KR100924948B1 - Coil-Probe for a magnetic curer formed with a metal plate - Google Patents

Abstract

The present invention relates to a magnetic therapy device, and more particularly, to a magnetic probe coil probe having an improved structure for cooling a magnetic probe coil probe.

In the present invention, a coil probe using a metal plate coil made of a plurality of side plates and a plurality of partition walls made of a thin band-shaped metal plate and embedded in a case made of an insulating material for smooth cooling of the coil probe of the magnetic therapy device. Comprising a plurality of side plates having a different diameter and share the center and are arranged to be spaced apart from each other, and a plurality of partition walls connecting the plurality of side plates are spaced apart from each other radially disposed, each of the side plates and the partitions flow refrigerant It provides a coil probe for a magnetic therapy device, characterized in that a plurality of refrigerant passage holes are provided to enable.

Magnetic therapy device, driving circuit part, coil probe, metal plate coil, side plate, partition wall, spacer plate, separation gap, refrigerant, refrigerant flow path, refrigerant passage hole, refrigerant tank, upper plate, lower plate

Description

Coil-Probe for a magnetic curer formed with a metal plate}

The present invention relates to a magnetic therapy device for treating various lesions by outputting magnetic pulses to the human body to generate induced electromotive force in the human body. It is about a therapeutic device.

Recently, various applications of electric or magnetic stimulators for treating various body diseases such as viewpoint fever, neuralgia, and low back pain by flowing electric current in the human body are expected to increase further. Typically, such electromagnetic stimulation therapy is an electrical stimulation method or a magnetic stimulation method, the former is a method of stimulating nerve cells in the electrode area by applying an electric current in the body after attaching the electrode directly to the human body, the latter to the coil wound around the electromagnet or iron core It is a method of stimulating nerve cells by generating induced electromotive force in the human body by projecting a magnetic force generated by flowing an electric current to the human body.

Recently, the magnetic stimulation method has attracted much attention due to the advantages of better penetration effect and no pain or discomfort caused by the electrical stimulation method. As such, the magnetic stimulator induces an electric field inside the human body by using a magnetic field that changes in time to allow stimulation of contactless, non-invasive, deep and wide areas. The range of applications is wide, ranging from muscle disease to rehabilitation.

1 is a schematic diagram of a conventional magnetic therapy device, which is largely composed of a magnetic pulse generator 1 and a coil probe 2, and a coil wound several times inside the coil probe 2. When the coil probe 2 is brought close to a desired body part and a current is flown, a magnetic force penetrates into the human body to induce an electric field. However, such a conventional magnetic therapy device has a problem in that a lot of heat is generated in the coil embedded in the coil probe 2 and thus it is difficult to continuously use it for a long time. For example, most of the magnetic therapy devices currently on the market have a drawback that the maximum duration of use is only about 30 to 40 minutes due to the heat generated. If you use it for more time, the coil may overheat and damage your skin. Therefore, after using the user for about 30 to 40 minutes, it is very inconvenient because the user turns off the power and waits for the coil to cool.

The object of the present invention made in view of the above-described problems is to remove the existing wire coils and arrange the metal plate coils in a unique structure and circulate the refrigerant therein to maintain the existing magnetic pulse output and at the same time excellent magnetic treatment coil To provide a probe.

In addition, to provide a coil probe with a forced circulation means of the refrigerant in order to allow the user to more easily and simply cool the coil probe.

In the present invention for the above-described object, in the magnetic probe coil probe for treating various lesions by inducing an electric field in the human body by projecting a magnetic pulse in the human body, a case made of an insulating material, as being embedded in the case thin It comprises a plurality of side plates made of a strip-shaped metal plate and a metal plate coil consisting of a plurality of partition walls and spacer plates, a plurality of side plates having different diameters are arranged so as to share the center and spaced apart from each other and connect the plurality of side plates to each other A plurality of partitions are spaced apart from each other and disposed radially, a pair of separation plates that connect each of the cut portions by cutting a portion of each side plate is formed facing each other, the refrigerant flows through each side plate and the partition wall Coil preparation for magnetic therapy device, characterized in that a plurality of refrigerant passage holes are provided so that It provides a probe.

Here, the refrigerant is filled in the metal plate coil and the case is preferably provided with a refrigerant flow passage extending from the metal plate coil to the outside of the case.

The refrigerant flow path provided in the case may be connected to the refrigerant tank in which the refrigerant is stored and may be connected to the refrigerant circulation hose connected to the external pump.

Upper and lower plates made of an insulating material may be provided on upper and lower portions of the metal plate coils, respectively, to cover the top and bottom surfaces of the metal plate coils, and the plurality of partition walls may be spaced apart from each other.

According to the coil probe for a magnetic therapy device of the present invention, it is possible to effectively cool the generated heat of the coil due to a long time of use, thereby enabling continuous use of the magnetic therapy device and preventing a situation of damaging the skin of the subject.

In addition, it outputs the same magnetic pulse as the existing wire coil and at the same time, the cooling performance is very excellent, which will prolong the life of the device and prevent damage caused by overheating of the device.

In addition, since the coil probe can be manufactured using a low-cost metal plate, the manufacturing cost of the magnetic therapy device is lowered, which can be widely distributed to general users, and there is also an effect of import substitution.

Hereinafter, with reference to the accompanying drawings, the configuration and operation principle of the present invention will be described in detail.

Figure 2 is a block diagram showing an example of a magnetic therapy device having a coil probe of the present invention. As shown, the coil probe 120 for a magnetic therapy device of the present invention is typically connected to a driving circuit unit 110 for supplying a current for generating a magnetic pulse. The illustrated driving circuit unit 110 may be variously modified as an example. In the present invention, the converter 111 rectifies AC power to DC power, the inverter 112 to convert the DC power to AC, and an inverter ( And a transformer 113 for boosting the voltage input from 112 and a filter 114 for removing noise from the current output from the transformer 113.

3 is an exploded perspective view of a metal plate coil embedded in a coil probe for a magnetic therapy device according to an embodiment of the present invention, and FIG. 4 is a cross-sectional view of the coil probe of the present invention. In the case 121 of the coil probe 120 of the present invention, a metal plate composed of a plurality of side plates 122a made of a thin strip-shaped metal plate and a plurality of partition walls 122b interconnecting them are removed from a coil made of a conventional wire. Coil 122 is embedded. The plurality of side plates 122a have a plurality of side plates having different diameters and are shared with each other and are spaced apart from each other on concentric circles. The partition walls 122b are radially spaced apart from each other to electrically connect the plurality of side plates 122a to each other. In addition, a portion of the continuous concentric portions of each side plate 122a is cut by a pair of spacer plates 122e and 122f. That is, the pair of spacer plates 122e and 122f cut off a portion of each side plate 122a and then connect the cut portions of each side plate to form a spaced gap 122g. This is to prevent the short circuit when the current is supplied to the metal plate coil 122. Each space partitioned by the side plates 122a and the partition walls 122b is filled with a refrigerant to be described later, and the refrigerant passage holes 134 and 136 to allow the refrigerant to flow through the side plates 122a and the partition walls 122b. This is provided a large number. Coolant passage holes are not formed in the spacer plates 122e and 122f.

The metal plate coil 122 having the above-described structure may be embedded in the case 121 made of an insulating material, but the upper plate 130 and the lower plate 132 made of the insulating material as shown in the upper portion of the metal plate coil 122 are shown. It is preferable to embed the case 121 so as to cover the lower surface.

One end of the metal plate coil 122 is provided with coil extensions 122c and 122d extending from the outermost side plate 122a and connected to the driving circuit unit 110 by external wires 115a and 115b. The metal material of the metal plate coil 122 may be an electrically conductive metal, but copper or bronze-based metal having good electrical and thermal conductivity may be advantageous in terms of economy.

The metal sheet coil 122 having such a structure also takes the form of a circular coil as a whole, and as a result of the experiment, it was confirmed that there is no problem in outputting the magnetic pulse as in the prior art, and the cooling performance is superior to that of the conventional wire coil. I could confirm that.

FIG. 5 is a schematic perspective view of the outer side of the coil probe for a magnetic therapy device according to an embodiment of the present invention, and FIG. 6 is a cross-sectional view taken along the line VI-VI of FIG. 5. As shown in FIG. 5, a coolant flow passage 123a is formed from the metal plate coil 122 to the outside of the case 121, and coolant tanks 124 and 125 may be connected thereto. The refrigerant flow passage 123a is for replacing or forcibly circulating the refrigerant 123 inside the metal plate coil 122. That is, when the refrigerant 123 stored in the metal plate coil 122 is to be replaced by a long time of use, the existing refrigerant is discharged through the refrigerant flow passage 123a and a new refrigerant is introduced. At least two refrigerant tanks 124 and 125 may be configured to be connected to the case 121. Preferably, the refrigerant tanks 124 and 125 are connected to the upper side of the coil probe 120 connected to the driving circuit unit 110 as shown. Do. The round curved body portions 124a and 125a of the refrigerant tanks 124 and 125 may be formed of a synthetic resin such as plastic or rubber of a flexible material. The reason is that if it is necessary to cool the metal plate coil 122 by pressing the body portion (124a, 125a) of the refrigerant tank (124, 125) to force the refrigerant 123 inside the metal plate coil 122 to force circulation Because it is for. For example, when one coolant tank 124 is filled with a coolant and the other coolant tank 125 is filled with little or no coolant, the round body portion 124a of the coolant tank 124 is pressed by hand. The refrigerant 123 inside the metal plate coil 122 is moved to another refrigerant tank 125 by the air pressure. On the contrary, if the body portion 125a of the refrigerant tank 125 filled with the refrigerant is pressed, the refrigerant 123 is moved back to the opposite refrigerant tank 124. When this process is repeated, the metal plate coil 122 is cooled.

Body portions 124a and 125a of the refrigerant tank are provided with air control switches 124b and 124b. The air control switches 124b and 125b may be manufactured in a cap type such as a bottle cap, and the specific shape thereof may be variously modified as long as it is a structure capable of adjusting air. Unexplained reference numeral 121a denotes a center hole of the coil probe, and 124c and 125c denote refrigerant circulation hoses.

7 is an external schematic perspective view of a coil probe for a magnetic therapy device according to another embodiment of the present invention. As shown, the refrigerant circulation passages 142a and 142b connected to the external pump 140 may be connected to the refrigerant flow passage 123a formed in the case 121. In this case, since the refrigerant 123 in the metal tube coil 122 is circulated at the consolidation pressure, the cooling effect is much more excellent.

When the coolant tanks 124 and 125 or the coolant circulation hoses 124c, 125c, 142a and 142b are not connected to the coolant flow passage 123a of the case 121, the coolant 123 is prevented from flowing out. Flow passage 123a is used by blocking with a separate stopper (not shown).

8 is a cross-sectional view of a metal plate coil according to another embodiment of the present invention. The plurality of partition walls 122b may be disposed to be spaced apart from each other without being located in a straight line as shown.

1 is a schematic diagram of a conventional magnetic therapy device.

Figure 2 is a block diagram showing an example of a magnetic therapy device having a coil probe of the present invention.

3 is an exploded perspective view of a metal plate coil embedded in a coil probe for a magnetic therapy device according to an embodiment of the present invention.

4 is a cross-sectional view of the coil probe of the present invention.

Figure 5 is an external schematic perspective view of a coil probe for a magnetic therapy device according to an embodiment of the present invention.

6 is a cross-sectional view taken along the line VI-VI of FIG. 5.

7 is an external schematic perspective view of a coil probe for a magnetic therapy device according to another embodiment of the present invention.

8 is a cross-sectional view of a metal plate coil according to another embodiment of the present invention.

<Description of the symbols for the main parts of the drawings>

100: magnetic therapy device 110: drive circuit

120: coil probe 122: metal plate coil

122a: side plate 122b: partition wall

122c and 122d: coil extension 122e and 122f: spacer plate

122 g: separation gap 123: refrigerant

123a: refrigerant flow passages 124, 125: refrigerant tank

130,132: upper plate, lower plate 134,136: refrigerant passage hole

Claims (6)

In the magnetic probe for the magnetic therapy for projecting a magnetic pulse to the human body to induce an electric field in the various lesions, A case made of an insulating material; Is embedded in the case and comprises a metal plate coil consisting of a plurality of side plates and a plurality of partition walls and spacer plates of a thin strip-shaped metal plate, A plurality of side plates having different diameters are disposed to share a center and are spaced apart from each other, and a plurality of partition walls connecting the plurality of side plates to each other are radially disposed to be spaced apart from each other, and each part cut by cutting a portion of each side plate. A pair of spacer plates connected to each other is formed to face each other, the coil probe for the magnetic therapy device, characterized in that a plurality of refrigerant passage holes are provided in each side plate and the partition wall to allow the refrigerant to flow. The method of claim 1, Coil probe for a magnetic therapy device, characterized in that the refrigerant is filled in the metal plate coil. The method of claim 2, The case has a coil probe for a magnetic therapy device, characterized in that the refrigerant flow passage extending from the metal plate coil to the outside of the case is provided. The method of claim 3, wherein The coil probe for magnetic therapy device, characterized in that the refrigerant flow path provided in the case is connected to the refrigerant tank in which the refrigerant is stored. The method of claim 1, Upper and lower plates made of an insulating material are provided on the upper and lower portions of the metal plate coils to cover the top and bottom surfaces of the metal plate coils, respectively. The method of claim 1, The plurality of partition walls are coil probes for magnetic therapy devices, characterized in that arranged to be spaced apart from each other.

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