JP5208656B2 - Biological compression device and blood pressure measurement device - Google Patents

Description

  The present invention relates to a living body compression device that is excellent in storability, economy, safety, and convenience, and a blood pressure measurement device that uses this living body compression device.

In recent years, sphygmomanometers have been widely used not only in hospitals and the like, but also for general households for the purpose of health management. These home blood pressure monitors are usually automatic blood pressure monitors that are easy to operate.
Various types of automatic sphygmomanometers have been developed, one of which is an oscillometric electronic sphygmomanometer. This oscillometric electronic sphygmomanometer detects a pulse wave superimposed on the internal pressure of an air bag and calculates a blood pressure based on a change in amplitude of the pulse wave. An oscillometric electronic sphygmomanometer is composed of a living body compression device (generally referred to as a cuff) wound around an upper arm and having an air bag, a pressure sensor, a pump, The information processing apparatus includes an exhaust valve, a pressure sensor, a pump, and an exhaust valve, and an operation switch and a display connected to the information processing apparatus.

The automatic sphygmomanometer uses various body compression devices.
These biological compression devices are roughly classified into three types. The first type is a soft cuff type provided with a belt-like body having a non-stretchable cloth or the like, an air bag accommodated in the belt-like body, a fastener, a hook-and-loop fastener, and the like. The second type is a hard core type including a resin-made core having elasticity and flexibility, an air bag attached to the inside of the core, and a fastening means for fastening the core to a part of the living body. The third type is a biological compression device that is assembled together with a pressure sensor, a pump, an exhaust valve, an information processing device, an operation switch, a display, and the like. It is an arm-in type that requires the upper arm to be set.

The soft cuff type living body compression device is inexpensive and has an advantage that it can be folded compactly. However, there are disadvantages in that a case where the air bag cannot be wound correctly occurs or a load is applied to the air bag by folding.
In addition, the arm-in type biological compression device is expensive and large as an automatic sphygmomanometer, and further has the disadvantage that the user must set the upper arm to the biological compression device in a correct measurement posture as described above. ing.
On the other hand, the hard core type biological compression device has a possibility of improving the above-mentioned disadvantages, and in recent years, a biological compression device having various cores has been developed.

For example, Patent Document 1 discloses an air bag, a flexible armband (core), a fastening belt formed with a rack and a holding hole, a pinion gear, a holding pin, and a photograph for rotating a pinion gear ( A technique of an arm band for a blood pressure monitor (biological compression device) provided with a dial) or the like is disclosed.
According to this sphygmomanometer wristband, it is possible to improve durability and downsizing, and to improve blood pressure measurement accuracy and operability.

Patent Document 2 discloses a technique of a wrist band for a blood pressure monitor having an air bag and a core disposed outside the air bag. The core has a flexible sheet-like first core and a second core that is formed in a curved shape, is attached to the first core so as to be bent, and curves the first core.
According to this sphygmomanometer arm band, it is possible to improve the operability when inserting and removing the arm and the fit when tightening the arm, and to reduce the manufacturing cost.

  Further, Patent Document 3 includes a case body that is internally equipped with a rotary shaft that includes a feed roller and a driven gear, and a drive gear that is spring-biased upward with respect to the case body and that engages with the driven gear at the lower end. At the same time, a shooting case is fitted to the upper end via a spring ball, and it is rotated by the rotation of the shooting case and is equipped with an inner wheel that rotates the shooting case under a constant rotational load. The blood pressure measurement cuff (biological compression device) technology is composed of a single shaft and a cuff main body (core) in which one end is fixed at an appropriate position of the case body and the other end is inserted and arranged in the case body via a delivery roller. It is disclosed.

  Patent Document 4 discloses a technique of a sphygmomanometer cuff winding device including a cuff storage cylinder, a cuff, an operation cylinder, a cuff feed cylinder, a rotary cylinder, an urging lock shaft, a rotation transmission coil spring, and a rotation control means. Is disclosed.

Further, Patent Document 5 discloses a cylindrical pressure increasing / decreasing member that compresses the upper arm, an instrument main body that is disposed above the pressure increasing / decreasing member, detects the pressure of the upper arm by pressurizing the pressure increasing / decreasing member, A technique of a portable blood pressure measurement device is disclosed that includes a gripping grip provided on the upper surface side of the instrument body in parallel with the insertion direction of the decompression member into the upper arm of the cylindrical space.
JP 2007-260293 A JP 2007-268052 A Japanese Utility Model Publication No. 2-37604 Japanese Utility Model Publication No. 2-82308 Utility Model No. 2560475

  However, the sphygmomanometer armband (biological compression device) described in Patent Documents 1 and 2 described above is used because the longitudinal ends of the flexible armband (core) and the first core are free. Depending on the storage condition when not, the flexible armband and the first core may be deformed. These sphygmomanometer arm bands tighten a part of the living body by turning the dial (dial) from the maximum diameter cylindrical state, so that proper winding can be easily and reliably performed. , One of the advantages. That is, in order to ensure the above advantages, it is necessary to improve the storability of the flexible armband and the first core and to prevent the deformation of the mold.

  Furthermore, the sphygmomanometer wrist band (biological compression device) described in Patent Document 1 exposes a tightening belt in which a rack and a holding hole are formed, and the tightening belt moves. Therefore, it has been necessary to further improve safety so that the moving rack does not come into direct contact with a finger or the like.

In addition, the sphygmomanometer armband (biological compression device) described in Patent Document 1 moves so that the tip side portion of the tightening belt fed out by the pinion gear protrudes outward when tightened to the arm, There was a possibility of getting in the way. That is, for example, when the user lies on the bed, it is assumed that the tightening is not properly performed by the portion of the tightening belt protruding outwardly hitting the bed. Therefore, it is necessary to further improve the usability so that the front end side portion of the fastening belt protruding outwards does not get in the way.
Furthermore, it is always desired for manufacturers to further reduce the cost of manufacturing products.

  And also about the technique described in the patent documents 3-5 mentioned above, since the front-end | tip of the cuff has come out outside, there exists a possibility of becoming obstructive at the time of cuff wearing or blood pressure measurement, and further improves usability There was a need.

  The present invention has been proposed in order to solve the problems of the conventional techniques as described above, and is a biocompression device that is excellent in storability, economy, safety, and usability, and the biocompression device. An object of the present invention is to provide a blood pressure measurement device using the sam

In order to achieve the above object, a living body compression apparatus of the present invention includes an air bag, a flexible core disposed outside the air bag, and a storage cover for storing the air bag and the core. The storage cover has an opening at one end in the longitudinal direction, and the other end in the longitudinal direction of the storage cover is inserted into the opening.
In this case, the core can be held in a substantially cylindrical shape by using a storage cover for improving the touch and the like. That is, since the core is stored in a state of being held in a substantially cylindrical shape, it is possible to prevent a problem that the mold is deformed.

Preferably, one end in the longitudinal direction of the core is wound inside the other end in the longitudinal direction, and the other end in the longitudinal direction of the core is in the opening of the storage cover. It should be inserted.
In this way, the structure can be simplified and the manufacturing cost can be reduced.

Preferably, the living body compression apparatus includes a fastening unit that fastens the core to a part of the living body, and the fastening unit is provided in the storage cover.
If it does in this way, since a fastening means is covered with a storage cover, safety can be improved. Further, since the tightening means is covered with the storage cover, the aesthetic appearance can be improved.

Preferably, the tightening means is a tightening belt having a holding mechanism for holding a tightened state.
In this way, the fastening belt is covered with the storage cover. Here, normally, the fastening belt is formed with locking portions such as a rack and a holding hole. That is, the fastening belt formed with the locking portion is covered with the storage cover, so that safety can be improved.
Further, the front end portion of the fastening belt is fed inward by the storage cover. As a result, for example, when the user is sleeping on the bed, it is possible to prevent a problem that tightening is not properly performed due to the portion of the tightening belt protruding outwardly hitting the bed. .

Moreover, it is preferable that a belt storage guide for directing a tip portion of the fastening belt inward is provided.
If it does in this way, the part by the side of the tip of a tightening belt can be certainly directed inside.

Preferably, an elastic member that urges at least one of the core and the tightening means in a direction of expanding the diameter is provided.
In this case, for example, when the release lever is pressed, the core that should be automatically expanded to the maximum diameter is not automatically expanded to the maximum diameter due to frictional resistance with the storage cover. Can be prevented.

In order to achieve the above object, the blood pressure measurement device of the present invention is configured using the above-described biological compression device according to the present invention.
Thus, the present invention is effective as a blood pressure measurement device, and can provide a blood pressure measurement device that is excellent in storability, economy, safety, usability, and the like.

  According to the living body pressure device and the blood pressure measurement device of the present invention, storability, economy, safety, usability, and the like can be improved.

[First embodiment of biological compression apparatus]
Hereinafter, a first embodiment of a living body compression apparatus of the present invention will be described with reference to the drawings.
FIG. 1: has shown the schematic perspective view of the biological compression apparatus which concerns on 1st embodiment of this invention.
In FIG. 1, the living body compression apparatus 1 is used as a sphygmomanometer arm band (cuff) and is worn on the upper arm of a user.
The living body compression apparatus 1 includes an air bag 12 to which a pipe 123 is attached, a flexible core 11 disposed outside the air bag 12, a core 11 fastened to an upper arm, and a tightened state. There are provided a fastening means 3 for holding, a protective plate 13 for protecting the fastening means 3, and a storage cover 2 for housing the air bag 12, the core 11 and the fastening belt 32.

(core)
FIG. 2: has shown the schematic perspective view of the state from which the protective cover was removed of the biological compression apparatus which concerns on 1st embodiment of this invention.
Moreover, FIG. 3 has shown the AA schematic sectional drawing of FIG. In FIG. 3, the gaps between the core 11, the air bag 12, the fastening belt 32, and the storage cover 2 are enlarged for easy understanding.
Further, FIG. 4 shows a schematic side view of FIG.
2 to 4, the core 11 is made of a thin flat sheet made of resin, and when deployed, has a substantially rectangular shape that is long in the circumferential direction. The core 11 has four corners formed in an arc shape. The illustrated core 11 is curved by a fastening belt 32 and has a cylindrical shape. In the present embodiment, one end 111 in the longitudinal direction of the deployed core 11 is wound inside the other end 112 in the longitudinal direction of the deployed core 11.
Note that the short direction of the deployed core 11 is the arm axis direction. Moreover, although the raw material of the core 11 is a ready-made thin flat sheet, it is not limited to this, For example, it is good also as a thin sheet manufactured by injection molding etc.

The core 11 has a flexibility that can follow various arm shapes by making it about 1 mm or a few millimeters in thickness, and when tightening an arm (not shown), Excellent fit. The core 11 has moderate elasticity. Therefore, even if the core 11 is reduced in diameter by the tightening means 3, when the tightening belt 32 is loosened, the core 11 itself is elastically stretched to the maximum diameter of the living body compression apparatus 1 (diameter when inserting and removing the arm). Expand the diameter.
The core 11 has a base 31 of the tightening means 3 attached to the substantially central portion thereof by adhesion, welding, sewing, eyelet eyelash or the like. Although not shown in the figure, the core 11 may be provided with a connecting portion for easily connecting with the base 31.

  In addition, in this embodiment, although the core 11 is formed from one member, it is not limited to this. For example, although not shown in the drawing, the core 11 is formed in a curved shape by being attached so as to overlap the outside of the first core with a flexible sheet-like flat first core. It is good also as a structure which consists of a 2nd core which has stronger elasticity. In this way, the operability when inserting and removing the arm and the fit when the arm is tightened are further improved, and the adverse effect due to the frictional resistance with the storage cover 2 (automatically due to the frictional resistance with the storage cover 2) Thus, it is possible to reduce adverse effects such that the maximum diameter is not expanded.

(Air bag)
The air bag 12 is made of a resin sheet member having elasticity or stretchability. When deployed, the air bag 12 has a substantially rectangular shape that is long in the circumferential direction, and four corners are formed in an arc shape.
Moreover, the air bag 12 is attached to the inner surface of the core 11 at both ends in the longitudinal direction by a double-sided tape or an adhesive. The air bag 12 is provided with a pipe 123 protruding in the arm axis direction, and air is fed through the pipe 123 when measuring blood pressure.
Note that the air bag 12 is usually dimensioned in the longitudinal direction so that one end 121 and the other end 122 do not overlap even when the core 11 is reduced to the smallest measurable diameter.

(Storage cover)
The storage cover 2 is made of a foldable woven fabric (for example, 2WAY fabric) that extends in all directions and can be restored from its extended state to its original shape. Further, when the storage cover 2 is unfolded, the storage cover 2 is a substantially rectangular bag that is long in the circumferential direction, and stores the air bag 12, the core 11, and the fastening belt 32. That is, the other end 112 in the longitudinal direction of the core 11 is inserted into the storage cover 2 in a state of abutting against the other end 22 in the longitudinal direction of the storage cover 2, and the other end 22 of the storage cover 2 is further inserted. Is attached to the other end 112 of the core 11 by sewing, bonding or welding. Further, the inner woven fabric at one end portion 21 in the longitudinal direction of the storage cover 2 is attached to one end portion 111 in the longitudinal direction of the core 11 by sewing, adhesion, welding, or the like.

  In the present embodiment, the storage cover 2 is manufactured by sewing, bonding, or welding one folded woven fabric. However, the present invention is not limited to this. For example, the storage cover 2 may be manufactured by sewing, bonding, or welding an inner woven fabric and an outer woven fabric. Furthermore, the woven fabric for the inner side and the woven fabric for the outer side may have different characteristics (for example, stretchability, restoring force, frictional resistance, thickness, etc.) or shape.

  Furthermore, although not shown, the storage cover 2 is joined to the core 11 by sewing, bonding, or welding at a plurality of locations in the circumferential direction of the core 11 in the vicinity of both ends in the lateral direction. Good. If it does in this way, the shift | offset | difference of the storage cover 2 with respect to the core 11 can be suppressed.

  The storage cover 2 of the present embodiment has a storage cover opening 23 formed at one end 21 in the longitudinal direction and a fastening belt opening 24 formed at the other end 22 in the longitudinal direction. An opening 25 is formed on the outer side of the substantially central portion, and a pipe opening 26 is formed at the end of the hand side in the short side direction.

The opening 23 for the storage cover has an elongated shape in the arm axis direction, and the other end 22 of the storage cover 2, the other end 112 of the core 11 and the fastening belt 32 are inserted movably in the circumferential direction. Has been.
Here, the phrase “movable in the circumferential direction” means that the core 11 is movable in the circumferential direction with respect to the storage cover opening 23 when the core 11 is reduced in diameter or expanded in diameter. That is, in the present embodiment, the other end 22 of the storage cover 2, the other end 112 of the core 11 and the fastening belt 32 are inserted so as to be movable in the circumferential direction, so that the core 11 is contracted. When the diameter or diameter is increased, one end 121 of the air bladder 12, one end 111 of the core 11, and one end 21 of the storage cover 2 can also freely move in the circumferential direction.
Normally, one end 21 (storage cover opening 23) of the storage cover 2 is folded inside and sewn, bonded or welded so that the woven fabric is not loosened.

  Moreover, when the biological compression apparatus 1 is not used, it is normally stored in a state where the diameter has been expanded to the maximum diameter (not shown). At this time, the other end 22 of the storage cover 2 is close to the storage cover opening 23 but maintains the state of being inserted into the storage cover opening 23. Then, both end portions of the core 11 are surrounded by the storage cover 2 on the other end side between the one end portion 21 and the other end portion 22. That is, one end 111 in the longitudinal direction of the core 11 and the other in the longitudinal direction of the core 11 by the storage cover 2 on the other end between the one end 21 and the other end 22. The end 112 is regulated at a predetermined position in the short direction so as to be fitted.

Here, the “predetermined position in the short direction” means a position where the core 11 has a substantially cylindrical shape, and the “regulate to a predetermined position in the short direction so as to fit” means a rectangular shape when unfolded. That is, the center line in the longitudinal direction of the core 11 is made substantially coincident at one end 111 and the other end 112. In addition, since the storage cover 2 has moderate elasticity, the core 11 should exhibit excellent fit even when tightening a muscular upper arm (an upper arm having a substantially truncated cone shape). Can do.
Thus, since the core 11 is stored in the state in which the core 11 is held in a substantially cylindrical shape by the storage cover 2 on the other end side, the living body compression apparatus 1 can prevent such a problem that the mold is deformed. Furthermore, in this embodiment, since the core 11 can be held in a substantially cylindrical shape by using the storage cover 2 for improving the touch and the like, the manufacturing cost can be reduced.

The fastening belt opening 24 has a shape that is substantially the same as the width of the fastening belt 32 and is elongated in the arm axis direction. The tightening belt 32 is inserted into the storage cover opening 23 such that a portion 321 on the tip side of the tightening belt 32 inserted into the storage cover 2 passes through the storage cover opening 23. The portion 321 on the tip side of the fastening belt 32 that has passed through the storage cover opening 23 is inserted into the base 31.
In this way, the fastening belt 32 between the connecting plate 35 and the base 31 is covered by the storage cover 2. Here, the fastening belt 32 of the present embodiment is formed with a rack 37 and a holding hole 38 as locking portions. That is, the tightening belt 32 having irregularities is covered by the storage cover 2, so that safety can be improved. Further, since the tightening belt 32 is covered by the storage cover 2, the aesthetic appearance can be improved.

Further, the opening 25 is substantially oval or rectangular, and the shooting 33 and the release lever 34 of the tightening means 3 are exposed through the opening 25.
Further, the storage cover 2 at the periphery of the opening 25 is hung on the upper portion of the base 31 and the release lever 34. As a result, the portion 321 on the distal end side of the fastening belt 32 delivered from the base 31 by the pinion gear 36 is stored in the storage cover 2. Thereby, as described above, the tightening belt 32 allows the tightening belt 32 between the connecting plate 35 and the base 31 and the tightening belt 32 fed from the base 31 to penetrate the storage cover 2. In addition, it is stored in the storage cover 2, that is, penetrated into the storage cover 2.

If it does in this way, the part 321 of the front end side of the sent out fastening belt 32 will contact | abut with the storage cover 2, and will change direction inside. That is, the portion 321 on the front end side of the fastening belt 32 is not sent out in the tangential direction as shown in FIG. Accordingly, for example, even when the user is lying on the bed, the problem that the tightening is not properly performed due to the portion 321 on the leading end side of the tightened belt 32 that has been sent out hits the bed is prevented. can do. In addition, it is possible to prevent such a problem that the portion 321 on the front end side of the tightening belt 32 that has been sent out hits the bed or the chest of the user and gets in the way.
Further, when tightened, the portion 321 on the front end side of the tightening belt 32 that has been sent out is stored in the storage cover 2 and the rack 37 and the like are covered by the storage cover 2, so that safety can be further improved.
Furthermore, since the core 11, the air bag 12, and the fastening belt 32 are covered by the storage cover 2, a smart impression can be given to the viewer and the aesthetics can be greatly improved.

Moreover, the opening part 26 for pipes is substantially circular shape, and the pipe 123 is inserted.
Normally, the pipe 123 is connected to the air bag 12 through the pipe opening 26 after the storage cover 2 is attached to the core 11, but is not limited thereto. For example, when the core 11 and the air bag 12 are stored in the storage cover 2, the pipe 123 connected to the air bag 12 may be passed through the pipe opening 26.

  The storage cover 2 is a single bag for storing the core 11, the air bag 12, and the fastening belt 32, but is not limited to this. For example, although not shown, the storage cover may include a single bag that stores the core 11 and the air bag 12 and a cover that is joined to the outside of the bag and covers the fastening belt 32. . In this case, for example, the cover that covers the fastening belt 32 can be formed into a shape having a low frictional resistance, or a material that has a low frictional resistance can be used for the cover that covers the fastening belt 32. Further, the cover 2 may be configured to store the core 11 and the air bag 12 without providing a cover that covers the fastening belt 32. In this case, the core 11 is held in a substantially cylindrical shape. Can be stored.

  Further, in the method of attaching the storage cover 2 of the present embodiment, first, the core 11 to which the air bag 12 is attached is stored in the storage cover 2 and the storage cover 2 and the core 11 are joined. Next, the distal end portion 321 of the fastening belt 32 removed from the base 31 is inserted into the storage cover 2 from the opening 25, passes through the fastening belt opening 24, and passes through the base 31. Then, it is inserted into the storage cover 2 again. Subsequently, the core 11 and the base 31 are joined, and the pinion gear 36 and the shooting 33 are assembled. However, it is not limited to this attachment method.

(Tightening means)
The tightening means 3 of the present embodiment includes a base 31, a tightening belt 32, a photographing 33, an opening lever 34, a connecting plate 35, a pinion gear 36, a holding pin 39, and the like. The base 31 is joined to the core 11 by adhesion, welding, sewing, eyelet eyelashes, or the like. The base 31 includes a connecting plate 35 that is rotatably attached, a pinion gear 36 that is connected to the shooting 33 for realizing a tightening function, a holding pin 39 for realizing a holding function, In addition, an opening lever 34 for releasing the holding state by the holding pins 39 is attached. Further, the fastening belt 32 is formed at a substantially central portion in the width direction, and in the longitudinal direction, a rack 37 that meshes with the pinion gear 36 is formed. Further, holding pins 39 are engaged at both ends in the width direction. A holding hole 38 is provided in parallel. The fastening belt 32 has one end attached to the connecting plate 35 and wound around the outer periphery of the core 11, and the other end (the tip 321) is inserted into the base 31. In this way, when the core 11 is tightened, the core 11 can be tightened from the entire circumferential direction, and the arm can be tightened without any sense of incongruity for the user.

In the tightening means 3 having the above configuration, when the user inserts his arm into the core 11 and rotates the photographing 33 in the tightening direction, the pinion gear 36 acts on the rack 37 and tightens the tightening belt 32. The core 11 is tightened as a whole. At this time, the holding pin 39 is repeatedly pulled out and engaged with the holding hole 38 as in the ratchet mechanism. When the rotation of the photographing 33 is stopped, the holding pin 39 is engaged with the holding hole 38 and the fastening belt 32 is engaged. Hold so that it does not return in the opening direction. When blood pressure measurement is completed and the user depresses the release lever 34, the holding pin 39 comes out of the holding hole 38, and the restoring force of the core 11 and the fastening belt 32 causes the core 11 and the fastening belt 32 to move. The diameter is automatically expanded to the maximum diameter.
The tightening means 3 of this embodiment has a function as a fixing means for holding one end of the core 11 inside the other end of the core 11 and a tightening function for tightening the core 11 to the arm. However, the present invention is not limited to this configuration. For example, a simple configuration using fixing means such as a hook-and-loop fastener, or a configuration in which the pinion gear 36 is rotated using driving means such as a motor may be used.

Next, the usage method and operation | movement of the biological compression apparatus 1 of the said structure are demonstrated.
First, the user of the living body compression apparatus 1 that measures blood pressure confirms that the circumference of the core 11 and the fastening belt 32 is increased to the maximum diameter. Here, since the living body compression apparatus 1 is almost covered with the storage cover 2, the aesthetic appearance is greatly improved, and the user can divert the troublesomeness associated with the measurement.
Normally, when the previous use is finished, the circumference diameters of the core 11 and the fastening belt 32 are increased to the maximum diameter, and the living body compression apparatus 1 is stored in this state.

When the diameter is reduced, the release lever 34 is pressed. Thereby, the living body compression apparatus 1 moves the fastening belt 32 in the opening direction by the restoring force of the core 11 and the fastening belt 32, and the circumference diameters of the core 11 and the fastening belt 32 are increased to the maximum diameter.
Here, since the fastening belt 32 is covered by the storage cover 2, it is possible to prevent a problem that a finger or the like is caught on the rack 37, the holding hole 38, or the like of the fastening belt 32.
Subsequently, the user inserts, for example, the left arm into the cylindrical storage cover 2 with the living body compression apparatus 1 placed horizontally so that the photographing 33 faces upward.

Next, the user rotates the shooting 33 in the tightening direction. By this operation, the pinion gear 36 feeds the rack 37 in the tightening direction, and the holding belt 39 moves in the tightening direction while repeating the removal and engagement of the holding pin 39 with respect to the holding hole 38. The circumference of the air bag 12 is reduced. Subsequently, when the user tightens the core 11 to a measurable state and stops the rotation of the photographing 33, the holding pin 39 is engaged with the holding hole 38, and the core 11 is kept in a well-tightened state. To do.
At this time, the portion 321 on the front end side of the fastening belt 32 sent out by the pinion gear 36 comes into contact with the storage cover 2 and is sent out in the inner direction. Therefore, for example, even when the user is sleeping on the bed, it is possible to prevent a problem that the tightening is not properly performed. Further, it is possible to prevent the trouble that the portion 321 on the front end side of the sent out fastening belt 32 hits the bed or the chest of the user and gets in the way, thereby improving usability.

  Next, air is sent to the air bag 12 and the blood pressure is measured. Subsequently, the blood pressure measurement result is displayed, and when the air is removed from the air bag 12, the user presses the release lever 34. As a result, the living body compression apparatus 1 is moved in the opening direction by the restoring force of the core 11 and the fastening belt 32, and the circumference diameter of the core 11 and the air bag 12 is increased, and the expanded state is maintained. Retained. Therefore, the user can easily remove the arm from the core 11 and can easily insert the arm in the next measurement. Further, as described above, since the fastening belt 32 is covered with the storage cover 2, it is possible to prevent a problem that a finger or the like is caught on the rack 37 and the holding hole 38 of the fastening belt 32. Can do.

Then, the user stores the biological compression device 1 on a shelf or the like.
Here, since the living body compression apparatus 1 is stored in a state where the core 11 is held in a substantially cylindrical shape by the storage cover 2 on the other end side, it is possible to prevent a problem such as causing a shape loss. Furthermore, in this embodiment, since the core 11 can be held in a substantially cylindrical shape by using the storage cover 2 for improving the touch and the like, the manufacturing cost can be reduced.

As described above, according to the living body compression apparatus 1 of the present embodiment, it is possible to improve storability, economy, safety, usability, and the like. Furthermore, the living body compression apparatus 1 is greatly improved in aesthetics by covering the fastening belt 32, the core 11 and the like with the storage cover 2, and the user forgets the troublesomeness associated with the measurement and feels comfortable with blood pressure measurement. It can be carried out.
Moreover, the living body compression apparatus 1 of this embodiment has various application examples.
Next, an application example thereof will be described with reference to the drawings.

<Application example of biological compression device>
FIG. 5: has shown the schematic plan view of the fastening belt of the application example of the biological compression apparatus which concerns on 1st embodiment of this invention.
In FIG. 5, the biological compression device of this application example is different from the biological compression device 1 of the first embodiment in that a fastening belt 32 ′ is used instead of the fastening belt 32. Other configurations of the biological compression device of this application example are substantially the same as those of the biological compression device 1.
In FIG. 5, the same components as those in the above-described drawings are denoted by the same reference numerals, and detailed description thereof is omitted.

The fastening belt 32 ′ has a holding hole 38 and a rack 37 formed at one end in the short direction. The fastening belt 32 ′ has a shape in which the other end portion in the short direction facing the portion where the rack 37 is formed is cut out. As a result, the width W _{0 of} the portion of the fastening belt 32 ′ where the rack 37 is formed is about 25% of the width W of the portion of the fastening belt 32 ′ where the rack 37 is not formed.
In this way, the distal end portion 321 of the tightening belt 32 ′ is easily bent, and thus the distal end portion 321 of the tightened belt 32 ′ sent out is stored in the storage cover 2 when tightened. It becomes easy. That is, when the distal end portion 321 contacts the storage cover 2, it is possible to prevent the storage cover 2 from being stretched outward or the shape of the distal end portion 321 is clearly raised.

In the present embodiment, the width W _{0 is set} to about 25% of the width W. However, the present invention is not limited to this. Usually, the width W ₀ is preferably 20 to 80% of the width W. The reason is that if the length is shorter than 20%, the mechanical strength is lowered, and the function as the locking portion cannot be exhibited. This is because the effect of facilitating storage in the container is greatly reduced.

  As described above, according to the living body compression apparatus of the present application example, substantially the same effect as that of the above-described living body compression apparatus 1 of the first embodiment can be obtained, and further, the tightening belt 32 fed out when tightened. The portion 321 on the tip side of ′ is easily stored in the storage cover 2.

[Second Embodiment of Biological Compression Device]
FIG. 6 is a schematic cross-sectional view in the arm axis direction of the living body compression apparatus according to the second embodiment of the present invention.
In FIG. 6, the biological compression apparatus 1a of this embodiment differs in the point provided with the belt accommodation guide 4 and the tension spring 5 compared with the biological compression apparatus of the application example mentioned above. In addition, the other structure of the biological compression apparatus 1a is as substantially the same as the biological compression apparatus of the application example mentioned above.
Therefore, in FIG. 6, the same components as those in FIGS. 3 and 5 are denoted by the same reference numerals, and detailed description thereof is omitted.

(Belt storage guide)
The belt storage guide 4 is a guide that directs the tip portion 321 of the fastening belt 32 ′ sent out in the fastening direction by the pinion gear 36 inward, and is provided on the base 31.
The belt storage guide 4 of this embodiment includes a resin curved plate 41, a flat plate 42, and side plates 43. The curved plate 41 is a circularly curved plate having one end connected to the base 31 and the other end connected to the flat plate 42. The flat plate 42 is a substantially flat plate having one end connected to the curved plate 41. The side plate 43 is a substantially parallelogram-shaped flat plate, and three sides are connected to the base 31, the curved plate 41, and the flat plate 42, respectively. The belt storage guide 4 is usually formed integrally with the base 31. The belt storage guide 4 is stored in the storage cover 2.

By providing the belt storage guide 4 described above, the living body compression apparatus 1a can surely orient the portion 321 on the distal end side of the fastening belt 32 'inward. In addition, even when the tip end portion 321 contacts the belt storage guide 4, it is possible to reliably prevent a problem such that the tip end portion 321 is raised in the storage cover 2 that covers the belt storage guide 4. Furthermore, the tension spring 5 can be protected.
The belt storage guide 4 is not limited to the above-described configuration (material, shape, or attachment site (base 31 in this embodiment)). For example, the belt storage guide 4 may be manufactured as one component and attached to the base 31.

(Tension spring)
One end of the tension spring 5 is locked to the tip of the protruding portion 311 of the base 31, and the other end is locked to a tightening belt 32 ′ connected to the connecting plate 35. The tension spring 5 pulls the tightened belt 32 'having a reduced diameter outward.
Here, the protrusion 311 is formed so as to protrude from the base 31 in the tightening direction. Further, the position of the fastening belt 32 ′ where the other end of the tension spring 5 is locked is separated from the connecting plate 35 by a predetermined distance. That is, when the diameter of the tightening belt 32 ′ is reduced, the tension spring 5 is extended, and a spring force that attempts to return the tightening belt 32 ′ to its original state (maximum diameter state) causes the tightening belt 32 ′. Act on. Therefore, when the release lever 34 is pressed, it is possible to prevent a problem that the tightening belt 32 ′ to be automatically expanded to the maximum diameter is not expanded due to frictional resistance with the storage cover 2. .

  In the present embodiment, the tension spring 5 is configured to pull the tightening belt 32 ′ having a reduced diameter outward and expand the diameter of the tightening belt 32 ′, but is not limited thereto. For example, although not shown, the other end of the tension spring 5 is locked to the core 11 located inside the tightening belt 32 ′ connected to the connecting plate 35, and the tension spring 5 is attached to the tightening belt 32 ′. You may form the opening part which passes. In this way, since the tension spring 5 pulls the core 11 having a reduced diameter outward, a spring force for returning the core 11 to the original state (maximum diameter state) acts on the core 11. .

That is, the tension spring 5 connected to the core 11 functions as an elastic member for expanding the diameter of the core 11 that has been reduced in diameter, and the core 11 cannot be expanded due to the frictional resistance between the core 11 and the storage cover 2. Such a problem can be prevented. Further, when the diameter of the core 11 is increased, the core 11 comes into contact with the tightening belt 32 ', so that even if the tightening belt 32' cannot be expanded, the reduced tightening belt 32 'is placed outward. Push up. Therefore, it is possible to overcome the frictional resistance between the core 11 and the storage cover 2 and the frictional resistance between the tightening belt 32 ′ and the storage cover 2, thereby reliably expanding the diameter of the core 11.
In addition, although said tension spring 5 was used as an elastic member which expands the diameter of the core 11 reduced in diameter, it is not limited to this structure (a material, a shape, a site | part which acts on restoring force, etc.). . For example, a rubber member in the form of a string, a band, or a sheet may be used as the elastic member.

As described above, according to the living body compression apparatus 1a of the present embodiment, substantially the same effects as those of the living body compression apparatus 1 of the first embodiment described above can be obtained.
Further, the portion 321 on the front end side of the tightening belt 32 ′ can be reliably directed inward. In addition, even when the tip end portion 321 contacts the belt storage guide 4, it is possible to reliably prevent a problem such that the tip end portion 321 is raised in the storage cover 2 that covers the belt storage guide 4.
Further, when the release lever 34 is pressed, it is possible to prevent a problem that the core 11 that should be automatically expanded to the maximum diameter is not expanded due to frictional resistance with the storage cover 2.

[One Embodiment of Blood Pressure Measuring Device]
The present invention is also effective as an invention of a blood pressure measurement device (appropriately abbreviated as a sphygmomanometer).
FIG. 7 shows a schematic block diagram of a main part of an oscillometric electronic sphygmomanometer according to an embodiment of the present invention.
In FIG. 7, the oscillometric electronic sphygmomanometer 6 includes a pressure sensor 62, a pump 63, and an exhaust valve 64, which are in communication with the air bag 12 through a pipe 61 and a pipe 123. And an information processing device 65 connected to the pressure sensor 62, the pump 63 and the exhaust valve 64, and an operation switch 66 and a display 67 connected to the information processing device 65.
Here, the oscillometric electronic sphygmomanometer 6 of the present embodiment is configured to include the living body compression apparatus 1 of the above-described embodiment.

In this way, the oscillometric electronic sphygmomanometer 6 according to the present embodiment can improve the storability, economy, safety and usability of the biological compression device 1 as described above. Furthermore, the oscillometric electronic sphygmomanometer 6 is greatly improved in aesthetics because the living body compression apparatus 1 covers the fastening belt 32, the core 11 and the like with the storage cover 2, and the user is accompanied by the measurement. Forgetting bothering, blood pressure can be measured with ease.
In addition, in this embodiment, although it is set as the structure which uses the living body compression apparatus 1, it is not limited to this, For example, as a structure using the living body compression apparatus of the example of application, or the living body compression apparatus 1a of 2nd embodiment. Also good.

As described above, the biological compression device and the blood pressure measurement device according to the present invention have been described with reference to preferred embodiments, but the biological compression device and the blood pressure measurement device according to the present invention are not limited to the above-described embodiments, It goes without saying that various modifications can be made within the scope of the present invention.
For example, the biological compression devices 1, 1a, etc. are not limited to use in an oscillometric electronic sphygmomanometer, and can be applied to, for example, an automatic sphygmomanometer that measures blood pressure based on Korotkoff sounds. .

  As described above, the living body compression device of the present invention is not limited to the case where it is used for an arm band for a sphygmomanometer. For example, it is necessary to accurately measure a pulse wave during pressurization. It can also be used for a living body compression device.

FIG. 1: has shown the schematic perspective view of the biological compression apparatus which concerns on 1st embodiment of this invention. FIG. 2: has shown the schematic perspective view of the state from which the protective cover was removed of the biological compression apparatus which concerns on 1st embodiment of this invention. FIG. 3 is a schematic cross-sectional view taken along the line AA in FIG. FIG. 4 shows a schematic side view of FIG. FIG. 5: has shown the schematic plan view of the fastening belt of the application example of the biological compression apparatus which concerns on 1st embodiment of this invention. FIG. 6 is a schematic cross-sectional view in the arm axis direction of the living body compression apparatus according to the second embodiment of the present invention. FIG. 7 shows a schematic block diagram of a main part of an oscillometric electronic sphygmomanometer according to an embodiment of the present invention.

Explanation of symbols

1, 1a Biological compression device 2 Storage cover 3 Tightening means 4 Belt storage guide 5 Tension spring 6 Oscillometric electronic sphygmomanometer 11 Core 12 Air bag 13 Protection plate 21 One end 22 The other end 23 Opening for storage cover Portion 24 Tightening belt opening 25 Opening portion 26 Pipe opening portion 31 Base 32, 32 'Tightening belt 33 Shooting 34 Opening lever 35 Connecting plate 36 Pinion gear 37 Rack 38 Holding hole 39 Holding pin 41 Curved Plate 42 Flat plate 43 Side plate 61 Pipe 62 Pressure sensor 63 Pump 64 Exhaust valve 65 Information processing device 66 Operation switch 67 Indicator 111 One end 112 The other end 121 One end 122 The other end 123 Pipe 311 Projection 321 Tip side part

Claims (7)

An air bag, a flexible core disposed outside the air bag, a fastening belt for fastening the core to a part of a living body, and a housing for housing the air bag, the core, and the fastening belt. With a cover,
The living body compression apparatus, wherein the storage cover has an opening at one end in the longitudinal direction, and the other end in the longitudinal direction of the storage cover is inserted into the opening.   One end in the longitudinal direction of the core is wound inside the other end in the longitudinal direction, and the other end in the longitudinal direction of the core is inserted into the opening of the storage cover. The living body compression apparatus according to claim 1, wherein: The living body compression apparatus according to claim 1, wherein a rack that meshes with the pinion gear is formed in a longitudinal direction of the fastening belt . The living body compression apparatus according to any one of claims 1 to 3, further comprising a holding mechanism that holds a tightened state in a longitudinal direction of the tightening belt . The living body compression apparatus according to claim 3 or 4, wherein a dimension in a short direction of a portion where the rack of the fastening belt is formed is shorter than a dimension in a short direction of a portion where the rack is not formed .   The living body compression apparatus according to any one of claims 1 to 5, further comprising a belt storage guide for directing a tip portion of the fastening belt inward. In a blood pressure measurement device using a biological compression device,
A blood pressure measurement device using the living body compression device according to any one of claims 1 to 6.

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