KR102196406B1 - Electrode for electrosurgical handpiece - Google Patents

Abstract

The present invention relates to a conductive electrode for a mono-polar handpiece, which is used for an electrosurgical handpiece. More particularly, the present invention relates to a conductive electrode for an electrosurgical handpiece, wherein the conductive electrode is split into two pieces, so that it is possible to select general surgery and precise microsurgery like a conventional electrosurgical handpiece, and carbonization of tissue and smog rarely occur.

Description

Conductive electrode for electrosurgical handpiece {Electrode for electrosurgical handpiece}

The present invention relates to a conductive electrode of a monopolar handpiece used in an electrosurgical handpiece. In particular, the conductive electrode is divided into two, so that general surgery like a conventional electrosurgical handpiece, The present invention relates to a conductive electrode for electrosurgical handpieces that can select and use precise microsurgery, hardly cause carbonization of tissues, and hardly generate smog.

Conventionally, an operation to cut a tissue was performed using a steel surgical scalpel, and although it is widely used now, advanced surgical tools using energy such as electricity, laser, and ultrasound have appeared due to the development of modern high engineering technology.

The principle of energy-based surgical instruments is to inject energy into the tissues of our body appropriately to cause tissue changes and to see the surgical effects.

Among them, the most widely used energy-based surgical instrument is electrosurgery, which uses Hing frequency (radio frequency) electric energy to incise, resection, or cauterize the patient's tissues. It is a surgical method to perform the back.

The human nervous system is very sensitive to low-frequency electricity up to 1,000 Hz. Therefore, if you are shocked by the AC electricity flowing through the household electric wire, you will be shocked.

Electrosurgery using high-frequency electrical energy uses high-frequency electricity ranging from 200 kHz to 5 MHz.

Intracellular vibration is generated by the electric energy supplied through the electrode, thereby increasing the intracellular temperature and heating the tissue.

When the temperature in the cell reaches about 60℃, cell death occurs, and when heated to 60~99℃, tissue drying (dehydration) and protein coagulation proceed, and when the intracellular temperature reaches 100℃, the cell volume expands and vaporizes. Occurs, and in this process, the tissue is cut or cauterized.

Such electrosurgery uses a high-frequency electric current for incision and coagulation of tissue. In the incision using an electrosurgical device, heat is generated in the tissue incision by a high-frequency electric current, resulting in a remarkable coagulation effect.

Such an electrosurgical incision inevitably destroys the air insulating layer due to incomplete contact between the conductive electrode and the tissue, resulting in an arc accompanied by high heat, which burns the tissue and causes burns, and carbonization of the tissue. And there is a problem that the conductive electrode is contaminated.

In addition, the tissues are carbonized by the arc and smog is generated, which is known to have adverse health effects on surgeons and patients.

In the monopolar electrosurgical device 10, as shown in FIG. 1, the conductive electrode 100 is fastened in front of the handpiece 30, which is a part held by the surgeon, and the ground pad 40 is grounded to the patient. In addition, the handpiece 30 and the ground pad 40 are connected to the control unit 20 for generating a high frequency through cables 31 and 41, respectively.

Applicant of the present invention developed "conductive electrode for electrosurgical handpiece" (hereinafter referred to as "prior art") of Korean Patent Office Registration No. 10-2020179 to enable micro-surgery, and arc and smog almost occur. A conductive electrode that does not have been developed.

2 and 3, the conductive electrode 50 is divided into a first blade 51 and a second blade 53, and the first and second blades 51 as shown in FIG. ,53) was tightened vertically.

Such prior art has a problem in that an external force is applied to the conductive electrode 50 during a manufacturing process or during an operation, and the first and second blades 51 and 53 are dropped, causing a defect.

In order to prevent this, the first and second blades 51 and 53 were wrapped around the guard tube 56 having contraction on the outer surface of the fastened first and second blades 51 and 53 as shown in FIG. 4 to prevent the first and second blades 51 and 53 from falling. During the use process, the first and second blades 51 and 53 are dropped, and production costs increase.

In addition, there is a problem in that the carbonized tissue adheres to the blade of the conductive electrode 50 during the surgical procedure and is not well cleaned.

Document 1. Korean Intellectual Property Office Registered Patent Publication No. 10-2020179, "Conductive Electrode for Electrosurgical Handpiece" Document 2. Korean Intellectual Property Office Registration Patent No. 10-1566766, "Medical Handpiece" Document 3. Korean Patent Office Publication No. 10-2016-0087288, "Precision blade electric surgical instrument" Document 4. Korean Intellectual Property Office Patent Publication No. 10-0818730, "Surgery Handpiece Equipped with Surgical Blade" Document 5. Korean Patent Office Publication No. 10-2017-0135823, "Tapered precision blade electrosurgical instrument"

The present invention has been devised to solve the above problems, and consists of dividing the conductive electrode for monopolar into first and second blades, but the first and second blades are firmly fastened, and precise microsurgery is performed. It is possible, and it is an object of the present invention to provide a conductive electrode for an electrosurgical handpiece in which an arc and smog hardly occur due to incomplete contact with a tissue.

In order to achieve the above object, the conductive electrode for an electrosurgical handpiece according to the present invention is a conductive electrode fastened to the handpiece 30 used in monopolar electrosurgery. A blade molded into a plate shape; Cutting edges formed at the upper and lower ends of the blade; An anodizing coating layer 102 formed by anodizing the surface of the blade excluding the edge portion; And a ceramic coating layer 103 formed by coating ceramic on the surface of the anodizing coating layer 102.

At this time, the blade is a first blade (110); And a second blade 120; and the first blade 110 and the second blade 120 are stacked and fastened in a vertical direction.

In addition, a first wall 113 in which one side of the first blade 110 extends downward; And a second wall 123 in which one side of the second blade 120 extends upwardly; is formed, and the first and second walls 113 and 123 are fastened while being in contact with each other in a lateral direction.

In addition, a first mounting portion 114 formed on one side of the first wall 113; And a second seating portion 124 formed on one side of the second wall 123; by being formed, the lower end of the first wall 113 is in contact with the second seating portion 124 and of the second wall 123 It characterized in that the upper end is fastened so as to contact the first seating portion (114).

In addition, the anodizing coating layer 102 is formed to a thickness of 30 μm to 50 μm, and the ceramic coating layer 103 is formed to a thickness of 20 μm to 40 μm.

In addition, the first plug 111 is formed in an extended form at the rear end of the first blade 110 and inserted into and fastened to the handpiece 30; It characterized in that it comprises a further; a second plug 121; the rear end of the second blade 120 is molded in an extended shape and inserted into and fastened to the handpiece 30.

In addition, a protruding stopper is formed at the upper and lower ends of the blade.

The conductive electrode 100 of the present invention configured as described above is configured by stacking and fastening the second blade 120 and the first blade 110 in a vertical direction, and one side of the first blade 110 extends downward. Since the January 113 and the second wall 123 extending upward on one side of the second blade 120 are connected while being in contact, the first blade 110 and the second blade 120 have excellent fastening strength. The first and second blades 110 and 120 are not separated by an external force during a process or surgery, but are firmly fastened.

In addition, since the contact area with the tissue is reduced during the pickling process, the current density is high, so that the tissue can be effectively incised even with small high-frequency electric energy, and the occurrence of smog is minimized because burns and carbonization of the tissue hardly occur.

1 is a view showing the configuration of an electric surgical instrument.
Figure 2 is a side view showing a conventional conductive electrode divided into first and second blades.
3 is a front cross-sectional view showing a conventional conductive electrode divided into first and second blades.
4 is a perspective view showing a state in which a guard tube is fastened to an outer surface of a conventional conductive electrode.
5 is a perspective view showing a handpiece in a state in which the conductive electrode of the present invention is coupled.
Figure 6 is an exploded perspective view showing a state in which the conductive electrode is separated from the handpiece of Figure 5;
7 is a front perspective view showing a conductive electrode according to the present invention.
8 is a cross-sectional view taken along line AA of FIG. 7.
9 is a rear perspective view showing a conductive electrode according to the present invention.
10 is an exploded perspective view showing an exploded conductive electrode according to the present invention.
11 is an exploded cross-sectional view showing a conductive electrode according to the present invention.
12 is a diagram showing a connection between a conductive electrode and a control unit of a handpiece according to the present invention.
13 is a view showing a state in which electrosurgery is performed using a conductive electrode according to the present invention.

Hereinafter, the present invention will be described in detail with reference to a preferred embodiment of the present invention and the accompanying drawings, but the same reference numerals in the drawings will be described on the premise that they refer to the same elements.

In the detailed description of the invention or in the claims, when any one component "includes" another component, it is not construed as being limited to only the component unless otherwise stated, and other components It is to be understood that it may further include.

The terms "top", "bottom", "bottom", "front", "rear", "bottom", and the like, as used herein, are for ease of explanation only, and the components as shown in the drawings are Refers to the orientation.

The conductive electrode 100 used in the handpiece 30 of the electrosurgical instrument is configured to cut, cut, or cauterize tissue by using high-frequency electric energy supplied to the conductive electrode 100.

The conductive electrode 100 of the present invention is used for the handpiece 30 of a monopolar electrosurgical instrument, and the conductive electrode 100 is fastened in front of the handpiece 30 as shown in FIG. 5. .

At this time, it is preferable to configure the conductive electrode 100 to be fastened to the handpiece 30 through the holder 34 to facilitate quick replacement.

The conductive electrode 100 according to the present invention is configured by vertically stacking and fastening the first blade 110 and the second blade 120 as shown in FIGS. 7 to 9.

In the first blade 110, a first plug 111 for electrical connection with the handpiece 30 is formed at the rear of the body, and a first cutting edge 112 is formed at the upper end of the first blade 110 do.

At one side of the first blade 110, a first wall 113 is formed in a form in which the body of the first blade 110 extends downward, and the tip of the first blade 110 allows the blade to penetrate into the tissue. It is formed to be curved in an arc shape for ease.

The second blade 120 is molded into the same shape and structure as the first blade 110 described above, and the second blade 120 is a second plug (for electrical connection of the handpiece 30) at the rear of the body. 121 is formed, and a second edge portion 122 is formed at the lower end of the second blade 120.

A second wall 123 is formed in a form in which the body extends upward in one side of the second blade 120, that is, in the opposite direction in which the first wall 113 of the first blade 110 is formed, and the second blade ( The upper end of 120) is a tissue, and the blade is formed to be curved in an arc shape to facilitate incision and penetration into the tissue.

The first blade 110 and the second blade 120 described above are manufactured in the same shape, structure, and size, and the first blade 110 and the second blade 120 are not separately manufactured, but the first After the blade 110 or the second blade 120 is manufactured, the rest are manufactured by turning them over and fastening them.

The first and second blades 110 and 120 are vertically stacked and fastened with a fastening means. As shown in Figs. 8, 10 and 11, the first cutting edge 112 of the first blade 110 is upwardly moved. In the state where possible, the second edge part 122 of the second blade 120 is positioned downward so that the first blade 110 and the second blade 120 are fastened and fixed with an adhesive 101 as a fastening means. .

At this time, the first wall 113 formed in a form extending downward from one side of the body of the first blade 110 and the second wall 123 formed in a form extending upward from one side of the body of the second blade 120 It is configured to be fastened by contacting in the lateral direction.

And, as shown in FIGS. 10 and 11, the lower end of the first wall 113 is in contact with the second seating portion 124 of the second blade 120, and the lower end of the second wall 123 is of the first blade 110. It is fastened so as to contact the first seating portion 114.

The surgery is performed by high-frequency electric energy transmitted to the conductive electrode 100 configured by fastening the first blade 110 and the second blade 120 as described above, and a long plate to facilitate tissue incision, ablation, and cauterization. Has a shape.

In addition, as shown in FIG. 8, the first and second blades 110 and 120 form an anodizing coating layer 102 and a ceramic coating layer 103 on the surface thereof.

Separate high-frequency energy is supplied to the first and second blades 110 and 120 formed of aluminum, respectively. Insulation of the first and second blades 110 and 120 and between the first and second blades 110 and 120 The surfaces of the first and second blades 110 and 120 are anodized to increase the surface strength.

Anodizing is to increase the surface stiffness. When metal is electrolyzed with a dilute-acid solution across the anode, the oxide film (aluminum oxide, Al ₂ O) that has strong adhesion to the material metal by oxygen generated from the anode ₃ ) is formed.

In the present invention, anodizing coating layer 102 having a thickness of 20 μm to 50 μm is formed by soft anodizing the surfaces of the first and second blades 110 and 120.

If the thickness of the anodizing coating layer 102 is less than 20 μm, the insulation performance is degraded, and when the thickness of the anodizing coating layer 102 exceeds 50 μm, the anodizing coating treatment is difficult, and since the ceramic coating is difficult, the anodizing coating layer 102 is 20 It is preferable to form a thickness of ㎛ to 50㎛.

In this case, the anodizing coating layer 102 is not formed on the first edge portion 112 of the first blade 110 and the second edge portion 122 of the second blade 120 substantially cutting the tissue.

Further, a ceramic coating layer 103 is formed on the anodizing coating layer 102 of the first and second blades 110 and 120.

The ceramic coating layer 103 serves to prevent tissue from sticking to the surfaces of the first and second blades 110 and 120 during surgery, and to easily wipe and remove the stuck tissue.

The ceramic coating layer 103 is formed to a thickness of 10 μm to 40 μm.

In general, the currently widely used monopolar conductive electrode is used by coating a glass with a thickness of 0.15mm on the surface of a conductive electrode molded of stainless steel, and coating a 0.15mm thick glass on the conductive electrode made of stainless steel is appropriate. Insulation and the ability to not adhere well to the structure are exhibited.

If the glass coating is too thick, cracks occur and the insulation is destroyed. Therefore, the glass is coated with a thickness of 0.15mm for proper insulation and non-stick performance.

In the present invention, the anodizing coating layer 102 is formed to have a thickness of 20 μm to 50 μm for insulation of the conductive electrode 100, and at this time, the ceramic coating layer 103 is 10 μm on the anodizing coating layer 102 for effective non-stick performance. It is formed to a thickness of 40㎛.

If the thickness of the ceramic coating layer 103 is less than 10 μm, the non-stick property is poor, and when the thickness exceeds 40 μm, cracks are likely to occur. Therefore, it is preferable that the ceramic coating layer 103 is formed to a thickness of 10 μm to 40 μm.

Preferably, the anodizing coating layer 102 is formed to have a thickness of 40 μm, and the ceramic coating layer 103 is formed to have a thickness of 30 μm to exhibit the best insulation and non-stick performance.

When cutting the tissue with the conductive electrode 100, the first cutting edge 112 formed at the top of the first blade 110 or the second cutting edge 122 formed at the lower end of the second blade 120 provides high-frequency electrical energy. The tissue is cut while being supplied, and for this purpose, the anodizing coating layer is not formed on the first and second cutting edges 112 and 122.

As described above, the conductive electrode 100 of the present invention composed of the first and second blades 110 and 120 is coupled to the handpiece 30 through the holder 34 as shown in FIG. 6, and the conductive electrode 100 is When coupled to the piece 30, the first plug 111 and the second plug 121 are electrically connected to the control unit 35 inside the head piece 300 as shown in FIG. 12.

The control unit 37 is driven by an operation button 33 formed on the case 32 of the handpiece 30 as shown in FIG. 5, and the operation button 33 generates high frequency electric energy in the control unit 20. Thus, it serves to selectively supply or block high-frequency electric energy to the first blade 110, the second blade 120, or the first and second blades 110 and 120 of the conductive electrode 100.

13 is a view showing a state in which a tissue is cut using the handpiece 30 to which the conductive electrode 100 of the present invention is fastened, and the lower portion of the conductive electrode 100 is a second blade 120, The upper part is the first blade 110.

Therefore, when the surgeon grips the handpiece 30 and performs surgery, the first part that contacts the tissue is the second blade 120, and the first blade 110 is applied to the tissue along the second blade 120. This is the incoming part.

The surgeon manipulates the operation button 33 of the handpiece 30 to supply high-frequency electric energy only to the second blade 120 for surgery, or operates the operation button 33 to operate both the first and second blades 110 and 120 It is also possible to perform surgery by supplying high-frequency electric energy to the body, and these two processes will be described in detail.

When high frequency electric energy is supplied only to the second blade 120

In a state where the surgeon supplies high-frequency electrical energy only to the second blade 120, when the conductive electrode 100 approaches the tissue, the second blade 120 first contacts the tissue and the tissue is cut by the high-frequency electrical energy.

At this time, since high-frequency electrical energy is not supplied to the first blade 110 following the second blade 120, an arc does not occur even if the first blade 110 contacts the tissue incompletely, and an arc does not occur. No burn or carbonization occurs, and no smog occurs.

In addition, as shown in FIG. 8, the first wall 113 in which one side of the first blade 110 extends downward and the second wall 123 in which one side of the second blade 120 extends upward contact each other, 2 Since the blades 110 and 120 are fastened, when the tissue is cut in a state where high-frequency electrical energy is supplied only to the first blade 110 of the conductive electrode 100, the high-frequency electrical energy flows only on one side of the conductive electrode 100. Since high-frequency electric energy does not flow to the other side of the conductive electrode 100, the burn or carbonization of the tissue by the second blade 120 for cutting the tissue can be reduced.

When the tissue is cut with only the second blade 120 supplied with high-frequency electrical energy, the second cutting edge 122 starts to cut the tissue while contacting the tissue, and the conductive electrode 100 is introduced into the tissue to conduct conductivity. Both sides of the electrode 100 are in contact with the tissue. Since high-frequency electrical energy is supplied only to the second wall 123 of the second blade 120, which is one side of the conductive electrode 100, the Burns and carbonization can be reduced, and smog hardly occurs.

As shown in FIG. 8, since insulation is made by the anodizing coating layer 102 formed on the surface of the conductive electrode 100, most of the high-frequency electrical energy is supplied only to the second edge part 122, so the structure by the second wall 123 Burns and carbonization hardly occurs.

As described above, if the operation is performed while the high frequency electric energy is supplied only to the second blade 120, the speed at which the conductive electrode 100 cuts, cuts or cauterizes tissues and tissues is reduced, but burns or carbonization of the tissues is hardly caused. No smog occurs, and precise surgery is possible.

In addition, when the operation is performed in a state where high-frequency electrical energy is supplied only to the second blade 120 as described above, most of the high-frequency electrical energy cuts the tissue through the second cutting edge 122, and a portion of the high-frequency electrical energy is Since it flows into the tissue through the wall 123, the current density is high, so that the tissue can be easily cut with a small high frequency electric energy.

Therefore, as described above, if the operation is performed in a state in which high-frequency electric energy is supplied only to the second blade 120, excessive incision, resection, or cauterization is prevented, so that even an unskilled surgeon can perform precise electric surgery.

In addition, even a skilled surgeon can perform a precise operation if the operation is performed in a state in which high-frequency electrical energy is supplied only to the second blade 120, so that fatigue during surgery can be reduced.

When high frequency electric energy is supplied to both the first and second blades 110 and 120

When performing general surgery (fast and incision, ablation, or cauterization of many tissues), the operation button 33 is operated to supply high-frequency electrical energy to both the first blade 110 and the second blade 120. Conduct.

When the conductive electrode 100 approaches the tissue while supplying high-frequency electrical energy to both the first and second blades 110 and 120 of the conductive electrode 100, the second blade 120 is in contact with the tissue, thereby generating high-frequency electrical energy. As a result, the tissue incision is started, and the first blade 110, which is supplied with high-frequency electrical energy while following the second blade 120, is introduced into the tissue, thereby cutting the tissue in a fast and wide range.

At this time, while the first blade 110 is incomplete contact with the tissue, an arc is generated, and some tissue is burned or carbonized to generate smog, but rapid electrosurgery is possible using the first and second blades 110 and 120.

Since the ceramic coating layer 103 is formed on the surfaces of the first and second blades 110 and 120 of the present invention, even if the tissue is adhered to the blade, it is possible to easily and conveniently wipe the tissue adhered to the blade and continue the operation.

As described above, in the conductive electrode 100 of the present invention, the second blade 120 and the first blade 110 are stacked and fastened in a vertical direction, and one side of the first blade 110 extends downward. Since the January 113 and the second wall 123 extending upward on one side of the second blade 120 are connected while being in contact, the first blade 110 and the second blade 120 have excellent fastening strength. The first and second blades 110 and 120 are not separated by an external force during a process or surgery, but are firmly fastened.

In addition, since the contact area with the tissue is reduced during the pickling process, the current density is high, so that the tissue can be effectively incised even with small high-frequency electric energy, and the occurrence of smog is minimized because burns and carbonization of the tissue hardly occur.

In the above-described embodiment of the present invention, the conductive electrode 100 is formed of aluminum, and the first blade 110 and the second blade 120 are vertically formed with the anodizing coating layer 102 and the ceramic coating layer 103, respectively. Although it was constructed by stacking, the conductive electrode 100 was not divided into the first blade 110 and the second blade 120, but one blade was formed using aluminum as a material, and each of the blades was 30 μm to 50 μm. The conductive electrode 100 is formed by forming an anodizing coating layer 102 having a thickness (preferably 40 μm thick), and forming a ceramic coating layer 103 having a thickness of 20 μm to 40 μm (preferably 30 μm thick). May be.

If the conductive electrode 100 is configured with one blade, microsurgery and general surgery cannot be selected, but due to insulation of the anodizing coating layer 102 formed on both sides of the blade, the current density of the cutting edge that substantially cuts the tissue can be increased. Therefore, smooth tissue incision is possible with little high-frequency electric energy.

In addition, the ceramic coating layer 103 formed on the blade prevents the tissue from sticking to the blade during surgery, and the stuck tissue can be easily wiped off.

The technical idea of the present invention has been described through the above-described embodiments.

It is apparent that those of ordinary skill in the art to which the present invention pertains can variously modify or change the above-described embodiments from the description of the present invention.

In addition, even if not explicitly shown or described, a person of ordinary skill in the technical field to which the present invention pertains can make various modifications including the technical idea according to the present invention from the description of the present invention. Is self-evident, which still belongs to the scope of the present invention.

The above embodiments described with reference to the accompanying drawings have been described for the purpose of describing the present invention, and the scope of the present invention is not limited to these embodiments.

10: electric surgical instruments
20: control unit
30: Handpiece
31: cable
32: case
33: operation button
34: holder
35: control unit
40: ground pad
41: cable
100: conductive electrode
101: adhesive
102: anodizing coating layer
103: ceramic coating layer
110: first blade
111: first plug
112: first cutting edge
113: 1st month
114: first seating portion
115: stopper
120: second blade
121: second plug
122: second cutting edge
123: 2nd month
124: second seating portion
125: stopper

Claims (8)

In the conductive electrode fastened to the handpiece 30 used in monopolar electrosurgery,
A first blade 110 having a first wall 113 extending downward on one side and a second blade 120 having a second wall 123 extending upwardly on one side are vertically stacked and fastened. , A blade configured to be fastened so that the first and second walls 113 and 123 are in contact with each other in the lateral direction;
Cutting edges formed at the upper and lower ends of the blade;
An anodizing coating layer 102 formed by anodizing the surface of the blade excluding the edge portion; And
A conductive electrode for electrosurgical handpiece comprising: a ceramic coating layer 103 formed by coating a ceramic on the surface of the anodizing coating layer 102.
delete delete The method of claim 1,
A first seating portion 114 formed on one side of the first wall 113; And a second seating portion 124 formed on one side of the second wall 123; by being formed, the lower end of the first wall 113 is in contact with the second seating portion 124, and Conductive electrode for electrosurgical handpiece, characterized in that the upper end is fastened so as to contact the first mounting portion (114).
The method of claim 1,
The anodizing coating layer 102 is a conductive electrode for electrosurgical handpiece, characterized in that formed to a thickness of 20㎛ 50㎛.
The method of claim 1,
The ceramic coating layer 103 is a conductive electrode for electrosurgical handpiece, characterized in that formed to a thickness of 10㎛ to 40㎛.
The method of claim 1,
A first plug 111 in which the rear end of the first blade 110 is formed in an extended shape and inserted into and fastened to the handpiece 30;
Conductive electrosurgical handpiece, characterized in that it further comprises a second plug 121 that is formed in an extended form and inserted into and fastened to the handpiece 30 at the rear end of the second blade 120 electrode.
The method of claim 1,
Conductive electrode for electrosurgical handpiece, characterized in that the protruding stopper is formed at the upper and lower ends of the blade.

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