JP2006102162A - Hemadynamometer - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a hemadynamometer capable of being always worn and easily mounted. <P>SOLUTION: The hemadynamometer has a pressure sensor detecting a pressurizing force pressurizing a living body, a pulse wave sensor detecting the pulse wave at the site where the pressure sensor detects, and at least one pressurizing part pressurizing the living body in an arm having at least two edge parts. The shape of the arm is the shape suitable for clamping the part of the living body such as a V shape, a U shape, a C shape, a channel shape, a W shape, and an E shape. The burden of the subject always wearing the hemadynamometer can be reduced by forming the arm in the shape suitable for wearing on the auricle of ear with many small unevennesses because the auricle of ear has few pain sites. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a sphygmomanometer that clamps a living body with an arm.

  With the aging of society, dealing with adult lifestyle-related diseases has become a major social issue. It is recognized that long-term blood pressure data collection is very important, especially for diseases related to high blood pressure. From such a point of view, various biological information measuring devices including blood pressure have been developed. Conventionally, there has been no sphygmomanometer having a structure in which only a corresponding surface is pressurized with only a sphygmomanometer that pressurizes with a structure that surrounds the entire measurement site.

  A conventional technique for measuring biological information with an external ear includes a patient monitor device that is inserted into the external auditory canal or another part in the external ear and is always worn (for example, see Patent Document 1). This apparatus calculates pulse, pulse wave, electrocardiogram, body temperature, arterial oxygen saturation, blood pressure, and the like from the amount of received infrared light and visible light scattered light. However, this apparatus has no means for fixing to the ear and cannot measure biological information stably. Moreover, the specific measurement method of blood pressure is not specified.

  In addition, the ear has a complicated shape (for example, see Non-Patent Documents 2 and 3), but a conventional device is attached to the ear canal. For this reason, fixation was difficult.

  On the other hand, regarding blood pressure measurement, blood pressure measurement devices based on pulsation waveforms of blood vessels are influential along with other methods such as cuff vibration method and volume compensation method (for example, see Non-Patent Document 1). It is recognized as a method for measuring blood pressure.

In the present application, the names of the auricles are based on Non-Patent Documents 2 and 3. The front side of the pinna refers to the surface of the pinna with the ear canal, and the back side of the pinna refers to the surface of the pinna without the ear canal.
JP-A-9-128203 Kenichi Yamakoshi, Tatsuo Togawa: “Biological Sensors and Measurement Devices”, MM Japan Society / ME Textbook Series A-1, pages 39-52 Sobotta Illustrated Human Anatomy Volume 1 (Translation by Michio Okamoto), p. 126, Medical School, issued October 1, 1996 Sobotta Illustrated Human Anatomy Volume 1 (Translation by Michio Okamoto), p. 127, Medical School, issued October 1, 1996

  Since it is difficult to measure blood pressure at regular intervals or continuously with daily blood pressure measurement or with a sphygmomanometer attached, a method for holding a biological information measuring device has been a problem.

  The present invention has been made to solve the above-described problems, and an object of the present invention is to provide a sphygmomanometer that can be always attached and can be easily attached.

  In order to achieve the above object, the present invention provides a pressure sensor for detecting a pressure applied to pressurize a living body, a pulse wave sensor for detecting a pulse wave at a site detected by the pressure sensor, and at least one for pressurizing the living body. And two pressure portions are provided on an arm having at least two ends. The shape of the arm is V-shaped, U-shaped, C-shaped, U-shaped, W-shaped, or E-shaped, and is suitable for holding a part of a living body. As described above, by providing a pressure sensor, a pulse wave sensor, and a pressurizing unit to an arm having a shape suitable for attachment to a living body, a blood pressure monitor that can be always attached and can be easily attached is provided. It becomes possible to do.

  In particular, since the pinna has few pain points, it is possible to reduce the burden on the subject who always wears the sphygmomanometer by making the arm shape suitable for mounting on the pinna with many fine irregularities. . Further, since the auricle is a part that is hardly covered by clothes or the like, it is easy to wear. As described above, the arm having a shape suitable for mounting on the protrusion of the living body, particularly the protrusion of the auricle, includes the pressure sensor, the pulse wave sensor, and the pressurizing unit, so that it can be always mounted. It is possible to provide a sphygmomanometer that is easy to wear.

  Specifically, a sphygmomanometer according to the present invention includes a V-shaped integrated arm having at least two ends, and at least one pressurizing unit that pressurizes a living body from either end of the arm, At least one pressure sensor that detects a pressure applied to the living body of the pressurizing unit from any one end of the arm; and a pulse wave at a part of the living body that is detected by the pressure sensor. And at least one pulse wave sensor that detects from the end.

  In addition, the sphygmomanometer according to the present invention includes a V-shaped monolithic arm having at least two ends, at least one pressurizing unit that pressurizes a living body from either end of the arm, and the pressurization At least one pressure sensor for detecting a pressurizing force to pressurize the living body of any part from any one end of the arm, and a pulse wave at a part of the living body to which the pressurizing part pressurizes, either end of the arm And at least one pulse wave sensor that detects from the above.

  Since the arm has an integral structure, it is possible to reduce the size and weight. As described above, by providing a pressure sensor, a pulse wave sensor, and a pressurizing unit on the arm of the V-shaped integrated structure having a shape suitable for mounting on the projection of the living body, particularly the projection of the auricle. Thus, it is possible to provide a blood pressure monitor that can be always worn and easily worn.

  A sphygmomanometer according to the present invention includes a U-shaped monolithic arm having at least two ends, at least one pressurizing unit that pressurizes a living body from either end of the arm, At least one pressure sensor that detects a pressure applied to pressurize a living body from one end of the arm, and a pulse wave at a part of the living body that is detected by the pressure sensor is detected from any end of the arm. And at least one pulse wave sensor.

  In addition, the sphygmomanometer according to the present invention includes a U-shaped monolithic arm having at least two ends, at least one pressurizing unit that pressurizes a living body from either end of the arm, and the pressurization At least one pressure sensor for detecting a pressurizing force to pressurize the living body of any part from any one end of the arm, and a pulse wave at a part of the living body to which the pressurizing part pressurizes, either end of the arm And at least one pulse wave sensor that detects from the above.

  Since the arm has an integral structure, it is possible to reduce the size and weight. In this way, by providing a U-shaped monolithic arm with a shape suitable for mounting on a living body protrusion, particularly an auricle protrusion, a pressure sensor, a pulse wave sensor, and a pressurizing section. Thus, it is possible to provide a blood pressure monitor that can be always worn and easily worn.

  A sphygmomanometer according to the present invention includes a C-shaped integrated structure arm having at least two end faces, at least one pressurizing part that pressurizes a living body from any one end face of the arm, and a living body of the pressurizing part. At least one pressure sensor that detects a pressing force to be applied from any end face of the arm, and at least one pulse that detects a pulse wave at a living body site detected by the pressure sensor from any end face of the arm. A wave sensor.

  In addition, the sphygmomanometer according to the present invention includes a C-shaped integrated structure arm having at least two end surfaces, at least one pressurizing unit that pressurizes a living body from one of the end surfaces of the arm, At least one pressure sensor for detecting a pressurizing force to pressurize a living body from any end face of the arm, and at least to detect a pulse wave at a part of the living body to be pressurized by the pressurizing unit from any end face of the arm. One pulse wave sensor.

  Since the arm has an integral structure, it is possible to reduce the size and weight. In this way, by providing a pressure sensor, a pulse wave sensor, and a pressurizing unit on the arm of a C-shaped integrated structure having a shape suitable for mounting on a living body projection, particularly an auricle projection. Thus, it is possible to provide a blood pressure monitor that can be always worn and easily worn.

  A sphygmomanometer according to the present invention includes a U-shaped monolithic arm having at least two ends, at least one pressurizing unit that pressurizes a living body from either end of the arm, and the pressurizing unit At least one pressure sensor for detecting a pressure applied to the living body from any one end of the arm, and detecting a pulse wave at a part of the living body detected by the pressure sensor from any end of the arm And at least one pulse wave sensor.

    In addition, the sphygmomanometer according to the present invention includes a U-shaped monolithic arm having at least two ends, at least one pressurizing unit that pressurizes a living body from either end of the arm, and the pressurizing unit. At least one pressure sensor for detecting a pressure applied to the living body of the pressure unit from any one end of the arm; and a pulse wave at a part of the living body to be pressurized by the pressurizing unit for either end of the arm. And at least one pulse wave sensor detected from the unit.

  Since the arm has an integral structure, it is possible to reduce the size and weight. As described above, a U-shaped monolithic arm having a shape suitable for attachment to a living body protrusion, particularly an auricle protrusion, includes a pressure sensor, a pulse wave sensor, and a pressurizing portion. Thus, it is possible to provide a sphygmomanometer that can be always worn and can be easily worn.

  The sphygmomanometer according to the present invention includes at least one arm that pressurizes a living body from an arm having a W-shaped integral structure having at least two ends and either of the two ends of the arm or an intermediate point facing the ends. One pressure sensor, at least one pressure sensor for detecting a pressurizing force to pressurize the living body of the pressure sensor from either one of the two ends of the arm or an intermediate point facing the end, and the pressure sensor And at least one pulse wave sensor that detects a pulse wave at a part of the living body to be detected from either of the two end portions of the arm or an intermediate point facing the end portion.

  The sphygmomanometer according to the present invention pressurizes a living body from either a W-shaped monolithic arm having at least two ends, or two ends of the arm or an intermediate point facing the ends. At least one pressurizing unit; and at least one pressure sensor that detects a pressurizing force that pressurizes the living body of the pressurizing unit from either of two ends of the arm or an intermediate point facing the end; and And at least one pulse wave sensor that detects a pulse wave at a part of the living body to be pressurized by the pressurizing unit from either one of the two ends of the arm or an intermediate point facing the end.

  Since the arm has an integral structure, it is possible to reduce the size and weight. In this way, by providing the pressure sensor, the pulse wave sensor, and the pressurizing unit on the arm of the W-shaped integrated structure having a shape suitable for mounting on the projection of the living body, particularly the projection of the auricle. Thus, it is possible to provide a blood pressure monitor that can be always worn and easily worn.

  A sphygmomanometer according to the present invention includes an E-shaped monolithic arm having at least three ends, at least one pressurizing unit that pressurizes a living body from one of the ends of the arm, At least one pressure sensor that detects a pressure applied to pressurize a living body from one end of the arm, and a pulse wave at a part of the living body that is detected by the pressure sensor is detected from any end of the arm. And at least one pulse wave sensor.

  The blood pressure monitor according to the present invention includes an E-shaped integrated arm having at least three ends, at least one pressurizing unit that pressurizes a living body from any one end of the arm, and the pressurization At least one pressure sensor for detecting a pressurizing force to pressurize the living body of any part from any one end of the arm, and a pulse wave at a part of the living body to which the pressurizing part pressurizes, either end of the arm And at least one pulse wave sensor that detects from the above.

  Since the arm has an integral structure, it is possible to reduce the size and weight. As described above, the E-shaped monolithic arm having a shape suitable for mounting on the protrusion of the living body, particularly the protrusion of the auricle, includes the pressure sensor, the pulse wave sensor, and the pressurizing unit. Thus, it is possible to provide a blood pressure monitor that can be always worn and easily worn.

  The sphygmomanometer according to the present invention includes a V-shaped structure arm having at least two ends, to which at least two structures are connected via one connection portion or one support shaft, and any one of the arms. At least one pressurizing unit that pressurizes the living body from an end of the arm, at least one pressure sensor that detects a pressurizing force that pressurizes the living body of the pressurizing unit from either end of the arm, and And at least one pulse wave sensor that detects a pulse wave at a part of the living body to be detected from either end of the arm.

  In addition, a sphygmomanometer according to the present invention includes a V-shaped arm having at least two ends, to which at least two structures are connected via one connection part or one support shaft, At least one pressurizing unit that pressurizes the living body from any one end, at least one pressure sensor that detects a pressurizing force that pressurizes the living body of the pressurizing unit from any one end of the arm, and the pressurizing unit And at least one pulse wave sensor for detecting a pulse wave at a part of the living body to be pressurized by the pressure unit from either end of the arm.

  Thus, by connecting via a connection part or a spindle, it becomes possible to vary the opening angle of an arm and the distance between arms using a connection part or a spindle. As a result, the arm can be temporarily expanded and attached, so that it is possible to provide a blood pressure monitor that is easier to attach. Moreover, if the adjustment of the clearance at the time of wearing by the subject is made possible, the burden on the subject who always wears the sphygmomanometer can be further reduced.

  A sphygmomanometer according to the present invention includes a U-shaped arm having at least two ends, to which at least two structures are connected via one connecting portion or one supporting shaft, and any one of the arms. At least one pressurizing unit that pressurizes the living body from an end of the arm, at least one pressure sensor that detects a pressurizing force that pressurizes the living body of the pressurizing unit from either end of the arm, and And at least one pulse wave sensor that detects a pulse wave at a part of the living body to be detected from either end of the arm.

  In addition, a sphygmomanometer according to the present invention includes a U-shaped structure arm having at least two ends, to which at least two structures are connected via one connection portion or one support shaft, At least one pressurizing unit that pressurizes the living body from any one end, at least one pressure sensor that detects a pressurizing force that pressurizes the living body of the pressurizing unit from any one end of the arm, and the pressurizing unit And at least one pulse wave sensor for detecting a pulse wave at a part of the living body to be pressurized by the pressure unit from either end of the arm.

  Thus, by connecting via a connection part or a spindle, it becomes possible to vary the opening angle of an arm and the distance between arms using a connection part or a spindle. As a result, the arm can be temporarily expanded and attached, so that it is possible to provide a blood pressure monitor that is easier to attach. Moreover, since it is possible to adjust the clearance when the subject wears, the burden on the subject who always wears the sphygmomanometer can be further reduced.

  A sphygmomanometer according to the present invention includes a C-shaped structure arm having at least two end faces in which at least two structures are connected via one connection part or one support shaft, and one of the arms At least one pressurizing unit that pressurizes a living body from an end surface; at least one pressure sensor that detects a pressing force that pressurizes the living body of the pressurizing unit from any end surface of the arm; and a living body that is detected by the pressure sensor And at least one pulse wave sensor that detects a pulse wave at a part of the arm from any end face of the arm.

  In addition, a sphygmomanometer according to the present invention includes a C-shaped structure arm having at least two end faces in which at least two structures are connected via one connection portion or one support shaft, and any of the arms. At least one pressurizing unit that pressurizes the living body from one of the end surfaces; at least one pressure sensor that detects a pressurizing force that pressurizes the living body of the pressurizing unit from any end surface of the arm; and And at least one pulse wave sensor that detects a pulse wave at a part of the living body to be pressurized from any end face of the arm.

  Thus, by connecting via a connection part or a spindle, it becomes possible to vary the opening angle of an arm and the distance between arms using a connection part or a spindle. As a result, the arm can be temporarily expanded and attached, so that it is possible to provide a blood pressure monitor that is easier to attach. Moreover, since it is possible to adjust the clearance when the subject wears, the burden on the subject who always wears the sphygmomanometer can be further reduced.

  A sphygmomanometer according to the present invention includes an arm having a U-shaped structure having at least two ends in which at least two structures are connected via one connection portion or one support shaft, At least one pressurizing unit that pressurizes the living body from the end, at least one pressure sensor that detects a pressing force that pressurizes the living body of the pressurizing unit from any end of the arm, and the pressure sensor And at least one pulse wave sensor that detects a pulse wave at a part of the living body to be detected from either end of the arm.

  In addition, a sphygmomanometer according to the present invention includes an arm having a U-shaped structure having at least two ends, to which at least two structures are connected via one connection portion or one support shaft, and the arm. At least one pressurizing unit that pressurizes the living body from any one of the end portions, at least one pressure sensor that detects a pressing force that pressurizes the living body of the pressurizing unit from any one end of the arm, and And at least one pulse wave sensor that detects a pulse wave at a part of the living body to be pressurized by the pressurizing unit from any end of the arm.

  Thus, by connecting via a connection part or a spindle, it becomes possible to vary the opening angle of an arm and the distance between arms using a connection part or a spindle. As a result, the arm can be temporarily expanded and attached, so that it is possible to provide a blood pressure monitor that is easier to attach. Moreover, since it is possible to adjust the clearance when the subject wears, the burden on the subject who always wears the sphygmomanometer can be further reduced.

  In the sphygmomanometer according to the present invention, both ends of the V-shaped structure and the ends of the two I-shaped structures are connected via two connecting portions or two support shafts at both ends of the V-shaped structure. An arm having a W-shaped structure having at least two ends, and at least one pressurizing unit that pressurizes the living body from either of the two ends of the arm or an intermediate point facing the ends, At least one pressure sensor for detecting pressure applied to pressurize the living body of the pressurizing unit from either one of the two ends of the arm or an intermediate point facing the end; and a part of the living body detected by the pressure sensor And at least one pulse wave sensor for detecting the pulse wave from either one of the two ends of the arm or an intermediate point facing the end.

  Moreover, the sphygmomanometer according to the present invention is configured such that both ends of the V-shaped structure and two end portions of the I-shaped structure are connected via two connecting portions or two support shafts at both ends of the V-shaped structure. W-shaped structure arms having at least two ends connected to each other, and at least one pressurizing unit that pressurizes the living body from either the two ends of the arms or an intermediate point facing the ends. And at least one pressure sensor for detecting a pressurizing force that pressurizes the living body of the pressurizing unit from either one of two ends of the arm or an intermediate point facing the end, and pressurizing the pressurizing unit And at least one pulse wave sensor that detects a pulse wave at a part of a living body from either of two ends of the arm or an intermediate point facing the end.

  Thus, by connecting via a connection part or a spindle, it becomes possible to vary the opening angle of an arm and the distance between arms using a connection part or a spindle. As a result, the arm can be temporarily expanded and attached, so that it is possible to provide a blood pressure monitor that is easier to attach. Moreover, since it is possible to adjust the clearance when the subject wears, the burden on the subject who always wears the sphygmomanometer can be further reduced.

  In the sphygmomanometer according to the present invention, the middle of the U-shaped structure having two connecting portions or two supporting shafts at the corner and the end of one I-shaped structure are connected. An arm having an E-shaped structure having at least three ends, at least one pressurizing unit that pressurizes the living body from any one end of the arm, and a pressing force that pressurizes the living body of the pressurizing unit. At least one pressure sensor for detecting from either end of the arm; and at least one pulse wave sensor for detecting a pulse wave at a part of the living body detected by the pressure sensor from either end of the arm; Is provided.

  Further, in the sphygmomanometer according to the present invention, the middle of the U-shaped structure having two connecting portions or two supporting shafts at the corner and the end of one I-shaped structure are connected. An E-shaped arm having at least three ends, at least one pressurizing unit that pressurizes the living body from any one end of the arm, and a pressurizing force that pressurizes the living body of the pressurizing unit At least one pressure sensor for detecting a pulse wave at a part of a living body to be pressurized by the pressurizing unit from any one end of the arm. And a sensor.

  Thus, by connecting via a connection part or a spindle, it becomes possible to vary the opening angle of an arm and the distance between arms using a connection part or a spindle. As a result, the arm can be temporarily expanded and attached, so that it is possible to provide a blood pressure monitor that is easier to attach. Moreover, since it is possible to adjust the clearance when the subject wears, the burden on the subject who always wears the sphygmomanometer can be further reduced.

  It is preferable that the connection portion includes a connection angle adjustment mechanism that can adjust an opening angle of the arm.

  By providing the connection angle adjusting mechanism that can adjust the opening angle of the arm, the opening angle of the arm can be varied. As a result, the arm can be temporarily expanded and attached, so that it is possible to provide a blood pressure monitor that is easier to attach. Moreover, since it is possible to adjust the clearance when the subject wears, the burden on the subject who always wears the sphygmomanometer can be further reduced.

  It is preferable that the support shaft includes at least one opening angle adjusting mechanism capable of adjusting the opening angle of the arm.

  By providing an opening angle adjusting mechanism that can adjust the opening angle of the arm, the opening angle of the arm can be varied. As a result, the arm can be temporarily expanded and attached, so that it is possible to provide a blood pressure monitor that is easier to attach. Moreover, since it is possible to adjust the clearance when the subject wears, the burden on the subject who always wears the sphygmomanometer can be further reduced.

  It is preferable that the support shaft includes a length adjusting mechanism that can adjust the length.

  By providing the support shaft with a length adjusting mechanism that can adjust the length, the distance between the arms can be varied. As a result, the arm can be temporarily expanded and attached, so that it is possible to provide a blood pressure monitor that is easier to attach. Moreover, since it is possible to adjust the clearance when the subject wears, the burden on the subject who always wears the sphygmomanometer can be further reduced.

  It is preferable that any one of the pressure sensor, the pulse wave sensor, or the pressurizing unit includes a distance adjustment mechanism that can adjust a distance from a portion where the arm faces.

  Any one of the pressure sensor, the pulse wave sensor, and the pressurizing unit includes a distance adjustment mechanism that can adjust a distance from a portion facing the arm, so that the pressure sensor 51, the pulse wave sensor 52, The distance from the arm of the pressurizing unit 53 can be finely adjusted to a distance suitable for constant wearing or blood pressure measurement. As a result, it is possible to provide a sphygmomanometer with improved blood pressure measurement accuracy and less burden on the subject.

  It is preferable that the pressure sensor, the pulse wave sensor, or the pressurizing unit includes a direction adjusting mechanism that can change a direction.

  The pressure sensor, the pulse wave sensor, or the pressurizing unit includes a direction adjustment mechanism that can change the direction, so that the pressure sensor, the pulse wave sensor, or the pressurizing unit is mounted at an angle that matches the shape of the test part. It becomes possible. This makes it possible to provide a blood pressure monitor that is easier to wear. Moreover, since a contact area with a test part can be increased, the burden of the test subject who always wears a sphygmomanometer can be further reduced.

  It is preferable that a portion of the arm that supports any one of the pressure sensor, the pulse wave sensor, and the pressurizing unit includes an extension mechanism that can extend in the major axis direction of the arm.

  The arm portion that supports any one of the pressure sensor, the pulse wave sensor, and the pressurizing unit includes an extension mechanism that can extend in the longitudinal direction of the arm, so that the pressure sensor, the pulse wave sensor, or the pressurizing unit is covered. It becomes possible to attach to the position according to the shape of the inspection part. This makes it possible to provide a blood pressure monitor that is easier to wear. Moreover, since it is possible to adjust the clearance when the subject wears, the burden on the subject who always wears the sphygmomanometer can be further reduced.

  It is preferable that the arm further includes a fixing mechanism to the human auricle.

  When the arm further includes a pinna fixing mechanism, it is possible to fix a portion where the arm is attached, that is, a portion where the pulse wave sensor is attached. As a result, the blood pressure can be measured at substantially the same site even when attached or detached, so that the accuracy of the sphygmomanometer can be improved.

  According to the present invention, the arm having a shape suitable for mounting on a living body protrusion, particularly an auricle protrusion, is provided with a pressure sensor, a pulse wave sensor, and a pressurizing section, so that it can be always mounted. It is possible to provide a sphygmomanometer that is easy to wear.

Hereinafter, the present invention will be described in detail with reference to the drawings, but the present invention is not construed as being limited to these descriptions.
(Embodiment 1)
FIG. 1 is a schematic diagram illustrating a sphygmomanometer according to the first embodiment. The sphygmomanometer according to the first embodiment includes at least one pressurizing unit 53 that pressurizes the living body from any one end 61 of the arm 11, and a pressurizing force that pressurizes the living body of the pressurizing unit 53. At least one pressure sensor 51 that is detected from the unit 61, and at least one pulse wave sensor 52 that detects a pulse wave at a body part detected by the pressure sensor 51 from any one end 62 of the arm 11. . The pulse wave sensor 52 may detect a pulse wave at a part of the living body to be pressurized by the pressurizing unit 53 from any end of the arm 11.

  In FIG. 1, the pressure sensor 51 is disposed at the end portion 61, but may be disposed at the end portion 62, or may be disposed at the end portions 61 and 62. Although the pulse wave sensor 52 is disposed at the end 62, it may be disposed at the end 61 or may be disposed at the ends 61 and 62. The pressurizing unit 53 is disposed at the end 61, but may be disposed at the end 62, or may be disposed at the ends 61 and 62.

  The arm 11 is in the form of a first arm, and is a V-shaped integrated structure that holds a part of the living body between the end portions 61 and 62. Examples of the material include metals such as gold, silver, and stainless steel, resin, leather, wood, rubber, and silicon. It is preferable that the refracting portion has elasticity and returns to the memorized shape. Moreover, since it is a thing which touches a biological body directly, it is preferable that the surface is flexible. For example, fibers, leather, resin, or rubber may be arranged on the surface.

  FIG. 2 is a schematic diagram of a sphygmomanometer having an arm of another form, in which (a) shows an example of the second arm and (b) shows an example of the third arm. The second arm is an arm having a V-shaped structure having at least two end portions 61 and 62 in which at least two structures 21a and 21b are connected via one connection portion 35. The third arm is a V-shaped arm having at least two end portions 61 and 62 to which at least two structures 21a and 21b are connected via one support shaft 36. The structures 21a and 21b include, for example, I-shaped structures such as rods, columns, cylinders, and prisms. The same material as that of the arm 11 can be used. However, since it does not need to bend, a hard material can be used. The connecting portion 35 and the support shaft 36 can connect the ends of the structures 21a and 21b to each other. The connection mechanism of the connection part 35 and the spindle 36 is not limited, and a movable mechanism may be provided. Thus, by connecting via a connection part or a spindle, it becomes possible to vary the opening angle of an arm and the distance between arms using a connection part or a spindle.

  The operation of the sphygmomanometer according to the first embodiment will be described. The pressurizing unit 53 applies pressure to a part of the living body (test portion) sandwiched between the end portions 61 and 62 to stop the blood flow flowing through the test portion. The pressure sensor 51 detects the pressure applied to the test part at this time. The pressurizing unit 53 gradually reduces the pressure to be applied, and the pulse wave sensor 52 detects a pulse wave at the pressurizing site in the process of decreasing the pressure. As described above, blood pressure can be measured. The pressure sensor 51 may detect the pressure applied to the pressurizing unit 53. Further, the pressure unit 53 may gradually increase the pressure, and the pulse wave sensor 52 may detect the pulse wave in the process of increasing the pressure.

  When the arm has an integral structure, the number of parts can be reduced, so that the size and weight can be reduced. Thus, by providing a pressure sensor, a pulse wave sensor, and a pressurizing unit on a V-shaped arm having a shape suitable for mounting on a protruding part of a living body, particularly an auricular protruding part, It is possible to provide a sphygmomanometer that can be always worn and easily worn. Further, since the arm is V-shaped, it can be easily manufactured.

(Embodiment 2)
FIG. 3 is a schematic diagram illustrating an example of a sphygmomanometer according to the second embodiment. The sphygmomanometer according to the second embodiment includes a U-shaped monolithic arm 12 having at least two ends, at least one pressurizing unit 53 that pressurizes a living body from either end 61 of the arm 12, and pressurization. At least one pressure sensor 51 that detects a pressing force that pressurizes the living body of the unit 53 from any one of the end portions 61 of the arm 12, and a pulse wave at a part of the living body that is detected by the pressure sensor 51 And at least one pulse wave sensor 52 that detects from the end 62. The pulse wave sensor 52 may detect a pulse wave at a part of the living body to be pressurized by the pressurizing unit 53 from any end of the arm 12.

  In FIG. 3, the pressure sensor 51 is disposed at the end portion 61, but may be disposed at the end portion 62, or may be disposed at the end portions 61 and 62. Although the pulse wave sensor 52 is disposed at the end 62, it may be disposed at the end 61 or may be disposed at the ends 61 and 62. The pressurizing unit 53 is disposed at the end 61, but may be disposed at the end 62, or may be disposed at the ends 61 and 62.

  The arm 12 is in the form of a fourth arm, and is a U-shaped integrated structure that holds a part of the living body between the end portions 61 and 62. Examples of the material include metals such as gold, silver, and stainless steel, resin, leather, wood, rubber, and silicon. It is preferable that the curved portion has elasticity and returns to a memorized shape. Moreover, since it is a thing which touches a biological body directly, it is preferable that the surface is flexible. For example, fibers, leather, resin, or rubber may be arranged on the surface.

  FIG. 4 is a schematic diagram of a sphygmomanometer having an arm of another form, in which (a) shows an example of a fifth arm and (b) shows an example of a sixth arm. The fifth arm is a U-shaped arm having at least two end portions 61 and 62 to which at least two structures 23 and 24 are connected via one connecting portion 35. The third arm is a U-shaped structure arm having at least two end portions 61 and 62 in which at least two structures 23 and 24 are connected via one support shaft 36. The structures 23 and 24 are I-shaped structures with curved ends. The connecting portion 35 or the support shaft 36 can connect the ends of the structures 23 and 24 on the curved side to each other. The connection mechanism of the connection part 35 and the spindle 36 is not limited, and a movable mechanism may be provided. Thus, by connecting via a connection part or a spindle, it becomes possible to vary the opening angle of an arm and the distance between arms using a connection part or a spindle.

  The operation of the sphygmomanometer of the second embodiment is the same as that of the sphygmomanometer of the first embodiment. When the arm has an integral structure, the number of parts can be reduced, so that the size and weight can be reduced. Thus, by providing a pressure sensor, a pulse wave sensor, and a pressurizing unit on a U-shaped arm having a shape suitable for mounting on a protruding part of a living body, particularly an auricular protruding part, It is possible to provide a sphygmomanometer that can be always worn and easily worn.

(Embodiment 3)
FIG. 5 is a schematic diagram illustrating an example of a sphygmomanometer according to the third embodiment. The sphygmomanometer according to the third embodiment includes a C-shaped monolithic arm 13 having at least two end surfaces, at least one pressurizing unit 53 that pressurizes a living body from any one end surface 63 of the arm 13, and a pressurizing unit 53. At least one pressure sensor 51 that detects a pressure applied to the living body from any one end surface 63 of the arm 13, and a pulse wave at a part of the living body that the pressure sensor 51 detects from any one end surface 64 of the arm 13. And at least one pulse wave sensor 52 for detection. The pulse wave sensor 52 may detect a pulse wave at a living body part to be pressurized by the pressurizing unit 53 from any end face of the arm 13.

  In FIG. 5, the pressure sensor 51 is disposed on the end surface 63, but may be disposed on the end surface 64, or may be disposed on the end surface 63 and the end surface 64. The pulse wave sensor 52 is disposed on the end surface 64, but may be disposed on the end surface 63, or may be disposed on the end surface 63 and the end surface 64. The pressurizing unit 53 is disposed on the end surface 63, but may be disposed on the end surface 64, or may be disposed on the end surfaces 63 and 62.

  The arm 13 is in the form of a seventh arm, and is an integral structure having a C-shape that sandwiches a part of a living body between the end face 63 and the end face 64. Examples of the material include metals such as gold, silver, and stainless steel, resin, leather, wood, rubber, and silicon. It is preferable that the curved portion has elasticity and returns to a memorized shape. Moreover, since it is a thing which touches a biological body directly, it is preferable that the surface is flexible. For example, fibers, leather, resin, or rubber may be arranged on the surface.

  FIG. 6 is a schematic diagram of a sphygmomanometer having an arm of another form, in which (a) shows an example of an eighth arm and (b) shows an example of a ninth arm. The eighth arm is a C-shaped structure arm having at least two end faces 63 and 64 in which at least two structures 25 and 26 are connected through one connection portion 35. The ninth arm is a C-shaped structure arm having at least two end faces 63 and 64 to which at least two structures 25 and 26 are connected via one support shaft 36. The structures 25 and 26 are curved arcuate structures. The same material as that of the arm 11 of the first embodiment can be used. The connecting portion 35 or the support shaft 36 can connect the ends of the structures 25 and 26 to each other. The connection mechanism of the connection part 35 and the spindle 36 is not limited, and a movable mechanism may be provided. Thus, by connecting via a connection part or a spindle, it becomes possible to vary the opening angle of an arm and the distance between arms using a connection part or a spindle.

  The operation of the sphygmomanometer of the third embodiment is the same as that of the first embodiment described above, but is different in the portion sandwiched by the pressurizing unit 53. In the first embodiment, a part of the living body (test portion) is clamped by the end portions 61 and 62, but in the present embodiment, it is clamped by the end surfaces 63 and 64.

  When the arm has an integral structure, the number of parts can be reduced, so that the size and weight can be reduced. Thus, by providing a pressure sensor, a pulse wave sensor, and a pressurizing unit on a C-shaped arm having a shape suitable for mounting on a protruding part of a living body, particularly an auricular protruding part, It is possible to provide a sphygmomanometer that can be always worn and easily worn.

(Embodiment 4)
FIG. 7 is a schematic diagram illustrating an example of a sphygmomanometer according to the fourth embodiment. The sphygmomanometer according to the fourth embodiment includes a U-shaped monolithic arm 14 having at least two ends 61 and 62, and at least one pressurizing unit 53 that pressurizes a living body from either end 61 of the arm 14. And at least one pressure sensor 51 that detects a pressure force that pressurizes the living body of the pressurizing unit 53 from one of the end portions 61 of the arm 14, and a pulse wave at a part of the living body that is detected by the pressure sensor 51. And at least one pulse wave sensor 52 that detects from any one of the end portions 62. The pulse wave sensor 52 may detect a pulse wave at a part of the living body to be pressurized by the pressurizing unit 53 from any end of the arm 14.

  In FIG. 7, the pressure sensor 51 is disposed at the end 61, but may be disposed at the end 62, or may be disposed at the ends 61 and 62. Although the pulse wave sensor 52 is disposed at the end 62, it may be disposed at the end 61 or may be disposed at the ends 61 and 62. The pressurizing unit 53 is disposed at the end 61, but may be disposed at the end 62, or may be disposed at the ends 61 and 62.

  The arm 14 is in the form of a tenth arm, and is an integral structure having a U-shape that sandwiches a part of a living body between the end portions 61 and 62. Examples of the material include metals such as gold, silver, and stainless steel, resin, leather, wood, rubber, and silicon. It is preferable that the bent portion has elasticity and returns to the memorized shape. Moreover, since it is a thing which touches a biological body directly, it is preferable that the surface is flexible. For example, fibers, leather, resin, or rubber may be arranged on the surface.

  FIG. 8 is a schematic diagram of a sphygmomanometer having an arm of another form, in which (a) shows an example of an eleventh arm and (b) shows an example of a twelfth arm. The eleventh arm is a U-shaped structure arm having at least two end portions 61 and 62 in which at least two structure bodies 27 and 28 are connected through one connection portion 35. The twelfth arm is a U-shaped structure arm having at least two end portions 61 and 62 to which at least two structures 27 and 28 are connected via one support shaft 36. The structures 27 and 28 are L-shaped structures that are bent at least partially. In FIG. 8, only one place is bent, but two or more places may be bent. The material of the structures 27 and 28 can be the same as that of the arm 11 of the first embodiment. The connecting portion 35 or the support shaft 36 can connect the ends of the structures 27 and 28 to each other. The connection mechanism of the connection part 35 and the spindle 36 is not limited, and a movable mechanism may be provided. Thus, by connecting via a connection part or a spindle, it becomes possible to vary the opening angle of an arm and the distance between arms using a connection part or a spindle.

The operation of the sphygmomanometer of the fourth embodiment is the same as that of the sphygmomanometer of the first embodiment.

  When the arm has an integral structure, the number of parts can be reduced, so that the size and weight can be reduced. In this way, by providing a pressure sensor, a pulse wave sensor, and a pressurizing unit on an arm having a U-shaped structure that is suitable for mounting on a living body protrusion, particularly an auricle protrusion. Thus, it is possible to provide a blood pressure monitor that can be always worn and easily worn.

(Embodiment 5)
FIG. 9 is a schematic diagram illustrating an example of a sphygmomanometer according to the fifth embodiment. The sphygmomanometer according to the fifth embodiment includes a W-shaped monolithic arm 15 having at least two ends, and two end portions 61 and 62 of the arm 15 or intermediate points 65 and 66 facing the end portions 61 and 62. At least one pressurizing unit 53 that pressurizes the living body from either the end 61 or the intermediate point 66, and the two end portions 61, 62 of the arm 15 or the end portion that pressurizes the living body of the pressurizing unit 53 At least one pressure sensor 51 that is detected from the end portion 61 and the intermediate point 66, which is one of the intermediate points 65 and 66 facing the 61 and 62, and the pulse wave at the body part detected by the pressure sensor 51 is detected by the arm 15 And the at least one pulse wave sensor 52 that detects from the end point 62 and the intermediate point 65, which is either the intermediate point 65 or 66 opposite to the end portions 61 and 62. The pulse wave sensor 52 may detect a pulse wave at a part of the living body to be pressurized by the pressurizing unit 53 from any end of the arm 15.

  In FIG. 9, the pressure sensor 51 and the pressurizing unit 53 are disposed at the end 61 and the intermediate point 66, but may not be disposed at the same end or intermediate point. The pressure sensor 51 and the pressurizing unit 53 may be either the end 61 or 62 or the intermediate point 65 or 66, the end 62 or the intermediate point 65, the intermediate point 65 or 66, or the end. All of the portions 61 and 62 and the intermediate points 65 and 66 may be used. The pulse wave sensor 52 is disposed at the end 62 and the intermediate point 65, but may be either the end 61 or 62 or the intermediate point 65 or 66, or may be the end 61 or the intermediate point 66 or intermediate. It may be the points 65 and 66, or all of the end portions 61 and 62 and the intermediate points 65 and 66.

  The arm 15 is in the form of a thirteenth arm, and has a W-shaped configuration in which a part of the living body is sandwiched between the end 61 and the intermediate point 65 and the other part of the living body is sandwiched between the end 62 and the intermediate point 66. It is a one-piece structure. Examples of the material include metals such as gold, silver, and stainless steel, resin, leather, wood, rubber, and silicon. It is preferable that the bent portion has elasticity and returns to the memorized shape. Moreover, since it is a thing which touches a biological body directly, it is preferable that the surface is flexible. For example, fibers, leather, resin, or rubber may be arranged on the surface.

  FIG. 10 is a schematic diagram of a sphygmomanometer having an arm of another form, in which (a) shows an example of the 14th arm and (b) shows an example of the 15th arm. The fourteenth arm has two ends 68 and 69 of the V-shaped structure 29 and two end portions 71 and 72 of the two I-shaped structures 22a and 22b at the both ends 68 and 69 of the V-shaped structure 29. The arm is a W-shaped structure having at least two end portions 61 and 62 connected via connection portions 35 and 37. The fifteenth arm has two ends 68 and 69 of the V-shaped structure 29 and two ends 71 and 72 of the two I-shaped structures 22a and 22b at the both ends 68 and 69 of the V-shaped structure 29. The arm is a W-shaped structure having at least two end portions 61 and 62 connected via support shafts 36 and 38. The 14th and 15th arm I-shaped structures 22 a have ends 61 and 71, and the 14th and 15th arm I-shaped structures 22 b have ends 62 and 72.

  The I-shaped structures 22a and 22b illustrated in FIG. 10 include, for example, rod-shaped, columnar, cylindrical, and prismatic structures having a similar shape to the I-shape. The V-shaped structure 29 includes, for example, a rod-like, columnar, cylindrical, or prismatic structure having a shape similar to a V-shape. As the materials of the I-shaped structures 22a and 22b and the V-shaped structure 29, the same materials as those of the arm 11 of the first embodiment can be used. The connecting portion 35 and the support shaft 36 are capable of connecting the end portion 71 of the I-shaped structure 22 a and the end portion 68 of the V-shaped structure 29. The connecting portion 37 and the support shaft 38 are capable of connecting the end portion 72 of the I-shaped structure 22 b and the end portion 69 of the V-shaped structure 29. The connection mechanism of the connection part 35 and the spindle 36 is not limited, and a movable mechanism may be provided. Thus, by connecting via a connection part or a spindle, it becomes possible to vary the opening angle of an arm and the distance between arms using a connection part or a spindle.

  The operation of the sphygmomanometer of the fifth embodiment will be described. The pressurizing part 53a applies pressure to a part of the living body (test part) sandwiched between the end part 61 and the intermediate point 65, and stops the blood flow flowing through the test part. Further, the pressurizing unit 53b applies pressure to a part of the living body (test portion) sandwiched between the end portion 62 and the intermediate point 66, and stops the blood flow flowing through the test portion. The pressure sensor 51 a detects the pressure applied to the test part sandwiched between the end 61 and the intermediate point 65. The pressure sensor 51 b detects the pressure applied to the test part sandwiched between the end 62 and the intermediate point 66. The pressurizing unit 53a gradually reduces the pressure to be applied, and the pulse wave sensor 52a detects the pulse wave at the pressurizing site in the process of decreasing the pressure. The pressurizing unit 53b gradually reduces the pressure to be applied, and the pulse wave sensor 52b detects the pulse wave at the pressurizing site in the process of decreasing the pressure. Note that the pressure sensors 51a and 51b may detect pressure applied to the pressurizing units 53a and 53b. Further, the pressurizing units 53a and 53b may gradually increase the pressure, and the pulse wave in the process of increasing the pressure may be detected by the pulse wave sensors 52a and 52b.

  Thus, by providing a pressure sensor, a pulse wave sensor, and a pressurizing unit on the arm of the W-shaped structure having a shape suitable for mounting on a protruding part of a living body, particularly an auricular protruding part, It is possible to provide a sphygmomanometer that can be always worn and easily worn. In the fifth embodiment, since the biological information can be measured simultaneously at two locations on the living body, the blood pressure is measured at the end 61 and the intermediate point 65, and the other biological information is measured at the end 62 and the intermediate point 53. You can also Further, when the arm has an integral structure, the number of parts can be reduced, so that the size and weight can be reduced.

(Embodiment 6)
FIG. 11 is a schematic diagram illustrating an example of a sphygmomanometer according to the sixth embodiment. The sphygmomanometer according to the sixth embodiment includes an E-shaped monolithic arm 16 having at least three ends, and at least one pressurizing unit 53 that pressurizes a living body from either end 61 or 67b of the arm 16, At least one pressure sensor 51 that detects a pressing force that pressurizes the living body of the pressurizing unit 53 from one of the end portions 61 and 67b of the arm 16, and a pulse wave at the part of the living body that the pressure sensor 51 detects And at least one pulse wave sensor 52 that detects from one of the end portions 62 and 67a. The pulse wave sensor 52 may detect a pulse wave at a part of the living body to be pressurized by the pressurizing unit 53 from any end of the arm 16.

  In FIG. 11, the pressure sensors 51a and 51b and the pressurizing parts 53a and 53b are arranged at the end part 61 and the end part 67b, but may not be arranged at the same end part. Further, the pressure sensors 51a and 51b and the pressurizing portions 53a and 53b may be either the end portions 61 and 62 or the end portions 67a and 67b, the end portions 67a and the end portions 62, or the end portions 67a and 67b. All of the end portions 61, 62, 67a, and 67b may be used. The pulse wave sensors 52a and 52b are disposed at the end portions 62 and 67a, but may be any of the end portions 61, 62, 67a and 67b, the end portions 61 and 67b, or the end portions 67a and 67b. Alternatively, all of the end portions 61, 62, 67a, and 67b may be used.

  The arm 16 is in the form of a sixteenth arm, and has an E-shape that sandwiches a part of the living body between the end 61 and the end 67a and the other part of the living body between the end 62 and the end 67b. It is a one-piece structure. Examples of the material include metals such as gold, silver, and stainless steel, resin, leather, wood, rubber, and silicon. It is preferable that the bent portion has elasticity and returns to the memorized shape. The opening angle of the E-shaped bent portion is not limited. Moreover, since it is a thing which touches a biological body directly, it is preferable that the surface is flexible. For example, fibers, leather, resin, or rubber may be arranged on the surface.

  FIG. 12 is a schematic diagram of a sphygmomanometer having an arm of another form, where (a) shows an example of the 17th arm and (b) shows an example of the 18th arm. The seventeenth arm has at least three corners connected to the middle of the corner of the U-shaped structure 30 having two connecting portions 35 and 37 at the corners and the end of one I-shaped structure 22d. The arm has an E-shaped structure with an end. The eighteenth arm includes at least three intermediate corners of the U-shaped structure 30 having two support shafts 36 and 38 at the corners and the end of one I-shaped structure 22d. The arm has an E-shaped structure with an end. Here, the U-shaped structure 30 has one end connected to the end 61, an I-shaped structure 22a to which the other end is connected, an I-shaped structure 22b to which both ends are connected, and one end. , And an I-shaped structure 22c in which the other end is the end 62. One end of the I-shaped structure 22d is connected to an intermediate point of the I-shaped structure 22b. The other end of the I-shaped structure 22d is an end portion 67, the side surface of the end portion 67 facing the end portion 61 is an end portion 67a, and the side surface of the end portion 67 facing the end portion 62 is an end portion 67b. Yes.

  The I-shaped structures 22a to 22d illustrated in FIG. 12 include, for example, rod-shaped, columnar, cylindrical, and prismatic shapes having a similar shape to the I-shape. The material of the I-shaped structures 22a to 22d can be the same as that of the arm 11 described above. The connecting portion 35 and the support shaft 36, and the connecting portion 37 and the support shaft 38 are arranged at the corners of the U-shaped structure 30, and the I-shaped structure 22 a, the I-shaped structure 22 b, and the I-shaped structure 22 b and I The character-shaped structure 22c can be connected. The connecting portion between the I-shaped structure 22b and the I-shaped structure 22d is not limited and may be integrated. The connection mechanism of the connection parts 35 and 37 and the spindles 36 and 38 is not limited. The connection mechanism of the connection part 35 and the spindle 36 is not limited, and a movable mechanism may be provided. Thus, by connecting via a connection part or a spindle, it becomes possible to vary the opening angle of an arm and the distance between arms using a connection part or a spindle.

  The operation of the sphygmomanometer of the sixth embodiment will be described. The pressurizing part 53a applies pressure to a part of the living body (test part) sandwiched between the end part 61 and the end part 67a, and stops the blood flow flowing through the test part. The pressurizing unit 53b applies pressure to a part of the living body (test portion) sandwiched between the end portion 62 and the end portion 67b, and stops the blood flow flowing through the test portion. The pressure sensor 51a detects the pressure applied to the test portion sandwiched between the end portion 61 and the end portion 67a. The pressure sensor 51b detects the pressure applied to the test portion sandwiched between the end portion 62 and the end portion 67b. The pressurizing unit 53a gradually reduces the pressure to be applied, and the pulse wave sensor 52a detects the pulse wave at the pressurizing site in the process of decreasing the pressure. The pressurizing unit 53b gradually reduces the pressure to be applied, and the pulse wave sensor 52b detects the pulse wave at the pressurizing site in the process of decreasing the pressure. Note that the pressure sensors 51a and 51b may detect pressure applied to the pressurizing units 53a and 53b. Further, the pressurizing units 53a and 53b may gradually increase the pressure, and the pulse wave in the process of increasing the pressure may be detected by the pulse wave sensors 52a and 52b.

  Thus, by providing a pressure sensor, a pulse wave sensor, and a pressurizing unit on an arm of an E-shaped structure that is suitable for mounting on a protruding part of a living body, particularly an auricular protruding part, It is possible to provide a sphygmomanometer that can be always worn and easily worn. In the sixth embodiment, since biological information can be measured simultaneously at two locations on the living body, blood pressure is measured at the end 61 and the intermediate point 67a, and other biological information is measured at the end 62 and the intermediate point 67b. You can also Further, when the arm has an integral structure, the number of parts can be reduced, so that the size and weight can be reduced.

  As materials of the structures 21, 23, 24, 25, 26, 27, 28, the I-shaped structures 22a-22d, the V-shaped structures 29, and the U-shaped structures 30 according to the first to sixth embodiments. May be the same as the arm 11 and may further include glass or ceramic. Moreover, since it is a thing which touches a biological body directly, it is preferable that the surface is flexible. For example, fibers, leather, resin, or rubber may be arranged on the surface.

  The structure of the connecting portions 35 and 37 included in the first to sixth embodiments is not limited. It may include one that integrates each structure and may be provided with a movable part. FIG. 13 is a schematic diagram of the 19th arm. The nineteenth arm includes a connection angle adjusting mechanism (not shown) that can adjust the opening angle A of the second arm described in the first embodiment. The connection angle adjustment mechanism is not limited, and includes, for example, a connection angle adjustment mechanism (not shown) that can rotate around one rotation axis. By providing such a connection angle adjusting mechanism, for example, the structure 21a is fixed to the connection portion 35, and the structure 21b is rotated in the direction K around the connection portion 35, thereby the structure 21a and the structure 21b. The opening angle A can be adjusted. Note that both the structure 21a and the structure 12b may be rotatable about the connection portion 35. Thus, by providing the connection angle adjusting mechanism that can adjust the opening angle of the arm, the opening angle of the arm can be varied. In addition, although demonstrated using the 2nd arm in FIG. 13, it is not limited to this, Any of the above-mentioned 5th arm, 8th arm, 11th arm, 14th arm, 17th arm, Also good.

  The structure of the support shafts 36 and 38 included in the first to sixth embodiments is not limited. It may include one that integrates each structure and may be provided with a movable part. FIG. 14 is a schematic diagram of a sphygmomanometer having a 20th arm. The twentieth arm includes at least one opening angle adjusting mechanism 81 that can adjust the opening angle A of the third arm described in the first embodiment. The opening angle adjusting mechanism 81 is not limited. For example, the opening angle adjusting mechanism 81 rotates in the direction K around the direction perpendicular to the plane formed by the structures 21a and 21b and varies the angle B with the support shaft 36. A mechanism 81 is included. By providing such an opening angle adjusting mechanism 81 at the connecting portion between the structure 21 b and the support shaft 36, for example, the structure 21 a is fixed to the support shaft 36, and the structure 21 b is centered on the rotation axis of the support shaft 36. By rotating, the opening angle A between the structure 21a and the structure 21b can be adjusted. The angle C between the structure 21a and the support shaft 36 may be variable. Either of the structures 21a and 21b may be rotatable. Thus, by providing the opening angle adjusting mechanism that can adjust the opening angle of the arm, the opening angle of the arm can be varied.

  Further, the twentieth arm includes a length adjusting mechanism 84 that can further adjust the length D on the support shaft 36 of the third arm described in the first embodiment. The length adjusting mechanism 84 may be provided at any position as long as it is intermediate between the structures 21a and 21b. The structure is not limited, and for example, it may be composed of a stretchable rod-like body and a frame that can fix the rod-like body. By providing the support shaft with a length adjusting mechanism that can adjust the length, the distance between the arms can be varied.

  Further, the twentieth arm is a portion of the third arm pressure sensor 51, pulse wave sensor 52, or pressurizing unit 53 described in the first embodiment, which is opposed to the structures 21a and 21b constituting the arm. A distance adjusting mechanism (not shown) that can adjust the distance to FIG. 14 shows an example in which the distance E between the pressurizing unit 53 and the structure 21a and the distance F between the pulse wave sensor 52 and the structure 21b can be adjusted. The distance adjustment mechanism is not limited, and may be the same as the length adjustment mechanism described above, for example. FIG. 14 shows an example in which only the pulse wave sensor 52 and the pressurizing unit 53 can be adjusted, but the present invention is not limited to this, and the pressure sensor 51 is directly connected to either the structure 21a or 21b. The distance from the structure may be adjustable. As described above, the distance between the pulse wave sensor 52 and the pressurizing unit 53 can be obtained by providing a distance adjustment mechanism that can adjust the distance between the pressure sensor, the pulse wave sensor, and the pressurizing unit with the opposite part of the arm. Therefore, the distance from the pressure sensor 51, the pulse wave sensor 52, and the arm of the pressurizing unit 53 that sandwich the living body can be finely adjusted to a distance that is always worn or suitable for blood pressure measurement. become. As a result, it is possible to provide a sphygmomanometer with improved blood pressure measurement accuracy and less burden on the subject.

  Further, the twentieth arm includes the third arm pressure sensor 51, the pulse wave sensor 52, or the pressurizing unit 53 described in the first embodiment, and includes a direction adjusting mechanism (not shown) that can change the direction. FIG. 14 shows an example in which the direction G of the pressurizing unit 53 with respect to the structure 21a and the direction H of the pulse wave sensor 52 with respect to the structure 21b are variable. The direction adjustment mechanism is not limited, and may be a mechanism similar to the connection angle adjustment mechanism described above, for example. As described above, the pressure sensor, the pulse wave sensor, or the pressurizing unit is equipped with the direction adjustment mechanism that can change the direction, so that the pressure sensor, the pulse wave sensor, or the pressurizing unit is mounted at an angle that matches the shape of the test part. It becomes possible to do. This makes it possible to provide a blood pressure monitor that is easier to wear. Moreover, since the contact area with the test part can be increased by changing the direction, the burden on the subject who always wears the sphygmomanometer can be further reduced.

  Further, the twentieth arm includes end portions 61 and 62 that are parts of the arm that supports any of the pressure sensor 51, the pulse wave sensor 52, and the pressurizing unit 53 of the third arm described in the first embodiment. And an extension mechanism 85 that can extend in the direction I and the direction J, which are the major axis directions of the axis. The extension mechanism 85 can extend the end portions 61 and 62 in the directions I and J, which are the major axis directions of the arms, and move the pressure sensor 51, the pulse wave sensor 52, or the pressurizing unit 53 in the directions I and J. it can. The extension mechanism 85 may be capable of expanding and contracting the end portions 61 and 62. The extension mechanism 85 is not limited. For example, the extension mechanism 85 may be configured by an extendable rod-like body and a frame that can fix the rod-like body.

  The 20th arm shown in FIG. 14 is not limited to the third arm. The first arm may be the second arm, the fourth arm, the fifth arm, the sixth arm, the seventh arm, the eighth arm, the ninth arm, the tenth arm, the eleventh arm, the twelfth arm, and the thirteenth arm. , 14th arm, 15th arm, 16th arm, 17th arm, 18th arm.

  Furthermore, the first arm to the twentieth arm can be combined. For example, the first arm and the fourth arm, the fourth arm and the fourth arm, and the like. The combination of the first arm and the first arm may be the 14th arm or the 15th arm.

  FIG. 15 is a schematic view when a sphygmomanometer 91 having a 21st arm is attached to the auricle 101 of a human body. The 21st arm is provided with a fixing mechanism 82 to the auricle 101 of the human body in addition to the aforementioned 1st to 20th arms. The sphygmomanometer 83 shown in the figure is a sphygmomanometer including the first to twentieth arms described above, and the arm 21 includes the arm provided in the sphygmomanometer 83 and the fixing mechanism 82. Although FIG. 15 shows an example of a semicircular annular body that can be fixed around the auricle, the fixing mechanism 82 is not limited. For example, it may be one that pinches the auricle or may be one that is fixed to a depression of the auricle. As described above, the first arm to the twentieth arm further include the pinna fixing mechanism 82, so that the portion where the pressure sensor, the pulse wave sensor, or the pressurizing unit is attached can be fixed. Become. As a result, blood pressure can be measured at substantially the same site even after attachment / detachment, so that the accuracy of blood pressure measurement can be improved.

  The pressurizing unit 53 included in the first to sixth embodiments applies pressure, and examples thereof include a cuff that applies pressure by air pressure. Further, the pressure may be applied by water pressure or hydraulic pressure. Moreover, what applies a pressure electromagnetically and mechanically may be used.

  The pressure sensor 51 included in the first to sixth embodiments can detect pressure. The pressure detection method is not limited, and examples thereof include a strain gauge type (piezoelectric sensor) and a bulldle tube. However, since it is to be attached to a living body, it is preferable to have a highly safe configuration. A part of the pressure sensor 51 may be separated from the arm. For example, when a cuff is used as the pressurizing unit 53, the inside air of the cuff constituting the pressurizing unit 53 may be guided by a hollow pipe, and the pressure of the cuff inside air may be detected by a detection device separate from the arm. .

  The pulse wave sensor 52 included in the first to sixth embodiments detects a pulse wave at a living body site detected by the pressure sensor 51 or a pulse wave at a living body site pressurized by the pressurizing unit 53. For example, what detects a blood flow by photoelectric conversion measurement can be illustrated. Blood flow detection by photoelectric conversion measurement includes a transmission type and a reflection type in addition to the Doppler effect. Alternatively, a pressure pulse caused by pressure or vibration may be detected. Moreover, it may be based on detecting Korotkoff sounds.

  An example in which the pulse wave sensor 52 detects blood pressure by detecting a pulse wave by photoelectric conversion measurement of a part of a living body (test portion) sandwiched between each end or each intermediate point will be described. Incident light obtained by causing light emitted from the light emitting element included in the pulse wave sensor to enter the test portion is scattered by the blood vessel, and the scattered light is received by the light receiving element included in the pulse wave sensor. The blood vessels in the test part pulsate according to the heartbeat, and the scattered light is received by the light receiving element in response to a change in the volume of the blood vessel corresponding to the pulsation. A pulse wave corresponding to the pulsation of the blood vessel can be detected by photoelectrically converting the scattered light received by the light receiving element. In addition, you may receive not the scattered light from a blood vessel but the scattered light by the blood cell in a blood vessel. In this case, blood cells in the blood vessel pulsate according to the heartbeat, and the scattered light undergoes a change in optical frequency due to the Doppler effect corresponding to this pulsation. This change in optical frequency may be received by a Doppler laser or an ultrasonic Doppler sensor to detect a pulse wave.

  The sphygmomanometer of the present invention can be applied as a biological information measuring device that continuously measures the pulse, blood pressure, blood flow, etc. depending on the type of the detection unit, and therefore can be applied not only for medical purposes but also for health management or beauty purposes. .

3 is a schematic diagram illustrating an example of a sphygmomanometer according to Embodiment 1. FIG. It is a schematic diagram of the sphygmomanometer which has the arm of the other form which concerns on Embodiment 1, (a) is a 2nd arm, (b) shows the example of a 3rd arm. 6 is a schematic diagram showing an example of a sphygmomanometer according to Embodiment 2. FIG. It is a schematic diagram of the sphygmomanometer which has the arm of the other form which concerns on Embodiment 2, (a) is a 5th arm, (b) shows the example of a 6th arm. 10 is a schematic diagram illustrating an example of a blood pressure monitor according to Embodiment 3. FIG. It is a schematic diagram of the blood pressure meter which has the arm of the other form which concerns on Embodiment 3, (a) shows the example of an 8th arm, (b) shows the example of a 9th arm. 10 is a schematic diagram illustrating an example of a blood pressure monitor according to Embodiment 4. FIG. It is a schematic diagram of the blood pressure meter which has the arm of the other form which concerns on Embodiment 4, (a) shows the example of the 11th arm, (b) shows the example of the 12th arm. FIG. 10 is a schematic diagram illustrating an example of a sphygmomanometer according to a fifth embodiment. It is a schematic diagram of the sphygmomanometer which has the arm of the other form which concerns on Embodiment 5, (a) shows the 14th arm and (b) shows the example of the 15th arm. 10 is a schematic diagram illustrating an example of a sphygmomanometer according to Embodiment 6. FIG. It is a schematic diagram of the sphygmomanometer which has the arm of the other form which concerns on Embodiment 6, (a) shows the example of the 17th arm and (b) shows the 18th arm. It is a schematic diagram of the 19th arm concerning the present invention. It is a schematic diagram of the sphygmomanometer having the 20th arm according to the present invention. It is a general-view figure at the time of mounting | wearing the blood pressure meter which has the 21st arm which concerns on this invention to the pinna of a human body.

Explanation of symbols

11-16, 21a, 21b, 21c, 21d, 22-30 Arm 21, 23, 24, 25, 26, 27, 28 Structure 22a, 22b, 22c, 22d I-shaped structure 29 V-shaped structure 30 U-shaped structure 35, 37, 39 Connection portion 36, 38, 40 Support shaft 51, 51a, 51b Pressure sensor 52, 52a, 52b Pulse wave sensor 53, 53a, 53b Pressure portion 61, 62, 67 End of arm Part 63, 64 End face of arm 65, 66 Middle point of arm 81 Opening angle adjusting mechanism 82 Fixing mechanism to auricle 83, 91 Blood pressure monitor
84 Length adjustment mechanism 85 Extension mechanism 101 Auricle of human body A Arm angle B, C Angle formed by arm and support shaft D Length of support shaft E, F Distance between pulse wave sensor or pressurizing unit and arm G, H Angle between pulse wave sensor or pressurizing part and arm I, J Arm extending direction K Arm rotating direction

Claims (31)

A V-shaped monolithic arm having at least two ends;
At least one pressurizing unit that pressurizes the living body from either end of the arm;
At least one pressure sensor for detecting a pressurizing force to pressurize the living body of the pressurizing unit from either end of the arm;
A sphygmomanometer, comprising: at least one pulse wave sensor that detects a pulse wave at a part of a living body detected by the pressure sensor from any end of the arm. A V-shaped monolithic arm having at least two ends;
At least one pressurizing unit that pressurizes the living body from either end of the arm;
At least one pressure sensor for detecting a pressurizing force to pressurize the living body of the pressurizing unit from either end of the arm;
A sphygmomanometer, comprising: at least one pulse wave sensor that detects a pulse wave at a part of a living body to be pressurized by the pressurizing unit from any end of the arm. A U-shaped monolithic arm having at least two ends;
At least one pressurizing unit that pressurizes the living body from either end of the arm;
At least one pressure sensor for detecting a pressurizing force to pressurize the living body of the pressurizing unit from either end of the arm;
A sphygmomanometer, comprising: at least one pulse wave sensor that detects a pulse wave at a part of a living body detected by the pressure sensor from any end of the arm. A U-shaped monolithic arm having at least two ends;
At least one pressurizing unit that pressurizes the living body from either end of the arm;
At least one pressure sensor for detecting a pressurizing force to pressurize the living body of the pressurizing unit from either end of the arm;
A sphygmomanometer, comprising: at least one pulse wave sensor that detects a pulse wave at a part of a living body to be pressurized by the pressurizing unit from any end of the arm. A C-shaped monolithic arm having at least two end faces;
At least one pressurizing unit that pressurizes the living body from either end face of the arm;
At least one pressure sensor for detecting a pressurizing force to pressurize the living body of the pressurizing unit from any end face of the arm;
A sphygmomanometer, comprising: at least one pulse wave sensor that detects a pulse wave at a part of a living body detected by the pressure sensor from any end face of the arm. A C-shaped monolithic arm having at least two end faces;
At least one pressurizing unit that pressurizes the living body from either end face of the arm;
At least one pressure sensor for detecting a pressurizing force to pressurize the living body of the pressurizing unit from any end face of the arm;
A sphygmomanometer, comprising: at least one pulse wave sensor that detects a pulse wave at a part of a living body to be pressurized by the pressurizing unit from any end face of the arm. A U-shaped monolithic arm having at least two ends;
At least one pressurizing unit that pressurizes the living body from either end of the arm;
At least one pressure sensor for detecting a pressurizing force to pressurize the living body of the pressurizing unit from either end of the arm;
A sphygmomanometer, comprising: at least one pulse wave sensor that detects a pulse wave at a part of a living body detected by the pressure sensor from any end of the arm. A U-shaped monolithic arm having at least two ends;
At least one pressurizing unit that pressurizes the living body from either end of the arm;
At least one pressure sensor for detecting a pressurizing force to pressurize the living body of the pressurizing unit from either end of the arm;
A sphygmomanometer, comprising: at least one pulse wave sensor that detects a pulse wave at a part of a living body to be pressurized by the pressurizing unit from any end of the arm. A W-shaped monolithic arm having at least two ends;
At least one pressurizing unit that pressurizes the living body from either of two ends of the arm or an intermediate point facing the end;
At least one pressure sensor for detecting a pressurizing force that pressurizes the living body of the pressurizing unit from either of two ends of the arm or an intermediate point facing the end;
A sphygmomanometer, comprising: at least one pulse wave sensor that detects a pulse wave at a part of a living body detected by the pressure sensor from either one of two ends of the arm or an intermediate point facing the end. A W-shaped monolithic arm having at least two ends;
At least one pressurizing unit that pressurizes the living body from either of two ends of the arm or an intermediate point facing the end;
At least one pressure sensor for detecting a pressurizing force that pressurizes the living body of the pressurizing unit from either of two ends of the arm or an intermediate point facing the end;
A sphygmomanometer, comprising: at least one pulse wave sensor that detects a pulse wave at a part of a living body to be pressurized by the pressurizing unit from either of two ends of the arm or an intermediate point facing the end. An E-shaped monolithic arm having at least three ends;
At least one pressurizing unit that pressurizes the living body from either end of the arm;
At least one pressure sensor for detecting a pressurizing force to pressurize the living body of the pressurizing unit from either end of the arm;
A sphygmomanometer, comprising: at least one pulse wave sensor that detects a pulse wave at a part of a living body detected by the pressure sensor from any end of the arm. An E-shaped monolithic arm having at least three ends;
At least one pressurizing unit that pressurizes the living body from either end of the arm;
At least one pressure sensor for detecting a pressurizing force to pressurize the living body of the pressurizing unit from either end of the arm;
A sphygmomanometer, comprising: at least one pulse wave sensor that detects a pulse wave at a part of a living body to be pressurized by the pressurizing unit from any end of the arm. An arm of V-shaped structure having at least two ends, wherein at least two structures are connected via one connection or one spindle;
At least one pressurizing unit that pressurizes the living body from either end of the arm;
At least one pressure sensor for detecting a pressurizing force to pressurize the living body of the pressurizing unit from either end of the arm;
A sphygmomanometer, comprising: at least one pulse wave sensor that detects a pulse wave at a part of a living body detected by the pressure sensor from any end of the arm. An arm of V-shaped structure having at least two ends, wherein at least two structures are connected via one connection or one spindle;
At least one pressurizing unit that pressurizes the living body from either end of the arm;
At least one pressure sensor for detecting a pressurizing force to pressurize the living body of the pressurizing unit from either end of the arm;
A sphygmomanometer, comprising: at least one pulse wave sensor that detects a pulse wave at a part of a living body to be pressurized by the pressurizing unit from any end of the arm. An arm of a U-shaped structure having at least two ends, wherein at least two structures are connected via one connection or one spindle;
At least one pressurizing unit that pressurizes the living body from either end of the arm;
At least one pressure sensor for detecting a pressurizing force to pressurize the living body of the pressurizing unit from either end of the arm;
A sphygmomanometer, comprising: at least one pulse wave sensor that detects a pulse wave at a part of a living body detected by the pressure sensor from any end of the arm. An arm of a U-shaped structure having at least two ends, wherein at least two structures are connected via one connection or one spindle;
At least one pressurizing unit that pressurizes the living body from either end of the arm;
At least one pressure sensor for detecting a pressurizing force to pressurize the living body of the pressurizing unit from either end of the arm;
A sphygmomanometer, comprising: at least one pulse wave sensor that detects a pulse wave at a part of a living body to be pressurized by the pressurizing unit from any end of the arm. An arm of a C-shaped structure having at least two end faces, wherein at least two structures are connected via one connection or one spindle;
At least one pressurizing unit that pressurizes the living body from either end face of the arm;
At least one pressure sensor for detecting a pressurizing force to pressurize the living body of the pressurizing unit from any end face of the arm;
A sphygmomanometer, comprising: at least one pulse wave sensor that detects a pulse wave at a part of a living body detected by the pressure sensor from any end face of the arm. An arm of a C-shaped structure having at least two end faces, wherein at least two structures are connected via one connection or one spindle;
At least one pressurizing unit that pressurizes the living body from either end face of the arm;
At least one pressure sensor for detecting a pressurizing force to pressurize the living body of the pressurizing unit from any end face of the arm;
A sphygmomanometer, comprising: at least one pulse wave sensor that detects a pulse wave at a part of a living body to be pressurized by the pressurizing unit from any end face of the arm. An arm of a U-shaped structure having at least two ends, wherein at least two structures are connected via one connection or one spindle;
At least one pressurizing unit that pressurizes the living body from either end of the arm;
At least one pressure sensor for detecting a pressurizing force to pressurize the living body of the pressurizing unit from either end of the arm;
A sphygmomanometer, comprising: at least one pulse wave sensor that detects a pulse wave at a part of a living body detected by the pressure sensor from any end of the arm. An arm of a U-shaped structure having at least two ends, wherein at least two structures are connected via one connection or one spindle;
At least one pressurizing unit that pressurizes the living body from either end of the arm;
At least one pressure sensor for detecting a pressurizing force to pressurize the living body of the pressurizing unit from either end of the arm;
A sphygmomanometer, comprising: at least one pulse wave sensor that detects a pulse wave at a part of a living body to be pressurized by the pressurizing unit from any end of the arm. At least two end portions in which both ends of the V-shaped structure and ends of the two I-shaped structures are connected via two connecting portions or two support shafts at both ends of the V-shaped structure. W-shaped structure arm having
At least one pressurizing unit that pressurizes the living body from either of two ends of the arm or an intermediate point facing the end;
At least one pressure sensor for detecting a pressurizing force that pressurizes the living body of the pressurizing unit from either of two ends of the arm or an intermediate point facing the end;
A sphygmomanometer, comprising: at least one pulse wave sensor that detects a pulse wave at a part of a living body detected by the pressure sensor from either one of two ends of the arm or an intermediate point facing the end. At least two end portions in which both ends of the V-shaped structure and ends of the two I-shaped structures are connected via two connecting portions or two support shafts at both ends of the V-shaped structure. W-shaped structure arm having
At least one pressurizing unit that pressurizes the living body from either of two ends of the arm or an intermediate point facing the end;
At least one pressure sensor for detecting a pressurizing force that pressurizes the living body of the pressurizing unit from either of two ends of the arm or an intermediate point facing the end;
A sphygmomanometer, comprising: at least one pulse wave sensor that detects a pulse wave at a part of a living body to be pressurized by the pressurizing unit from either of two ends of the arm or an intermediate point facing the end. It has at least three ends where the middle of the U-shaped structure having two connecting portions or two supporting shafts at the corner is connected to the end of one I-shaped structure. An arm with an E-shaped structure;
At least one pressurizing unit that pressurizes the living body from either end of the arm;
At least one pressure sensor for detecting a pressurizing force to pressurize the living body of the pressurizing unit from either end of the arm;
A sphygmomanometer, comprising: at least one pulse wave sensor that detects a pulse wave at a part of a living body detected by the pressure sensor from any end of the arm. It has at least three ends where the middle of the U-shaped structure having two connecting portions or two supporting shafts at the corner is connected to the end of one I-shaped structure. An arm with an E-shaped structure;
At least one pressurizing unit that pressurizes the living body from either end of the arm;
At least one pressure sensor for detecting a pressurizing force to pressurize the living body of the pressurizing unit from either end of the arm;
A sphygmomanometer, comprising: at least one pulse wave sensor that detects a pulse wave at a part of a living body to be pressurized by the pressurizing unit from any end of the arm.   The sphygmomanometer according to any one of claims 13 to 24, wherein the connection portion includes a connection angle adjustment mechanism capable of adjusting an opening angle of the arm.   The sphygmomanometer according to any one of claims 13 to 25, wherein the support shaft includes at least one opening angle adjusting mechanism capable of adjusting an opening angle of the arm.   27. The sphygmomanometer according to any one of claims 13 to 26, wherein the support shaft includes a length adjusting mechanism capable of adjusting a length.   Any one of the pressure sensor, the pulse wave sensor, or the pressurizing unit includes a distance adjustment mechanism that can adjust a distance from a portion facing the arm. Sphygmomanometer.   The sphygmomanometer according to any one of claims 1 to 28, wherein the pressure sensor, the pulse wave sensor, or the pressurizing unit includes a direction adjusting mechanism capable of changing a direction.   The part of the arm that supports any one of the pressure sensor, the pulse wave sensor, and the pressurizing unit includes an extension mechanism that can extend in a major axis direction of the arm. Blood pressure monitor. The sphygmomanometer according to any one of claims 1 to 30, wherein the arm further includes a fixing mechanism for pinching the human body.

Images