RU147904U1 - ELECTROSURGICAL BIPOLAR TWEEZERS-DISSECTOR (OPTIONS) - Google Patents

Abstract

1. Electrosurgical bipolar forceps-dissector, comprising two jaws electrically isolated from each other, made of conductive material having high thermal conductivity, characterized in that the working end of one of the jaws contains a longitudinal dielectric insert of high-strength non-stick material, representing a blade thickness 0, 6 ± 0.1 mm, extending along the entire length of the working part of one of the branches and having an angle of sharpening of the cutting edge in the range of 65-75 °. 2. The tweezers-dissector according to claim 1, characterized in that the longitudinal dielectric insert is made of nanostructured partially stabilized zirconia. 3. A tweezers-dissector according to claim 1, characterized in that a corrosion-resistant protective coating of rhodium 0.5-2.5 microns thick is applied to the working ends of the tweezers-dissector. 4. Electrosurgical bipolar forceps-dissector, including two jaws electrically isolated from each other, made of conductive material having high thermal conductivity, characterized in that the working end of one of the jaws contains a longitudinal dielectric insert of high-strength non-stick material, which is a plate thickness of 0.6 ± 0.1 mm with a smooth surface with rounded ribs running along the entire length of the working part of one of the branches. 5. A forceps dissector according to claim 4, characterized in that the longitudinal dielectric insert is made of nanostructured partially stabilized zirconia. The tweezers-dissector according to claim 4, characterized in that a corrosion-resistant protective coating of p�� is applied to the working ends of the tweezers-dissector

Description

Electrosurgical bipolar forceps-dissector refers to medical electrosurgical instruments and can be used in surgical operations for dissection and simultaneous coagulation of biological tissues and blood vessels.

The closest to the proposed tweezers-dissector is an electrosurgical bipolar tweezers, including two jaws electrically isolated from each other, made of conductive material with high thermal conductivity (see http://dialite.com.ua/p9716193-prinadlezhnosti-dlya-bipolyarnoj. html, published July 4, 2013). The disadvantages of this tool include:

1) the formation of carbon deposits on the working surfaces of the branches of the tweezers;

2) lag of coagulation from tissue dissection.

The technical result of this utility model is to improve the operational characteristics of the electrosurgical bipolar forceps-dissector by providing the ability to simultaneously ensure dissection and electrocoagulation of biological tissue and improve non-stick properties.

The specified technical result is achieved in that in an electrosurgical bipolar forceps-dissector, comprising two jaws electrically isolated from each other, made of conductive material having high thermal conductivity, the working end of one of the jaws contains on the inner surface a longitudinal dielectric insert made of high-strength non-stick material, representing a blade with a thickness of 0.6 ± 0.1 mm, extending along the entire length of the working part of one of the branches and having an angle of sharpening the cutting edge and in the range of 65-75 °.

The specified technical result is achieved in that in an electrosurgical bipolar forceps-dissector, comprising two jaws electrically isolated from each other, made of conductive material having high thermal conductivity, the working end of one of the jaws contains on the inner surface a longitudinal dielectric insert made of high-strength non-stick material, representing a plate 0.6 ± 0.1 mm thick with a smooth surface with rounded ribs running along the entire length of the working part th of jaws

The specified technical result is also achieved by the fact that the longitudinal dielectric insert is made of nanostructured partially stabilized zirconia.

The specified technical result is also achieved by the fact that the working ends of the tweezers-dissector are equipped with a corrosion-resistant protective coating of rhodium with a thickness of 0.5-2.5 microns.

The essence of the utility model is illustrated in FIG. 1-2

In FIG. 1 shows the proposed tweezers-dissector (option 1).

In FIG. 2 shows the proposed tweezers-dissector (option 2).

In FIG. 1-2 show the options of the proposed electrosurgical bipolar forceps-dissector and used together with the forceps, a high-frequency current generator and a connecting electric cable, where 1 is the jaw, 2 is the proximal end of the jaw, 3 is the working ends of the jaw, 4 is the current input electrode, 5 is the coating based on rhodium, 6 — insert of nanostructured partially stabilized zirconia, 7 — connecting cable, 8 — high-frequency current generator.

The proposed electrosurgical bipolar forceps-dissector (option 1, Fig. 1) consists of two branches 1 made of conductive material with high thermal conductivity, the proximal ends 2 of which are structurally combined with electrodes for inputting electric current 4. Moreover, the working ends isolated from each other 3 branches 1, on which a layer of rhodium 5 is applied, are active bipolar electrodes. Insert 6 extends along the entire length of the working part of one of the jaws in the form of a blade made of nanostructured partially stabilized zirconium dioxide (NFCS) with a thickness of 0.6 ± 0.1 mm and a sharpening angle in the range of (65-75) °. This ensures optimal compression force of the jaws and minimal injuries in the process of dissection of biological tissue. The electrodes 4 are connected via cable 7 to the generator 6.

The proposed electrosurgical bipolar forceps-dissector (option 2. Fig. 2) consists of two branches 1 made of conductive material with high thermal conductivity, the proximal ends 2 of which are structurally combined with electrodes for inputting electric current 4. Moreover, the working ends 3 isolated from each other branch 1, on which a layer of rhodium 5 is applied, are active bipolar electrodes. Insert 6 in the form of a plate of crystalline nanostructured partially stabilized zirconium dioxide (NFCS) with a thickness of 0.6 ± 0.1 mm with a smooth surface with rounded edges extends along the entire length of the working part of one of the branches. The electrodes 4 are connected via cable 7 to the generator 8.

The proposed tweezers-dissector works as follows.

The high-frequency voltage from the RF generator 8 is supplied through cable 7 to the current input electrodes 4, structurally integrated with the proximal ends of the jaw 1. Moreover, the working ends of the jaws isolated from each other are active bipolar electrodes. The high-frequency current supplied to the instrument flows between the contact points of the rhodium-coated electrodes with the biological tissue. Coating the working ends of 3 tweezers with a layer of rhodium 5 improves their anticorrosion properties. Insert 6 of the NFSCe, depending on its shape, provides for dissection or compression of the biological tissue.

The proposed tweezers-dissector (options 1 and 2) contains two insulated jaws made of conductive material with high thermal conductivity, thereby reducing the likelihood of thermal injury to biological tissue and burning tissue due to reduced heating of the working surfaces of the branches of the tweezers-dissector due to the high speed of removal heat.

The insert in the tweezers-dissector (option 1) has a cutting edge protruding 1.0 ± 0.5 mm above the surface of the working part. In the dissection mode, the biotissue layer undergoes bipolar coagulation, and with further compression of the branches, it intersects. The force of information of the branches of the tweezers-dissector (option 1) is determined by the dimensions of the spring part of the branches and is 4.0 ± 0.5 H

The insert in the tweezers-dissector (option 2) is made in the form of a plate with a smooth surface and rounded ribs. In the coagulation mode, the insert presses on the layer of biological tissue, which ensures the displacement of blood from the coagulated vessel and an increase in the strength of the coagulation compound. The low adhesion of the biological tissue to the surface of the insert from NFSCC allows the use of tweezers-dissector to perform a number of sequential manipulations of surgical access for a long time and for a considerable length. The force of information of the branches of the tweezers-dissector (option 2) is determined by the size of the springy part of the branches and is 3.0 ± 0.5 H.

High-frequency current flows between the points of contact of the electrodes coated with rhodium, with biological tissue. Coating the working ends 3 of the tweezers with a layer of rhodium 5 provides an improvement in their anticorrosion properties.

Claims (6)

1. Electrosurgical bipolar forceps-dissector, comprising two jaws electrically isolated from each other, made of conductive material having high thermal conductivity, characterized in that the working end of one of the jaws contains a longitudinal dielectric insert of high-strength non-stick material, representing a blade thickness 0, 6 ± 0.1 mm extending along the entire length of the working part of one of the branches and having a cutting edge sharpening angle in the range of 65-75 °. 2. The tweezers-dissector according to claim 1, characterized in that the longitudinal dielectric insert is made of nanostructured partially stabilized zirconia. 3. The tweezers-dissector according to claim 1, characterized in that on the working ends of the tweezers-dissector a corrosion-resistant protective coating of rhodium is applied with a thickness of 0.5-2.5 microns. 4. Electrosurgical bipolar forceps-dissector, comprising two jaws electrically isolated from each other, made of conductive material having high thermal conductivity, characterized in that the working end of one of the jaws contains a longitudinal dielectric insert of high-strength non-stick material, which is a plate thickness 0, 6 ± 0.1 mm with a smooth surface with rounded ribs running along the entire length of the working part of one of the branches. 5. The tweezers-dissector according to claim 4, characterized in that the longitudinal dielectric insert is made of nanostructured partially stabilized zirconia. 6. The tweezers-dissector according to claim 4, characterized in that on the working ends of the tweezers-dissector a corrosion-resistant protective coating of rhodium is applied with a thickness of 0.5-2.5 microns.

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