is not transmitted to the external manipulation module 300 , so that the durability of the external manipulation module 300 can be increased.
In addition, by fixing the external manipulation module 300 to the outside of the pocket 21 , the user can conveniently operate the external manipulation module 300 while seated, and the external manipulation module 300 can be inserted into the pocket 21 . By inserting it in the cushion 20, it is possible to prevent the disconnection of the wire 330 without damaging the aesthetics of the cushion 20, and to prevent the loss of the external operation module 300.
Exemplary embodiments have been disclosed in the drawings and specification as described above. Although the embodiments have been described using specific terms in the present specification, these are used only for the purpose of explaining the technical spirit of the present disclosure, and are not used to limit the meaning or the scope of the present disclosure described in the claims. Therefore, it will be understood by those skilled in the art that various modifications and equivalent other embodiments are possible therefrom. Accordingly, the true technical protection scope of the present disclosure should be defined by the technical spirit of the appended claims.

Claims (9)

An electronic device for guiding posture correction, comprising:
A cushion;
an internal sensor module positioned inside the cushion and including a substrate including a plurality of sensor units;
an internal processing module located inside the cushion, including a vibration unit and a battery providing driving power, and transmitting posture data to a user terminal through a communication unit based on a sensing signal output from the internal sensor module; and
An external operation module located outside the cushion and including an input unit for controlling the power state of the internal processing module; includes,
The external operation module,
In order to charge the battery, electric power provided from an external power source is transferred to the battery through a wire interconnected with a first connector of the internal processing module formed on a first substrate and a second connector of the external operation module formed on a second substrate provided by
The internal processing module,
a processor for managing the power state of the electronic device as one of a standby mode, a sleep mode, and a power off mode based on a period in which a sensing signal is received;
a voltage regulator that limits and outputs a voltage of the driving power provided from the battery to a preset level range of 3.0 volts or more and 3.3 volts or less in the standby mode; and
When the voltage of the driving power provided from the battery is difficult to maintain the torque and speed of the motor of the vibrating unit, a voltage sensor boosting the voltage of the driving power and providing it to the processor;
The cushion is
The external manipulation module may include a locking groove on which a locking member of the external manipulation module is seated so that the user can sculpt while seated; and
and a pocket into which the external manipulation module can be inserted to prevent the external manipulation module from being lost on a left side or a right side when the external manipulation module is not seated in the locking groove. According to claim 1,
The internal sensor module,
a first row sensor group including some of the plurality of sensor units; a second row sensor group including another part of the plurality of sensor units; a third row sensor group including another part of the plurality of sensor units; and a fourth row sensor group including the rest of the plurality of sensor units,
A separation distance between the first row sensor group and the second row sensor group is greater than a separation distance between the second row sensor group and the third row sensor group, and the distance between the second row sensor group and the third row sensor group is greater than that of the second row sensor group and the third row sensor group. The separation distance is substantially equal to the separation distance between the third row sensor group and the fourth row sensor group. 3. The method of claim 2,
The number of the plurality of sensor units included in the first row sensor group and the fourth row sensor group is the same, and the number of the plurality of sensor units included in the second row sensor group and the third row sensor group is Electronic devices characterized in that they are identical to each other. According to claim 1,
One end of each of the plurality of sensor units located on the left half of the internal sensor module is electrically connected by a first channel, and one end of each of the plurality of sensor units positioned on the right half of the internal sensor module is An electronic device electrically connected by a second channel, and the other end of each of the plurality of sensor units outputs sensing signals through a plurality of different channels. According to claim 1,
The cushion includes a pocket into which the external manipulation module located on the left side or the right side can be inserted,
In the external manipulation module, a locking member provided to be fixed to the cushion is formed on a lower surface of the case, and the input unit and the display unit are formed on an upper surface of the case opposite to the lower surface.

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