KR20220044689A - A Trocar for Improving a Property of a Tool Movement - Google Patents

Abstract

The present invention relates to a trocar with a tool fluidity improvement structure. The trocar includes a cannula and a needle. The cannula includes: a receiving body (11) formed in a structure which decreases in diameter as going downward; an induction pipe (12) extending from a lower end of the receiving body (11) in a hollow tube shape; a discharge portion (121) formed at an end of the induction pipe (12) and having a relatively small diameter compared to other portions; and a gas induction unit (13) coupled to a lower part of the receiving body (11) to enable gas flow with the induction pipe (12).

Description

A Trocar for Improving a Property of a Tool Movement

The present invention relates to a trocar having a structure for improving tool fluidity, and more particularly, to a trocar having a structure for improving tool fluidity so that the fluidity of a surgical tool injected through a cannula is improved.

A trocar composed of an obturator made of metal or synthetic resin and a cannula having a hollow tube structure is applied to laparoscopic surgery, and various structures are known in the art. For example, Patent Publication No. 10-2014-0097814 discloses a trocar assembly in which convenience of use can be achieved while allowing a laparoscopic surgical instrument to be inserted at an accurate position. In addition, Patent Registration No. 10-1268705 discloses a laparoscopic trocar capable of preventing gas leakage while maintaining close contact with an elastic member in the process of inserting or withdrawing surgical tools having different sizes. The laparoscopic trocar needs to be structurally stable and easy to handle during surgery. For example, it is advantageous if the needle needle has a structure such that slipping can be prevented. At the same time, it is necessary to have a structure in which a field of view is secured while being inserted into the human body for surgery, so that the surgical tool can flow in various directions. However, the prior art does not disclose a trocar having such a structure.

The present invention is to solve the problems of the prior art and has the following objects.

Patent Document 1: Patent Publication No. 10-2014-0097814 (Sejong Medical Co., Ltd., published on August 07, 2014) Trocar assembly Patent Document 2: Patent Registration No. 10-1268705 (Han Hee-sang, Announced on May 28, 2013) Laparoscopic Trocar

It is an object of the present invention to provide a trocar having a structure for improving tool fluidity, which is structurally stable and has a field of view during a surgical procedure so that it can flow in various directions.

According to a suitable embodiment of the present invention, the cannula for the trocar consisting of a cannula and a trocar includes a receiving body formed in a structure in which the diameter decreases while going downward; a guide tube extending in the form of a hollow tube from the lower end of the receiving body; While forming at the end of the guide tube, the discharge portion having a relatively small diameter compared to other portions; and a gas induction unit coupled to a lower portion of the receiving body to enable gas flow with the guide tube.

According to another suitable embodiment of the present invention, a discharging tip extending to the same diameter is formed at the end of the discharging section.

According to another suitable embodiment of the present invention, it includes an induction unit and a sealing unit coupled to each other while being accommodated in the accommodation body, wherein the induction unit and the sealing unit are fixed by the protrusion and the groove.

In the trocar according to the present invention, the lower end of the cannula has a flat shape, so that the field of view is secured in various directions during the surgical procedure, so that the surgical tools can flow in various directions. In the trocar according to the present invention, the induction unit and the sealing unit for induction of trocar needle are firmly coupled to prevent leakage occurring during the flow of the tool. In addition, the trocar according to the present invention has the advantage of being easy to handle because the upper part is made of a multi-layer structure in which the upper part is separated from each other and stacked. In addition, in the trocar according to the present invention, the gas injection unit is formed integrally with the cannula, so that the gas injection is performed stably while structurally simple.

1 shows an embodiment of a cannula forming a trocar having a structure for improving tool fluidity according to the present invention.
Figure 2 shows an embodiment of the body cover and the sealing structure forming the trocar according to the present invention.
Figure 3 shows an embodiment of the overall coupling structure of the trocar according to the present invention.

Hereinafter, the present invention will be described in detail with reference to the embodiments shown in the accompanying drawings, but the embodiments are for a clear understanding of the present invention, and the present invention is not limited thereto. In the following description, components having the same reference numerals in different drawings have similar functions, so unless necessary for the understanding of the invention, the description will not be repeated and well-known components will be briefly described or omitted, but the present invention It should not be construed as being excluded from the embodiment of

1 shows an embodiment of a cannula forming a trocar having a structure for improving tool fluidity according to the present invention.

Referring to Figure 1, the trocar can be made of a cannula and a trocar guided into the human body by the cannula, the receiving body 11 is formed in a structure in which the diameter decreases as going downward; a guide tube 12 extending from the lower end of the receiving body 11 in a hollow tube shape; While being formed at the end of the guide tube 12, the discharge portion 121 having a relatively small diameter compared to other portions; and a gas induction unit 13 coupled to a lower portion of the receiving body 11 to enable gas flow with the guide tube 12 .

A part of the cannula is located outside the human body, and the other part is located inside the human body, so that the cannula has a function of guiding surgical tools, including trocar needles, into the human body. The trocar or surgical tool may be introduced into the receiving body 11 and guided by the guide tube 12 to be guided into the body through the discharge portion 121 . The accommodating body 11 may have a structure in which an accommodating space is formed therein, and a diameter decreases while going downward. The lower portion of the receiving body 11 may have a funnel shape, and the guide tube 12 may be integrally coupled to the end of the funnel shape. The guide tube 12 may extend in a hollow tube shape having a circular cross section, and may have a structure in which the diameter decreases in the discharge portion 121 after being extended while having a constant diameter. The discharge site 121 is formed at the lower end of the guide tube 12 and may be a portion through which the trocar needle or surgical tool is discharged to the outside, for example, 1/100 to 1 of the total length of the guide tube 12 . It can be, but is not limited to, /5. The discharge portion 121 may be formed integrally with the guide tube 12 and have a smaller diameter as a whole, and the end of the discharge portion 121 may have a circular or ring shape positioned on a plane. And the end of the discharge portion 121 may be 9/10 to 99/100 of the diameter of the guide tube 12, but is not limited thereto. As described above, when the discharge portion 121 having a relatively small diameter is formed at the end of the guide tube 12 to stably fix the needle needle or surgical tool, the fluidity increases in the surgical process. In addition, since it becomes a circle or ring shape located on the plane of the discharge site 121, a view in all directions is secured, so that the degree of freedom of flow is increased, and surgical stability can be improved. Optionally, the discharge tip 122 corresponding to the end of the discharge portion 121 may have a circular ring shape having a circular cross section in a direction perpendicular to the circumferential direction. This structure prevents damage to the area in contact with the discharge tip 122 in the course of surgery, while improving adhesion to the outer peripheral surface of the penetrating or surgical tool. The discharge portion 121 may be made of various structures to widen the field of view during the surgical procedure, and is not limited to the presented embodiment.

The gas induction unit 13 may be coupled to one side of the accommodation body 11 , and the gas induction unit 13 may be formed integrally with the accommodation body 11 or may be independently made and coupled. The gas induction unit 13 may be firmly coupled to the lower side of the receiving body 11 . A gas supply means for supplying or discharging gas may be connected to one side of the gas induction unit 13 . The gas injected through the gas induction unit 13 may be guided into the human body through the receiving body 11 and the induction tube 12 . In addition, the gas inside the human body may also be discharged to the outside through the gas induction unit 13 via the receiving body (11). The gas induction unit 13 may be formed in various structures and is not limited to the presented embodiment. The guide tube 12 may include a locking protrusion portion 14 having a plurality of locking protrusions formed therein, and a plurality of locking protrusion groups 14_1 to 14_K may be formed in the locking protrusion portion 14 . Each of the locking projection groups 14_1 to 14_K may include a plurality of locking projections formed in a circle along the outer circumferential surface of the guide tube 12 . In addition, the different locking protrusion groups 14_1 to 14_K may be formed to be separated from each other along the extension direction of the guide tube 12 . By such a locking protrusion structure, it is possible to prevent damage to the jammed part while stably maintaining the jammed state. A cover is coupled to the upper portion of the accommodation body 11 , and sealing means for preventing gas leakage may be disposed inside the accommodation body 11 .

Figure 2 shows an embodiment of the body cover and sealing structure forming the trocar according to the present invention.

Referring to FIG. 2 , it includes an induction unit and a sealing unit coupled to each other while being accommodated in a receiving body, and the induction unit and the sealing unit are fixed by protrusions 262a and 262b and circular grooves 282a and 282b. The body cover may be coupled to the upper portion of the receiving body, and the body cover may be independently made and coupled to the upper portion of the receiving body. The body cover may be made of the same or similar synthetic resin material as the accommodation body, and after the induction unit and the sealing unit are disposed inside the accommodation body, they may be coupled to each other by an ultrasonic bonding method. For example, an adhesive layer may be formed on the upper edge of the receiving body and the lower edge of the body cover, and ultrasonic waves may be applied to the adhesive layer in a state in which they are in close contact with each other to adhere to each other. The receiving body and the body cover may be firmly adhered to each other in various ways and are not limited to the presented embodiment. The body cover has a cylindrical shape as a whole and a circumferential wall 21 that increases in diameter toward the bottom; an input face 22 formed on the upper face of the circumferential wall 21; an induction tube 23 extending in the form of a hollow tube from the lower center of the input surface 22; And it includes a pair of fastening holes (24a, 24b) formed in the edge portion of the input surface (22). The input surface 22 may consist of a horizontal edge surface extending inward from the upper edge of the peripheral wall 21 and an input guide part extending downwardly from the horizontal edge surface in a concave shape. A pair of fastening holes 24a and 24b to which the fixing protrusions formed on the penetrator are coupled may be formed at positions facing each other on the horizontal edge surface. And the input guide portion extends downward in the shape of a fallopian tube, the guide tube 23 may extend to a length protruding downward of the peripheral wall 21 from the end of the introduction guide portion. Optionally, a reinforcing circumferential wall 211 may be formed in a shape surrounding the input guide portion in a cylindrical shape between the horizontal edge surface and the input guide portion. The sealing unit is disposed inside the accommodating body, and the induction unit may be coupled to the sealing unit in a form in which the lower part is accommodated in the sealing unit. The induction unit includes an induction vane 26; an extension portion 261 extending downwardly from the guide vane 26; an induction cylinder 25 extending in a cylindrical shape from the extension portion 261; and a guide tip 251 extending in a conical shape from the guide cylinder 25 . The induction vane 26 may have a plate shape with an induction hole formed therein, and the induction cylinder 25 has a smaller diameter than the outer diameter of the induction vane 26 and is formed by the extension portion 261. 26) can be connected. The guide tip 251 may extend from the end of the guide cylinder 25 , and may have a relatively large elasticity by having a smaller thickness than the guide cylinder 25 . For example, the guide tip 251 may be made of a structure that gradually becomes thinner toward the end, and the end portion may be in close contact with the circumferential surface of the trocar needle or surgical tool guided thereby. The sealing unit may be made of the same or similar material to the induction unit, and specifically, the induction unit and the sealing unit may be made of a synthetic resin material having great elasticity and a large coefficient of friction at the same time. The sealing unit includes a sealing rim 28 on which the guide vanes 26 are overlapped from above; While extending in a cylindrical shape downward from the sealing rim 28, the induction cylinder 25 is accommodated therein the receiving tube 27; and a sealing cap 29 extending from the lower side of the receiving tube 27 . The sealing cap 29 may be formed of a pair of sealing blades extending while facing each other to form a linear sealing inlet 291 at the end.

According to one embodiment of the present invention, the induction unit and the sealing unit may be fixed by the projections (262a, 262b) and the grooves (282a, 282b). A contact plane 263 having a lower height than that of the circumferential portion of the guide vane 26 may be formed inside the guide vane 26 , and located at a position opposite to each other under the circumferential portion of the guide vane 26 . A pair of coupling protrusions 262a and 262b may be formed. In addition, a separation rim 281 may be formed at the lower portion of the sealing rim 28 while being separated from the accommodating tube 27 and the outer circumferential surface and enclosing it. In addition, a pair of receiving grooves 282a and 282b to which a pair of coupling protrusions 262a and 262b are coupled may be formed on the sealing edge 28 corresponding to the upper portion of the separation edge 281 . Both the induction unit and the sealing unit may be made of a material having elasticity or elasticity, and the coupling protrusions 262a and 262b and the receiving grooves 282a and 282b may be coupled to each other by elasticity or elasticity. Thereby, while the induction unit and the sealing unit are closely coupled to each other, the induction cylinder 25 may flow independently of the sealing edge 28 by the separating rim 28 . The induction unit and the sealing unit may be coupled to each other in various ways and are not limited to the embodiments presented. The basal needle may be guided into the interior of the induction unit and an embodiment of the trocar needle will be described below.

Figure 3 shows an embodiment of the overall coupling structure of the trocar according to the present invention.

Referring to the left side of FIG. 3 , the penetrating needle has a linear member shape with a circular cross section and is inserted into the guide tube 12 via the guide unit disposed inside the accommodation body 11 so that the tip protrudes to the outside It may consist of a trocar head 32 coupled to one end of the induction needle 31 and the induction needle 31 . The trocar head 32 may have a structure in which a plurality of plates are separated from each other and arranged in a vertical direction. Specifically, the trocar head 32 includes a first separating plate 32_1 to which one end of the induction needle 31 is coupled to the center; a second separating plate separated from the first separating plate and disposed above the second separating plate having a larger diameter than that of the first separating plate; and a plurality of separation plates 32_N whose diameters are gradually reduced while being separated from each other on the upper portion of the second separation plate, and the trocar head 32 may have a hemispherical shape as a whole. By such a structure, the handling convenience can be improved while slipping is prevented in the handling process of the needle needle. Fixing protrusions 33a and 33b that are coupled to the fastening hole of the receiving body 11 and extend linearly to limit the movement of the penetrating needle may be formed on the lower surface of the first separating plate 32_1. When the sealing unit and the induction unit are disposed inside the accommodation body 11, the body cover 15 is coupled to the accommodation body 11 by, for example, ultrasonic bonding, so that the sealing unit and the induction unit are stably fixed. can Thereafter, the needle needle is inserted into the guide tube 12 from the top of the body cover 15 , and the end of the guide needle 31 may be discharged to the outside through the lower end of the guide tube 12 . The gas generated inside the human body during the operation may be guided to the gas induction unit 13 through the guide tube 12 and discharged to the outside. The needle needle may be made in various structures and is not limited to the presented embodiment.

In the trocar according to the present invention, the lower end of the cannula has a flat shape, so that the field of view is secured in various directions during the surgical procedure, so that the surgical tools can flow in various directions. In the trocar according to the present invention, the induction unit and the sealing unit for induction of trocar needle are firmly coupled to prevent leakage occurring during the flow of the tool. In addition, the trocar according to the present invention has the advantage of being easy to handle because the upper part is made of a multi-layer structure in which the upper part is separated from each other and stacked. In addition, in the trocar according to the present invention, the gas injection unit is formed integrally with the cannula, so that the gas injection is performed stably while structurally simple.

Although the present invention has been described in detail with reference to the presented embodiment, those skilled in the art will be able to make various modifications and variations of the invention without departing from the technical spirit of the present invention with reference to the presented embodiment. . The present invention is not limited by such variations and modifications, but only by the claims appended hereto.

11: receiving body 12: guide tube
13: air guiding unit 14: locking protrusion
21: circumferential wall 22: input side
23: guide tube 24a, 24b: fastening hole
25: induction cylinder 26: induction vane
121: ejection area 122: ejection tip
211: reinforcement perimeter wall 262a, 262b: projection
282a, 282b: home

Claims (3)

In the trocar consisting of a cannula and a trocar,
the cannula
The receiving body 11 is formed in a structure in which the diameter decreases while going downward;
Induction tube 12 extending from the lower end of the receiving body 11 in the form of a hollow tube;
While being formed at the end of the guide tube 12, the discharge portion 121 having a relatively small diameter compared to other portions; and
Consists of a gas induction unit 13 coupled to a lower portion of the receiving body 11 to enable gas flow with an induction tube 12,
Further comprising an induction unit coupled to the sealing unit in a form in which the lower portion is accommodated in the sealing unit and the sealing unit disposed inside the receiving body 11,
The induction unit includes an induction vane 26; an extension portion 261 extending downwardly from the guide vane 26; an induction cylinder 25 extending in a cylindrical shape from the extension portion 261; and a guide tip (251) extending in a conical shape from the guide cylinder (25),
The sealing unit includes a sealing rim 28 on which the guide vanes 26 are overlapped from above; While extending in a cylindrical shape downward from the sealing rim 28, the induction cylinder 25 is accommodated therein the receiving tube 27; and a closure cap (29) extending from the underside of the receiving tube (27);
and a pair of engaging projections 262a and 262b formed at positions opposite to each other under the circumferential portion of the induction vane 26 of the induction unit, and a receiving tube 27 under the sealing rim 28 of the sealing unit. and a pair of receiving grooves (282a, 282b) formed in the upper portion of the separation rim 281 formed in the form of enclosing while being separated from the outer circumferential surface,
The induction unit and the sealing unit are made of a material having elasticity or elasticity, and the coupling protrusions 262a, 262b and the receiving grooves 282a, 282b are coupled to each other by elasticity or elasticity,
A trocar having a structure for improving tool fluidity, characterized in that a discharging tip 122 extending with the same diameter is formed at the end of the discharging portion 121 . The trocar of claim 1, further comprising a plurality of locking protrusion groups (14_1 to 14_K) formed on the circumferential surface of the guide tube (12). The trocar of claim 1, further comprising a body cover coupled to the receiving body (11).

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