KR101175720B1 - The Sphygmomanometer - Google Patents

Abstract

The present invention relates to a blood pressure measuring device that operates smoothly in an internal environment of a low temperature systemic treatment device. The blood pressure measuring device according to the present invention provides compressed air for measuring blood pressure, and detects a change in pressure according to the provision of compressed air. A blood pressure monitor for measuring blood pressure; A compression table that expands by compressed air from the blood pressure monitor and presses the body of the patient; And a sphygmomanometer cable for transferring the compressed air from the sphygmomanometer to the sphygmomanometer, the sphygmomanometer cable heating wire for heating the compression bar and the sphygmomanometer cable heating wire for the heating of the sphygmomanometer cable. The blood pressure monitor further includes a power supply for supplying power to the pressure bar heating wire and the blood pressure monitor cable heating wire.

Description

Blood Pressure Monitor {The Sphygmomanometer}

The present invention relates to a blood pressure meter, and more particularly, to a blood pressure meter that operates smoothly in a low temperature systemic treatment environment.

Cryo Therapy applies the principle of ice cooling when there are pains such as bruises or inflammations, exposing the user's whole body to low temperature air for 2 to 3 minutes to dissipate heat to maintain body temperature from the body. By strengthening the immune system in the body, increasing the natural healing power of the body through the fever action of the inflammatory site, and also giving a strong stimulation to the nervous system, thereby relieving pain by preventing the pain-induced nerve fibers from working. It's becoming a cure.

In order for the systemic cryogenic therapy to have the maximum effect, the temperature of the main treatment room should be about -110 degrees Celsius, because the body's warmth discharge reaches a peak at -100 degrees Celsius to -120 degrees Celsius.

However, if the user enters the main treatment room immediately, the body may not adapt to the sudden change in temperature, which may cause a heart attack. Also, when the low temperature air and the relatively high outside air of the main treatment room meet, there is a sudden convection phenomenon. As they exchanged with each other, the temperature of the main treatment room was raised to reduce the effectiveness of treatment and to replenish the lost cold air, resulting in economic losses.

This allows the user's body to adapt to cold before entering the main treatment room, while at the same time extending the auxiliary treatment room, which is maintained at about -40 degrees Celsius, to one side wall of the main treatment room so that the cold of the main treatment room is not rapidly lost to the outside. Formed to be configured to communicate with each other through a separate door.

Such a conventional systemic cryotherapy device has a problem in that it is not possible to check the condition of the patient in the treatment room. In order to treat the patient, it is necessary to continuously measure the blood pressure, the pulse, and the temperature of the affected part. However, the conventional systemic cryotherapy device has no method of monitoring the patient's condition in the treatment room. In particular, since the systemic cryotherapy device is for the treatment of non-normal patients, new care is required, but the installation and operation of a device capable of monitoring such a patient is difficult due to an internal environment different from the outside.

Accordingly, it is an object of the present invention to provide a blood pressure meter that operates smoothly in a sub-zero system.

In addition, another object of the present invention is to prevent the body damage caused by the super-cooled blood pressure monitor when wearing a blood pressure monitor left in a low temperature state, to prevent the increase of fatigue of the blood pressure monitor according to the maintenance of the low temperature state, and to make accurate blood pressure measurement To provide a blood pressure monitor.

In order to achieve the above object, the blood pressure measuring device according to the present invention provides a compressed air for measuring blood pressure in a blood pressure measuring device operating at subzero temperature, and detects a change in pressure according to the provision of compressed air, thereby measuring the blood pressure of the patient. A blood pressure monitor to measure; A compression table that expands by compressed air from the blood pressure monitor and presses the body of the patient; And a sphygmomanometer cable for delivering the compressed air from the sphygmomanometer to the sphygmomanometer, wherein the pressure bar and the sphygmomanometer cable include a heating wire for heating, and the sphygmomanometer supplies power to the heating wire. It further comprises a power supply for.

The blood pressure monitor cable includes a tube having a hollow therein for delivering the compressed air from the blood pressure monitor to the compression table; A heating wire wound on the outside of the tube; A heat conductive film coated on the hot wire and the tube surface to cover the hot wire and the tube; And an outer cover coated on the outside of the thermal conductive film.

The compression table is connected to the tube and the balloon is expanded by the compressed air supplied through the tube; A compression bar heating wire wound on an outer surface of the balloon and electrically connected to the heating wire of the blood pressure monitor cable; A heat conductive film coated on surfaces of the balloon and the pressure bar heating wire to surround the hot wire and the balloon; And an outer cover coated on the outside of the thermal conductive film.

Blood pressure monitor according to the present invention can operate smoothly in the environment of the sub-zero temperature systemic treatment device.

In addition, the pincer pressure measuring device according to the present invention prevents damage to the body caused by the supercooled blood pressure monitor when wearing a blood pressure monitor left in a low temperature state, prevents an increase in the fatigue of the blood pressure monitor according to the maintenance of the low temperature state, and accurate blood pressure measurement It is possible to make it happen.

1 is a configuration example showing the configuration of a cryotherapy system according to the present invention.
Figure 2 is a perspective view showing a cryotherapy room of a cryotherapy system according to the present invention.
3 is an exemplary view schematically showing the installation of the blood pressure meter.
4 is a cross-sectional view illustrating the longitudinal / lateral cross-sectional shape of the blood pressure monitor cable.
5 is an exemplary view showing the cross section and planar shape of the pressure bar.

Hereinafter, with reference to the accompanying drawings, preferred embodiments of the present invention will be described to be easily carried out by those skilled in the art. In the accompanying drawings, it should be noted that the same reference numerals are used in the drawings to designate the same configuration in other drawings as much as possible. In addition, in describing the present invention, when it is determined that a detailed description of a related known function or known configuration may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted. And certain features shown in the drawings are enlarged or reduced or simplified for ease of description, the drawings and their components are not necessarily drawn to scale. In addition, in the direction of the device or element, front and rear, right and left, up and down, vertical and horizontal do not mean that the associated device or element should have a specific direction to facilitate the description of the present invention. In addition, terms such as “first” and “second” are used for convenience of description and do not mean a relative majority or spirit or order in the detailed description and the claims. Such matters will be readily understood by those skilled in the art.

1 is a configuration example showing the configuration of a cryotherapy system according to the present invention.

Referring to FIG. 1, the cryogenic systemic treatment apparatus according to the present invention includes a cryotherapy room 100, a measuring device 130: 131, 141, 151, a controller 200, a cooling system 300, and an outdoor unit 400. do.

The cryotherapy room 100 is composed of two rooms that maintain the first low temperature and the second low temperature, and the patient enters the room to perform treatment by low temperature stimulation and fever. The cryotherapy room is composed of an auxiliary chamber 110 to maintain a first low temperature and a treatment chamber 120 to maintain a second low temperature. Here, the first low temperature is set to a temperature halfway between the low temperature treatment room 100 and the second low temperature, and provides an environment for shock and low temperature adaptation of the patient entering the low temperature treatment room 100. The first low temperature is set within about 30 degrees Celsius to minus 50 degrees Celsius, and the second low temperature is determined between minus 100 degrees Celsius and minus 120 degrees Celsius. After entering the cryotherapy room 100, the auxiliary chamber 110 enters the chamber, and after entering the auxiliary chamber 110 and temperature adaptation, the treatment chamber 120 moves to the treatment chamber 120, and the treatment proceeds. In particular, the cryotherapy room 100 is provided with a measuring device 130 for monitoring the state of the patient entered. The measuring device 130 may be configured in various ways, but basically includes a pulse (or heart rate) measuring device 131, a blood pressure measuring device 141, and a temperature measuring device 151 capable of measuring pulse, body temperature, and blood pressure. do. Among these measuring devices 130, the pulse measuring device 131 and the blood pressure measuring device 141 penetrate the wall of the cryotherapy room 100 and are provided in the treatment room, and the patient who enters the room wears the measurement. In addition, the body temperature meter 151 uses a thermal imaging apparatus and is installed outside the cryotherapy room 100 to observe the patient through a viewing window. Detailed configuration of such a cryotherapy room 100 will be described with reference to FIGS. 2 and subsequent drawings.

The measuring devices 130: 131, 141, and 151 measure the condition of the patient entered into the cryotherapy room 100 and transmit the measurement information to the external controller 200. To this end, the measuring device 130 may be configured in various ways, but basically includes a pulse measuring device 131, a blood pressure measuring device 141, and a body temperature measuring device 151. The pulse measuring device 131 and the blood pressure measuring device 141 are installed to penetrate the wall of the cryotherapy room 100 and are disposed inside the cryotherapy room 100, and the body temperature meter 151 is installed outside the cryotherapy room 100. . The pulse measuring device 131 may be used as a measuring device in a manner of being attached to the fingertip of the patient or the chest area near the heart, but this does not limit the present invention. In addition, in the case of the blood pressure measuring instrument 141, compressed air for blood pressure measurement is supplied from the outside, and compressed air having a pressure higher than room temperature is supplied in consideration of the temperature inside the treatment room. To this end, in the case of the blood pressure measuring instrument 141, a pressure adjusting device for adjusting the pressure of the compressed air may be added. In particular, the blood pressure measuring instrument 141 of the present invention prevents the increase in the fatigue life of the blood pressure measuring instrument 141 by keeping it at a low temperature state, thereby extending the service life of the blood pressure measuring instrument 141, and when worn by the patient, It is configured to include a heat supply device for preventing damage from being applied and for reducing the pressure of the compressed air due to the low temperature environment. Details of the blood pressure measuring instrument 141 will be described in detail with reference to the accompanying drawings. The body temperature meter 151 preferably uses a thermal imaging apparatus and is installed outside the cryotherapy room 100. At this time, the body temperature measuring instrument 151 is installed at a position where the patient can be observed through the viewing window provided in the cryotherapy room 100. The measuring device 130 transmits the measured information to the controller 200 to enable the operator to monitor the condition of the patient and confirm the treatment status of the patient. In addition, the pulse measuring device 131 and the blood pressure measuring device 141 installed in the cryotherapy room 100 may be configured in plural, but the present invention is not limited thereto.

The controller 200 controls the low temperature treatment room 100 and the cooling system 300, and outputs the measurement information from the measurement device 130 to the operator. To this end, the controller 200 is easy to control the cryotherapy room 100, the cooling system 300, and is installed at a position where the patient inside the cryotherapy room 100 can be identified as a related tube.

The cooling system 300 controls the outdoor unit 400 under the control of the controller 200, and is connected to the outdoor unit 400 to maintain the low temperature treatment room 100 in the first and second low temperature states. The cooling system 300 includes a compressor that compresses the refrigerant and circulates the refrigerant through a pipe (not shown) connected to the outdoor unit 400 and the cryotherapy room 100.

The outdoor unit 400 operates by the cooling system 300 to maintain the low temperature treatment room 100 in a low temperature state.

Figure 2 is a perspective view showing a cryotherapy room of the cryotherapy system according to the present invention.

Referring to FIG. 2, the cryotherapy room 100 of the cryogenic systemic treatment apparatus according to the present invention includes an outer wall 500, a partition wall 550, an auxiliary chamber 110, and a treatment chamber 120.

The outer wall 500 is configured to form a hollow hexahedral inner space by combining a plurality of mutually. More specifically, the outer wall 500 is composed of a vacuum insulation wall, the outer wall 500 on both sides of the upper, lower, upper and lower sides to form an hexahedral inner space to form a hexahedral shape, the inner space ( The partition wall 550 is inserted and installed in the 561. The interior space 561 is divided into the auxiliary chamber 110 and the treatment chamber 120 by the partition wall 550.

The partition wall 550 is vertically inserted into an inner space 561 formed inside the outer wall 500, and partitions the inner space 561, thereby making the inner space 561 the auxiliary chamber 110 and the treatment chamber. It is divided into 120. The barrier 550 is formed at one side of the portal 551 so that the patient can move between the auxiliary chamber 10 and the treatment chamber 120. The partition wall 550 is composed of a vacuum insulating wall like the outer wall, so that the vacuum insulating walls of different widths are combined in a puzzle shape so that the door 551 can be formed to secure a space for forming the door.

The auxiliary chamber 110 is formed with an entrance door 610 that is opened and closed on one outer wall 500, and includes an internal space 561, a temperature control device 620, a humidity control device 630, and a pressure control device 640. , By the interrogator 551 of the partition wall 550 formed on one side, it is in communication with the treatment chamber 120. More specifically, the auxiliary chamber 110 is one of the two inner spaces 561 which is inserted into the inner space 561 of the outer wall 500 having a hexahedral shape and is divided into two, and the internal temperature of the outer By setting the first temperature lower than the temperature, and higher than the internal temperature of the main treatment room, it is used as a buffer space so that the body of the patient can adapt to low temperature before entering the treatment chamber 120. In addition, the auxiliary chamber 110 is to prevent the treatment effect is lowered by lowering the temperature of the treatment chamber 120 by the temperature of the treatment chamber 120 is directly contacted and exchanged between the low temperature of the treatment chamber 120 and the relatively high outside air directly Play a role. The front outer wall 500 of the auxiliary chamber 110 is formed with a door 610 for entering the patient's interior space 561, the door 610 to observe the situation inside the auxiliary chamber 110 from the outside. The door viewing window 611 having a heating wire may be formed. In addition, the side or rear of the auxiliary chamber 110 is provided with a temperature control device 620 and the air pressure control device 640 of the auxiliary chamber 110, connected to the temperature control device 620 and the air pressure control device 640. Piping port (not shown) or connector may be formed to pass through the pipe. The handle bar 660 is installed on the outer wall surface of the inner space 561 of the auxiliary chamber 110 so that the patient can maintain the standing state through the hand rod 660 even when the movement is inconvenient. In addition, a signal lamp 651 or a speaker 652 is installed inside the auxiliary chamber 110 to transmit a warning signal in case of movement to the main treatment room or an emergency to the patient, and to the outside when an emergency situation of the patient enters. An emergency switch 653 may be provided to call for help, but this is not a limitation of the present invention.

Treatment chamber 120 is formed on the outer wall 500 is a viewing window 610 to observe the inside from the outside. The treatment chamber 120 has a temperature control device 620, humidity control device 630, air pressure control device 640, the handle bar 660, the signal lamp 651, the speaker inside the auxiliary chamber 110, 652, an emergency switch 653 is provided. In particular, the pulse chamber 131 and the blood pressure measurement value 141 of the measuring device 130 is installed in the treatment chamber 120, the body temperature meter 151 is disposed outside the viewing window 610. The patient is moved to the treatment chamber 120 through the auxiliary chamber 110, exposed to a low temperature environment for a predetermined time in the treatment chamber 120, to strengthen the immune system through the fever of the patient's body itself, and natural healing power In addition to the increase, by giving a strong stimulation to the nervous system to prevent the pain-induced nerve fibers to work, pain relief and treatment of the affected area is made. Since other features are the same as the above-described auxiliary chamber 110, detailed description thereof will be omitted.

Figure 3 is an exemplary view schematically showing the installation of the blood pressure meter.

Referring to FIG. 3, the blood pressure measuring instrument 141 is disposed inside the cryotherapy unit 100 as shown, and is provided on the compression table 742: 742a to 74d, which is worn by the patient, and disposed outside the cryotherapy unit 100. Sphygmomanometer 741: 741a to 741d, and squeezer 742 and sphygmomanometer for supplying compressed air for measurement to each compression table 742 and detecting a change in pressure according to the supply of compressed air. And a sphygmomanometer cable 743 for connecting the 741 and delivering the compressed air supplied from the sphygmomanometer 741 to the pressure table 742. In addition, each blood pressure monitor 741 is connected to the controller 200, and outputs the patient-specific blood pressure measured through the controller to inform the operator of the patient's condition.

In the blood pressure measuring device 141, the pressure bar 742 and the blood pressure monitor cable 743 are partially exposed to a relatively low temperature environment, which is not room temperature, unlike the blood pressure monitor 741 and the controller 200. This low temperature environment significantly lowers the pressure of the compressed air delivered from the blood pressure monitor 741 to the pressure bar 742, making accurate blood pressure measurement difficult, as well as increasing the fatigue of the pressure bar 742 and the blood pressure monitor cable 743. Resulting in a shortened life. Furthermore, when the pressure bar 742 exposed to low temperature is brought into direct contact with the skin of the patient, the pressure bar 742 sticks to the skin, causing a wound, or a skin rash or frostbite. Will be created.

Therefore, in order to solve this problem in the present invention, the pressure bar 742 and the blood pressure monitor cable 743 are maintained at a predetermined temperature or more to prevent the problem as described above from occurring. Is shown.

4 is a cross-sectional view illustrating the longitudinal / lateral cross-sectional shape of the blood pressure monitor cable.

Referring to FIG. 4, the blood pressure monitor cable 743 includes a tube 805, a blood pressure monitor cable heating wire 810, a thermal conductive film 820, and an outer shell 830 as shown.

The tube 805 has a hollow 800 formed therein, and serves as a pipe for supplying the compressed air supplied from the blood pressure monitor 741 through the hollow 800 to the compression table 742.

The blood pressure monitor cable heating wire 810 is spirally wound on the outer surface of the tube 805, generates power by receiving power from a power supply unit (not shown) included in the blood pressure monitor 741, and generates the temperature of the blood pressure monitor cable 743 through the heating. To maintain higher than the temperature of the cryotherapy room (100).

The thermal conductive film 820 serves to evenly transfer the heat supplied by the blood pressure monitor cable heating wire 810 to the outer surface of the cable 743. To this end, the thermal conductive film 820 is coated in a tubular shape on the outside of the blood pressure monitor cable heating wire 810 in a form that accommodates the blood pressure monitor cable heating wire 810 and the tube 805 therein. The thermal conductive film 820 may be made of a synthetic resin having high thermal conductivity and heat resistance, such as polystyrene, or a metal foil coated with an insulator on a contact portion with a blood pressure monitor cable heating wire 810, but thus, the present invention. It is not intended to limit.

The outer shell 830 is coated on the outer side of the thermal conductive film 820 (where the outer side means a side closer to the external environment away from the tube). The shell 830 may be configured using a vegetable fiber or synthetic resin that is resistant to low temperature environment.

In addition, an insulator may be applied to the surface of the tube 805 in contact with the blood pressure monitor cable heating wire 810, or a thermal conductive film 820 may be formed.

5 is an exemplary view showing a cross section and a planar shape of the pressure bar.

Referring to FIG. 5, the pressure bar 742 includes a balloon 850, a pressure wire hot wire 811, a heat conductive film 820, and an outer shell 830.

The balloon 850 is connected with the tube 805 to inflate by compressed air supplied through the tube 805 or contracted by the removal of the compressed air to apply pressure to or reduce pressure on a specific part of the patient. Blood pressure can be measured. The surface of the balloon 850 may be wound around the pressure bar heating wire 811, and an insulation may be applied to the contact area between the balloon 850 and the pressure bar heating wire 811, or the thermal conductive film 820 may be placed thereon. It is not intended to limit the invention.

Press bar hot wire 811 is configured to wind the balloon 850 in the cable 743 as well, and transmits heat to the press bar 742 through the balloon 850 and the heat conduction 820. The pressure bar heating wire 811 is electrically connected to the blood pressure monitor cable heating wire 810 included in the cable 743.

The thermal conductive film 820 is made of a synthetic resin having excellent thermal conductivity and heat resistance, as in the cable 743, or by using a metal foil coated with an insulation on the contact portion with the pressure bar heating wire 811. Can be configured. The heat conductive film 820 serves to evenly distribute the heat supplied from the pressure zone hot wire 811 to the pressure zone 742.

The outer shell 830 is coated on the outside of the heat conductive film 820 to protect the heat conductive film 820, the pressure bar heating wire 811, and the balloon 850. The shell 830 may be configured using a vegetable fiber or synthetic resin that is resistant to low temperature environment.

Although illustrated and described in the specific embodiments to illustrate the technical idea of the present invention, the present invention is not limited to the same configuration and operation as the specific embodiment as described above, and various modifications do not depart from the scope of the present invention. It can be carried out within. Accordingly, such modifications are deemed to be within the scope of the present invention, and the scope of the present invention should be determined by the following claims.

100: cryotherapy unit 110: auxiliary chamber
120: treatment chamber 130: measuring device
131 pulse rate meter 141 blood pressure meter
151: body temperature measuring instrument 200: controller
300: cooling system 400: outdoor unit
500: outer wall 550: partition wall
561: Interior space 610: Door
611: door viewing window 620: temperature control device
630: humidity control device 640: pressure control device
650: alarm means 660: handle bar
741: blood pressure monitor 742: pressure bar
743: blood pressure monitor cable 800: hollow
805: tube 810: blood pressure monitor cable heating wire
811: pressure bar heating wire
820: heat conductive film 830: shell
850 balloons

Claims (6)

In blood pressure monitors operating at sub-zero temperatures,
A blood pressure monitor that provides compressed air for blood pressure measurement and measures blood pressure of a patient by detecting a change in pressure according to the provision of compressed air;
A compression table that expands by compressed air from the blood pressure monitor and presses the body of the patient; And
And a blood pressure monitor cable for transferring the compressed air from the blood pressure monitor to the blood pressure monitor.
It includes a pressure bar heating wire for heating the pressure bar and a blood pressure monitor cable heating wire for heating the blood pressure monitor cable,
The blood pressure monitor further comprises a power supply for supplying power to the pressure bar heating wire and the blood pressure monitor cable heating wire. The method of claim 1,
The blood pressure monitor cable
A tube having a hollow formed therein for delivering the compressed air from the blood pressure monitor to the compression table;
The blood pressure monitor cable heating wire wound around the outside of the tube;
A heat conductive film coated on a surface of the blood pressure monitor cable hot wire and the tube to cover the blood pressure monitor cable hot wire and the tube; And
Blood pressure measuring device, characterized in that it comprises a; the outer cover is coated on the outside of the thermal conductive film. The method of claim 2,
The pressure bar
A balloon connected to the tube and expanded by the compressed air supplied through the tube;
The compression bar heating wire is wound on an outer surface of the balloon and electrically connected to the heating wire of the blood pressure monitor cable;
A heat conductive film coated on surfaces of the balloon and the compression bar heating wire to surround the compression bar heating wire and the balloon; And
Blood pressure measuring device, characterized in that it comprises a; the outer cover is coated on the outside of the thermal conductive film. delete delete delete

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