KR20190030290A - A Trocar Having a Structure of Preventing an End Part Being Drawn - Google Patents

Abstract

The present invention relates to a trocar having a structure of preventing an end part from being drawn and, more specifically, to a trocar having a structure of preventing an end part from being drawn, which prevents an end part of a sealing tube arranged therein from being drawn and pulled with a mechanism. The trocar having the structure of preventing an end part from being drawn comprises: a housing (11) having a holding space therein; an inflow path unit (15) extended from a lower side of the housing (11); an inflow adjustment unit (13) coupled to a side surface of the housing (11); an induction tube (17) arranged within the housing (11) and having a deformation preventing part (174) formed with a curved tilted structure having at least two different radii of curvature; and a contact tube (16) held within the induction tube (17) and having a cylindrical contact body (161) and a tilted part (162) extended as radius gets smaller from a contact body (161).

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a trocar having an end portion,

The present invention relates to a trocar having an end pull-out preventing structure, and more particularly, to a trocar having an end pull-out preventing structure in which an end portion of a sealing tube disposed therein is prevented from pulling up together with a tool.

Trocar, consisting of a cannula of hollow or tubular structure, made of metal or synthetic resin, is applied to laparoscopic surgery, and various structures are known in the art. For example, U.S. Patent Publication No. 10-2014-0097814 discloses a trocar assembly that allows ease of use while permitting a laparoscopic surgical instrument to be inserted in a precise location. Also, Patent Registration No. 10-1268705 discloses a laparoscopic trocar which is in close contact with an elastic member during insertion or withdrawal of surgical instruments having different sizes to keep the airtight and prevent leakage of gas.

Through the trocar, various surgical instruments including a foot can be inserted into the human body, and a gas such as carbon dioxide, for example, can be injected into the human body. Therefore, the trocar must have an airtight function while allowing the use of surgical instruments, and at the same time, it must be prevented from entering the sealing means or similar passages during the entrance and exit of surgical instruments. However, the prior art does not disclose a trocar having such a structure.

The present invention has been made to solve the problems of the prior art and has the following purpose.

Prior Art 1: Patent Publication No. 10-2014-0097814 (Sejong Medical Co., Ltd., published on August 07, 2014) Trocar Assembly Prior Art 2: Patent Registration No. 10-1268705 (Han Hee Sang, Notice of May 28, 2013) Laparoscopic Trocar

An object of the present invention is to provide a double-tube structure in which the end portion of the surgical instrument is prevented from being pulled in or pulled out during the entrance and exit of the surgical tool while exhibiting a high sealing function during the use of the surgical tool, Car.

According to a preferred embodiment of the present invention, a trocar having an end pull-out preventing structure includes: a housing having a receiving space formed therein; An inflow unit extending from the underside of the housing; An inflow control unit coupled to the side of the housing; An induction tube disposed inside the housing and formed with a deformation preventing portion formed of a curved surface inclined structure having at least two different radii of curvature; And a contact tube comprised of a cylindrical contact body received in the interior of the guide tube and an inclined portion extending in a radial direction from the contact body.

According to another preferred embodiment of the present invention, a rounded anti-curling rim is formed at the end of the inclined portion.

According to another preferred embodiment of the present invention, there is further provided an induction limiting hole formed in the interior of the induction tube, the induction limiting hole having a cylinder-shaped uniform area and a needle-like connection area.

The trocar according to the present invention has a double tube structure having elasticity to seal the entry and exit passage, thereby enhancing the sealing function. The trocars according to the present invention are provided with a curling-preventing edge at the end of the path along which the surgical tool is contacted in the closed path, thereby preventing the end portion of the path from being pulled out during the entrance and exit of the surgical tool. This also improves the airtightness of the trocar.

Figures 1a and 1b show an embodiment of a trocar according to the invention.
Fig. 2 shows an embodiment of a housing and an operating lever applied to a trocar according to the present invention.
Figure 3 shows an embodiment of an inner contact tube applied to a trocar according to the invention.
Figure 4 shows an embodiment of a guide tube applied to a trocar according to the invention.
5 shows an embodiment of the internal coupling structure of a trocar according to the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the present invention will be described in detail with reference to the embodiments shown in the accompanying drawings, but the present invention is not limited thereto. In the following description, components having the same reference numerals in different drawings have similar functions, so that they will not be described repeatedly unless necessary for an understanding of the invention, and the known components will be briefly described or omitted. However, It should not be understood as being excluded from the embodiment of Fig.

Figures 1a and 1b show an embodiment of a trocar according to the invention.

1A and 1B, a trocar having an end pulling-preventing structure includes a housing 11 having a housing space formed therein; An inflow path unit 15 extending from the lower side of the housing 11; An inflow control unit (13) coupled to a side surface of the housing (11); A guide tube 17 disposed inside the housing 11 and formed with a deformation preventing portion 174 having a curved surface inclined portion having at least two different radii of curvature; And a contact tube 16 comprised of a cylindrical contact body 161 received in the interior of the guide tube 17 and a sloped portion 162 extending radially from the contact body 161.

The housing 11 may have a structure in which the upper surface as a whole is opened, the lower surface is opened, and the lower portion is hemispherical. Further, a receiving space may be formed inside the housing 11, and a detachable cover 12 may be coupled to the upper portion. The inflow path unit 15 having the insertion path connected to the inside of the housing 11 may be integrally formed with the housing 11. [ An inlet hole may be formed at the center of the lid 12 to be connected to the inside of the housing 11 and the inlet hole may be connected to the insertion path formed in the inlet unit 15. And through the inflow hole and the insertion path, the foot (OB) or various surgical or medical devices can be inserted and operated.

An inflow adjusting unit 13 coupled with the operating lever 14 may be formed on one side of the housing 11. [ The inflow adjusting unit 13 may have a function of injecting carbon dioxide or the like into the human body during a surgical procedure and may include a connection tab 131 connected to an external supply tank. The gas injected into the inflow adjusting unit 13 can be adjusted by the operating lever 14 and is rotated right and left around a point where the operating lever 14 is engaged with the inflow adjusting unit 13, Inflow can be controlled. The inflow control unit 13 may be manufactured and coupled independently of the housing 11, but may be integrally formed with the housing 11 preferably.

1B, a hollow tube-shaped connection pipe 121 extending inwardly of the housing 11 may be formed on the inner side of the lid 12, (Not shown). A guide tube 17 can be disposed inside the housing 11 and a contact tube 16 can be disposed inside the guide tube 17. [ The induction tube 17 has a cylindrical induction body 171; A fixing frame 173 is formed on the upper surface of the induction body 171 so as to be disposed inside the housing 11 while forming an outer frame and an intermediate portion having a smaller radius along the extending direction of the induction body 171 And a connecting portion 172 connected to the inflow path unit 15 as an intermediate portion may be formed. The deformation preventing portion 174 having a curved surface inclination structure having different curvature radii may be formed in the connecting portion 172.

The deformation preventing portion 174 may be formed by making an inner concave circular structure so that both side surfaces of the cylinder shape face each other, and the circular concave portion may be formed in an inclined structure. Concretely, at least two curved surfaces having a convex shape concave inward in both directions with respect to the diameter of one side of the cylinder shape, or at least two curved structures having different curvature radii or inclination levels in a circular shape may be connected. The deformation preventing portion 174 prevents the position of the surgical tool from being displaced due to the movement of the surgical tool inserted in the surgical procedure. Specifically, the deformation preventing portion 174 can be maintained in a predetermined shape, whereby the surgical tool can be fixed at a predetermined position. The deformation-preventing portion 174 can be made in various structures and is not limited to the illustrated embodiment.

The contact tube 16 may be disposed inside the guide tube 17 and the contact tube 16 may include a cylindrical contact body 161, a contact receiving portion 163 formed at one portion of the contact body 161 A contact fixing portion 164 having an outer rim shape having a relatively large radius while being connected to the contact receiving portion 163 and an inclined portion 162 formed on the other side of the contact body 161.

The coupling tube 121 formed in the lid 12 is positioned at the upper portion of the slope portion 162 in the engaged state so that the sealing performance can be improved while at the same time the surgical tool is withdrawn for replacement with another surgical tool, Thereby preventing the portion 162 from being pulled upward.

The contact tube 16 can be placed inside the guide tube 17 and the contact tube 16 and guide tube 17 can be moved in such a way that the contact fastening portion 164 overlaps above the fastening rim 173. [ Can be combined with each other. A structure in which the fixing rim 173 can be fixed is formed inside the housing 11 so that the guide tube 17 is fixed and then the contact tube 16 can be disposed inside the guide tube 17. And the connector tube 121 may be disposed inside the contact tube 16 while the lid 12 is coupled to the upper side of the housing 11. [ The outer circumferential surface of the contact body 161 may have a radius that can be brought into contact with or separated from the inner circumferential surface of the induction body 171. [ A through hole may be formed at an end portion of the inclined portion 162 extending conically from one end of the contact body 161 so that the projection OB or the surgical tool can be penetrated. And the anti-curl or pull-restricting structure may be formed at the portion where the through-hole of the inclined portion 162 is formed as described below.

A contact receiving portion 163 may be formed between the contact body 161 and the contact fixing portion 164 and the contact receiving portion 163 may be formed in a shape having a gradually increasing radius from one end of the contact body 161, And then connected to the fixing part 164 while being in the shape of a cylinder. And a shape corresponding to the contact receiving portion 163 may be formed inside the induction body 171. [ By forming the contact portion in this way, the contact tube 16 can be stably fixed in the predetermined position during the operation of the projectile OB or the surgical tool.

Each constitution for forming the cannula is specifically described below.

2 shows an embodiment of a housing 11 and an operating lever 14 applied to a trocar according to the present invention.

2 (A), the connection tab 131 can extend into the housing 11 and a tube fixing part 111 for fixing the induction tube is formed inside the housing 11 . A coupling hole may be formed through the path of the connection tab 131 in the inflow control unit 13, and the operation lever 14 may be coupled to the coupling hole.

The operating lever 14 includes an opening / closing cylinder 141 for regulating the inflow of gas coupled to the engaging hole; And a lever 142 which is integrally formed with the opening and closing cylinder 141 and rotates the opening and closing cylinder 141. An opening / closing hole is formed in a direction perpendicular to the extending direction of the opening / closing cylinder 141 so that gas can flow in or out along the direction of the opening / closing cylinder 141. An operation restricting stopper 143 is formed at a boundary portion between the opening and closing cylinder 141 and the lever 142 to prevent the lever 142 from being operated arbitrarily. The inflow adjusting unit 13 may be integrally formed with the housing 11, and the inflow adjusting unit 13 may be constructed in various ways.

Figure 3 shows an embodiment of an inner contact tube applied to a trocar according to the invention.

Referring to FIG. 3, a through hole is formed at an end portion of the inclined portion 162, and a plunge or a surgical tool can be inserted into the human body through the through hole. A plurality of surgical instruments may be used in the surgical procedure, and the surgical instruments inserted through the contact tubes 16 need to be replaced. In the replacement process, one surgical tool must be taken out again through the through hole, and in this process, a part of the slope part 162 may be pulled upward. This may cause a gap to leak into the contact tube 16 of the gas. To prevent this, according to the present invention, a circular anti-curling rim 165 may be formed along the end portion of the inclined portion 162 or the peripheral surface of the through hole. The anti-curling rim 165 may have a different structure than the inclined portion 162, or may be made of another material or made of a different thickness. For example, the anti-curling rim 165 may have a semicircular cross-section along the circumferential direction, and may have a convex shape compared to other portions of the inclined portion 162. Or the surface of the curling prevention frame 165 that contacts the surgical tool may be made of a material having a low frictional force or may be coated with a material having a small friction coefficient. Or the anti-curling rim 165 may have a relatively thicker shape than the other portions. The anti-curling rim 165 is prevented from being rolled up by having other geometric characteristics compared to the angled portion 162, thereby preventing leakage of the gas.

The left side of FIG. 3 (B) shows the internal structure of the contact tube 16, and the right side shows the structure seen from the outside of the contact tube 16.

The contact fixing portion 164 can form a stepped surface, and the through hole can be formed at the center of the contact tube 16. And the anti-curling rim 165 may be convex outwardly. The contact tube 16 may be made of a stretchable synthetic resin material and the anti-curling rim 165 may be made to have a smaller elasticity than the sloped portion or the contact body 161. The small elasticity can be formed structurally or by a relatively large thickness. The anti-curling rim 165 can be made in a variety of configurations and is not limited to the embodiments shown.

Figure 4 shows an embodiment of a guide tube 17 applied to a trocar according to the invention.

Referring to FIG. 4, the trocar according to the present invention further includes an induction limiting hole 176 formed in the induction tube 17 and having a cylinder-shaped uniform area and a needle-like connection area.

Fig. 4A shows the outer structure and the inner structure of the guide tube 17, and Fig. 4B shows the shape seen from the inside and the shape viewed from the outside. 4, a band-shaped restricting strip portion 175 may be formed along the radial direction at the end of the connecting portion 172, and a through-slit 175a may be formed at the center of the restricting strip portion 175 . The restriction strip portion 175 may have a function to prevent deformation of the guide tube 17 in a state in which the surgical tool is inserted. Both edges of the restriction strip portion 175 may form the end portion of the deformation preventing portion 174. [

The induction limiting hole 176 needs to be made in a structure capable of preventing the leakage of the gas while stably guiding and fixing the surgical tool. For this purpose, an induction limiting hole 176 may be formed in the connecting portion 172. [ The uniform region of the cylindrical shape of the induction limiting hole 176 may have a function of stably fixing the surgical tool, and the needle-shaped connecting region extending as the radius becomes smaller as the uniform region may have a sealing function. And an induction portion may be formed in the upper portion of the induction limiting hole 176. [ As described above, the contact tube can be fixed inside the guide tube 17, and the guide tube 17 can be made in a structure suitable for it.

5 shows an embodiment of the internal coupling structure of a trocar according to the present invention.

5, a guide tube 17 and a contact tube 16 can be disposed inside the housing 11, and the contact fixing portion 164 is in contact with the upper surface of the fixed rim 173, The contact tube 16 can be received and fixed in the interior of the guide tube 17. [ The tube fastening portion 111 extending downwardly of the lid 12 can be extended so that the end portion is located sufficiently above the slant portion 162. [ For example, to a limit position L1 that is 1/3 to 3/4 of the total length of the contact body 161. [ The anti-curling rim 165 may be formed at a boundary portion between the induction body 171 and the connecting portion 172.

The guide restriction hole 176 and the restriction strip portion 175 described above can be located in the upper portion of the path connection cavity 112 formed below the inside of the housing 11. [ The path connection cavity 112 may be hemispherical or similar in shape and the lower portion may be connected to the inflow unit 15. The path connection cavity 112 allows this structure to be freely operated, such as rotation of the surgical tool, and the induction limiting hole 176 prevents gas leakage.

The guide tube 17 or the contact tube 16 can be arranged and fixed within the housing 11 in various ways and is not limited to the embodiment shown.

The trocar according to the present invention has a double tube structure having elasticity to seal the entry and exit passage, thereby enhancing the sealing function. The trocars according to the present invention are provided with a curling-preventing edge at the end of the path along which the surgical tool is contacted in the closed path, thereby preventing the end portion of the path from being pulled out during the entrance and exit of the surgical tool. This also improves the airtightness of the trocar.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it will be understood by those of ordinary skill in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention . The invention is not limited by these variations and modifications, but is limited only by the claims appended hereto.

11: housing 12: cover
13: inflow control unit 14: operation lever
15: inflow unit 16: contact tube
17: guide tube 111: tube fixing part
112: path connection cavity 121: connection tube
131: connection tab 141: opening / closing cylinder
142: Lever 143: Operation limit stopper
161: contact body 162: inclined portion
163: contact receiving portion 164: contact fixing portion
165: anti-curl frame 171: induction body
172: connecting portion 173: stationary rim
174: deformation preventing portion 175: limiting strip portion
175a: Through-hole slit 176: Induction limiting hole
L1: Limit position OB:

Claims (3)

A housing (11) having a housing space formed therein;
An inflow path unit 15 extending from the lower side of the housing 11;
An inflow control unit (13) coupled to a side surface of the housing (11);
A guide tube 17 disposed inside the housing 11 and formed with a deformation preventing portion 174 formed of a curved surface inclined structure having at least two different radii of curvature; And
And a contact tube 16 which is housed inside the induction tube 17 and includes a cylindrical contact body 161 and an inclined portion 162 extending from the contact body 161 with a reduced radius from the contact body 161. [ Structure of Trocar. The trocar according to claim 1, wherein a curling-preventing rim (165) is formed in a circular shape at an end portion of the inclined portion (162). The trocar of claim 1, further comprising an induction limiting hole (176) formed in the induction tube (17), the induction limiting hole (176) comprising a cylinder-shaped uniform area and a needle-like connection area.

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