KR100962611B1 - A Heating Acupuncture Unit Having Maximized Operating Effect - Google Patents

Abstract

The present invention relates to a thermal needle device that maximizes the treatment effect through the heat supply, and in particular, the heat transfer to the skin directly or indirectly heat transfer to the skin in the state converted to heat by supplying electricity to one policy The thermal needle device that maximizes the treatment effect through the heat supply to

A central support made of a metal having low thermal conductivity, a heat conduction heating element located at the outer periphery of the center support and conducting heat by receiving electricity from the outside, and a needle extending at the lower end of the central support and extending the heating element into the skin. A heat policy needle comprising a heat supply needle for penetrating into and transferring heat, and a gold or silver plating layer plated on an outer circumference of the heat supply needle to protect a human body;

A housing main body having a housing hole for accommodating the cold policy assembly, a guide groove formed in the interior of the housing body to guide the heat generating element, and a heat generating element inserted into an inner circumference of the housing body. And an electrical supply terminal electrically connected to the electrical supply terminal, and a power ground terminal for supplying electricity to the electrical supply terminal which is located at an upper portion of the receiving body and is connected to the electrical supply terminal.

Heat supply, treatment effect, thermal needle, device

Description

A Heating Acupuncture Unit Having Maximized Operating Effect}

The present invention relates to a thermal needle device that maximizes the treatment effect through the heat supply, and in particular, the heat supply characterized in that the heat transfer to the skin directly or indirectly heat transfer to the skin in the state converted into heat by supplying electricity to one policy. It relates to a thermal needle device to maximize the treatment effect.

In general, one policy is to process a metal material harmless to the human body to have a predetermined thickness, to create a thin circular pin-shaped needle bar that bends when a certain force is applied, and to smoothly polish one end of the needle part so that it can be easily introduced into the human body. It forms a pointed tip of the needle, and the other side is extended to the coil and other shapes so that the operator can hold the needle by the hand to place the needle.

One policy used for acupuncture is to inject metal needles such as gold, silver, platinum, and stainless steel through the skin of the patient's treatment site to induce mechanical stimulation to the tissues to promote disease healing or promote health. Try to do it.

On the other hand, our body, which is part of nature, is affected by electricity, and the human body generates a bioelectric current that circulates throughout the body. This bioelectricity was discovered by galvanic as an electrical phenomenon occurring in a living body. It is known that electricity of 5-6V flows to the body, but falls below 2.5V when the elderly become biological. Therefore, when abnormalities occur in the body's biocurrents, diseases occur, and these biocurrents are widely applied in the treatment of oriental medicine and new clinical treatment of modern science.

The electroacupuncture was developed as a treatment for such a biocurrent, and by 1816, the electroacupuncture was announced by Berlioz, France, to treat neuralgia with electric current acupuncture, and around 1825, French doctor Charindie ( Sarlandier) applied electroacupuncture to treat gout and nervous system. In 1921, the modern electroacupuncture was established by E.A. Golden, a British, and has been actively studied in China, Japan, and Germany. In particular, by sending a continuous current to the acupuncture by the electro-acupuncture to maintain the health by discharging the terrestrial cells around the blood through the digestion and excretory tract, it is used for the relief of acute pain after surgery or postpartum.

However, the current generation of electricity used in electric needles is to use AC current down to allow a small amount of biocurrent to flow in the human body. However, if a malfunction occurs in the electric device, a large current flows to the human body, causing an electric shock. As well as adversely affects the life of the patient, such problems occur.

The present invention is to solve the above problems, by using a device that converts electricity into heat, rather than using a direct electricity supply method by inserting the Han policy into the skin, the heat penetrates deep into the skin to effect the effect of Han policy procedure. The purpose is to maximize.

As a means for achieving the above object,

The present invention is a center support made of a metal having a low thermal conductivity, a heat conduction heating element which is located at the outer circumference of the center support and receives electricity from the outside, and conducts heat, and is located at the bottom of the center support, and the needle is extended to the heating element. A heat treatment needle comprising a heat supply needle penetrating into the skin to transfer heat and a gold or silver plating layer plated on an outer circumference of the heat supply needle to protect the human body; A housing main body having a housing hole for accommodating the cold policy assembly, a guide groove formed in the interior of the housing body to guide the heat generating element, and a heat generating element inserted into an inner circumference of the housing body. A power supply terminal electrically connected to the power supply terminal, a power grounding terminal connected to the power supply terminal and connected to the power supply terminal to supply electricity to the power supply terminal, and a lid casing the top of the storage body; It comprises a temperature sensing sensor installed in the center of the lid to detect the internal temperature of the main body, and a direct heat supply device formed with grooves on both sides of the lid and the wire inlet protruding outward along the groove. It is characteristic.

In addition, by forming a hole in the upper portion in the shape of a cone covered in the upper portion of the direct heat supply device, characterized in that it further comprises a finishing material through which the temperature sensing line and the power connection line pass.

In addition, the heat exchanger comprising a heat supply support and a heat supply needle made of a metal such as silver or gold having high thermal conductivity; A housing main body having an insertion hole for accommodating the cold policy assembly, a guide groove formed in the interior of the housing body to guide the center support, and inserted into an inner circumference of the housing main body to support the heat supply. A ceramic heating unit for indirectly transferring heat, a heating element built in the ceramic heating unit, a heating element made of nichrome wire, an electrical connection terminal formed by protruding molding of the heating element, and connected to the electrical connection terminal to supply electricity And a heat supply device including a power supply line for supplying and a lid including a casing of the housing main body and a temperature sensing sensor for sensing the internal temperature of the housing main body.

In addition, the outer side of the main body for receiving is characterized in that the coupling plate further made of a square panel form.

As described above, the present invention provides an advantage of maximizing the effect of the procedure in a state of excellent stability unlike the electric needle by continuously supplying appropriate heat stimulation to the affected area by transferring heat deep into the skin of the patient.

In addition, although the invention has been described in connection with the preferred embodiments mentioned, other various modifications and variations may be made without departing from the spirit and scope of the invention. Accordingly, it is intended that the appended claims cover such modifications and variations as fall within the true scope of the invention.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. First, in adding reference numerals to the components of each drawing, it should be noted that the same reference numerals are used as much as possible even if displayed on different drawings. In addition, in the following description of the present invention, if it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted.

First of all, the present invention uses a nichrome wire as a thermal material. Nichrome is a heat resistance material, which is an alloy resistance wire based on the most common nickel and chromium, and has a high resistivity (about 110 μΩcm). It has the property of not being oxidized well even at high temperatures, having sufficient corrosion resistance, and having excellent workability and mechanical properties at high temperatures.

In KS (Korean Industrial Standards), two types are used. The first type (77% or more of nickel, 19 to 21% of chromium, 0.75 to 1.5% of silicon) is a high-performance industrial high temperature heating element having a maximum temperature of 1100 ° C. It is used for electric furnaces and the like.

The second type (57% or more nickel, 15 to 18% chromium, 0.75 to 1.5% silicon, the rest iron) is slightly inferior to the first type in oxidation resistance and high temperature strength, but workability It is good and inexpensive, and is widely used in electric furnaces, heaters, resistance wires, and the like with a maximum temperature of 950 ° C or lower. The thickness of the nichrome wire reaches 0.04 to 13 mm, and other strip-shaped products are also made.

In the present invention, a device for supplying heat to one policy is manufactured by using a nichrome wire which is widely known as a heating element. Hereinafter, a specific structure of the present invention will be described. First, the one-policy heat supply device by direct heat transfer method will be described.

1 is an exploded perspective view of a direct heat supply device of a policy of the first embodiment of the present invention.

Figure 2 is a cross-sectional view of a direct heat supply device of a policy of the first embodiment of the present invention.

Figure 3 is an example of using a direct heat supply device of a policy of the first embodiment of the present invention.

Figure 4 is an exploded perspective view of an indirect heat supply device of a policy of the second embodiment of the present invention.

5 is a cross-sectional view of an indirect heat supply device of a policy of the second embodiment of the present invention.

Figure 6 is a schematic diagram of the indirect heat supply device heating element of the present invention a second embodiment of the present invention.

7 is a diagram illustrating the use of a direct and indirect heat supply device of a policy of the first and second embodiments of the present invention.

(1) Hankyu Thermal Supply System by Direct Heat Transfer Method

The present invention is largely composed of one policy assembly 100 and a direct heat supply device (200).

The one policy assembly 100 includes a center support 110 made of a metal having low thermal conductivity, a heat conduction heating element 120 positioned at an outer circumference of the center support 110 and receiving electricity from the outside to conduct heat; Located at the bottom of the central support 110, the heating element 120 is a prolonged needle penetrates into the skin and transfers heat to the heat supply needle 130 and plated on the outer periphery of the heat supply needle to protect the human body It comprises a gold or silver plating layer 140 to.

The direct heat supply device 200 is formed in the accommodating main body 210 having the accommodating hole 210a and the accommodating main body 210 to accommodate the one-way assembly to guide the heat conducting heating element 120. A guide groove 220 to be inserted into the inner circumference of the accommodating main body 210, and an electrical supply terminal 230 electrically connected to the heat conducting heating element 120, and an upper portion of the accommodating main body 210. It is located and connected to the power supply terminal 230, the power supply ground terminal 240 for supplying electricity to the power supply terminal, the lid 250 casing the upper portion of the housing body 210, and the housing body 210 Temperature sensor 260 is installed in the center of the lid 250 to detect the internal temperature of the) and the wire supply line 270 is formed on both sides of the lid 260 and connected to the outside along the groove ), Including

Finishing material 280 is a conical shape that is directly inserted into the inner upper portion of the heat supply device to form a hole in the upper, the temperature sensing line 260a and the power connection line 270 through the hole.

Hereinafter, the operation and operation effect of the Han-polik heat supply device by the direct heat transfer method will be described.

The present invention is provided with a housing main body 210 for supplying electricity and for receiving the central support 110, the electrical supply terminal 230 is provided inside the housing main body 210, the electrical supply terminal 230 is connected to the power ground terminal 240 and the power ground terminal 240 is connected to the power supply line 270 when the electricity is supplied through the power supply line 270 from the outside of the power ground terminal 240 And flows through the power supply terminal 230.

At this time, the wire inlet is formed in the lid 250, the power supply line 270 is connected to the power ground terminal 240 through the wire inlet, the sensor in the center of the lid 250 for temperature sensing 260 is mounted to sense the temperature generated inside the receiving body 210 to control the amount of electricity supplied from the outside.

On the other hand, the cylindrical center support 110 made of a metal having a low thermal conductivity is fitted to the inside of the main body 210 for receiving, the advancing from the bottom to the top along the receiving hole (210a), the guide groove ( The wing portion of the heat conduction heating element 120 is guided and rises along 220, and after fully entering the upper portion, rotates clockwise or counterclockwise at intervals of 90 degrees.

Then, the heat conduction heating element 120 is connected to the electricity supply terminal 230 to receive electricity, and the heat conduction heating element 120 generates heat and is firmly fixed so as not to be separated to the outside. That is, the center support 110 and the heat supply needle 130 is provided on the outer periphery of the center support 110 is coated with a heat conduction heating element 120 made of nichrome wire, and the heat supply needle 130 is nichrome Since the wire is made of electricity is supplied to the heat supply heating element 120 and the heat supply needle 130 for the heat supplied through the electrical supply terminal 230 is to dissipate heat.

When the heat supply needle 130 penetrates into the skin, the heat generated from the heat supply needle 130 penetrates deeply into the skin due to the effect of gold or silver applied to the outer circumference of the heat supply needle 130. .

After use, twist the center support 110 at intervals of 90 degrees so that the heat conduction heating element 120 is in the guide groove 220 to the position of the guide groove 220, and then removed to the lower portion of the main body for storage 210. The policy assembly is completely separated from it.

In addition, as shown in FIG. 3, the power control unit 400 may be connected to designate as much heat as necessary to perform a policy.

(2) Han-polik heat supply device by indirect heat transfer method

Hereinafter, one policy heat supply apparatus by an indirect heat transfer method of the present invention will be described.

An indirect heat transfer method of a cold heat supply device is largely composed of a cold heat assembly 100a and an indirect heat supply device 300.

The cold policy assembly 100a is made of a heat supply support and a heat supply needle made of a metal such as silver or gold having high thermal conductivity.

The indirect heat supply device 300 is formed in the accommodating body 310 and the accommodating body 310a to accommodate the one-piece assembly 100a, and is formed inside the accommodating body 100a to guide the central support. A guide groove 320 to be inserted into the inner periphery of the housing body 100a to indirectly transfer heat to the support for heat supply, and an inside of the ceramic heat generator 330. A heating element 340 embedded in the nichrome wire, an insertion hole 350 into which the heating element 340 is inserted, an electrical connection terminal 360 formed by protruding the end portion of the heating element, and the electrical connection terminal A lid having a power supply line 370 connected to the 360 to supply electricity, and a temperature sensor 380 for casing the housing main body 310 and sensing an internal temperature of the housing main body. 390). If necessary, the temperature sensor is mounted on a portion where the spring is installed so that the temperature sensor is in close contact with the heat supply support by the spring so that the heat sensing proceeds smoothly.

Hereinafter, the operation and operation effect of the Han-polik heat supply device by the indirect heat transfer method will be described.

The one policy assembly 100a according to the indirect heat transfer method of the present invention is a metal having a high thermal conductivity, constituting a heat supply support 110a and a heat supply needle 130a so that the heat supply needle penetrates the skin.

The heat supply support 110a and the heat supply needle 130a are made of silver or gold, and the one-piece assembly 100a is inserted into and coupled to the housing body 310.

A receiving hole 310a and a guide groove 320 are formed in the main body for receiving 310, and the heat supply support 110a and the wing of the support guide along the receiving hole 310a and the guide groove 320. When the wing portion of the support is transported to the upper end is temporarily fixed by 90 degrees to prevent the one policy assembly from being separated from the receiving body 310.

The housing body 310 is provided with a ceramic heating unit 330, the ceramic heating unit 330 has a heating element 340 made of nichrome wire is built, the electricity supply line (340) through the heating element (340) 370 is connected so that heat is dissipated from a heating element that converts external electricity into heat.

When the heat generating element 340 emits heat, heat is emitted from the ceramic heat generating portion 330, and then the heat supplying heat generating element 110a of the Hankyu assembly 100a closely coupled with the ceramic heat generating portion 330 generates heat. The heat of the heat supply heating element 110a is transferred to the heat supply needle 130a, which eventually heats the heat supply needle 130a and heats the skin deeply.

At this time, the ceramic heating unit 330 is a built-in heating element 340 made of nichrome wire therein, and after the ceramic powder and bond is mixed in the upper and lower end holes in order to make the nichrome wire invisible, and then solidified. do.

In addition, as shown in FIG. 7, the patient can be treated by inserting the needle into the affected part while the support plate 500 is fixed to the affected part, and then supplying proper heat to the affected part by using the power control unit 400. have.

1 is an exploded perspective view of a direct heat supply device of a policy of the first embodiment of the present invention.

Figure 2 is a cross-sectional view of a direct heat supply device of a policy of the first embodiment of the present invention.

Figure 3 is an example of using a direct heat supply device of a policy of the first embodiment of the present invention.

Figure 4 is an exploded perspective view of an indirect heat supply device of a policy of the second embodiment of the present invention.

5 is a cross-sectional view of an indirect heat supply device of a policy of the second embodiment of the present invention.

Figure 6 is a schematic diagram of the indirect heat supply device heating element of the present invention a second embodiment of the present invention.

Figure 7 is an example of using a direct or indirect heat supply device of a policy of the first and second embodiments of the present invention.

Explanation of symbols on the main parts of the drawings

100: cold weather assembly

110: center support

120: heating element for heat conduction

130: heat supply needle

140: gold or silver plating layer

200: direct heat supply

200-270: means of direct heat supply arrangement,

200: direct heat supply

210: body for storage

210a: storage hole

220: guide groove

230: electricity supply terminal

240: power ground terminal

250: lid

260: temperature sensor

270: power connection line

300-390: indirect heat supply device means,

310: main body for storage

310a: insertion hole

320: guide groove

330: ceramic heating unit

340: heating element

350: hole for heating element insertion

360: electrical connection terminal

370: power supply line

380: temperature sensor

390: lid

400: power control unit

500: support plate

Claims (4)

Located in the lower portion of the center support 110 and the center support 110 made of a metal having a low thermal conductivity, the heat conduction heating element 120 is located on the outer periphery of the center support 110 to receive heat from the outside to conduct heat; The heating element includes a heat supply needle 130 that penetrates into the skin as an extended needle and transfers heat, and a gold or silver plating layer 140 which is plated on the outer circumference of the heat supply needle to protect the human body. A policy assembly 100; A housing main body 210 having a receiving hole 210a for accommodating the cold policy assembly, a guide groove 220 formed inside the housing main body and guiding a heat conducting element for heat conduction, and the housing main body. A power supply terminal 230 inserted into an inner circumference of the power supply terminal and electrically connected to a heat conduction heating element, and a power ground terminal 240 connected to the power supply terminal and positioned at an upper portion of the housing body to supply electricity to the power supply terminal; ), A lid 250 casing the upper portion of the housing body, a temperature sensor 260 installed at the center of the lid to sense the internal temperature of the housing body, and grooves are formed at both sides of the lid. The thermal needle device maximizing the treatment effect through the heat supply, characterized in that it comprises a direct heat supply device consisting of a power connection line 270 connected to the outside along the groove. The method of claim 1, Forming a hole in the upper portion in the shape of a cone covered in the upper portion of the direct heat supply device, further comprising a finishing material 280 through which the temperature sensing line 260a and the power connection line 270 passes. A thermal needle device that maximizes the treatment effect through the heat supply. A heat exchanger support 100a consisting of a heat supply support and a heat supply needle made of a metal such as silver or gold having high thermal conductivity; A housing main body 310 having an insertion hole 310a for accommodating a cold policy assembly, a guide groove 320 formed inside the housing main body to guide the center support, and A ceramic heating unit 330 inserted into an inner circumference to indirectly transfer heat to a support for heat supply, a heating element 340 embedded in the ceramic heating unit 330 and made of nichrome wire, and the heating element inserted therein A heating element insertion hole 350 formed in the ceramic heating element, an electrical connection terminal 360 formed by protruding the end of the heating element, a power supply line 370 connected to the electrical connection terminal to supply electricity; And an indirect heat supply device 300 comprising a lid 390 in which the housing main body is casing and a temperature sensor 380 for sensing the internal temperature of the housing main body is included. The thermal needle device to maximize the treatment effect through the heat supply characterized in that. The method of claim 3, wherein The thermal needle device to maximize the treatment effect through the heat supply, characterized in that the outer side of the receiving body 310 is made by further combining the support plate 500 of the rectangular panel form.

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