KR102502904B1 - A Troca Having a Safety of Regulating a Gas Injection - Google Patents

Abstract

The present invention relates to a trocar with improved gas flow control stability. The trocar with improved gas inlet control stability includes an inlet body 11 in which an induction cylinder 12 is formed; An inlet unit 13 formed to be connected to the inside of the inlet body 11; A flow unit 16 coupled to the inlet unit 13 and forming an inlet or outlet passage of gas; A valve 15 coupled to the flow unit 14 to open and close the gas flow path; and fixing means 14a to 14d for fixing the valve 15 to a fixed position, wherein the fixing means 14a to 14d fix the valve 15 to the fixed position in the open or closed state of the flow path.

Description

Troca having a safety of regulating a gas injection {A Troca Having a Safety of Regulating a Gas Injection}

The present invention relates to a trocar with improved gas inflow control stability, and more particularly, to a trocar with improved gas inflow control stability that allows a stable gas injection blocking state to be maintained.

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 that allows a laparoscopic surgical instrument to be inserted into an accurate position while providing convenience in use. In addition, Patent Registration No. 10-1268705 discloses a laparoscopic trocar that is in close contact with an elastic member in the process of retracting or withdrawing surgical tools having different sizes to maintain airtightness and prevent leakage of gas. During surgery, gas may be injected into the human body through the trocar, or gas may be blocked from being injected into the human body. When the opening/closing control valve is rotated due to various reasons in a state in which gas injection is blocked, gas may be injected into the human body in an unexpected state. It is therefore necessary to create means to prevent such unintended actuation of the valve. However, the prior art does not disclose such means.

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

Prior Art 1: Patent Publication No. 10-2014-0097814 (Sejong Medical Co., Ltd., published on August 7, 2014) trocar assembly Prior art 2: Patent Registration No. 10-1268705 (Han Hee-sang, published on May 28, 2013) Laparoscopic trocar

An object of the present invention relates to a trocar with improved stability of gas inlet control with improved operational stability of a valve controlling gas injection.

According to a preferred embodiment of the present invention, a trocar having improved gas flow control stability includes an inlet body having an induction cylinder; An inlet unit formed to be connected to the inside of the inlet body; a flow unit coupled to the inflow unit to form an inflow or outflow passage of gas; A valve coupled to the flow unit to open and close the gas flow path; and a fixing means for fixing the valve to the fixed position, wherein the fixing means fixes the valve to the fixed position in the open or closed state of the flow path.

According to another preferred embodiment of the present invention, the fixing means is a magnetic coupling means or engagement locking means formed on the outer surfaces of the valve and inlet body.

According to another preferred embodiment of the present invention, the permeation unit coupled to the inlet body includes a permeation needle; a combination head formed on the upper part of the penetrating needle; a cap coupled to the coupling head; and a fastening unit coupled to the cap.

In the trocar with improved gas inflow control stability according to the present invention, the valve is stably fixed in a state in which gas injection is blocked to prevent gas from being injected into the human body in an unintended state or from reversing the gas inside the trocar. do. The trocar according to the present invention has a simple assembly structure and improved usability.

1 shows an embodiment of a trocar with improved gas flow control stability according to the present invention.
Figure 2 shows an embodiment of the overall assembly structure of the trocar according to the present invention.
3 illustrates an embodiment of a sealing article applied to a trocar according to the present invention.
4 shows an embodiment to which the trocar according to the present invention is applied.

Below, the present invention will be described in detail with reference to the embodiments presented 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 repeated descriptions are not made unless necessary for understanding the invention, and well-known components are briefly described or omitted, but the present invention It should not be understood as being excluded from the embodiment of.

1 shows an embodiment of a trocar with improved gas flow control stability according to the present invention.

Referring to FIG. 1, the trocar with improved gas flow control stability includes an inlet body 11 having an induction cylinder 12; An inlet unit 13 formed to be connected to the inside of the inlet body 11; A flow unit 16 coupled to the inlet unit 13 and forming an inflow or discharge passage of gas; a valve 15 coupled to the flow unit 14 to open and close the flow path of gas; and the valve 15 at a predetermined position. and fixing means 14a to 14d for fixing the valve 15 to a predetermined position in the open or closed state of the flow path.

The trocar may consist of a cannula and an obturator, and for example, the cannula may have a function of forming a hole in the abdomen for guiding a surgical tool into the human body by inserting the cannula. . In addition, a camera unit or similar image acquisition means may be guided by the trocar during the formation of a hole or during a surgical procedure. The trocar may have various structures capable of guiding various surgical instruments into the human body. The cannula may include a hemispherical inlet body 11 having an accommodation space formed therein, and an induction cylinder 12 extending from the inlet body 11 into a hollow circular tube shape. Gas may flow into the inlet body 11 and be injected into the human body, or may be introduced from the inside of the human body to the inlet body 11 via the induction cylinder 12 . An inlet unit 13 for gas flow may be coupled to the inlet body 11 , and a part of the inlet unit 13 may protrude outside the inlet body 11 . The flow unit 16 may be coupled to the inlet unit 13, and the flow unit 16 may be connected to a gas supply tank that is installed outside and supplies gas. The flow unit 16 has a hollow cylinder shape, at least one side of which is open, the flow body 161; A connecting tube 162 coupled in a form penetrating in a direction perpendicular to the flow body 161; and a fixing unit 163 formed at one end of the connection tube 162 and coupled to the inlet body 11 . The flow unit 16 can be coupled to the inlet body 11 by the fixing unit 163, and a connector that can be coupled to the flow tube connected to the gas supply tank can be coupled to the other end of the connection tube 162. Gas supplied from the gas supply tank may be guided into the inlet body 11 through the connection tube 162 . In addition, the flow of gas guided to the connection tube 162 may be controlled by the valve 15 . The valve 15 may have a structure capable of being coupled to the flow unit 16, and may have a function of opening and closing a flow path formed in the induction unit 16. The valve 15 includes a valve body 151 coupled to the flow body 161 so as to be rotatably inserted therein; An adjustment tab 152 coupled to an upper portion of the valve body 151 to rotate the valve body 151; and a flow hole 153 formed in a shape penetrating the valve body 151 and connected to the flow path of the connection tube 162 . The valve body 151 may have a cylindrical shape extending in a vertical direction, and the control tab 152 may have a structure extending in a direction perpendicular to the valve body 151 while being integrally formed with the valve body 151. can By rotating the valve body 151 clockwise or counterclockwise, the flow hole 153 can be rotated to open and close the gas flow path. For example, when the control tap 152 is rotated in one direction and one part of the control tap 152 comes into contact with the outer circumferential surface of the inlet body 11, the flow of gas may be blocked. As such, when the control tap 152 is rotated in the opposite direction in a state in which the flow of gas is blocked, gas may flow again. In the process of performing surgery in a state in which the flow of gas is blocked, the control tab 152 may be unintentionally rotated, thereby causing gas to flow. Alternatively, although the control tap 152 is rotated to block gas flow, the control tap 152 is not rotated at a predetermined angle, and gas may leak due to this. Fixing means (14a, 14b, 14c, 14d) are disposed on the inlet body 11 and the control tab 152 according to one embodiment of the present invention, such that the rotation or incomplete locking of the control tab 152 is not intended. Accordingly, leakage of gas can be prevented. The fixing means (14a, 14b, 14c, 14d), for example, the fixing means (14a to 14d) is a magnetic coupling means (14a, 14b) formed on the outer surface of the valve 15 and the inlet body 11 or fastening locking means (14c, 14d) can be. The magnetic coupling means 14a and 14b may include first and second magnetic bodies 14a and 14b formed on the outer circumferential surface of the inlet body 11 and the end of the control tab 152 . The first and second magnetic materials 14a and 14b may each have a pad shape, and may be disposed at positions where they can come into contact with each other by rotation of the adjusting tab 152 . The first and second magnetic bodies 14a and 14b may be formed on the outer circumferential surface of the inlet body 11 or the control tab 152 or disposed inside. The first and second magnetic bodies 14a and 14b can be formed in various positions where they can be coupled to each other by the rotation of the control tab 152, and the shape or arrangement of the first and second magnetic bodies 14a and 14b according to the present invention is not limited

The fastening locking means 14c and 14d can be rotated by engaging units 14c or hook units 14d formed on the end portion 152a of the inlet body 11 or the adjusting tab 152 that can be engaged with each other. For example, the engaging unit 14c may be shaped like a groove having elasticity, and the hook unit 14d may be shaped like a protrusion that can be inserted into and coupled to the shaped groove. Alternatively, the hooking unit 14c may have a pair of clamps facing each other, and the hook unit 14d may have a linear protrusion structure with a convex front portion inserted into or separated from the clamps facing each other. The fixing means 14a to 14d may have various structures and are not limited to the presented embodiments. Optionally, a locking protrusion 154 may be formed on the valve 15 to allow the control tab 152 to remain open. For example, the upper portion of the valve body 151 may have a cylindrical shape having a larger diameter than the lower portion due to the coupling of the control tab 152 . In addition, a fastening protrusion 154 may be formed at a position facing the extended position of the adjusting tab 152 . A spherical coupling ball may be formed at the end of the fastening protrusion 154 or another appropriate engaging means may be formed so that the control tab 152 is stably maintained in an open state. The fastening protrusion 154 may have various structures and is not limited to the presented embodiment.

Figure 2 shows an embodiment of the overall assembly structure of the trocar according to the present invention.

Referring to FIG. 2, the penetration unit coupled to the inlet body 11 includes a penetration needle 22; a coupling head 23 formed on the upper part of the penetrating needle 22; a cap 24 coupled to the coupling head 23; and a fastening unit 26 coupled to the cap 24. The trocar may consist of a cannula and a penetration unit, and the cannula includes an inlet body 11; an induction cylinder 12 extending downward of the inlet body 11; inlet unit 13); and a fixing unit 14a, and a cover unit is coupled to an upper portion of the inlet body 11 to seal the upper portion of the inlet body 11. The permeation unit can be inserted from the top of the cover unit, and the permeation unit becomes a hollow tube shape that is guided into the induction cylinder 12 and is coupled to the permeation needle 22 having a sharp end and the upper part of the permeation needle 22. It may include a combined head 23. A circular contact edge 231 may be formed at the boundary between the penetrating needle 22 and the coupling head 23, and the coupling head 23 may have a half-cylindrical shape with one side open. The hemispherical cap 24 may be coupled in a form in which the coupling head 23 is accommodated, and protruding grooves 241 may be formed at positions of the cap 24 facing each other. The handle 25 may be coupled to the inside of the cap 24, and the fastening unit 26 is coupled to the coupling head 23 so that the handling portion 261 protrudes to the outside through the protruding groove 241. It can be fixed between (26) and the coupling head (23). The fastening unit 26 may have a curved strip shape and be symmetrical with respect to a hole formed in the center. Fastening hooks 262 are formed at both ends of the fastening unit 26 and can be detachably coupled to fastening holes formed in the cover unit. A handle 25 may be coupled to an open portion of one side of the coupling head 23, and a part of the handle 25 protrudes to the outside of the cap 24 to improve the handling convenience of the penetration unit. The inlet body 11 and the cover unit may be separable structures, and the cover unit may be separated from the inlet body 11 by, for example, a separation ring 27 . A rotation tab 271 may be formed on the separation ring 27, and by rotation of the rotation tab 271, the cover unit may be coupled to the inlet body 11 to be locked or unlocked and separated. . A sealing product is disposed inside the inflow body 11 to prevent external gas from leaking while the penetrating needle 22 or a similar surgical tool is inserted.

3 shows an embodiment of a sealing article 30 applied to a trocar according to the present invention.

Referring to FIG. 3 , the sealing article 30 includes a cylindrical sealing body 31; a pair of sealing wings 32a and 32b extending in a concave lens shape in directions facing each other from the sealing body 31; An opening and closing sling 33 extending in a linear horizontal direction at a point where the extensions of the sealing wings 32a and 32b meet each other; and a pair of linear elastic protrusions 35a and 35b formed on inner surfaces of each of the sealing wings 32a and 32b, respectively. A fixed edge 311 may be formed along the upper edge of the sealing body 31, and a protruding edge 312 is formed in a direction in which the sealing body 31 extends in a direction perpendicular to the fixed edge 311. It can be. Each of the linear elastic protrusions 35a and 35b may extend linearly along the extending direction of each of the sealing wings 32a and 32b. Shape maintaining protrusions 34a and 34b may be formed at positions corresponding to the middle portions of the separation gap formed by the pair of extending linear elastic protrusions 35a and 35b. The shape-retaining protrusions 34a and 34b may be formed at positions where the sealing wings 32a and 32b are formed from the sealing body 31, and have a gradually thinner shape, for example, each sealing wing. It may be formed with a length of 1/10 to 1/2 of the extension length of the center line of (32a, 32b). The sealing article 30 may be formed in various structures and is not limited to the presented embodiments.

4 shows an embodiment to which the trocar according to the present invention is applied.

Referring to FIG. 4, the cover unit 41 may be coupled to the separation ring 27 above the inlet body 11, the penetration unit may be introduced above the cover unit 41, and the penetration needle 22 ) is guided through the induction cylinder 12 so that the tip of the penetrating needle 22 protrudes to the outside of the induction cylinder 12. The cap 24 may be coupled to or separated from the cover unit 41 by the fastening hook 262 . A hole may be formed in the abdomen by the tip of the penetrating needle 22, and gas may be introduced into the human body through the flow unit 16 while the valve 15 is opened in this process. Then, when a hole is formed in the abdomen, gas injection may be stopped, and for this purpose, the valve 15 may be maintained in a closed state. And, as described above, the valve 15 may be secured by a fixing means so as to remain locked. The trocar may have a variety of structures and is not limited to the examples presented.

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

11: inlet body 12: induction cylinder
13: intake unit 14a, 14b: fixing means
15: valve 16: flow unit
22: impregnation 23: combined head
24: cap 26: fastening unit

Claims (3)

In the trocar for a surgical tool,
an inlet body 11 in which an induction cylinder 12 is formed;
An inlet unit 13 formed to be connected to the inside of the inlet body 11;
A flow unit 16 coupled to the inlet unit 13 and forming an inlet or outlet passage of gas;
A valve 15 coupled to the flow unit 14 to open and close the gas flow path; and
It includes fixing means (14a to 14d) for fixing the valve 15 in a predetermined position,
The fixing means 14a to 14d fix the valve 15 to a predetermined position in the open or closed state of the flow path,
The valve 15 includes a valve body 151 coupled to the flow unit 16 so as to be rotatably inserted therein; An adjustment tab 152 coupled to an upper portion of the valve body 151 to rotate the valve body 151; A flow hole 153 formed in a shape penetrating the valve body 151 and connected to the flow path of the connecting tube 162; and a fastening protrusion 154 formed at a position facing the extended position of the control tab 152 so that the control tab 152 is maintained in an open state,
The fixing means (14a to 14d) are magnetic coupling means (14a, 14b) formed at the end of the control tab 152 and the outer surface of the inlet body 11 and coupled to each other by rotation of the control tab 152, or A trocar with improved gas flow control stability, characterized in that it becomes the fastening locking means (14c, 14d). delete The method according to claim 1, wherein the permeation unit coupled to the inlet body (11) includes a permeation needle (22); a coupling head 23 formed on the upper part of the penetrating needle 22; a cap 24 coupled to the coupling head 23; and a fastening unit (26) coupled to the cap (24).

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