KR102029255B1 - Apparatus For Body Wormer And Maintenance Using Mid-Infrared Radiation - Google Patents

Abstract

An apparatus for managing blood vessels using mid-infrared radiation comprises: an outer case formed to surround a part of the user′s body; and a mid-infrared radiation emission module forming the curved surface corresponding to the curve of the inner surface of the part of the user′s body in the outer case, disposed to directly face the inner surface of the part of the body and emitting mid-infrared radiation. The mid-infrared radiation emission module comprises: a round frame including a cell bottom unit and a partition protruding from the periphery of the cell bottom unit to the inner side and forming mid-infrared radiation cell accommodation units, and arranged so that the plurality of mid-infrared radiation cell accommodation units form the curved surface corresponding to the inner surface of the part of the body; and a plurality of mid-infrared radiation cells respectively inserted to the plurality of mid-infrared radiation cell accommodation units, and fixed and supported.

Description

Apparatus For Body Wormer And Maintenance Using Mid-Infrared Radiation

The present invention relates to a medical aid, and more particularly to a mid-infrared blood vessel management device for maintaining the vascular state of hemodialysis patients.

Hypothemia symptoms are a common disease among the elderly and women, including patients, which can cause chronic fatigue, allergies, lower digestion, and especially infertile infertility in severe cases, accompanied by a decrease in immunity. .

Hypothermia or cold hands and feet are symptoms of sympathetic nerve reactions to external stimuli, causing blood vessels to contract and blood supply to the hands and feet being excessively reduced, resulting in severe cold. As of 2014, there are more than 17,300 patients.

Hemodialysis patients, as well as the general population, whose vascular management is very important, should be regularly replaced with hemodialysis therapy.

At this time, one of the difficulties for hemodialysis patients is that maintenance of such a vascular passage is not easy. Repeatedly inserting a dialysis needle into the same area is likely to cause an aneurysm that swells the blood vessel wall due to high pressure on the site. In addition, near the vascular passages due to thrombus accumulation, problems such as swelling and stiffening of the veins or narrowing of blood vessels are likely to occur, which requires continuous management.

As a management method, the most effective method is poultice therapy around the vascular pathway. In general, heat therapy is known to increase the body temperature of the site to activate blood circulation, thereby promoting metabolism, including the discharge of waste products, to recover the fatigue of muscles and surrounding tissues, and to enhance immunity.

However, if you continue to heat the hot pack through the skin for a long time there is a risk of low temperature burn due to a decrease in the skin sensation to temperature. Thermal heating by infrared rays can be divided into those using near infrared rays emitted from infrared lamps and those using far infrared rays emitted from minerals such as germanium, biotite and biotite.

As can be seen, the thermal poultice using the near infrared lamp is hygienic advantageous because there is no skin contact, there is an advantage that can deliver energy to the skin without raising the ambient air temperature. However, near-infrared radiation is emitted from high temperature radiation of about 1800 ° C. or higher, so the distance between the lamp and the skin should be separated. As a result, the irradiation range is inevitably affecting the surroundings, there is a burning sensation due to the high energy, there is a problem that the temperature of the skin tissue to raise the temperature above 40 ℃ causes drying and damage.

Therefore, there is a need for a method for solving such problems.

Korean Laid-Open Patent Publication No. 10-2003-0016533

The present invention has been made in order to solve the above-mentioned problems of the prior art, an object of the present invention is to provide a mid-infrared blood vessel management device optimized for blood vessel maintenance around the vascular passage of the dialysis patient.

In another aspect, the present invention is to provide a mid-infrared vascular management device, there is no risk of excessive burning or skin damage and low-temperature burn, easy to carry and use, and can effectively irradiate the mid-IR to the vascular passages of dialysis patients Has its purpose.

The objects of the present invention are not limited to the above-mentioned objects, and other objects that are not mentioned will be clearly understood by those skilled in the art from the following description.

The mid-infrared blood vessel management apparatus of the present invention for achieving the above object, the outer case formed to surround the user's body portion and the inner surface of the outer case is roughly corresponding to the curvature of the inner surface of the body portion of the user And a mid-infrared emission module arranged to face the inner surface of the body part and radiating mid-infrared, wherein the mid-infrared emission module protrudes inward from the cell bottom and around the cell bottom, A plurality of mid-infrared cell receivers inserted into and fixed to each of the plurality of mid-infrared cell receivers, each having a partition wall forming a receiver, wherein the plurality of mid-infrared cell receivers are arranged to form a curved surface corresponding to the inner surface of the body part as a whole; It includes a mid-infrared cell of.

The round frame may be formed of a metal plate, and the mid-infrared emission module may further include a linear, film-type or thin-film heater disposed on the rear side of the round frame.

In addition, the linear heater may be disposed along the valley of the rear surface of the partition wall.

The film heater may be disposed in close contact with the rear surface of the round frame.

The round frame may include a plurality of mid-infrared cells inserted into the plurality of mid-infrared cell accommodating parts in a state where the plurality of cell bottom surfaces are generally planar, and the plurality of cell bottom surfaces form a concave curved surface. In the state, the plurality of mid-infrared cells may be formed so as not to be separated from the mid-infrared cell accommodating portion by interference with adjacent mid-infrared cells or the partition wall.

And the height of the partition wall may be lower than the thickness of the mid-infrared cell.

In addition, the plurality of mid-infrared cell accommodating parts may be arranged in a lattice form or honeycomb form in a state where the cell bottom surface is generally flat.

And a heat reflecting layer including a metal thin film between an inner surface of the outer case facing the rear surface of the mid-infrared emitting module.

The outer case may further include a plurality of vents connected to an air passage formed in the outer case.

And a linear, film or thin film heater disposed on the rear side of the round frame, and a temperature sensor measuring a temperature of the round frame, and feeding back a temperature signal measured by the temperature sensor to a controller for controlling the heater. feedback)

The mid-infrared blood vessel management device of the present invention for solving the above problems has the following effects.

First, there is no risk of excessive burning or skin damage and low temperature burn, easy to carry and use, there is an advantage that can effectively irradiate the mid-infrared to the vascular passages of dialysis patients.

Second, as optimized for vascular maintenance around the vascular passage of the hemodialysis patient, there is an advantage that allows the patient to receive regular hemodialysis through a healthy vascular passageway.

Third, in general, the vascular passage part of the hemodialysis patient is not only at high risk of an aneurysm or blood circulation disorder, but also close to the heart, so that the risk of progression to sepsis is increased when inflammation occurs. In addition to maintaining a healthy state, there is an advantage that dramatically reduces the risk of burns or infections that can occur during the heat treatment process.

The effects of the present invention are not limited to the above-mentioned effects, and other effects not mentioned will be clearly understood by those skilled in the art from the description of the claims.

1 is a view showing a state of use of the mid-infrared blood vessel management apparatus according to an embodiment of the present invention;
2 is a view showing the internal structure of the mid-infrared blood vessel management apparatus according to an embodiment of the present invention;
3 is a schematic cross-sectional view taken along line III-III ′ of FIG. 2;
4 is a diagram illustrating an example of a mid-infrared emission module corresponding to region A in FIG. 3;
FIG. 5 is a view showing another example of a mid-infrared emission module corresponding to region A in FIG. 3;
6 and 7 is a view showing the manufacturing process of the mid-infrared emission module in the mid-infrared blood vessel management apparatus according to an embodiment of the present invention;
8 is a front view of the lattice (a) and honeycomb (b) mid-infrared emission modules;
FIG. 9 is a rear view of the lattice (a) and honeycomb (b) mid-infrared emission modules with a linear heater;
10 shows an example of a mid-infrared emission module having a film heater;
11 is a view showing a locking structure of the mid-infrared blood vessel management apparatus according to another embodiment of the present invention;
12 is a view showing a mid-infrared blood vessel management apparatus according to another embodiment of the present invention;
Figure 13 is a schematic view showing the configuration of the mid-infrared blood vessel management apparatus according to the present invention;
14 is a view showing a change in erythrocyte activity before and after using the mid-infrared vascular management device according to the present invention;
15 is a view showing the changes in body temperature of the forearm before and after using the mid-infrared blood vessel management device according to the present invention; And
16 and 17 are views showing changes in body temperature of the whole body before and after using the mid-infrared blood vessel management apparatus according to the present invention.

DETAILED DESCRIPTION Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the description of this embodiment, the same name and the same reference numerals are used for the same configuration and additional description thereof will be omitted.

1 is a view showing a state of use of the mid-infrared blood vessel management apparatus according to an embodiment of the present invention.

The mid-infrared blood vessel management apparatus 100 according to an embodiment of the present invention may have a cylindrical or conical shape surrounding the forearm as a whole.

The outer case 10 defining the shape may include an inner case 11 surrounding the lower part of the lower part, that is, the forearm body portion on which the vascular passage is disposed, and an outer case 12 surrounding the opposite side thereof. In this case, the inner case 11 and the outer case 12 may be connected to each other through a hinge (15).

The meaning of the lower part may be understood to mean a part of the body in addition to the arm, which is a dictionary meaning, and thus the mid-infrared blood vessel management device of the present invention may be used for the leg.

Accordingly, in the state in which the user opens the outer case 10 around the hinge 15, the user places the lower thin portion facing the inner surface of the inner case 11 and closes the mid-infrared blood vessel management device. 100 can be worn.

On the other hand, one side of the outer case 10 is provided with an input unit 14 for receiving on / off and control inputs from the user, and a display unit 13 for displaying the operating state of the device or the user's control input content is provided Can be. In the present exemplary embodiment, the input unit 14 and the display unit 13 are provided in the inner case 11, but the present invention is not limited thereto.

In addition, at least one, more preferably a plurality of vents 113 may be provided at one side of the outer case 10. The plurality of vents 113 are connected to allow air to communicate with an air passage or a breathable member provided in the outer case 10 to prevent excessive heat from accumulating inside the outer case 10, and the user The moisture emitted from the skin of the outside may be discharged to the outside to maintain the inside of the mid-infrared blood vessel management device in a comfortable state.

In addition, although not shown in the drawing, when the user opens and closes the inner case 11 and the outer case 12, a fastening structure that can be easily locked or opened may be provided. This will be described later.

In addition, the mid-infrared blood vessel management device 100 may be further provided with a necklace strap to be supported on the user's neck, the power supply is provided on one side of the outer case 10 to connect an external power source to the device The terminal or the rechargeable battery compartment may be further provided.

2 is a view showing the internal structure of the mid-infrared blood vessel management apparatus according to an embodiment of the present invention.

As shown, the inner case 11 and the outer case 12 may each have a semi-cylindrical or semi-conical shape. In these, support members 21 and 22 may be arranged along the contour thereof. The support members 21 and 22 may be further divided into an inner support member 21 and an outer support member 22. The mid-infrared emission module 30 is disposed inside the inner support member 21.

The mid-infrared emission module 30 is preferably disposed to correspond to the vascular passage portion of the hemodialysis patient that is the user. In addition, the mid-infrared emission module 30 may be formed to form a curved surface substantially corresponding to the curvature of the inner side of the lower part of the user.

The mid-infrared emission module 30 includes a plurality of mid-infrared cells having a mineral component that absorbs heat energy and instead emits mid-infrared rays, which may be arranged in a lattice as shown. It may be arranged in another form.

On the other hand, the mid-infrared emission module 30 may be arranged so as not to touch or touch the user's skin according to the operating temperature, in order to prevent low-temperature burns, when the operating temperature is about 40 ℃ or more, do not directly contact Can be. However, it is preferable that no member is interposed between the mid-infrared emission module 30 and the user's skin regardless of contact.

The inner support member 21 and the outer support member 22 are made of a porous material such as cotton or sponge that provides a soft and stable fit to the user, or a plastic injection molded product, a synthetic material having a soft touch such as leather or velvet. B may be made of natural or composite materials.

The inner support member 21 and the outer support member 22 may be formed of different materials. In the case of the inner support member 21, it is advantageous to have a relatively higher thermal insulation. This is to prevent the heat applied for mid-infrared radiation from the mid-infrared emission module 30 to escape through the rear surface. On the other hand, the outer support member 22 is preferably made of a material having excellent air permeability and cushioning in order to prevent sweating inside when used for a long time.

Meanwhile, another mid-infrared emission module, for example, an auxiliary mid-infrared emission module 30B may also be disposed inside the outer case 12. Since the auxiliary mid-infrared emission module 30B is disposed opposite the vascular passage of the user when worn, it may be provided to emit a smaller amount of mid-infrared rays than the above-described mid-infrared emission module 30.

For example, the auxiliary mid-infrared emission module 30B may be configured to emit mid-infrared at a temperature of the skin temperature level of the user without a separate heating means. In addition, the auxiliary mid-infrared emission module 30B may also be seated in a groove formed in the outer support member 22.

FIG. 3 is a schematic cross-sectional view taken along line III-III ′ of FIG. 2.

As shown, the mid-infrared emission module 30 may be seated in a groove recessed in the inner support member 21. The surface of the mid-infrared emission module 30 may be arranged to contact the skin of the user, or may be arranged not to contact. Although not shown in detail in the drawing, if the surface of the mid-infrared emission module 30 is not to be in direct contact with the user's skin, at least a portion of the inner support member 21 around the formation is relatively higher You can do that.

Meanwhile, a portion of the inner support member 21 made of a composite material and in contact with the rear surface of the mid-infrared emission module 30 may be configured to have a relatively high thermal insulation property or to have a heat reflecting function, and the remaining portion may be relatively It may be configured to be excellent in breathability.

Meanwhile, the plurality of vents 113 described above with reference to FIG. 1 may be connected to an air passage 112 formed between the inner support member 21 and the inner case 11 or in the inner support member 21. . When the inner support member 21 is formed of a member having excellent air permeability having an open cell structure such as, for example, sponge tissue, the separate air passage 112 may be omitted.

FIG. 4 is a diagram illustrating an example of a mid-infrared emission module corresponding to region A in FIG. 3.

As described above, the mid-infrared emission module may include a plurality of mid-infrared cells 31. The plurality of mid-infrared cells 31 may be arranged in various forms, such as a lattice, in a planar manner as described above, and when viewed in cross section, a plurality of pieces may be arranged to form a similar shape as a whole as shown in this drawing. Can be.

To this end, a round frame 32 having a plurality of mid-infrared cell accommodating parts including a cell bottom part 321 and a partition wall 322 surrounding the cell bottom part 321 and formed in a shape similar to a curved surface in at least one direction is provided. Here, the shape similar to the curved surface means that the adjacent small planes are arranged at a predetermined angle to each other to form a curved surface as a whole.

The plurality of mid-infrared cells 31 may be processed by processing a raw ore mineral having a high mid-infrared emissivity in a unit cell form, or may be plastically processed in a unit cell form using mineral powder. Here, examples of the mineral having a high mid-infrared emissivity include biotite, biotite, elvan, germanium, and the like, but are not limited thereto. In addition, in the present embodiment, the plurality of mid-infrared cells 31 may have a rectangular cross section.

On the other hand, what is represented by the dotted line at the bottom of the figure shows a plurality of mid-infrared cells 31 are arranged in the round frame 32 in a state before the curved in the manufacturing process of the mid-infrared emission module. In this state, unless the bottom 312 of the mid-infrared cell 31 is adhered to the cell bottom part 321, the mid-infrared cell 31 may fall off, but as shown in the upper portion of the drawing, the round frame 32 ) Bent to form a curved surface, the edges of the upper surface 311 of the mid-infrared cell 31 are in close contact with each other of the cells adjacent to each other, causing interference and do not fall out.

To this end, the height of the partition wall 322 is preferably formed lower than the thickness of the mid-infrared cell 31. This structural feature of the round frame 32 and the plurality of mid-infrared cells 31 contributes to the productivity improvement of the mid-infrared vascular management apparatus.

In addition, at least a portion of the above-described inner support member 21 disposed under the mid-infrared emission module may have a multi-layered structure in which a heat reflection layer 213 is formed on the surface of the heat-insulating support layer 211 toward the mid-infrared emission module. . The heat reflecting layer 213 may include a metal thin film to reflect the heat energy emitted rearward in the form of infrared rays back toward the mid-infrared emitting module to contribute to the improvement of energy efficiency.

FIG. 5 is a diagram illustrating another example of the mid-infrared emission module corresponding to the region A in FIG. 3.

This is similar to the embodiment of Figure 4 described above, but the embodiment of the figure is formed so that the cross section of the plurality of mid-infrared cells 31B to form a trapezoid, when the round frame 32B is curved to form a curved wall 322B ), And more specifically, the relatively wide bottom 312B portion of the mid-infrared cell 31B is formed so as not to be caught by the partition wall 322B.

Meanwhile, in the embodiments of FIGS. 4 and 5, the bottom surfaces 312 and 312B and the partition walls 322 and 322B, which define a space in which the mid-infrared cells 31 and 31B are accommodated, are expressed in a bent form. It is not limited to this. For example, some sections between the bottom surfaces 312 and 312B and the partition walls 322 and 322B may be formed in a cut shape.

6 and 7 are views showing the manufacturing process of the mid-infrared emission module in the mid-infrared blood vessel management apparatus according to an embodiment of the present invention.

As a material of the round frame 32 of the mid-infrared emission module, a metal having high thermal conductivity, for example, copper or the like, may be generally used, and processing the composite into a complicated shape in which the mid-infrared cell 31 may be accommodated may be used. Difficulties follow

Therefore, the process of molding the round frame 32 may be performed as shown in FIGS. 6 and 7.

First, as shown in FIG. 6, the round frame 32 having a linear shape is fixed at a predetermined position while being transferred in one direction, and the mid-infrared cell 31 is approached from the top.

Subsequently, as shown in FIG. 7, the mid-infrared cell 31 is pressed onto the round frame 32 to correspond to the bottom surface 312 of the mid-infrared cell 31 on the round frame 32. The length is recessed downward to allow deformation.

Such a process may be repeated at regular intervals so that a plurality of mid-infrared cells 31 are provided in one round frame 32, and the shape of the round frame 32 in which a plurality of partition walls 322 are formed. Can be easily formed.

On the other hand, in the process of pressing the mid-infrared cell 31 to the round frame 32, to support the area adjacent to both ends of the mid-infrared cell 31 of the round frame 32 from the bottom to provide a support force As a result, the recessed cell bottom 312 may be formed.

Figure 8 is a view showing a front view of the lattice (a) and honeycomb (b) mid-infrared emission module.

In the lattice type mid-infrared emission module 30L as shown, a plurality of mid-infrared cells 31L are arranged in a lattice form when viewed from the front. The plurality of mid-infrared cells 31L are respectively disposed in regions partitioned by the partition walls 322L which are part of the above-described round frame.

However, as shown in the above-described drawings, the vertical barrier ribs may be narrower than the horizontal barrier ribs 322L, or may be covered by a plurality of mid-infrared cells 31L while the round frame forms a vertically concave curved surface. .

In the honeycomb type mid-infrared emission module 30H, when viewed from the front, a plurality of mid-infrared cells 31H are arranged in a honeycomb shape. To this end, the plurality of mid-infrared cells 31H may be formed in a hexagonal shape of the plane. In this case, as described above, the vertical partition may be narrower than the horizontal partition 322H.

The honeycomb-type mid-infrared emission module 30H is structurally very stable due to the characteristics of the honeycomb structure, enables various curved surfaces, and has an advantageous surface for heat conduction to the mid-infrared cell 31H.

FIG. 9 is a view showing the grid-type (a) and honeycomb (b) mid-infrared emission modules having a linear heater as viewed from the rear.

As an example of the present invention, the mid-infrared emission modules 30L and 30H according to the present embodiment may include linear heaters 35L and 35H. As a more specific example, the linear heaters 35L and 35H may be disposed along a partition wall formed as a valley when viewed from the rear of the lattice-shaped and honeycomb mid-infrared emission modules 30L and 30H, and the width thereof is relatively wide. It may be arranged along a wider transverse bulkhead.

Here, the linear heaters 35L and 35H may take the form of wires, but the present invention is not limited thereto and may be a resistive heating element pattern printed on the rear side of the round frame.

As such, when the linear heater is disposed along the partition wall, the honeycomb mid-infrared emission module 30H can transfer heat to the mid-infrared cell 32H in a larger area, thereby providing a substantial mid-infrared emission effect in a shorter time. This has the advantage of being available.

10 is a diagram illustrating an example of a mid-infrared emission module having a film heater.

This is in contrast to the embodiment of FIG. 9, the mid-infrared emission module according to the present embodiment may have a film heater 35F on its rear surface. The film heater 35F is also called a planar heating element, and may be a resistive heating heater in the form of a flexible film.

In each embodiment described above, the round frame is advantageously formed of a metallic material. For example, metal materials such as aluminum and copper have high malleability, which is advantageous for processing bulkhead structures, and has high thermal conductivity, so that heat generated by the aforementioned linear heater or film heater can be quickly and evenly transmitted to a plurality of mid-infrared cells. Because there is.

On the other hand, the mid-infrared blood vessel management apparatus according to the present invention may be provided with a thin-film heater formed by coating or printing on the back of the mid-infrared emission module, that is, the back of the round frame. For example, a heater technology using an F-doped tin oxide (FTO) thin film may be applied to the thin film heater.

More specifically, a thin film type heater in which an insulating film is coated on a rear surface of the round frame formed of a metal plate and a surface heating material pattern such as FTO and an electrode pattern are printed thereon may be applied.

11 is a view showing a locking structure of the mid-infrared blood vessel management apparatus according to another embodiment of the present invention.

As shown in FIG. 11, the mid-infrared blood vessel management device according to another embodiment of the present invention is easily locked or opened when a user opens and closes the inner case 11 and the outer case 12 of the outer case 10. It can have a fastening structure that can be.

Specifically, in the present embodiment, the inner case 11 is provided with a fastening cover 17 rotatably formed by the inner case 11 and the auxiliary hinge 19, the inner side of the fastening cover 17 A plurality of magnet portions 18a, 18b, and 18c may be formed on the surface and the outer surface of the outer case 12.

In the present embodiment, the magnets 18a, 18b, and 18c may include a first magnet 18a provided closer to the auxiliary hinge 19 in the fastening cover 17, and the first magnet 18a. The second magnet 18b provided farther from the auxiliary hinge 19, and the outer surface of the outer case 12 is provided on the first magnet 18a and the second magnet 18b of the fastening cover 17. ) And a third magnet 18c to be fastened to each other by an attraction force.

Accordingly, the user rotates the inner case 11 and the outer case 12 to surround the entire lower portion of the lower case in a state in which the lower portion is accommodated inside the outer case 10, and the fastening cover 17. The outer case 10 may be closed and fixed by attaching one of the first magnets 18a and the second magnets 18b and the third magnets 18c to each other.

In this case, when the first magnet 18a is attached to the third magnet 18c, the diameter of the outer case 10 may be reduced to obtain a more stable fixing force, and the second magnet 18b may be replaced with the third magnet 18c. When the third magnet 18c is attached to the third magnet 18c, the outer case 10 may have a larger diameter, thereby providing a more comfortable fit.

12 is a view showing a mid-infrared blood vessel management apparatus according to another embodiment of the present invention.

The mid-infrared blood vessel managing apparatus according to still another embodiment of the present invention illustrated in FIG. 12 may further include a spacer 16 formed to protrude around the outer side of the outer case 12.

The spacer 16 maintains a constant height when the user puts the outer case 10 on the lower part in a state where the outer case 10 is mounted on the lower part, and is more stable on the bottom surface. It is intended to be mounted as.

In particular, in the present embodiment, the outer surface of the spacer 16 is formed to have a flat surface, so that the outer case 10 is rotated by bending when the user makes the outer surface of the spacer 16 in contact with the bottom surface, etc. The user's arm can be prevented from bending.

13 is a view schematically showing the configuration of the mid-infrared blood vessel management apparatus according to the present invention. Looking at the operation of the mid-infrared blood vessel management apparatus according to the present invention with reference to the drawings as follows.

When the user turns on the power through the above-described input unit 14 and inputs a temperature and time suitable for managing his blood vessel, the controller 40 receives this and displays the input content on the display unit 13. The heater 35 is driven to apply heat to the mid-infrared generator 33 composed of the above-described round frame and the mid-infrared cell. As a result, the mid-infrared light of the intended intensity is irradiated directly to the skin of the user's specific area according to the temperature of the mid-infrared cell. In this case, the temperature sensor 36 may provide a feedback signal to the controller 40 by measuring the temperature of the round frame or the mid-infrared cell, for example.

The mid-infrared blood vessel management apparatus according to the present invention has been described above. Hereinafter, an experimental result of measuring a change in the user's body according to the use of the present invention will be described.

14 is a view showing a change in erythrocyte activity before and after using the mid-infrared blood vessel management device according to the present invention.

In this experiment, the blood of the user was extracted 10 times after the use of the mid-infrared blood vessel management device of the present invention and at 30-minute intervals to check the exercise state of red blood cells.

As a result, as shown in FIG. 14, the red blood cells that showed very low activity and clustered with each other before using the mid-infrared blood vessel managing apparatus of the present invention spread and smooth as the use time of the mid-infrared blood vessel managing apparatus increases. You can see the mobility.

15 is a view showing the changes in body temperature of the forearm before and after using the mid-infrared blood vessel management apparatus according to the present invention.

In this experiment, the forearm body temperature of the user was measured 30 minutes after use and 60 minutes after using the mid-infrared blood vessel management device of the present invention.

As a result, as shown in Figure 15, before using the mid-infrared blood vessel management device of the present invention forearm portion of the user who showed a low body temperature from about 35 ℃ to 36 ℃ 30 minutes after use to 38 ℃ ~ 39 ℃ Body temperature was improved, after 60 minutes of use can be seen that the body temperature improved to 39 ℃ ~ 41 ℃.

16 and 17 are views showing changes in body temperature of the whole body before and after using the mid-infrared blood vessel management apparatus according to the present invention.

In this experiment, the body temperature across the front and rear of the user's entire body was measured 30 minutes after use and 60 minutes after using the mid-infrared blood vessel management device of the present invention.

As a result, as shown in Figure 16 and 17, the forearm portion of the user who showed a low body temperature from about 35 ℃ to 36 ℃ before using the mid-infrared blood vessel management device of the present invention 38 ℃ ~ 30 minutes after use Body temperature was improved to 39 ℃, after 60 minutes of use can be seen that the body temperature improved to 39 ℃ ~ 41 ℃.

As described above, a preferred embodiment according to the present invention has been described, and the fact that the present invention can be embodied in other specific forms without departing from the spirit or scope in addition to the embodiments described above is known to those skilled in the art. It is obvious to those who have it. Therefore, the above-described embodiments should be regarded as illustrative rather than restrictive, and thus, the present invention is not limited to the above description and may be modified within the scope of the appended claims and their equivalents.

10: outer case
11: inner case
12: outer case
13: display
14: input unit
16: spacer
17: fastening cover
18a, 18b, 18c: magnet section
21, 22: support member
30, 30L, 30H: mid-infrared emission module
31, 31B, 31L, 31H: mid-infrared cells
32, 32B: round frame
35L, 35H: Linear Heater
35F: film heater
40: control unit

Claims (10)

An outer case formed to surround a part of a user's body; And
A mid-infrared emission module constituting a curved surface corresponding to the curvature of the inner surface of the body part of the user and directly facing the inner surface of the body part to radiate mid-infrared rays inside the outer case;
Including,
The mid-infrared emission module,
A round frame having a cell bottom part and a partition wall protruding inward from the cell bottom part to form a mid-infrared cell accommodating part, wherein the plurality of mid-infrared cell accommodating parts are arranged to form a curved surface corresponding to the inner surface of the body part as a whole; ; And
A plurality of mid-infrared cells that are respectively inserted into and fixed to the plurality of mid-infrared cell receivers;
Including,
The round frame,
The plurality of mid-infrared cells are inserted into the plurality of mid-infrared cell receivers while the plurality of cell bottom surfaces are generally planar, and the plurality of mid-infrared cells are concave curved surfaces. And a mid-infrared blood vessel managing device configured to support an infrared cell not to be separated from the mid-infrared cell accommodating portion by interference with an adjacent mid-infrared cell or the partition wall. The method of claim 1,
The round frame is formed of a metal plate,
The mid-infrared emission module further comprises a linear, film-like or thin-film heater disposed on the rear side of the round frame. The method of claim 2,
The linear heater is a mid-infrared blood vessel management device disposed along the bone of the back of the partition wall. The method of claim 2,
The film heater is a mid-infrared blood vessel management device disposed in close contact with the back of the round frame. delete The method of claim 1,
The height of the partition wall is mid-infrared blood vessel management device lower than the thickness of the mid-infrared cell. The method of claim 1,
The plurality of mid-infrared cell receiving unit is a mid-infrared blood vessel management device arranged in a grid form or honeycomb form in a state that the cell bottom surface is generally planar. The method of claim 1,
And a heat reflecting layer including a metal thin film between an inner surface of the outer case facing the rear surface of the middle infrared emitting module. The method of claim 1,
The outer case,
And a plurality of vents connected to air passages formed inside the outer case. The method of claim 1,
A linear, film or thin film heater disposed on the rear side of the round frame; And
A temperature sensor measuring a temperature of the round frame;
More,
And a mid-infrared blood vessel managing device for feeding back the temperature signal measured by the temperature sensor to a controller for controlling the heater.

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