KR102491849B1 - Retainer for photoelectric sensor and photoelectric pulse wave masuring apparatus having the same - Google Patents

Abstract

A photoelectric sensor retainer and a photoelectric pulse wave measuring device having the same are disclosed. The disclosed photoelectric sensor retainer includes a pedestal including a sensor installation portion to which a photoelectric sensor having a light-receiving surface is detachable, a presser that presses and presses an upper surface of the sensor installation portion, and a seat plate that supports the pressurizer. The photoelectric sensor may be mounted on the sensor installation part so that the light-receiving surface faces the measurement direction. The pressurizer may press while pressing the sensor installation part in the measurement direction with respect to the pedestal. The main plane of the seat plate is parallel to a plane orthogonal to the pressing direction of the pressing machine.

Description

Retainer for photoelectric sensor and photoelectric pulse wave masuring apparatus having the same}

The present invention relates to a photoelectric sensor retainer for supporting a photoelectric sensor and a photoelectric pulse wave measuring device including the same.

Patent Document 1 discloses a pulse wave measuring device as an example of a photoelectric pulse wave measuring device. The pulse wave measuring device includes a light emitter and a photoelectric sensor. The light emitter includes a light emitting element that irradiates, for example, near-infrared light to blood vessels. The near-infrared light is reflected from blood vessels and becomes reflected light. A photoelectric sensor includes a light receiving element that receives reflected light.

As shown in the 12th to 27th lines of page 6 of Patent Document 1, the pulse wave measuring device is used only for measuring the pulse rate. In addition, since it is lightweight and suitable for carrying, it is possible to check the pulse rate during exercise.

The inventors have further developed the prior art and attempted to accurately measure pulse wave waveforms to the extent that biomarkers can be estimated from pulse wave waveforms. The background of the discovery of the subject by the inventors will be described below.

Figure 1 shows a photoelectric sensor retainer 14 for the subject. The retainer 14 includes a pedestal 19 of the photoelectric sensor and a band 90 coupled thereto. A photoelectric sensor 75 is mounted on the pedestal 19 . The band 90 is a band or belt made of resin used in a wristwatch.

Retainer 14 is mounted around forearm 95 . Figure 1 shows in particular around the wrist of the forearm 95. When the band 90 is tightened, the photoelectric sensor 75 contacts the skin surface 96 of the forearm 95.

In order to perform measurement accurately with the photoelectric sensor 75 shown in Fig. 1, it is necessary to create a state in which the paths of irradiation light and scattered light do not deviate. This state needs to be maintained for a certain period of time to measure the pulse wave. Therefore, when measuring pulse waves, it is necessary to bring the light emitter 80 and the photoelectric sensor 75 into close contact with the surface 96. Further, the suppressing force must be such that the optical axis of the irradiated light does not shift.

For this reason, it is preferable that the light receiving surface 77 of the photoelectric sensor 75 is in contact with the surface 96 near the radial artery 97 of the forearm 95. The light-receiving surface 77 is preferably directed in a predetermined measurement direction. The predetermined measurement direction is preferably a direction parallel to the normal of surface 96 .

However, the shape of the surface 96 differs greatly depending on the subject's age, sex, and physique. For this reason, it is difficult to press the photoelectric sensor 75 toward the predetermined measurement direction in the vicinity of the radial artery 97 only by simply tightening the band 90 .

This is because it is difficult to control the magnitude and direction of the force applied to the photoelectric sensor only by tightly tightening the band 90 . That is, since the position of the photoelectric sensor on the band 90 is not constant, the force applied by the band 90 is distributed according to the law of action and reaction.

It is conceivable to solve the above problems by enlarging the size of the retainer 14 shown in Fig. 1 and adding electric pressurizing equipment. However, in this case, it is difficult to make the retainer 14 lightweight and of a suitable size for carrying.

1. Japanese Unexamined Patent Publication No. 2005-040259

An object of the present invention is to enable accurate measurement of pulse wave waveforms when a photoelectric sensor is mounted on a photoelectric sensor retainer.

A photoelectric sensor retainer according to an embodiment:

a sensor installation unit to which a photoelectric sensor having a light receiving surface is detachable;

a pressurizer that presses and presses the upper surface of the sensor installation unit; and

A pedestal including a seat plate supporting the pressurizer;

The photoelectric sensor can be installed in the sensor installation part so that the light-receiving surface faces the measurement direction,

The pressurizer presses while pressing the sensor installation part in the measurement direction with respect to the pedestal,

The main plane of the seat plate is parallel to a plane orthogonal to the pressing direction of the press machine.

The presser is screwed to the seat plate, and an end thereof pushes the upper surface of the sensor installation part by the rotation of the presser to adjust the distance between the seat plate and the upper surface.

Further comprising a suspension mechanism supporting the sensor installation unit,

The suspension mechanism includes a frame disposed to face the sensor installation unit with respect to the seat;

A plurality of links are fixedly connected to the frame and the sensor installation part and pass through the seat plate.

Further comprising a coil spring surrounding the link between the seat plate and the frame,

The coil spring repels the sensor installation part in a direction opposite to the measurement direction.

The plurality of links are three or more, and surround the pressurizer.

According to one aspect, it further includes a band connected to the pedestal,

The measurement direction is toward the inside of the ring formed from the band and the pedestal,

The pedestal includes wings formed on both sides of the seat plate,

The band includes one end and the other end connected to the wing,

The pedestal is rotatable about each rotation axis with respect to the band in each wing,

An adjustment mechanism for adjusting the inclination of the main plane of the seat plate and the plane including the pivot shaft is further provided.

The adjustment mechanism is formed on each wing and adjusts the distance between the rotation axis and the main plane.

In each of the blades, a pin constituting the pivot shaft is further provided,

In the wing, the adjusting mechanism includes a plurality of holes having different distances from the main plane,

The pins are attached to and detached from the plurality of holes, respectively.

The sensor installation part:

foundation;

a sensor support located on a measurement direction side with respect to the foundation;

And a piezoelectric element between the base and the sensor support,

The base unit is coupled to the suspension mechanism,

The sensor support portion includes a sensor support surface facing the measurement direction.

According to another aspect,

a stage supporting the pedestal;

a forearm support located on a side of the measurement direction with respect to the sensor installation unit;

A pair of support pillars supporting the stage and connected to the forearm support;

The stage is movable with respect to the support column in the measuring direction and in a direction opposite to the measuring direction,

The forearm support supports the forearm so that the radial artery of the forearm faces the sensor installation unit.

The stage is rotatable around a rotational axis orthogonal to a plane parallel to the longitudinal direction of the forearm support and the measurement direction.

The stage includes a protrusion extending in a direction facing the pair of support pillars and extending in parallel with the pivot shaft,

A long hole corresponding to the protrusion is formed in the pair of support pillars,

The protruding part is fixed to a position on the support pillar and a position rotated from the pivot shaft by a fixing means to the support pillar.

The photoelectric pulse wave meter according to the embodiment:

the photoelectric sensor retainer;

The photoelectric sensor having a light receiving surface and a substrate surface opposite to the light receiving surface and mounted on the sensor support surface;

The substrate surface faces the sensor support surface,

The light receiving surface is located inside the annulus.

When the photoelectric sensor is mounted on the photoelectric sensor retainer according to the embodiment, the waveform of the pulse wave can be accurately measured.

1 is a use diagram of a photoelectric sensor retainer of a related art;
Fig. 2 is a perspective view of the photoelectric sensor retainer of the first embodiment.
Fig. 3 is a perspective view of the photoelectric sensor retainer of the second embodiment.
Fig. 4 is a usage diagram of the photoelectric sensor retainer of the second embodiment.
5 is a front view of the photoelectric sensor retainer of the second embodiment.
6 is a diagram showing the use of the adjusting mechanism of the second embodiment.
7 is a diagram showing the use of the adjusting mechanism of the second embodiment.
Fig. 8 is a perspective view of the photoelectric sensor retainer of the third embodiment.
9 is a partially enlarged view of the photoelectric sensor retainer of the third embodiment.
Fig. 10 is a partially enlarged plan view of the photoelectric sensor retainer of the third embodiment.

Hereinafter, each embodiment is described referring drawings. In the description, like reference numerals are attached to equivalent components. In addition, the same code is used for components that are homogeneous components and differ only in positional relationship or arrangement position, and these are distinguished by alphabets at the end of the code. Accordingly, redundant description of equivalent or homogeneous components will be omitted.

Fig. 2 is a perspective view of the photoelectric sensor retainer 15 of the first embodiment. The retainer 15 includes a pedestal having an installation portion 60, a presser 30, and a seat plate 24. The installation unit 60 is a sensor installation unit. A photoelectric sensor is detached from the installation part 60 . The photoelectric sensor is a light receiver having a light receiving surface. A photoelectric sensor and a light emitter are installed in the retainer 15 to be used as a photoelectric pulse wave measuring instrument.

The installation part 60 is located on the lower part of the seat plate 24. The installation part 60 includes a base part 61 and a support part 66. The support 66 is a sensor support on the side of the measurement direction 74 with respect to the base 61 . Base 61 has a top surface 62 .

The pressurizer 30 of FIG. 2 includes a head part 31 and a shaft part 35. The head portion 31 and the shaft portion 35 may be integrally formed bolts. A screw groove may be formed in the shaft portion 35 . A direction in which the screw groove is formed may be a right screw direction. The shaft portion 35 is screwed into a hole formed in the seat plate 24.

The direction 32 shown in FIG. 2 is a clockwise direction with respect to the central axis of the shaft portion 35 when the pressurizer 30 is viewed as a plane. When the head part 31 rotates in the direction 32, the shaft part 35 rotates in the direction 32, and the pressurizer 30 moves in the same direction as the measuring direction 74 with respect to the seat plate 24.

As shown in FIG. 2 , when the head 31 is rotated in the direction 32 , the pressurizer 30 presses the upper surface 62 . The seat plate 24 supports the press machine 30 . The presser 30 contacts the seat plate 24 at a position passing through the seat plate 24 .

A photoelectric sensor may be mounted on the installation unit 60 shown in FIG. 2 so that the light receiving surface of the photoelectric sensor faces the measurement direction 74 . The surface of the forearm skin may be located in front of the measurement direction 74 . The measurement direction 74 may be parallel to the normal direction of the surface of the skin.

The pressurizer 30 shown in FIG. 2 presses and presses the installation part 60 in the same direction as the measurement direction 74 . Seat 24 has a main plane 18. The main plane 18 is parallel to the direction in which the pressurizer 30 presses the installation part 60, that is, a plane orthogonal to the pressing direction. When the installation unit 60 is viewed as a plane in the same direction as the measurement direction 74, the area of the installation unit 60 may be larger than that of the pressurizer 30.

The base portion 61 shown in FIG. 2 is coupled to the suspension mechanism 40 . Thus, the suspension mechanism 40 supports the installation portion 60 . The suspension mechanism 40 may include means for repelling the installation portion 60 toward a direction opposite to the measurement direction 74 . That is, a repulsive force in the opposite direction to the pressing force by the pressurizer 30 acts on the installation portion 60 . The means may be buffers 70a and 70b shown in FIG. 4 .

Since the area of the installation portion 60 shown in FIG. 2 is larger than that of the pressurizer 30, it is difficult for the pressurizer 30 to press the installation portion 60 while maintaining the appropriate direction of the light-receiving surface. Here, maintaining the appropriate direction of the light-receiving surface means maintaining a plane perpendicular to the light-receiving surface of the photoelectric sensor and the measurement direction 74 or parallel to the surface of the skin.

As shown in FIG. 1, if the light-receiving surface 77 cannot be held in an appropriate direction, the stress acting on the photoelectric sensor 75 from the surface 96 of the skin As a result, the installation portion 60 can be pressed while being oblique. In this case, the close contact between the light receiving surface 77 and the surface 96 is damaged.

In the case shown in Fig. 1, there is a possibility that the reflected light from the blood vessel escapes through the gap between the light receiving surface 77 and the surface 96 and does not reach the light receiving surface 77. Because of this, the signal/noise ratio can be reduced. In addition, disturbance light may enter from the gap between the light receiving surface 77 and the surface 96. When the disturbance light is photoelectrically converted, noise is newly generated for the signal of the pulse wave.

Considering this problem, it is preferable that the suspension mechanism 40 of FIG. 2 supports the installation part 60 at three or four or more points. Suspension mechanism 40 preferably surrounds pressurizer 30 .

The suspension mechanism 40 of FIG. 2 includes a frame 41 and links 50a, 50b, 50c, and 50d. The frame 41 is located above the seat board 24. The links 50a, 50b, 50c, and 50d are located below the frame 41.

The links 50a, 50b, 50c, and 50d of FIG. 2 are located between the frame 41 and the installation part 60. The links 50a, 50b, 50c, and 50d are coupled to the frame 41 and the installation portion 60, respectively. Links 50a, 50b, 50c and 50d surround the pressurizer 30. The links 50a, 50b, 50c, and 50d may be composed of bolts.

In the retainer 15 of FIG. 2 , the pressurizer 30 presses and presses the installation portion 60 . For this reason, the light-receiving surface of the photoelectric sensor attached to the installation portion 60 can be brought into closer contact with the skin surface of the forearm than when the pressurizer 30 is not present.

In the retainer 15 of FIG. 2 , the suspension mechanism 40 corrects the difference between the pressing direction of the pressurizer 30 and the measuring direction 74 . For this reason, compared to the case without the suspension mechanism 40, the photoelectric sensor can be pressed against the surface of the skin of the forearm along a direction close to parallel to its normal direction.

In the retainer 15 shown in FIG. 2 , the pressurizer 30 can press the installation portion 60 while maintaining the proper orientation of the light-receiving surface. A detailed description of the suspension mechanism 40 will be given in the second embodiment using the same suspension mechanism 40.

A second embodiment will be described with reference to FIGS. 3 to 7 . 3 is a perspective view of the photoelectric sensor retainer 16. The retainer 16 differs from the retainer 15 shown in FIG. 2 in that it further includes a band 90 and wings 26 and 27.

The retainer 16 shown in FIG. 3 includes a pedestal 20 . The pedestal 20 includes a wing 26 installed on one end of the seat board 24 and a wing 27 installed on the other end. The band 90 is connected to the pedestal 20 at the wings 26 and 27. Each of the wings 26 and 27 includes two blades facing each other with a predetermined gap therebetween.

The band 90 of FIG. 3 has one end 91 and the other end 92 . One end 91 is connected to the wing 26. One end 92 is connected to the wing 27. One end 91 and the other end 92 may be disposed between the two wing shapes of the wings 26 and 27.

The retainer 16 of FIG. 3 includes a pin 36 . The pin 36 constitutes a rotation axis. The pedestal 20 is rotatable about the pin 36 with respect to the band 90 .

Retainer 16 of FIG. 3 includes pins 37 . The pin 37 constitutes a rotation axis. The pedestal 20 is rotatable about the pin 37 with respect to the band 90 .

Retainer 16 of FIG. 3 includes adjustment mechanisms 28 and 29 . The adjusting mechanisms 28 and 29 are located on the wings 26 and 27, respectively. The pins 36 and 37 are detachable from the holes of the adjusting mechanisms 28 and 29, respectively. The pins 36 and 37 are easily detachable and facilitate adjustment of the inclination by the adjustment mechanisms 28 and 29.

4 is a front view of the retainer 16. Some members of the retainer 16 are omitted in FIG. 4 .

The suspension mechanism 40 of FIG. 4 includes a frame 41, links 50a and 50b, and shock absorbers 70a and 70b. Links 50c and 50d shown in FIGS. 2 and 3 are covered by links 50a and 50b in FIG. 4 .

Further, the links 50c and 50d shown in Figs. 2 and 3 also include shock absorbers equivalent to the shock absorbers 70a and 70b in Fig. 4 . In the following description, the links 50a and 50b and their associated members and sites will be described. However, the links 50c and 50d and members and parts related to them have the same configuration as those related to the links 50a and 50b.

The seat plate 24 included in the pedestal 20 of FIG. 4 includes an upper surface 21a and a lower surface 21b. The seat plate 24 includes a plurality of holes. The plurality of holes pass through the seat plate 24 . A hole surface 23 and hole surfaces 25a and 25b are formed in the plurality of holes, respectively. Screw grooves may be formed in the hole surface 23 and the hole surfaces 25a and 25b, respectively. The direction of the screw groove may be a right-hand screw direction.

The wings 26 of the pedestal 20 of FIG. 4 contact one end 22a of the seat plate 24. The wings 27 of the pedestal 20 contact the other end 22b of the seat plate 24.

The frame 41 of FIG. 4 includes an upper surface 46 on the opposite side of the measurement direction 74 and a lower surface 47 on the side of the measurement direction 74 . The frame 41 has a plurality of holes. The plurality of holes pass through the frame 41 . A hole surface 43 and hole surfaces 45a and 45b are formed in the plurality of holes, respectively. Screw grooves may be formed in the hole surface 43 and the hole surfaces 45a and 45b, respectively. The direction of the screw groove may be a right-hand screw direction.

The base portion 61 of FIG. 4 includes a lower surface 63 . The base portion 61 has a plurality of holes. The plurality of holes pass through the base portion 61 . A plurality of holes need not pass through the base portion 61 . Hole surfaces 65a and 65b are formed in the plurality of holes, respectively. Screw grooves may be formed in the hole surfaces 65a and 65b, respectively.

The support part 66 of FIG. 4 includes a support surface 68 which is a lower surface. The support surface 68 is a sensor support surface facing the measurement direction 74 . The support portion 66 includes a top surface 67 on the opposite side of the support surface 68 .

The shaft portion 35 of the pressurizer 30 of FIG. 4 includes shaft surfaces 33a, 33b, 33c, 33d, and 33e and end surfaces 34 in order of proximity from the head portion 31. The axial planes 33a, 33b, 33c, 33d, and 33e are identical axial planes. Each alphabet is nothing more than a convenient distinction to indicate the positional relationship between the axial plane, the frame 41, the seat 24, and the base 61.

The shaft surface 33a of FIG. 4 is located above the upper surface 46 of the frame 41 . The shaft portion 35 includes a portion where the shaft surface 33a is formed, and separates the head portion 31 from the frame 41 . The head portion 31 is formed so that the operator of the retainer 16 can easily hold it by hand.

The shaft surface 33b of FIG. 4 is located inside the hole surface 43 of the frame 41 or the hole formed by the hole surface 43 . The shaft surface 33b and the hole surface 43 are not in contact. Alternatively, even when the shaft surface 33b and the hole surface 43 come into contact, friction to the extent of obstructing the change in the position of the pressurizer 30 relative to the frame 41 is not generated.

The shaft surface 33c of FIG. 4 is located below the lower surface 47 of the frame 41 and above the upper surface 21a of the seat plate 24. The shaft surface 33c is surrounded by shock absorbers 70a and 70b and other shock absorbers (not shown ) associated with the links 50c and 50d.

The shaft surface 33d in FIG. 4 is located inside the hole surface 23 of the seat plate 24 or the hole formed by the hole surface 23. Screw grooves are formed at least in the shaft surface 33d and in the shaft surfaces 33c and 33e in regions close to the shaft surface 33d.

The shaft surface 33d and the hole surface 23 in Fig. 4 are screwed together as described above. There is a frictional force between the shaft surface 33d and the hole surface 23. The frictional force does not prevent the manipulator of the retainer 16 from turning the head 31. On the one hand, the friction force maintains the position of the pressurizer 30 after actuating the pressurizer 30 in the measuring direction 74 or in the opposite direction.

The shaft surface 33e of FIG. 4 is located below the lower surface 21b of the seat plate 24 and above the upper surface 62 of the base portion 61. The axial plane 33e is adjacent to the end face 34 . Of the shaft portion 35, the portion where the shaft surface 33e is formed changes in length according to the rotation of the shaft portion 35. This area determines the distance between the lower surface 21b and the upper surface 62 of the seat plate 24 .

The end face 34 in FIG. 4 contacts the upper surface 62 of the base 61 . Presser 30 presses against top surface 62 at end surface 34 . The end face 34 preferably contacts just above the center of the installation portion 60 . Accordingly, the pressurizer 30 can easily press the installation portion 60 in the same direction as the measuring direction 74 .

Links 50a and 50b in FIG. 4 include head portions 51a and 51b and shaft portions, respectively. The shafts of the links 50a and 50b are, in order closer to each other from the head 51a, shaft surfaces 52a and 52b, shaft surfaces 53a and 53b, shaft surfaces 54a and 54b, shaft surfaces 55a and 55b, and shaft surfaces 56a. , 56b) and cross sections 57a and 57b.

The links 50a and 50b may be bolts integrally formed with head portions 51a and 51b and shaft portions, respectively. A screw groove may be formed in the shaft portion. The screw groove direction may be a right-hand screw direction. Screw grooves are formed on at least the shaft surfaces 52a and 52b and the shaft surfaces 56a and 56b.

For the links 50a and 50b in Fig. 4, the shaft surfaces 52a and 52b, the shaft surfaces 53a and 53b, the shaft surfaces 54a and 54b, the shaft surfaces 55a and 55b, and the shaft surfaces 56a and 56b are the same shaft surfaces, respectively. . Each number of the axis planes 53a and 53b, the axis planes 54a and 54b, and the axis planes 55a and 55b are convenient for representing the positional relationship between the axis plane and the frame 41, the seat plate 24, and the base portion 61. nothing more than a distinction

The heads 51a and 51b of FIG. 4 are in contact with the upper surface 46 of the frame 41, respectively. The head portions 51a and 51b are used to rotate the links 50a and 50b when screwing the links 50a and 50b to the frame 41 and the base portion 61, respectively. The heads 51a and 51b may not be present.

Shaft surfaces 52a and 52b of FIG. 4 are screwed into hole surfaces 45a and 45b, respectively. There is a frictional force between the shaft surfaces 52a and 52b and the hole surfaces 45a and 45b, respectively. The friction force fixes the links 50a and 50b to the frame 41 .

Instead of screwing the shaft faces 52a, 52b and the hole faces 45a, 45b in Fig. 4 to each other, the links 50a, 50b and the frame 41 may be welded. In this case, it is not necessary to have screw grooves on the shaft surfaces 52a and 52b and the hole surfaces 45a and 45b, respectively.

The shaft surfaces 53a and 53b of FIG. 4 are located below the lower surface 47 of the frame 41 and above the upper surface 21a of the seat plate 24, respectively.

The shaft surfaces 54a and 54b of FIG. 4 are located inside the hole surfaces 25a and 25b of the seat plate 24 or the hole formed by the hole surfaces 25a and 25b, respectively. The shaft surfaces 54a and 54b and the hole surfaces 25a and 25b may not contact each other. Alternatively, even if the shaft surfaces 54a, 54b and the hole surfaces 25a, 25b are in contact with each other, friction to the extent of obstructing the positional change of the frame 41 and the mounting portion 60 relative to the seat plate 24 does not occur.

Shaft surfaces 55a and 55b of FIG. 4 are located below the lower surface 21b of the seat plate 24 and above the upper surface 62 of the base portion 61, respectively. Axial surfaces 55a and 55b are adjacent to end faces 57a and 57b, respectively.

Shaft surfaces 56a and 56b in FIG. 4 are screwed into hole surfaces 65a and 65b, respectively. There is a frictional force between the shaft surfaces 56a and 56b and the hole surfaces 65a and 65b, respectively. The friction force fixes the links 50a and 50b to the base 61, respectively.

Instead of screwing the shaft surfaces 56a, 56b and the hole surfaces 65a, 65b in Fig. 4, respectively, the links 50a, 50b and the base portion 61 may be welded. In this case, it is not necessary to have screw grooves on the shaft surfaces 56a and 56b and the hole surfaces 65a and 65b, respectively.

Sections 57a and 57b in FIG. 4 are exposed on the lower surface 63 side of the base portion 61, respectively. As long as the holes associated with the hole faces 65a and 65b do not penetrate the base 61, respectively, the end surfaces 57a and 57b may be inside the base 61, respectively. Further, the shaft surfaces 56a and 56b and the hole surfaces 65a and 65b may be respectively omitted. In this case, the end faces 57a and 57b are preferably bonded to the upper surface 62 of the base portion 61, respectively.

The shock absorbers 70a and 70b of FIG. 4 are preferably coil springs that form a spiral around the shaft surfaces 53a and 53b, respectively. When the coil spring is installed in the suspension mechanism 40, it is preferable that it is equal to or less than the length of the uncompressed state. That is, the coil spring is preferably a compressed spring.

The shock absorbers 70a and 70b of FIG. 4 include upper ends 71a and 71b and lower ends 72a and 72b, respectively. The upper ends 71a and 71b contact the lower surface 47 of the frame 41, respectively. The upper ends 71a and 71b may or may not be fixed to the lower surface 47, respectively. The lower ends 72a and 72b contact the upper surface 62 of the base portion 61, respectively. The lower ends 72a and 72b may or may not be fixed to the upper surface 62, respectively.

The adjusting mechanism 28 of FIG. 4 has a plurality of holes 28a, 28b and 28c at different distances from the principal plane 18. The distance between the holes 28a, 28b, and 28c and the principal plane 18 increases according to the order of the holes 28a, 28b, and 28c. The adjusting mechanism 29 has a plurality of holes 29a, 29b and 29c different in distance from the main plane 18. The distance between the holes 29a, 29b and 29c and the principal plane 18 increases in the order of the holes 29a, 29b and 29c. Holes 28a, 28b, 28c and holes 29a, 29b, 29c may or may not penetrate the wings 26 and 27, respectively.

The pedestal 20 composed of the seat plate 24 and wings 26 and 27 of FIG. 4 has a crank shape. That is, when the retainer 16 is viewed from the front, the longitudinal direction of the wings 26 and 27 is preferably orthogonal to a plane parallel to the main plane 18 of the seat plate 24. Further, it is preferable that the blades 26 extend downward from the main plane 18 and the blades 27 extend upward.

Also, at least one of the blades 26 and 27 in FIG. 4 may extend upward and downward from the main plane 18 . That is, the pedestal 20 composed of the seat plate 24 and the wings 26 and 27 may have an H shape.

The holes 28a, 28b, and 28c and the holes 29a, 29b, and 29c of FIG. 4 may be formed along the longitudinal direction of the wings 26 and 27, respectively. That is, the holes 28a, 28b, and 28c and the holes 29a, 29b, and 29c are preferably aligned in a direction orthogonal to a plane parallel to the principal plane 18, respectively.

In addition, each of the wings 26 and 27 of FIG. 4 has two wings as shown in FIG. 3 . Because of this, holes are formed on both sides of the two wings. That is, in FIG. 3, holes are formed on the front and rear sides of the wings 26 and 27, respectively.

The installation part 60 of FIG. 4 includes one or more piezoelectric elements 85 . The piezoelectric element 85 is located between the base part 61 and the support part 66. The piezoelectric element 85 has an upper surface 86 in contact with the lower surface 63 of the base portion 61 . The piezoelectric element 85 has a lower surface 87 in contact with the upper surface 67 of the support part 66 .

As shown in FIG. 4 , the photoelectric sensor 75 and the light emitters 80a and 80b are installed on the support surface 68 of the support part 66 to form a photoelectric pulse wave measuring instrument. The photoelectric pulse wave measuring device can measure the volume of a predetermined region of a blood vessel.

The mounted photoelectric sensors may be 1, 2, or 3 or more. The mounted light emitters may be 1, 2, or 3 or more. The arrangement of the photoelectric sensor and light emitter is not limited. It is preferable that the photoelectric sensor and the light emitting device be a single module. With the module, the photoelectric sensor and the light emitter can be attached or detached from the support surface 68 of the support part 66 efficiently.

When the light emitters 80a and 80b of FIG. 4 emit green light, the distance between the photoelectric sensor 75 and the light emitters 80a and 80b may be, for example, 2 mm or more and 3 mm or less. When the light emitters 80a and 80b emit red light, the interval may be around 5 mm, or between 4.5 mm and 5.5 mm.

As shown in FIG. 4 , the aforementioned photoelectric pulse wave measuring device may include a retainer 16 , one photoelectric sensor 75 , and two light emitters 80a and 80b. The light emitters 80a and 80b may emit light having different wavelength peaks. The photoelectric sensor 75 may receive and photoelectrically convert light having a different wavelength peak.

The photoelectric sensor 75 of FIG. 4 has a light receiving surface 77. The photoelectric sensor 75 has a substrate surface 76 on the opposite side of the light receiving surface 77. The photoelectric sensor 75 is mounted on the installation part 60 . Substrate surface 76 faces support surface 68 .

Light emitters 80a and 80b of FIG. 4 have light emitting surfaces 82a and 82b. The light emitters 80a and 80b have substrate surfaces 81a and 81b opposite to the light emitting surfaces 82a and 82b. The light emitters 80a and 80b are mounted on the installation part 60 . The substrate surfaces 81a and 81b oppose the support surface 68 .

The light emitters 80a and 80b of FIG. 4 are suitable for reducing the weight of the photoelectric pulse wave measuring instrument and may be light emitting diodes (LEDs). The light emitters 80a and 80b preferably emit light, for example, light having a single wavelength or a single wavelength peak.

The light emitters 80a and 80b of FIG. 4 emit light into the living body, specifically toward the skin or blood vessels of the forearm. Light is reflected in vivo, specifically in the skin or blood vessels of the forearm. Light scatters upon reflection. The photoelectric sensor 75 receives the scattered light and converts it into an electrical signal. The photoelectric pulse wave measuring device may calculate the pulse wave from the electrical signal by a predetermined method.

The pressurizer 30 of FIG. 4 presses the upper surface 62 with a predetermined force. For this reason, the photoelectric sensor 75 and the light emitters 80a and 80b mounted on the mounting portion 60 are pressed in the measurement direction 74 with a predetermined force. It is preferable that the predetermined force is adjusted so that a pressure equivalent to the blood pressure at the measurement site is applied. When the area of the upper surface 62 is about 0.5 cm ² , it is preferably 0.5 N or more and 1.5 N or less, more preferably 0.9 N or more and 1.1 N or less, and even more preferably 1 N. The piezoelectric element 85 detects the magnitude of the force.

On the other hand, since the structure of the surface of the skin is not the same, it is preferable that the area to which the pressure is applied is small enough not to disturb the positional relationship between the light-receiving surface 77 and the light-emitting surfaces 82a and 82b. Therefore, in order to satisfy the items related to the predetermined force of the pressurizer 30 described above, it is preferable to obtain the predetermined force empirically after optimizing the surface shape and the area of the upper surface 62 of the pressurizer 30. .

The piezoelectric element 85 of FIG. 4 may bring reproducibility of pressure applied to a blood vessel when measuring a pulse wave. That is, by adjusting the position of the pressurizer 30, the pressure applied to each blood vessel can be made constant when the pulse wave is measured several times. For this reason, the measurement accuracy of the pulse wave is improved, and the bias in the collected data is reduced.

5 is a view of retainer 16 in use. Some members included in the retainer 16 are omitted from FIG. 5 . The band 90 and the pedestal 20 may form a ring. The measurement direction 74 is directed toward the inside of the ring composed of the band 90 and the pedestal 20. The light receiving surface 77 is positioned inside the ring.

The band 90 of FIG. 5 is preferably a belt or band made of resin. Since the band 90 has certain elasticity or rigidity, it is possible to maintain a positional relationship between the pedestal and the forearm. Since it is difficult to resist the stress at the time of pressing by the pressurizer 30 of FIG. 3, it is preferable that the band does not have the elasticity of rubber.

The band 90 of FIG. 5 may have a changeable length. Accordingly, pulse waves of a plurality of subjects having different forearm thicknesses can be measured with one photoelectric sensor retainer.

The band 90 of FIG. 5 may be separated into two bands between both ends 91 and 92 . The ring composed of the pedestal 20 and the band 90 may open and close the ring by separating and combining the two bands. The means for separating and coupling the band may be a combination of a buckle and a fixing bar, or may be a fastener. Accordingly, the photoelectric sensor retainer can be easily attached or detached from the forearm.

In FIG. 5, pins 36 and 37 are attached to holes 28b and 29b of the adjustment mechanisms 28 and 29 shown in FIG. Holes (not shown) through which the pins 36 and 37 pass may be formed at both ends 91 and 92 of the band 90, respectively. Pins 36 and 37 may be mounted in holes 28c and 29c remote from principal plane 18 as shown in FIG. This will be described in more detail with reference to FIGS. 6 and 7 .

6 and 7 are views of the adjustment mechanism 28, 29 in use. Adjusting mechanisms 28 and 29 respectively adjust the inclination between the principal plane 18 of the seat 24 and the plane containing the pivot axes associated with the pins 36 and 37. Specifically, the distance between the rotational axis associated with the pins 36 and 37 and the main plane 18 of the seat 24 shown in FIG. 4 is adjusted. Pins 36 and 37 temporarily fix the tilt. That is, the pins 36 and 37 fix the slope during pulse wave measurement.

In Fig. 6, pins 36 and 37 are mounted in holes 28b and 29b. As shown in FIG. 4, the holes 28b and 29b are closer to the principal plane 18 than the holes 28c and 29c, and farther from the principal plane 18 than the holes 28a and 29a.

By selecting the mounting positions of the pins 36 and 37 shown in FIG. 6, it is possible to give an inclination between the main plane 18 and the plane containing the axis of rotation associated with the pins 36 and 37. The slope may be, for example, greater than 0° and less than or equal to 20°. Alternatively, a step may be provided between the main plane 18 and the plane including the axis of rotation associated with the pins 36 and 37.

In Fig. 7, pins 36 and 37 are attached to holes 28c and 29c. As shown in FIG. 4, holes 28c and 29c are farther from principal plane 18 than holes 28a and 29a and holes 28b and 29b. Therefore, as shown in FIG. 7, by selecting the mounting positions of the pins 36 and 37, the gap between the main plane 18 and the plane including the rotation axis associated with the pins 36 and 37 is larger than that shown in FIG. slope can be given.

In FIG. 6 , the pins 36 and 37 may be attached to positions asymmetrical with respect to the center of the pedestal 20 . For example, when attaching the pin 36 to the hole 28b, you may attach the pin 37 to the holes 29a and 29c. When the pin 37 is attached to the hole 29b, the pin 36 may be attached to the holes 28a and 28c.

In addition, in Fig. 7, when the pin 36 is attached to the hole 28c, the pin 37 may be attached to the hole 29a. When the pin 37 is attached to the hole 29c, the pin 36 may be attached to the hole 28a. As shown in FIG. 3, it is not necessary to give a gradient.

Referring back to FIG. 5 , in retainer 16 , adjustment mechanisms 28 and 29 comprising holes 28b and 29b are adapted to press light receiving surface 77 against surface 96 perpendicularly. That is, the adjusting mechanisms 28 and 29 can rotate the light receiving surface 77 about an axis parallel to the radial artery 97.

In particular, the radial artery 97 shown in FIG. 5 is located at a distance from the long axis or short side of the forearm cross-sectional ellipse. Adjustment mechanisms 28, 29 are adapted to press the photoelectric sensor perpendicularly against the surface 96 of the skin near the radial artery 97.

The above effect can be obtained even when the surface 96 of the skin is not parallel to the plane including the axis of rotation associated with the pins 36 and 37 shown in FIG.

In order to maintain the proper direction of the light receiving surface 77 for each subject's forearm 95 shown in Fig. 5, the adjusting mechanisms 28 and 29 have selectable holes other than the holes 28b and 29b as described above.

As shown in FIG. 5 , the retainer 16 makes it possible to press the photoelectric sensor 75 on the wrist artery including the radial artery 97 and measure the pulse wave. At this time, since the retainer 16 has the suspension mechanism 40 and the adjusting mechanisms 28 and 29, the proper direction of the light receiving surface 77 can be maintained. The definition of maintaining the appropriate orientation of the light receiving surface is as described above.

As shown in FIG. 5, the surface 96 and the light receiving surface 77 are brought into close contact with the light receiving surface 77 maintaining an appropriate direction. Accordingly, it is possible to suppress the above-described decrease in the signal/noise ratio or generation of new noise.

According to this embodiment, it is possible to provide a structure suitable for accurately measuring pulse wave waveforms when a photoelectric sensor is attached to the photoelectric sensor retainer while making the size of the photoelectric sensor retainer lightweight and suitable for carrying.

A third embodiment will be described with reference to FIGS. 8 and 9 . 8 is a perspective view of the photoelectric sensor retainer 17. Retainer 17 includes retainer 15 . On the other hand, the retainer 17 is different from the retainer 16 in that it includes a stage 69, support pillars 59a and 59b, and a forearm support 64 instead of the band and adjusting mechanisms 28 and 29 of FIG. .

As for the retainer 17 shown in Fig. 8, detailed descriptions of components identical to those of the retainer 16 (Figs. 3 to 7) related to the second embodiment are omitted. It is the same as the second embodiment in that it can be used as a photoelectric pulse wave measuring device by installing a photoelectric sensor and a light emitter. The retainer 17 is suitable for use in a stationary type photoelectric pulse wave measuring device.

9 is a partially enlarged view of the retainer 17. The stage 69 of FIG. 9 supports a pedestal including a seat plate 24 . The pedestal including the seat plate 24 includes end portions 38a and 38b. Preferably, the width of the ends 38a and 38b is greater than the width of the seat plate 24 . When retainer 15 is mounted on stage 69, stage 69 supports ends 38a and 38b. Accordingly, the retainer 15 can be stably mounted on the stage 69 .

As shown in FIG. 8 , the retainer 17 includes a cover 49 . As seen in FIG. 9 , the cover 49 is mounted on the upper surface side of the stage 69 . The cover 49 includes a hole 79 . Holes 79 are open on the upper and lower surfaces of the cover 49 . A hole 79 passes through the cover 49 . The longitudinal direction of the hole 79 is preferably parallel to the longitudinal direction of the hole 39 formed on the stage 69 .

As shown in FIG. 9 , a hole 39 passes through the stage 69 . It is preferable that the longitudinal direction of the hole 39 is substantially orthogonal to the longitudinal direction of the forearm support 64 shown in FIG. 8, that is, the extending direction of the radial artery of the forearm.

As shown in FIG. 9 , the installation part 60 is located in the hole 39 or exiting the hole 39 on the lower surface side of the stage 69 . Accordingly, the installation portion 60 faces the surface of the skin of the forearm fixed on the forearm support 64.

On the other hand, as shown in FIG. 8, the pressurizer 30 is located in the hole 79 or exiting the hole 79 on the upper surface side of the cover 49. Thus, the head 31 of the pressurizer 30 is exposed on the upper side of the cover 49 . For this reason, even after attaching the cover 49 to the stage 69, the pressurizer 30 can be operated to press the installation part 60.

The retainer 15 shown in FIGS. 8 and 9 is slideable in the longitudinal direction of the hole 39 and the hole 79 . Therefore, when the retainer 17 is viewed as a flat surface, the positional relationship between the part where the pulse wave is to be measured and the photoelectric sensor attached to the retainer 15 can be arbitrarily adjusted.

As shown in FIG. 9 , mounted cover 49 presses ends 38a and 38b against stage 69 . At this time, the cover 49 restricts the retainer 15 from sliding on the hole 39. Therefore, it is possible to stably maintain the above-described adjusted positional relationship. Instead of the cover 49, the pedestal including the seat plate 24 may be temporarily fixed to the stage 69 with screws, pins, or the like.

Referring to FIG. 8 , the forearm support 64 is located on the side of the measurement direction 74 with respect to the installation portion 60 (see FIG. 2 ) included in the retainer 15 . The forearm support 64 supports the forearm so that the radial artery of the forearm faces the installation part 60 . Accordingly, when the retainer 17 is viewed as a flat surface, the positional relationship between the part where the pulse wave is to be measured and the photoelectric sensor attached to the retainer 15 can be stably maintained.

Support pillars 59a and 59b in FIG. 8 support the stage 69 . The stage 69 is movable in the measuring direction 74 and in the direction opposite to the measuring direction 74 with respect to the support pillars 59a and 59b. That is, the stage 69 can be moved in the vertical direction. Accordingly, when the retainer 17 is viewed from the side, the positional relationship between the part where the pulse wave is to be measured and the photoelectric sensor attached to the retainer 15 can be arbitrarily adjusted.

The stage 69 of FIG. 8 is rotatable about a rotation axis 89 . The pivot axis 89 is orthogonal to a plane parallel to the longitudinal direction and the measurement direction 74 of the forearm support 64 . 10 is a plane view of the retainer 17 shown in FIG. 9 . The pivot axis 89 is parallel to the direction in which the support pillars 59a and 59b face each other.

Protrusions 69a may be formed on opposite sides of the stage 69 , respectively. The protrusions 69a are supported in the vertical holes 59c and 59d of the support pillars 59a and 59b. The protrusion 69a is formed along the rotation axis 89 and has a cylindrical shape. Accordingly, the stage 69 may rotate about the pivot axis 89 . Screw grooved holes 69c may be formed on both sides of the protruding portion 69a and the stage 69 contacting the protruding portion 69a. The bolts 69e and 69f may be combined with screw grooves formed in the holes 89c to fix the stage 69 to the support pillars 59a and 59b. After adjusting the vertical position of the stage 69 by turning the heads 69h formed on the bolts 69e and 69f, by turning the heads 69h of the bolts 69e and 69f again, the position of the stage 69 is moved to the support pillar 59a. , 59b).

The retainer 17 of FIG. 10 includes spacers 99a, 99b, 99c, and 99d between the support posts 59a and 59b and the stage 69. In Fig. 10, the support column 59a includes spacers 99a and 99c. Further, the support pillar 59b includes spacers 99b and 99d. The spacers 99a, 99c and the spacers 99b, 99d contact the protruding portion 69a of the stage 69, respectively, and support the protruding portion 69a.

According to the illustration of FIG. 10, unintentional rotation of the stage 69 and the retainer 15 can be prevented. In addition, by making the spacers 99a, 99b, 99c, and 99d of a high-friction material such as rubber, the force for limiting unintentional rotation can be further increased.

Referring again to FIG. 8 , the support posts 59a and 59b are directly or indirectly connected to the forearm support 64 . The positional relationship between the support pillars 59a and 59b and the forearm support 64 is temporarily or permanently fixed. Further, the positional relationship between the stage 69 and the support pillars 59a and 59b can be temporarily fixed. Thereby, even if it presses while pressing the attachment part 60 and the skin surface with the pressurizer 30, the positional relationship adjusted as mentioned above can be stably maintained. In addition, the support pillar may be straight or curved.

The forearm support 64 of FIG. 8 may further include a wrist support 94 . The wrist support portion 94 opposes the installation portion 60 that the retainer 15 includes. Accordingly, the forearm support 64 can make the surface of the skin immediately above the radial artery oppose the light-receiving surface of the photoelectric sensor mounted on the installation part 60.

The retainer 17 shown in FIG. 8 is suitable for pressing a photoelectric sensor on the wrist artery including the radial artery and measuring the pulse wave. At this time, since the retainer 17 has the suspension mechanism 40 and the forearm support 64, the proper orientation of the light receiving surface 77 can be maintained. The definition of maintaining an appropriate direction of the light receiving surface has been described above.

The present invention is not limited to the above embodiments, and appropriate changes are possible within a range not departing from the gist. The photoelectric sensor retainer related to the above embodiment may be a jig used when testing the performance of the photoelectric sensor or comparing data collected by the photoelectric sensor.

The retainer 15 shown in Fig. 2 may be used as a sensor jig for maintaining an appropriate orientation of the light-receiving surface. The retainers 16 and 17 shown in Figs. 3 to 9 may be used as a measuring jig for maintaining an appropriate orientation of the light-receiving surface. Such a photoelectric sensor retainer can increase reproducibility at the time of measurement in testing or data comparison.

For example, data collected using the retainer 16 shown in FIG. 3 and data collected using the retainer 17 shown in FIG. 8 may be compared. This makes it possible to measure the difference in performance of the photoelectric sensor when it is attached to a portable type photoelectric pulse wave measuring device and when it is attached to a stationary type photoelectric pulse wave measuring device.

In addition, a database is required to convert pulse waves into blood pressure. Using the photoelectric sensor retainer of the above embodiment as a jig improves the degree of data collection for building the database. This is because the photoelectric sensor retainer of this embodiment makes the pressure applied to the blood vessel and the direction of the blood vessel constant during measurement of the pulse wave.

The pressurizer 30 of FIG. 2 may be a cylinder whose length changes with a fluid containing air.

The holes 28a, 28b, and 28c and the holes 29a, 29b, and 29c of FIG. 4 may be one long hole. That is, the inclination of the main plane 18 can be adjusted steplessly. In this case, it is preferable to provide a fixing mechanism to the pins 36 and 37 of FIG. 3 and the long hole. In addition, it is also possible to provide a means for measuring the inclination.

15: retainer 18: main plane
24: seat plate 30: pressurizer
31: head part 35: shaft part
40: suspension mechanism 41: frame
50a, 50b, 50c, 50d: link 60: installation part
61: base 66: support
74: measurement direction

Claims (13)

a sensor installation unit to which a photoelectric sensor having a light receiving surface is detachable;
a pressurizer that presses and presses the upper surface of the sensor installation unit;
a pedestal including a seat plate supporting the pressurizer; and
a suspension mechanism supporting the sensor installation unit; Provided with,
The photoelectric sensor can be installed in the sensor installation part so that the light-receiving surface faces the measurement direction,
The pressurizer presses while pressing the sensor installation part in the measurement direction with respect to the pedestal,
The main plane of the seat plate is parallel to a plane orthogonal to the pressing direction of the presser,
The suspension mechanism includes a frame disposed to face the sensor installation unit with respect to the seat; and
a plurality of links that pass through the seat plate while fixing and connecting the frame and the sensor installation unit; A photoelectric sensor retainer comprising a. According to claim 1,
The pressurizer is screwed to the seat plate, and an end portion of the pressurizer adjusts the distance between the seat plate and the top surface by pushing the upper surface of the sensor installation part by the rotation of the pressurizer. delete According to claim 1,
Further comprising a coil spring surrounding the link between the seat plate and the frame,
The coil spring repels the sensor installation part in a direction opposite to the measurement direction. According to claim 1,
The plurality of links are three or more, and the photoelectric sensor retainer surrounds the pressurizer. According to claim 1,
Further comprising a band connected to the pedestal,
The measurement direction is toward the inside of the ring formed from the band and the pedestal,
The pedestal includes wings formed on both sides of the seat plate,
The band includes one end and the other end connected to the wing,
The pedestal is rotatable about each rotation axis with respect to the band in each wing,
and an adjusting mechanism for adjusting an inclination of the main plane of the seat plate and a plane including the pivot shaft. According to claim 6,
The adjusting mechanism is formed on each wing and adjusts the distance between the pivot shaft and the main plane. According to claim 7,
In each of the blades, a pin constituting the pivot shaft is further provided,
In the wing, the adjusting mechanism includes a plurality of holes having different distances from the main plane,
The photoelectric sensor retainer wherein the pins are attached to and detached from the plurality of holes, respectively. The method of claim 1, wherein the sensor installation unit:
foundation;
a sensor support located on a measurement direction side with respect to the foundation; and
And a piezoelectric element between the base and the sensor support,
The base unit is coupled to the suspension mechanism,
The photoelectric sensor retainer of claim 1 , wherein the sensor support portion includes a sensor support surface facing the measurement direction. According to claim 1,
a stage supporting the pedestal;
a forearm support located on a side of the measurement direction with respect to the sensor installation unit; and
A pair of support pillars supporting the stage and connected to the forearm support;
The stage is movable with respect to the support column in the measuring direction and in a direction opposite to the measuring direction,
The forearm support is a photoelectric sensor retainer that supports the forearm so that the radial artery of the forearm faces the sensor installation unit. According to claim 10,
The photoelectric sensor retainer of claim 1 , wherein the stage is rotatable around a rotational axis orthogonal to a plane parallel to the longitudinal direction of the forearm support and the measurement direction. According to claim 11,
The stage includes a protrusion extending in a direction facing the pair of support pillars and extending in parallel with the pivot shaft,
A long hole corresponding to the protrusion is formed in the pair of support pillars,
The photoelectric sensor retainer of claim 1 , wherein a position of the protruding part on the support pillar and a position rotated from the rotation axis are fixed to the support pillar by a fixing means. The photoelectric sensor retainer of claim 9; and
The photoelectric sensor having a light receiving surface and a substrate surface opposite to the light receiving surface and mounted on the sensor support surface;
The photoelectric sensor retainer further includes a band connected to the pedestal,
The measurement direction is toward the inside of the ring formed from the band and the pedestal,
The substrate surface faces the sensor support surface,
The light-receiving surface is located inside the ring.

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