KR102021266B1 - Electrogurgical handpiece - Google Patents

Abstract

The present invention relates to an electrosurgical handpiece capable of performing various surgeries, which comprises: a conductive electrode (120) which includes first and second blades (122, 124) and a gap (A); a division angle (α) at which line lengths of the first and second blades (122, 124) are differentially formed; and a control unit (114) which includes an operation button (105) and a selection lever (106).

Description

Electrosurgical Handpiece {Electrogurgical handpiece}

The present invention relates to an electrosurgical handpiece, and in particular, the blade of the conductive electrode is divided, the electrosurgical handpiece that can be performed by selecting a general surgery and fine microsurgery as in the conventional electrosurgical handpiece. It is about.

Iron surgical scalpels must be injured only at the time of incision to ensure a clean incision. However, iron scalpels have no coagulation effect. In other words, the tissue is bleeding until the end of the incision or the area is naturally solidified.

Electrosurgical (Electrosurgery) is a surgical method that uses a high frequency (radio frequency) electrical energy to incision, excision or cauterization of the tissue of the patient.

Intracellular vibrations are generated by the high frequency electrical energy supplied through the electrodes, thereby increasing the intracellular temperature and heating the tissue.

Cell death occurs when the cell temperature reaches about 60 ° C, and drying (dehydration) and protein coagulation of the tissue proceeds when heated to 60 ~ 99 ° C. Volume expansion and evaporation of the cell when the cell temperature reaches 100 ° C And in this process tissue is cut or cauterized.

Such electrosurgery includes a control unit 10 for generating a high frequency electric current as shown in FIG. 1 for cutting and coagulation of the tissue, and a hand piece 100 for cutting, cutting and cauterizing the tissue using the high frequency electrical energy. In this case, the incision using the electrosurgical device generates heat in the incision of the tissue by the high frequency electric current, resulting in a significant coagulation effect.

However, electrosurgical incision inevitably results in the destruction of the air insulation layer due to incomplete contact between the conductive electrode and the tissue, resulting in an arc with high heat, which burns the tissue, and burns the tissue. And the blade is contaminated.

In addition, the carbonization of the tissue by the arc generates smog (smog) as shown in Figure 1, which is known to adversely affect the health of the doctor and the patient.

(Document 1) Republic of Korea Patent Office Publication No. 10-1566766, "Medical Handpiece" (Document 2) Korean Patent Office Publication No. 10-2016-0087288, "Precision blade electrosurgical instrument" (Document 3) Republic of Korea Patent Publication No. 10-0818730, "Surgical handpiece with a surgical blade" (Document 4) Korean Patent Office Publication No. 10-2017-0135823, "Tapered precision blade electrosurgical instrument"

The present invention has been made to solve the above problems, can be used to select a general surgical electrosurgical and microelectrosurgery, less contamination on the conductive electrode, reduce the burn of the patient, the smog generation It is an object of the present invention to provide an electrosurgical handpiece that can be minimized.

In order to achieve the above object, the electrosurgical handpiece according to the present invention is a handpiece used for electrosurgical (Electrosurgery), the first blade 122 formed in the form of a plate of a conductive material, and the conductive material A conductive electrode 120 composed of a second blade 124 formed in the form of a furnace plate and a gap A formed between the first and second blades 122 and 124 so that the first and second blades 122 and 124 are spaced apart by a predetermined interval. ; And a connector 108 electrically connecting the conductive electrode 120 and the cable 103 to each other. High-frequency electric energy introduced through the cable 103 to the conductive electrode 120, the operation button 105, and the high frequency to the first blade 122 or the second blade 124 of the conductive electrode 120 And a control unit 114 composed of a selection lever 106 for selectively connecting electrical energy.

At this time, the connector 108 is formed in a dried form so that the film of the thin film is overlapped so that the connector 108 is elastically deformed and conductive when the slide is moved or rotated with respect to the case 101 of the hand piece 100 It is characterized in that the electrode 120 and the cable 103 is configured to be electrically connected.

In addition, the rear end of the first blade 122 is formed in an extended form, the first plug 121 to be inserted and fastened to the hand piece 100 and the rear end of the second blade 124 is extended Molded to be characterized in that it further comprises a second plug 123 is inserted, fastened to the hand piece 100.

In addition, the front end portion of the gap A is characterized in that the divided angle α is inclined with a predetermined angle and the axial line of the conductive electrode 120 is formed.

In addition, the dividing angle (α) is characterized in that more than 0 ° and 120 ° or less.

In addition, the first blade 122 and the second blade 124 is coated with an insulating material so that the first blade 122 and the second blade 124 is configured to be insulated and fixed while maintaining a gap (A). It is done.

In addition, the selection lever 106 has a mode for conducting high frequency electric energy to all the divided blades, another mode for conducting high frequency electric energy only to the blades in a direction in which the splitting angle α is inclined, and the splitting angle α. Is configured to select another mode of conducting high frequency electrical energy only to the blade in the opposite direction to which it is tilted.

The handpiece of the present invention configured as described above divides the conductive electrode 120 for cutting, cutting or cauterizing the tissue into the first blade 122 and the second blade 124, thereby making the first, Both blades 122 and 124 conduct high frequency electrical energy to conduct high frequency electrical energy, or conduct high frequency electrical energy only to the first blade 122 or second blade 124 to enable fine and precise electrosurgical operation. This is possible.

In addition, fine electrosurgical operation is possible, thereby reducing the tension of the surgeon, thereby reducing the fatigue of the doctor.

In addition, when performing microsurgery using the handpiece 100 of the present invention, contamination of the conductive electrode and burn of the patient can be reduced, and smog that does not adversely affect the health of the patient and the patient is not generated.

1 is a diagram illustrating a configuration of an electrosurgical instrument.
2 is a perspective view showing a hand piece according to the present invention.
Figure 3 is an exploded perspective view showing the exploded hand piece according to the present invention.
Figure 4 is a perspective view showing the movement of the conductive electrode of the handpiece according to the present invention.
5 is a perspective view showing a state in which the conductive electrode is detached from the hand piece according to the present invention.
Figure 6 is a perspective view showing a conductive electrode fastened to the hand piece according to the present invention.
7 is a view illustrating a state in which a coating layer and an insulator are removed from a conductive electrode.
8 is a view illustrating electrical connection of a conductive electrode and a control unit.
9 is a view showing a state of performing microelectrosurgery with the hand piece of the present invention.
10 is a view showing a state in which the general electrosurgery with the handpiece of the present invention.
11 is a view showing a state in which a split angle is formed at a tip of a conductive electrode;
12 is a view showing a selection lever formed on the control panel of the hand piece according to the present invention.

Hereinafter, with reference to the preferred embodiments of the present invention and the accompanying drawings will be described in detail, the same reference numerals in the drawings will be described on the assumption that the same components.

When any one element in the description or claims of the invention "includes" another element, unless otherwise stated, it is not limited to consisting only of that element, and other elements are not interpreted. It should be understood that it may include more.

Electrosurgical instruments are configured to cut, ablate or cauterize tissue using high frequency electrical energy. The handpiece 100 of the present invention is a monopolar (Monopolar) control unit for generating high frequency electrical energy as shown in FIG. 10) and the handpiece 100 to cut, ablate or cauterize tissue with the high frequency electric energy generated by the control unit 10 by holding a gongdo, and the body of the patient is grounded high frequency electric energy control unit 10 It is composed of a ground pad 12 to return to.

In the hand piece 100 according to the present invention, as shown in FIGS. 2 and 3, a case 101 is formed in a pipe shape having a space formed therein, and a pipe-shaped operation is performed in the case 101. The rod 111 is inserted.

The connecting bar 107 is inserted into the operating rod 111, and the connecting bar 107 is inserted into the holder 112 of the operating rod 111 to the insertion hole 113 in a state where the connecting bar 107 is inserted into the operating rod 111. When the conductive electrode 120 is inserted, the first plug 121 and the second plug 123 of the conductive electrode 120 are inserted into the tip of the connection bar 107.

In the rear of the connection bar 107, the thin film film is rolled up so that the connecting body 108 is fastened. The connecting bar 107 allows the conductive electrode 120 and the connecting body 108 to be electrically connected to each other. .

The operating rod 111 into which the connecting bar 107 is inserted is inserted into the case 101, and the connecting body 108 is electrically connected to the cable 103.

A collet 102 is radially formed at the front end of the case 101. When the fixing nut 109 is fastened to the front end of the case 101 while the operating rod 111 is inserted into the case 101 as described above. The fixing nut 109 compresses the collet 102 and the operating rod 111 is fastened and fixed to the case 101.

As the operating rod 111 is fastened to the case 101, a portion of the operating rod 111 protrudes toward the front of the case 101 to expose the conductive electrode 120 as shown in FIG. 2.

And a control panel 104 is installed on the outer surface of the case 101 is configured to control the hand piece 100.

The control panel 104 has an operation button 105 for supplying or blocking high frequency electric energy to the conductive electrode 120, and a selection lever 106 for selectively supplying high frequency electric energy to the divided blades of the conductive electrode 120. ) Is formed.

In the hand piece 100 of the present invention configured as described above, as shown in FIG. 4, when the fixing nut 109 is rotated and released, the operating rod 111 can slide in the axial direction, and the rotation is based on the axis. It is possible.

When the gynecologist performs electrosurgical operation, the operating rod 111 is drawn out or inserted and rotated according to the treatment conditions, thereby adjusting the direction and depth of the conductive electrode 120 and locking the fixing nut 109.

As described above, the conductive electrode 120 is electrically connected to the connection 108 through the connection bar 107 inside the operating rod 111, the connector 108 is a cable at the rear of the case 101 Is connected to the 103, the electrical connection between the conductive electrode 120 and the cable 103 while the connecting body 108 is elastically deformed when the operating rod 111 slides and rotates in the case 101 as described above Keep it.

The connecting body 108 is formed in a dried form such that the thin film is superimposed as shown in Figure 3, when the operating rod 111 slides in the case 101, the overlapped film of the connection 108 is coil spring While maintaining the electrical connection between the conductive electrode 120 and the cable 103 while elastically deformed, and when the operating rod 111 is rotated, the film of the connection 108 is loosened or dried further and the conductive electrode 120 and the cable Maintain an electrical connection of the 103.

As shown in FIG. 6, the first electrode 121 and the second plug 123 formed at the rear of the conductive electrode 120 may be inserted into the front holder 112 of the handpiece 100. The high frequency electric energy generated by the control unit 10 and inserted into the 113 is supplied through the cable 103, the connecting body 108, and the connecting bar 107.

Surgery is performed by high frequency electrical energy delivered to the conductive electrode 120. The conductive electrode 120 is shaped into a long plate to facilitate cutting, ablation, and ablation of the tissue. In particular, the incision of the tissue has a long plate shape. It is made by the corner part of the electrode.

As shown in FIGS. 6 and 7, the conductive electrode 120 according to the present invention is formed in a shape in which the first plug 121 is extended to the rear of the first blade 122 formed in a plate shape of a conductive metal material. The second plug 123 is formed to extend behind the second blade 124 formed in a plate shape of a conductive metal material.

The first blade 122 and the second blade 124 are spaced apart from each other to have a predetermined gap A as shown in FIG. 7.

As described above, the front of the first blade 122 and the second blade 124 spaced to have a predetermined gap A as described above is coated with a coating material of ceramic material to form a coating layer 125 as shown in FIG. The blade 122 allows the second blade 124 to be fixed while maintaining a predetermined gap A.

Insulation between the first blade 122 and the second blade 124 is maintained by the coating layer 125.

The rear of the first and second blades 122 and 124 on which the coating layer 125 is formed surrounds the insulator 126 so that the conductive electrode 120 is inserted into the holder 112 insertion hole 113 of the hand piece 100 as shown in FIG. 2. It is preferable that the first and second blades 101 and 103 are not exposed when they are inserted.

As described above, the conductive electrode 120 divided into the first and second blades 122 and 124 is inserted into the holder 112 and the insertion hole 113 of the hand piece 100 to be fastened and fixed to the hand piece 100. When the conductive electrode 120 is inserted into the holder 112 insertion hole 113 of the hand piece 100, the first plug 121 and the second plug 123 are the controllers of the hand piece 100 as shown in FIG. 8. Electrically connected with 114.

The control unit 114 is composed of an operation button 105 and a selection lever 106 formed in the case 101 of the hand piece 100, as shown in Figure 2, the operation button 105 in the control unit 10 The high frequency electrical energy is generated to supply or block the conductive electrode 120, and the selector 106 transmits the high frequency electrical energy supplied to the conductive electrode 120 to the first blade 122 and the second blade 124. It can be configured to supply selectively).

The selection lever 106 may select a 'NOR' mode and a 'MICRO' mode. In the 'NOR' mode, high frequency electric energy is supplied to both the first blade 122 and the second blade 124, and the 'MICRO' is selected. In the mode, high frequency electric energy is supplied only to the first blade 122.

The first blade 122 of the conductive electrode 120 according to the present invention is a part in which the gynecologist first contacts the tissue when gripping the handpiece 100 and the second blade 124 is the first blade. It is the portion that enters the tissue along the blade 122.

When the gynecologist puts the selection lever 106 of the hand piece 100 in the 'MICRO' mode and presses the operation button 105 of the hand piece 100, the high frequency electric energy is supplied to the conductive electrode 120. High frequency electrical energy is supplied only to the first blade 122 of the 120 and the high frequency electrical energy is not supplied to the second blade 124.

In this state, when the conduit approaches the conductive electrode 120 to the tissue, as shown in FIG. 9, the first blade 122 is first contacted with the tissue, and the tissue is cut by the high frequency electric energy.

Since the second blade 124 following the first blade 122 proceeding with cutting tissue is not supplied with high-frequency electrical energy in the 'MICRO' mode, the arc does not occur even if the second blade 124 is incompletely contacted with the tissue. In addition, since arcing does not occur, the tissue is not carbonized or burned, and smog does not occur.

As described above, when electrosurgical operation is performed in the 'MICRO' mode using the conductive electrode 120, the first blade 122 is in close contact with the tissue, and the second blade 124 is not supplied with high frequency electric energy. Since the state does not generate an arc during operation as shown in Figure 9, the tissue is not carbonized or burned, and smog does not occur.

As described above, when the selection lever 106 of the hand piece 100 is operated in the 'MICRO' mode, the conductive electrode 120 reduces the rate of cutting, cutting, or cauterization of the tissue. Precise surgery is possible using little high frequency electrical energy without generating smog and without smog.

Therefore, when an operation is performed using the conductive electrode 120, excessive incision, ablation, or cauterization is prevented using only the first blade 122, so that unskilled aggregation can be precisely performed by electrosurgery.

In addition, even a skilled gynecologist can use the 'MICRO' mode to supply high-frequency electrical energy only to the first blade 122, so that precise surgery is possible, thereby reducing fatigue during surgery.

When performing general electrosurgical operation (fast, incision, ablation or cauterization of many tissues), the selector 106 of the handpiece 100 is placed in 'NOR' mode and the operation button 105 of the handpiece 100 is released. When pressed, high frequency electrical energy is supplied to both the first blade 122 and the second blade 124 of the conductive electrode 120.

In this state, when the concentrator approaches the conductive electrode 120 to the tissue, as shown in FIG. 10, as the first blade 122 contacts the tissue, incision of the tissue is started by high frequency electric energy, and the conductive electrode 120 is started. As the second blade 124 entering the tissue and following the first blade 122 is introduced into the tissue, the tissue is incised quickly and in a wide range.

At this time, the first blade 122 is cut in a state of being completely in contact with the tissue, while the second blade 124 is incompletely in contact with the tissue, so an arc occurs to generate smog as shown in FIG. The first and second blades 122 and 124 can be used for fast electrosurgery.

As described above, the conductive electrode 120 is configured by separating the first blade 122 and the second blade 124 into a predetermined gap A. As shown in FIG. 11, the front ends of the first and second blades 122 and 124 are separated from each other. It is preferable that the gap A is formed to be inclined at a predetermined angle with the longitudinal axis of the first and second blades 122 and 124.

Hereinafter, the angle at which the tip gap A of the first and second blades 122 and 124 is inclined is referred to as a 'division angle α'.

Since the portion where the conductive electrode 120 contacts the tissue first during the electrosurgery is the first blade 122, the splitting angle α formed at the tip of the first and second blades 122 and 124 as described above is in the direction of the first blade 122. It is formed to be inclined at inclination angle exceeding 0˚ and below 120˚.

By forming the inclined splitting angle α in the tip gap A of the first and second blades 122 and 124 as described above, the cutting edge length (blade length of the blade) of the first blade 122 is adjusted so that 'MICRO' More precise and finer operations are possible in this mode.

When the dividing angle α is 120 °, the cutting edge length of the first blade 122 is shorter than when the dividing angle α is 0 °, so the dividing angle α is smaller than when the dividing angle α is 0 °. When the 120˚ is more fine precision surgery is possible.

When the splitting angle α is 0 °, since the cutting edge length of the first blade 122 is not meaningful, the splitting angle α may be molded to exceed 0 °.

In addition, since the general angle between the conductive electrode 120 and the tissue is 120 ° when the surgeon grips the handpiece 100 and operates, the division angle α is preferably molded to be 120 ° or less.

As described above, when the gap A of the tip of the first and second blades 122 and 124 is formed to be inclined at a predetermined angle with the longitudinal axis line of the first and second blades 122 and 124, the above-described 'MICRO' In addition to the 'mode and the' NOR 'mode, the' MEDIUM 'mode may be driven in the selection lever 106 as shown in FIG. 12.

The 'MEDIUM' mode is configured to supply high frequency electric energy only to the second blade 124 and not to supply high frequency electric energy to the first blade 122.

When the chief physician puts the selection lever 106 of the handpiece 100 in the 'MEDIUM' mode and presses the operation button 105 of the handpiece 100, high frequency electric energy is supplied only to the second blade 124 and the first The blade 122 is not supplied with high frequency electric energy.

In the 'MEDIUM' mode, the second blade 124 is first in contact with the tissue, and the first blade 122 is introduced into the tissue following the second blade 124.

As described above, since the dividing angle α is formed to be inclined in the direction of the first blade 122, the cutting edge of the second blade 124 is longer than the cutting edge of the first blade 122.

Accordingly, the 'MEDIUM' mode in which the second blade 124 having a longer edge than the first blade 122 contacts the tissue first than the 'MICRO' mode in which the first blade 122 having the shortest edge contacts the tissue first. Incision, ablation or cauterization of tissues is nearly as fast as in 'NOR' mode.

In addition, since the high-frequency electrical energy is not supplied to the first blade 122 following the second blade 124 when the electrosurgical operation is performed in the 'MEDIUM' mode, an arc occurs even when the first blade 122 is incompletely contacted with the tissue. In addition, since arcing does not occur, the tissue does not generate carbonization or burns and does not generate smog.

That is, when the handpiece 100 is operated in the 'MEDIUM' mode as described above, the conduction electrode 120 is almost as fast as the 'NOR' mode and the incision, ablation or cauterization of the tissue is almost similar. Precise surgery is possible without carbonization or burns and without smog.

The conductive electrode 120 of the present invention configured as described above is divided into a first blade 122 and a second blade 124, thereby conducting high frequency electric energy to both the first and second blades 122 and 124 according to the treatment conditions. General electrosurgery may be performed, or microsurgery may be performed by conducting high frequency electric energy only to the first blade 122 or the second blade 124.

In addition, fine and precise electrosurgical operation is possible by conducting high frequency electric energy only to the first blade 122 or the second blade 124, thereby reducing the tension of the collector and thus reducing the fatigue of the doctor.

In addition, it is possible to reduce the contamination of the blade and the burn of the patient during micro-surgery, and does not generate smog that adversely affects the health of the patient and the surgeon.

Although the above-described embodiment of the present invention is configured to match a monopolar electric circuit, the conductive electrode 120 may be configured to match a bipolar.

The technical spirit of the present invention has been described through the above-described embodiment.

It will be apparent to those skilled in the art that the present invention may be variously modified or changed from the description of the present invention.

In addition, even if not explicitly shown or described, those skilled in the art to which the present invention pertains various modifications, including the technical idea according to the present invention from the description of the present invention. Is obvious, and still belongs to the scope of the present invention.

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

10: control unit
11: cable
12: grounding pad
100: hand piece
101: case
102: collet
103: cable
104: control panel
105: operation button
106: Selection lever
107: connecting bar
108: connector
109: fixing nut
111: Operation Button
112: holder
113: insertion hole
114: control unit
120: conductive electrode
121: the first plug
122: first blade
123: second plug
124: second blade
125: coating layer
126: insulator
A: gap
α: dividing angle

Claims (7)

In a hand piece used for monopolar electrosurgical operation including a ground pad 12 and a high frequency control unit 10,
A first blade 122 formed of a conductive material in the form of a plate, a second blade 124 formed of a conductive material in the form of a plate and positioned on the same plane as the first blade 122, and the first, A conductive electrode 120 having a gap A formed between the first and second blades 122 and 124 and the same plane so that the two blades 122 and 124 are spaced apart from each other by a predetermined distance;
A splitting angle (α) for differently forming the cutting edge lengths of the first blade 122 and the second blade 124 by inclining the tip portion of the gap A from an axis of the gap A; And
A connector 108 for electrically connecting the conductive electrode 120 and the cable 103;
High-frequency electric energy introduced through the cable 103 to the conductive electrode 120, the operation button 105, and the high frequency to the first blade 122 or the second blade 124 of the conductive electrode 120 Hand control for electrosurgical, characterized in that it comprises a; control unit 114 consisting of a selection lever 106 for selectively connecting electrical energy.
The method of claim 1,
The connector 108,
When the film of the thin film is formed into a dried form so as to slide the slide or move relative to the case 101 of the hand piece 100, the connecting body 108 is elastically deformed and the conductive electrode 120 and the cable 103 Electrosurgical hand piece, characterized in that configured to be electrically connected.
The method of claim 1,
A first plug 121 formed at an extended end of the first blade 122 and inserted into and fastened to the hand piece 100;
The rear end of the second blade 124 is formed in an extended form, the hand piece for electrosurgical, characterized in that it further comprises a second plug 123 is inserted, fastened to the hand piece (100).
delete The method of claim 1,
The division angle (α) is an electrosurgical hand piece, characterized in that more than 0 ° and less than 120 °.
The method of claim 1,
The first blade 122 and the second blade 124 is coated with an insulating material, characterized in that the first blade 122 and the second blade 124 is configured to be insulated and fixed while maintaining a gap (A) Electrosurgical handpieces.
The method of claim 1,
The selection lever 106 is,
A mode for conducting high frequency electrical energy to all divided blades,
Another mode for conducting high frequency electric energy only to the blade in a direction in which the splitting angle α is inclined,
An electrosurgical hand piece, characterized in that it is configured to select another mode of conducting high frequency electrical energy only to the blade in the opposite direction in which the splitting angle α is inclined.

Images