KR20200069150A - Pulse wave detecting device for reducing hand fatigue - Google Patents

Abstract

The present invention relates to a pulse wave detection device for reducing hand fatigue, which comprises a light emitting element and a light receiving device, and stably and precisely detects a pulse wave by supporting a fingertip in an optimal condition in accordance with the shape and size of the fingertip, when detecting a change in volume of a blood vessel, according to a beat in the state of fixing the fingertip, as an electrical signal.

Description

Pulse wave detecting device for reducing hand fatigue}

The present invention relates to a pulse wave sensing device, and in detail, a light emitting element and a light receiving element are provided, and the fingertip is detected as an electrical signal by detecting the change in the volume of the blood vessel according to the beat by changing the amount of transmitted light while the fingertip is fixed. The present invention relates to a pulse wave sensing device that stably and accurately detects pulse waves and reduces hand fatigue by supporting optimal conditions in response to the shape and size of the portion.

With the development of medical IT technology, various types of bio-information detection devices have been developed, and instead of the conventional invasive method for detecting bio-information such as pulse waves, the subject does not cause pain and simply detects pulse waves. Noninvasive methods that can be done are preferred.

For accurate pulse wave analysis (PWA), information based on an optical signal or a pressure signal is obtained from a body part of a subject, and a fingertip is mainly used.

1 is a side cross-sectional view showing a finger fixing structure of a conventional pulse wave sensing device, and is configured to fix a sensor device having a light-receiving element and a light-emitting element in a form of pressing a finger tip.

This has the advantage that the sensor device can be easily detached, but since the pressure is pressed through the spring, the force is not constant according to the size and shape of the user's various hands. It causes problems such as sharpening the tension waveform of the amount that returns to the vein of heavy blood.

Of course, methods such as correcting these problems through algorithms are being considered, but it is not a fundamental solution due to mechanical correction, and even if the force of the spring is weakened, the user may experience sweat due to compression or close contact with the sensor device. I had no choice but to feel uncomfortable.

Patent Publication No. 10-2014-0031589 (2014.03.13)

The present invention was created to solve the above problems, and an object of the present invention is to detect a change in volume of a blood vessel according to a heartbeat in a state in which a fingertip is inserted as an electrical signal by changing the amount of transmitted light, but the fingertip It is to provide a pulse wave sensing device that reduces fatigue of a hand that can stably and accurately detect pulse waves by supporting it in optimum conditions in response to the shape and size of a part.

In order to achieve the above object, the present invention provides a pulse wave sensing device that supports a fingertip, comprising: a body formed with an insertion portion capable of inserting a user's finger in front; A first sensor unit which is formed at the inner rear end of the insertion unit and senses the contact or approach of the inserted finger tip; A second sensor unit having a light emitting device that emits light toward the inserted finger and a light receiving device that receives light transmitted through the finger; A position adjusting unit which moves the second sensor unit in the vertical direction, and raises the user's finger from the initial position at the bottom to a height pressing the set pressure; A control unit calculating a pulse wave through a waveform of light received through the light receiving element, and operating the position adjusting unit according to the contact detection of the first sensor unit; It is characterized by consisting of.

At this time, the second sensor unit is coupled to be movable up and down by a distance set by the position adjusting unit, and may further include an elastic body acting to raise the second sensor unit.

In addition, the position control unit further includes a decompression element that senses the pressure applied to the second sensor unit, and the control unit is configured to not collect a signal through the second sensor unit when the pressure of the decompression element is greater than or equal to a set value. Can be.

In addition, a plurality of vent holes communicating with the insertion portion are formed in the body, and the inside of the insertion portion is made of a fiber member made of a ventilation material, and the second sensor portion is formed in the longitudinal direction of the insertion portion to be in contact with the user's hand. A light emitting element and a light receiving element may be configured between a pair of supports.

In addition, the second sensor unit may be configured such that the light emitting element is located on the upper side of the user's finger inserted in the insertion portion and the light receiving element is located on the lower side of the finger.

In addition, it is preferable to further include a fixing part supporting the user's finger by ascending and descending in connection with the position adjusting part 130.

According to the present invention, in detecting pulse wave through the fingertip, the pulse wave can be stably and accurately detected by supporting the optimal condition in response to the shape and size of the inserted fingertip, and greatly reducing hand fatigue. You can get the effect.

1 is a side sectional view showing a finger fixing structure of a conventional pulse wave sensing device,
2 is a perspective view according to an embodiment of the present invention,
Figure 3 is a side cross-sectional view according to an embodiment of the present invention,
Figure 4 is a partial perspective view showing the state of the second sensor unit according to an embodiment of the present invention,
5 is a side cross-sectional view according to another embodiment of the present invention.

Hereinafter, the structure of the pulse wave sensing device for reducing fatigue of the hand of the present invention will be described in detail with reference to the accompanying drawings.

Figure 2 is a perspective view according to an embodiment of the present invention, Figure 3 is a side cross-sectional view according to an embodiment of the present invention, Figure 4 is a partial perspective view showing the state of the second sensor unit according to an embodiment of the present invention, the present invention is a finger The end part is supported to detect the pulse wave.

The body 100 provided for this purpose is formed in such a way that an insertion portion 101 through which a user's finger can be inserted is formed on the front side to surround the inserted finger tip.

A first sensor unit 110 for detecting contact or approach of the inserted finger tip is installed at the inner rear end of the insertion unit 101 to detect whether a finger is inserted into the insertion unit 101 at a predetermined depth. do. The first sensor unit 110 is made of various sensors capable of detecting a finger contact, for example, a decompression sensor or an electrostatic sensor, and supports a smooth insertion of a finger for pulse wave measurement.

A second sensor unit 120 having a light emitting element 121 that emits light toward the inserted finger side and a light receiving element 122 that receives light transmitted through the finger is installed in the lower portion inside the insertion portion 101. Since this can be said to be substantially the same as the configuration of the conventional pulse wave sensor mentioned above, a detailed description will be omitted to prevent the spirit of the invention from being blurred.

In the prior art, the second sensor unit 120 is fixed to the user's fingertip in the form of forceps, but in the present invention, the second sensor unit 120 is moved up and down through the electric position adjusting unit 130. It moves in the direction and makes contact with the finger.

That is, the position adjusting unit 130 raises the user's finger inserted from the initial position of the lower end away from the user's finger to a height that presses the set pressure to the second sensor unit 120 to stably contact the user's fingertip. In order to be configured, a motor 131 with an adjustable speed and a gear part 132 for changing the rotation direction of the shaft of the motor 131, the second sensor part through rotation of the gear part 132 ( It is configured so that the height of 120) can be adjusted.

In the accompanying drawings, through the gear portion 132 made of a bevel gear, the rotational direction of the rotational axis of the motor lying sideways is rotated to rotate the vertical axis, but the plate material combined with the screw formed through the outer circumferential surface of this axis is penetrated. It supports the sensor unit 120 and shows a state in which it can be lifted through axial rotation.

If the user detects this by pulling the finger out of the insertion unit 101, the position adjusting unit 130 lowers the second sensor unit 120 to restore the initial position.

At this time, the second sensor unit 120 is coupled to be movable to move up and down by a predetermined interval by floating upward to the plate for supporting the position adjustment unit 130, that is, the second sensor unit 120 from the bottom, the second It is preferable to be coupled to the plate through an elastic body 133 acting to raise the sensor unit 120.

This is for the buffering action corresponding to the pressure applied through the user's hand in the state where the second sensor unit 120 is in contact with the user's finger, reducing the discomfort caused by unintentional finger movement and the second sensor unit ( 120) can be prevented from being pressed by excessive force.

The control unit 140 is basically configured to calculate the pulse wave of the user through the waveform of the light received through the light receiving element 122 constituting the second sensor unit 120, in addition to this, the first sensor unit According to the contact detection of (110) performs control to operate the position adjustment unit 130. That is, as described above, when a finger is inserted into the insertion unit 101, the first sensor unit 110 senses this and the position adjusting unit 130 raises the second sensor unit 120 to contact the finger. . Conversely, when a finger is removed from the insertion unit 101, the first sensor unit 110 detects it and the position adjusting unit 130 lowers the second sensor unit 120 to restore the initial position. At this time, a signal may be given to the position adjusting unit 130 using a switch or sensor for separating fingers.

At this time, it is important that the second sensor unit 120 is in contact with the finger at a constant pressure, and if the finger is pressed too strongly, the blood vessel is pressed and smooth pulse wave measurement cannot be performed. It is preferable to further include a decompression element 134 for sensing the pressure applied to the 2 sensor unit 120. The pressure-reducing element 134 may be installed in various ways, and in the accompanying drawings, it is installed under the elastic body 133 to detect that the second sensor unit 120 is pressurized to a predetermined or higher level.

In response to this, the control unit 140 is configured not to collect a signal through the second sensor unit 120 when the pressure of the pressure reduction element 134 is greater than or equal to a set value, so as to prevent an error value of pulse wave measurement from being collected. do.

Basically, the body 100 is provided with an environment in which only the insertion portion 101 is opened, so that a substantially closed environment is created when a finger is inserted. Due to this, discomfort due to sweat or body temperature generated by the finger and malfunction of the sensor may be caused, the body 100 is formed with a plurality of vent holes 102 communicating with the inside of the insertion portion between the inside and outside. In order to allow the flow of air, the inside of the insertion portion 101 is made of a fiber member 103 made of a ventilation material to suppress the occurrence of sweat due to finger contact.

In addition, when the second sensor unit 120 is in contact with a finger for a long time, a malfunction may occur due to sweat or the like generated from the finger, so it is necessary to configure the device to minimize contact with the finger. To this end, in the present invention, the light emitting element 121 and the light receiving element 122 are formed between the pair of supports 123 that are formed in the longitudinal direction of the insertion portion 101 and are in contact with the user's hand. By doing so, the contact between the second sensor unit 120 and the finger is minimized.

That is, as shown in the accompanying drawings, a groove is formed in the center and both ends are projected upward, so that the light emitting element 121 and the light receiving element 122 are positioned in the central concave portion of the structure forming the support 123, so that the linear support is Only the (123) maintains the state in contact with the finger, minimizes the occurrence of sweat in the contact portion, and the light emitting element 121 and the light receiving element 122 can be operated smoothly.

5 is a side cross-sectional view according to another embodiment of the present invention.

The second sensor unit 120 shown in FIG. 3 is a reflection type, and has a structure in which both the light emitting element 121 and the light receiving element 122 are located at the lower side, but the light emitting element 121 is lower at the upper side of the finger due to the transmission type. The light-receiving element 122 is positioned to receive light transmitted through a finger. Of course, it is obvious that the same effect can be obtained by placing the light-receiving element on the upper side of the finger and the light-emitting element on the lower side.

Further, in order to stably fix the finger inserted into the insertion part 101, the area of the position adjusting part 130 may be widened to support the finger, but support may be made by separately configuring the fixing part 150 having a similar structure. Can be configured to.

That is, the fixing part 150 is a plate-shaped configuration that raises the user's finger inserted from the initial position of the lower end away from the finger to a height that presses at a set pressure to fix the finger to the body 100. (151), the motor 151 is provided with a gear portion 152 for changing the rotation direction of the shaft, the height of the fixed portion 150 can be adjusted through the rotation of the gear portion 152, 2, the elevating and descending is performed in connection with the elevating operation of the sensor unit 120.

Likewise, the plate of the fixing part 150 is coupled to be movable up and down by a predetermined interval, but is coupled through an elastic body 153 that acts to raise it, so that it can buffer the pressure applied through the user's hand. It is desirable to construct.

The rights of the present invention are not limited to the embodiments described above but are defined by the claims, and those skilled in the art can make various modifications and adaptations within the scope of the claims. It is self-evident.

100: body 101: insert
102: vent 103: fiber member
110: first sensor unit 120: second sensor unit
121: light emitting element 122: light receiving element
123: support 130: position adjustment unit
131: motor 132: gear unit
133: elastic body 134: pressure reducing element
140: control unit 150: fixing unit

Claims (6)

In the pulse wave sensing device for supporting the fingertip,
Body 100 is formed with an insertion portion 101 that can insert the user's finger in the front;
A first sensor unit 110 formed on the inner rear end of the insertion unit 101 to sense contact or approach of the inserted finger tip;
A second sensor unit 120 having a light emitting element 121 that emits light toward the inserted finger side and a light receiving element 122 that receives light transmitted through the finger;
A position adjusting unit 130 which moves the second sensor unit 120 in the vertical direction, and raises the user's finger to a height that presses the user's finger at a preset pressure from the initial position at the bottom;
A control unit 140 for calculating a pulse wave through a waveform of light received through the light receiving element 122, and operating the position adjusting unit 130 according to the contact detection of the first sensor unit 110; Pulse wave sensing device for reducing the fatigue of the hand, characterized in that consisting of.
According to claim 1,
The second sensor unit 120 is coupled to be movable up and down by a distance set in the position adjustment unit 130, but further comprising an elastic body 133 that acts to raise the second sensor unit 120 A pulse wave sensing device that reduces hand fatigue.
According to claim 2,
The position adjustment unit 130 further includes a decompression element 134 for sensing the pressure applied to the second sensor unit 120,
The control unit 140 is a pulse wave sensing device for reducing the fatigue of the hand, characterized in that configured to not collect a signal through the second sensor unit 120 when the pressure of the decompression element 134 is greater than or equal to the set value.
According to claim 1,
The body 100 is formed with a plurality of vent holes 102 communicating with the insertion portion 101,
The inside of the insertion portion 101 is made of a fiber member 103 of a ventilation material,
The second sensor unit 120 is formed in the longitudinal direction of the insertion unit 101 is positioned between the light emitting device 121 and the light receiving device 122 between the pair of supports 123 in contact with the user's hand A pulse wave sensing device that reduces hand fatigue.
According to claim 1,
The second sensor unit 120 is configured to position the light emitting element 121 on the upper side of the user's finger inserted in the insertion portion 101 and the light receiving element 122 on the lower side of the finger. Reducing pulse wave sensing device.
According to claim 2,
In conjunction with the position adjustment unit 130, the elevating and descending,
Pulse wave sensing device for reducing the fatigue of the hand, characterized in that it further comprises a fixing portion 150 to support the user's fingers by rising.

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