JP2014158598A - Underwater sphygmomanometer/electrocardiograph - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an underwater sphygmomanometer/electrocardiograph capable of measuring a blood pressure and an electrocardiogram of a human body without being affected by water and a water pressure.SOLUTION: The underwater sphygmomanometer/electrocardiograph comprises: a body waterproof case in which a sphygmomanometer body part and an electrocardiograph body part are stored; a sphygmomanometer cuff and a microphone extending from the sphygmomanometer body part to the outside of the body waterproof case; an electrocardiograph electrode extending from the electrocardiograph body part to the outside of the body waterproof case; an air introduction regulator provided in the body waterproof case so as to be connectable to a diving air tank; and an air exhaust valve tube provided in the body waterproof case.

Description

  The present invention relates to an underwater blood pressure electrocardiograph capable of measuring a blood pressure and an electrocardiogram of a human body in water.

In general, underwater exercise such as swimming is regarded as a health method, but about 30% of AED (automated external defibrillator) use cases are related to seizures during underwater exercise. For those with cardiovascular disease, underwater exercise is a health risk. Therefore, obtaining blood pressure information and electrocardiogram information of the human body in water has become an important element in sports health medicine.
However, since conventional blood pressure monitors and electrocardiographs are premised on measurement under atmospheric pressure, blood pressure and electrocardiograms can be measured not only in water under pressure by water pressure but also in contact with water in the first place. It was not possible to measure.

  Incidentally, the present inventors have previously developed an underwater sphygmomanometer in which a sphygmomanometer body is housed and installed in a waterproof case having a function of balancing internal pressure and external pressure (patented). Although the underwater sphygmomanometer is capable of measuring blood pressure, the electrocardiogram, which is an important element along with blood pressure, has not yet been obtained for the health management of cardiovascular patients. .

JP 2012-34898 A

  The present invention has been made in view of the conventional problems as described above, and provides an underwater blood pressure electrocardiograph capable of measuring a human blood pressure and an electrocardiogram in water without being affected by water or water pressure. It is an issue.

  As a result of various studies to solve the above-mentioned problems, the inventors have housed the sphygmomanometer main body and the electrocardiograph main body in a waterproof case that maintains water pressure and equilibrium pressure. Thus, the inventors have found that extremely good results can be obtained and completed the present invention.

That is, the present invention relates to a waterproof case for a main body in which a blood pressure monitor main body and an electrocardiograph main body are accommodated;
A sphygmomanometer cuff and a microphone respectively extending from the sphygmomanometer main body outside the waterproof case for the main body;
An electrocardiogram electrode extending from the electrocardiograph main body outside the waterproof case for the main body;
An air introduction regulator provided on the waterproof case for the main body so as to be connectable to an air tank for diving;
An air discharge valve pipe provided in the waterproof case for the main body;
The above-mentioned problem is solved by an underwater blood pressure electrocardiograph characterized by comprising:

By using the underwater blood pressure electrocardiograph of the present invention, the blood pressure and electrocardiogram of a human body can be measured in water without being affected by water or water pressure.
Therefore, according to the present invention, health management of various underwater athletes such as swimming can be performed by using pre-measured blood pressure information and electrocardiogram information in water, which greatly contributes to the reduction of health risks caused by underwater exercise. It becomes possible.

BRIEF DESCRIPTION OF THE DRAWINGS Schematic structure explanatory drawing of this invention underwater blood pressure electrocardiograph. Schematic explanatory drawing which shows the example of air introduction to the waterproof case for connectors. Schematic explanatory drawing which shows the operation example of a regulator. Schematic explanatory drawing which shows the usage example of this invention underwater blood pressure electrocardiograph.

  A description will now be given with reference to the drawings showing an embodiment of the present invention.

FIG. 1 is an explanatory diagram of a schematic configuration of an underwater blood pressure electrocardiograph according to the present invention.
In FIG. 1, 10 is a waterproof case for the main body, and the material is not particularly limited as long as the material is waterproof. A blood pressure monitor main body 20 and an electrocardiograph main body 30 are accommodated in the waterproof case 10 for main body.

The sphygmomanometer main body 20 has a blood pressure value display part (not shown) and a memory part (not shown) for recording the blood pressure value, and can be printed out by an analysis device as appropriate. . The electrocardiograph main body 30 is preferably a so-called holder electrocardiograph and has a memory unit (not shown) for recording an electrocardiogram so that it can be printed out by an analysis device as appropriate. The sphygmomanometer main body 20 and the electrocardiograph main body 30 may be separate from each other, but it is desirable that the sphygmomanometer main body 30 be integrated with the sphygmomanometer main body 20.
The sphygmomanometer main body 20 and the electrocardiograph main body 30 are fixed to a substantially central portion in the main body waterproof case 10 with a plurality of support rods 11 so as to be appropriately spaced from all inner wall surfaces of the main body waterproof case 10. is set up. By forming such an interval, the blood pressure monitor main body 20 and the electrocardiograph main body 30 are in direct contact with water even if condensation occurs in the waterproof case 10 for the main body or there is some water immersion. It is possible to prevent the normal measurement.

  Reference numeral 21 denotes a sphygmomanometer cuff extending from the sphygmomanometer main body 20 accommodated in the main body waterproof case 10 to the outside of the main body waterproof case 10. A pressure bag 22 is provided inside the sphygmomanometer cuff 21, and air is introduced into the pressure bag 22 from an internal pump 23 provided in the sphygmomanometer body 20 through a waterproof tube 24. It is like that. With such a configuration capable of introducing air, the pressure bag 22 can maintain a balance with an external pressure and a waterproof function.

  A sphygmomanometer microphone 25 extends from the sphygmomanometer main body 20 accommodated in the main body waterproof case 10 to the outside of the main body waterproof case 10 via a cord 26. Used inside (see FIG. 4). The sphygmomanometer microphone 25 is housed in a microphone waterproof case 28 that is connected to the main body waterproof case 10 via a waterproof tube 27 so as to allow air flow, and is also inserted into the waterproof tube 27. 26 is connected to the sphygmomanometer body 20 in the waterproof case 10 for the body. With such a configuration capable of introducing air, high water pressure is not applied to the sphygmomanometer microphone 25, so that the Korotkoff sound can be transmitted to the sphygmomanometer body 20 with high accuracy.

  An electrocardiogram electrode 31 extends from the electrocardiograph main body 30 accommodated in the main body waterproof case 10 to the outside of the main body waterproof case 10 via a waterproof cord 32. As shown in FIG. 2, the waterproof cord 32 is wired via a connector 32 a in the main body waterproof case 10 and a connector 32 b outside the main body waterproof case 10. The connector 32b is housed in a connector waterproof case 33 installed outside the main body waterproof case 10, and the connector waterproof case 33 has an air introduction pipe 34 detachably connected to the diving air tank T. I have. By adopting such a connector method, an electrocardiogram electrode of a normal blood pressure electrocardiograph can be used as it is in the underwater blood pressure electrocardiograph of the present invention without changing the connector.

  A part of the air introduction pipe 34 passes through the waterproof case 10 for the main body, and the waterproof cord 32 drawn out from the connector 32 a is an opening formed in the air introduction pipe 34 in the waterproof case 10 for the main body. The opening 34a is inserted into the connector 34b from the portion 34a and wired to the connector 32b. The opening 34a is sealed after wiring, so that the space between the waterproof case 10 for the main body and the waterproof case 33 for the connector is not vented. . Reference numeral 34b denotes a throttle valve provided in the air introduction pipe 34 in the vicinity of the connecting portion with the diving tank T. With such a configuration, air is introduced from the diving air tank T into the connector waterproof case 33 during measurement, and air is prevented from entering the water through the gap between the waterproof case 33 and the waterproof cord 32. As a result, the connector 32b does not come into contact with water, and a more accurate electrocardiogram can be obtained. Further, since the electrocardiogram electrode 31 comes into contact with water at the time of measurement, the wiring may be corroded. However, even if the wire is broken, the waterproof cord 32 is securely waterproof up to the waterproof case 33 for the connector. Therefore, since only the portion of the electrocardiogram electrode 31 from the connector 32b can be exchanged via the connector 32b, a so-called disposable type electrode can be used as the electrocardiogram electrode 31, which is convenient.

  A regulator 40 is provided at the lower portion of the waterproof case 10 for the main body so as to be connectable to the air tank T for diving. As shown in FIG. 3, the regulator 40 automatically introduces air into the waterproof case 10 and increases the external pressure of the waterproof case 10 for the main body when diving. The internal pressure and the external pressure are balanced, and includes a diaphragm 41 and an air introduction pipe 43 provided with a valve 42 that opens and closes in conjunction with the deformation of the diaphragm 41. The air introduction pipe 43 is used for diving. The air tank T is detachably connected.

  Reference numeral 50 denotes an air discharge valve pipe provided at the lower part of the waterproof case 10 for the main body. This air discharge valve pipe 50 discharges the air in the waterproof case 10 to the outside as the internal pressure of the waterproof case 10 for the body rises when it rises. A valve 52 that opens when the internal pressure of the waterproof case 10 is higher than the external pressure (when floating) and closes when the internal pressure is equal to or lower than the external pressure (when diving) is installed in the pipe portion 51.

  A water receiving space 60 is provided on the inner bottom of the main body waterproof case 10. Due to the presence of the water receiving space portion 60, even if the water W enters the waterproof case 10 for the main body due to some reason, the water is stored in the space portion 60. Direct contact between the electrocardiograph main body 30 and water can be prevented. Moreover, if the diaphragm 41 is pushed, the valve 42 is opened and air is introduced from the diving air tank T into the waterproof case 10 for the main body, the internal pressure in the waterproof case 10 becomes higher than the external pressure, and the valve 52 is opened. The water W in the water receiving space portion 60 can be drained out of the waterproof case 10 from the discharge pipe portion 51.

  Reference numeral 70 denotes a measurement start button, which has a protruding collar 70a that comes into contact with the switch 71 of the sphygmomanometer main body 20 and the electrocardiograph main body 30 to control its operation, and is provided on the upper part of the waterproof case 10 for main body so as to be movable up and down. When the measurement start button 70 is depressed, the protruding collar 70a contacts the switch 71 to operate the blood pressure monitor main body 20 and the electrocardiograph main body 30, while the protruding collar 70a is switched when the button 70 is pulled up. The operation is stopped after leaving 71. A waterproof O-ring 70b is appropriately mounted around the protruding collar 70a.

  As shown in FIG. 4, the underwater blood pressure electrocardiograph of the present invention further includes a float F that is detachably attached and fixed to the main body waterproof case 10 and the diving air tank T by a belt B. As a result, the main body waterproof case 10 is integrated with the diving air tank T, and can be used floating without being carried on the back. Since it is not affected by fluctuations in blood pressure or the like accompanying the load, it is possible to measure blood pressure and electrocardiogram more accurately.

  Next, a method of using the underwater blood pressure electrocardiograph according to the above embodiment will be described.

  First, as shown in FIG. 4, the waterproof case 10 for the main body and the air tank T for diving are attached and fixed to the float F by the belt B, and the waterproof case 10 for the main body and the diving air tank T are submerged without carrying the back. Float on. Next, in this state, the blood pressure cuff 21 is wound around and fixed to the arm A of the person to be measured by inserting the sphygmomanometer microphone 25 inside the pressure bag 22. Incidentally, the valve 42 of the regulator 40 in such a state is closed because the internal pressure and the external pressure of the waterproof case 10 for the main body are in an equilibrium state, as shown in FIG. The valve 52 of the air discharge valve pipe 50 is also closed.

  Next, when a breathing regulator (not shown) connected to the diving air tank T is attached to the mouth and submerged, the external pressure of the waterproof case 10 for the main body increases as shown in FIG. Therefore, the diaphragm 41 of the regulator 40 is deformed and the valve 42 is opened in conjunction with the deformation, so that air is introduced from the diving air tank T into the waterproof case 10 for the main body and the waterproof case 28 for the microphone. Next, when air is introduced into the main body waterproof case 10 and the microphone waterproof case 28 until the internal pressure and the external pressure of the main body waterproof case 10 and the microphone waterproof case 28 are balanced, the deformation of the diaphragm 41 is the original. Thus, the state shown in FIG. 3A is reached, the valve 42 of the regulator 40 is closed, and the introduction of air is stopped. Incidentally, even in this state, since the valve 52 of the air discharge valve pipe 50 is closed, water does not enter the waterproof case 10 for the main body. At this time, by opening the throttle valve 34c of the air introduction pipe 34 and introducing air into the waterproof case 33 for connectors, it is possible to prevent water from entering the waterproof case 33 for connectors.

  Next, when the measurement start button 70 is pressed in this state and the switch 71 of the sphygmomanometer main body 20 and the electrocardiograph main body 30 is turned on and operated, in the atmosphere without being affected by water or water pressure. Similarly, the blood pressure and electrocardiogram of the subject under measurement are measured and recorded normally. Moreover, since the waterproof case 10 for main bodies is floating in the position away from the to-be-measured person at this time, the to-be-measured person can visually recognize the blood pressure value shown on the display unit.

  Next, when rising after the measurement, the external pressure in the waterproof case 10 for the main body decreases from the internal pressure, so the valve 52 of the air discharge valve pipe 50 is opened by the large internal pressure, and the air in the waterproof case 10 for the main body When the pressure is discharged out of the waterproof case 10 and the internal pressure and the external pressure are balanced, the valve 52 is closed.

10: Waterproof case for main body 11: Support rod 20: Blood pressure monitor main body 21: Cuff for blood pressure monitor 22: Pressure bag 23: Internal pump 24: Waterproof tube 25: Microphone for blood pressure monitor 26: Code 27: Waterproof tube 28: Microphone waterproof case 30: Electrocardiograph main body 31: Electrocardiogram electrode 32: Waterproof cord 32a: Connector 32b: Connector 33: Connector waterproof case 34: Air introduction pipe 34a: Opening 34b: Throttle valve 40: Regulator 41: Diaphragm 42: Valve 43: Air introduction pipe 50: Air discharge valve pipe 51: Discharge pipe section 52: Valve 60: Water receiving space section 70: Measurement start button 70a: Protruding rod 70b: O-ring 71: Switch A: Arm B : Belt F: Float T: Diving tank W: Water

Claims (8)

A waterproof case for the main body in which the blood pressure monitor main body and the electrocardiograph main body are housed;
A sphygmomanometer cuff and a microphone respectively extending from the sphygmomanometer main body outside the waterproof case for the main body;
An electrocardiogram electrode extending from the electrocardiograph main body outside the waterproof case for the main body;
An air introduction regulator provided on the waterproof case for the main body so as to be connectable to an air tank for diving;
An air discharge valve pipe provided in the waterproof case for the main body;
An underwater blood pressure electrocardiograph characterized by comprising:   The underwater blood pressure electrocardiograph according to claim 1, wherein the electrocardiogram electrode is extended through a connector in a waterproof case for a connector installed outside the waterproof case for a main body.   The underwater blood pressure electrocardiograph according to claim 2, wherein the waterproof case for connectors includes an air introduction tube that is detachably connected to an air tank for diving.   The underwater blood pressure heart according to any one of claims 1 to 3, wherein the sphygmomanometer cuff includes a pressure bag that receives air from an internal pump provided in a sphygmomanometer body. Electric meter.   The underwater blood pressure electrocardiograph according to any one of claims 1 to 4, wherein the sphygmomanometer microphone is housed in a microphone waterproof case connected to the main body waterproof case so as to allow air flow. Total.   6. The sphygmomanometer main body and the electrocardiograph main body are fixedly installed in the main body waterproof case at appropriate intervals from all inner wall surfaces of the main body waterproof case. The underwater blood pressure electrocardiograph according to any one of the above.   The underwater blood pressure electrocardiograph according to any one of claims 1 to 6, wherein the waterproof case for a main body includes a water receiving space portion at an inner bottom portion thereof.   The underwater blood pressure electrocardiograph according to any one of claims 1 to 7, further comprising a float that is detachably attached and fixed to the waterproof case for the main body and the air tank for diving.

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