KR101092938B1 - Trocar apparatus for laparoscopy and making method thereof - Google Patents

Abstract

PURPOSE: A cannula apparatus for laparoscopic surgery and a manufacturing method thereof are provided to prevent the discharge of a fluid through a cannula part during surgical operation by detachably installing a valve part in the cannula part, thereby easily discharging extracts by the surgical operation. CONSTITUTION: A cannula part(10) is inserted through a cut-out part of a human body. A trocar part(90) is inserted in order to be able to appear/disappear from the cannula part. The trocar part cuts an abdominal wall. A valve part(30) is detachably combined in the cannula part. The valve part movably supports the trocar part. A case is inserted in a mounting part. An inner case is combined in the case while fixing a support part.

Description

Laparoscopic Surgical Bushing Device and Manufacturing Method Thereof {TROCAR APPARATUS FOR LAPAROSCOPY AND MAKING METHOD THEREOF}

The present invention relates to a laparoscopic bushing apparatus and a method for manufacturing the same, and more particularly, to a laparoscopic surgical bushing device and a method for manufacturing the same that can be easily discharged by surgery and to easily operate the surgical instruments It is about.

In general, laparoscopy is a type of endoscope, similar to a small telescope with a light source.

Laparoscopic examination began in the early 20th century, and was initially used to diagnose abdominal pain.

In the 1960s, laparoscopic examinations were used by obstetricians to perform tubal ligation.

The current laparoscope is equipped with a fiber optic light source and a small video camera that allows the surgical team to see the tissues and organs of the abdomen on a monitor in the operating room.

These developments have greatly expanded the scope of laparoscopic application, and are used not only for obtaining diagnostic information, but also for many surgeries such as cholectomy, appendectomy, hysterectomy, hernia repair, and tumor removal surgery.

A general laparoscopic trocar device includes a trocar part inserted into a traction device for maintaining an open state of a human body, and a tromper that is inserted into the trocar so that it can be sunk and cuts the abdominal wall inside the human body.

After the abdominal wall incision is performed by inserting the trocar portion coupled with the penetrator into the traction device installed in the incision of the human body, the penetrator is separated from the trocar and the surgical instrument is inserted into the trocar to perform the operation.

The technical structure described above is a background technique for assisting the understanding of the present invention, and does not mean the prior art widely known in the technical field to which the present invention belongs.

The general laparoscopic trocar device has a problem that it is difficult to discharge the extract taken by surgery because the valve is installed to prevent the fluid is discharged to the outside of the trocar.

In addition, the general laparoscopic trocar device has a problem that the operation of the surgical instrument is difficult because the valve installed in the trocar is in close contact with the surgical instrument.

Therefore, there is a need for improvement.

An object of the present invention is to provide a laparoscopic surgical trocar and a method for manufacturing the same, which can easily discharge the surgical extract and support the surgical instrument.

In order to achieve the above object, the present invention, a trocar portion inserted through the incision of the human body, the penetrating portion is inserted into the permeable portion and the penetrating portion for cutting the abdominal wall, and detachably coupled to the trocar It provides a laparoscopic surgical trocar device comprising a valve unit for supporting the penetrating portion to flow.

The bushing part may include a tubular insertion part inserted through the cutout part, and a seating part in which an upper end of the insertion part is expanded and a detachable groove part to which the valve part is coupled is formed.

The valve unit may include a case inserted into the seating part, a support part slidably and rotatably supporting the surgical instrument inserted into the case in a horizontal direction or a vertical direction, and fixed to the support part to be coupled to the case. And an inner case, a sealing part installed on the support part and in close contact with the penetrating part, and a detachable part coupled to the detachable groove part.

The case may include an upper case in which the penetrating part is detachably coupled to the lower case, and a lower case in which a coupling protrusion is mounted on the seating portion and penetrates into the upper case through the inner case. .

The support part may include a rotation ring rotatably installed in the inner case, a support ring slidably installed in the inner case in a lateral direction and rotatably supporting the rotation ring, and the rotation ring in a left and right direction. Or it characterized in that it comprises a resilient support portion coupled to the inner case to support the flow in the vertical direction.

The rotating ring may include a first rotating ring having a mounting portion and an insertion hole portion coupled to the sealing portion and having a first curved portion rotatably seated in the inner case, and coupled to the insertion hole portion through the sealing portion. It characterized in that it comprises a second rotary ring is formed between the insertion projection is formed and the second curved portion, and the gap ring interposed between the sealing portion.

The support ring may include a first support ring slidably installed in the inner case and slidably supporting the first curved portion, and a flow portion slidably seated on the second curved portion. It characterized in that it comprises a second support ring is formed in the inner case jaw portion is slidably inserted in the left and right directions.

In addition, the elastic support portion is made of a cylindrical shape and includes an elastic material, the upper connection hole is formed in the upper end interposed in the inner case is formed through the coupling projection, between the second rotary ring and the spacer ring The lower end interposed therebetween is characterized in that the lower connection hole is formed through the insertion protrusion.

The inner case may include a first inner case through which the accommodating part accommodating the first support ring and the coupling protrusion penetrates, and a fixing groove through which the coupling protrusion penetrates and the detachable part is rotatably inserted. And a fixing case having a second inner case and a step interposed between the first inner case and the second inner case and on which the jaw is seated.

In addition, the detachable portion, a rotating shaft which is rotatably inserted into the fixing groove portion is formed, and the hook piece is formed to be hooked to the removable groove portion, and extending from the locking piece to press the second inner case to the hook portion It characterized in that it comprises an elastic portion for providing a rotational force.

The sealing part may include a first sealing part including a plurality of sealing pieces interposed between the first rotating ring and the spacer ring and including an elastic material and partially overlapping each other; The second sealing portion is interposed between the second rotary ring and the hole is inserted into the surgical instrument is formed and comprises a elastic material, and the intervening portion is inserted between the case and the inner case and the surgical instrument is inserted and formed of an elastic material It characterized in that it comprises a third sealing portion comprising a.

In addition, the outer edge of the sealing piece is formed with a through-hole portion through which the insertion protrusion passes, and the inner side of the sealing piece is characterized in that the sealing curved surface portion which is concave inclined inwardly into the bushing portion.

The second sealing part may include a sealing body which is formed concave inside the bushing part, the hole part is formed, and includes an elastic material, and a reinforcing member fused to the bottom surface of the sealing body.

In addition, a reinforcing rib is formed on the interface between the sealing body and the reinforcing member.

In addition, the reinforcing member is characterized in that it comprises a fiber material.

In addition, the third sealing portion is formed to be concave inside the bushing portion, the bottom surface of the third sealing portion is cut in a '×' shape to form the passage portion, the bending between the through portion is bent out of the bushing portion. It is characterized in that the addition is formed.

In addition, the penetrating portion, the insertion pipe is coupled to the through-hole through the valve portion, the blade portion is provided on the lower end of the insertion tube and comprises a transparent material, and is installed on the upper end of the insertion tube and the valve portion It characterized in that it comprises a head portion that is installed detachably coupled to the connection.

In addition, the present invention comprises the steps of (a) forming a sealing body of the elastic material coupled to the rotary ring rotatably supporting the surgical instrument inserted into the incision of the human body, (b) fusion bonding the reinforcing member to the sealing body (C) forming a first hole in the sealing body and the reinforcing member, (d) applying the sealing body in the first hole, and (e) the first body in the sealing body. It provides a method of manufacturing a laparoscopic surgical trocar device comprising the step of forming a second hole portion relatively small compared to the hole portion.

In the step (d), the reinforcing ribs perpendicular to the second hole are formed.

Laparoscopic surgical bushing apparatus according to the present invention can be installed in the bushing to the detachable valve portion can prevent the fluid from being discharged through the bushing during the operation, the valve is easily separated from the bushing to facilitate the extraction by surgery There is an advantage to discharge.

In addition, the laparoscopic surgical trocar according to the present invention has the advantage that it is possible to effectively prevent the discharge of the fluid through the trocar during surgery because it prevents the fluid is discharged through the trocar by the plurality of sealing portion.

In addition, the laparoscopic surgical bushing device according to the present invention is supported so that the surgical instrument inserted into the trocar is slidable and rotatable in the vertical direction and the left and right directions, the operating radius of the surgical instrument is increased to perform an easy operation There is this.

In addition, the manufacturing method of the laparoscopic bushing apparatus according to the present invention is to prevent the sealing body from being damaged by the piercing unit or the surgical instrument because the reinforcing member including the fiber material is fused to the sealing body, and the piercing unit or surgical instrument is There is an advantage that can be easily discharged.

1 is a perspective view showing a laparoscopic surgical trocar according to an embodiment of the present invention.
Figure 2 is a cross-sectional view showing a laparoscopic surgical trocar according to an embodiment of the present invention.
Figure 3 is an exploded perspective view showing a laparoscopic surgical trocar according to an embodiment of the present invention.
Figure 4 is an exploded perspective view showing the valve portion of the laparoscopic bushing apparatus according to an embodiment of the present invention.
Figure 5 is a cross-sectional view showing the valve portion of the laparoscopic bushing apparatus according to an embodiment of the present invention.
Figure 6 is a partial cross-sectional view showing a first support ring mounting structure of the laparoscopic bushing apparatus according to an embodiment of the present invention.
7 is a partial cross-sectional view showing a second support ring mounting structure of the laparoscopic bushing device according to an embodiment of the present invention.
8 is a bottom perspective view illustrating a mounting structure of a first sealing part of a laparoscopy surgical bushing device according to an embodiment of the present invention.
9 is a bottom perspective view of the second sealing part of the laparoscopic bushing device according to an embodiment of the present invention.
10 is a cross-sectional view showing a second sealing portion of the laparoscopic bushing device according to an embodiment of the present invention.
11 is a bottom perspective view of the third sealing part of the laparoscopic bushing device according to an embodiment of the present invention.
12 is an exploded perspective view showing the penetrating portion of the laparoscopic surgical trocar according to an embodiment of the present invention.
Figure 13 is a flow chart illustrating a method of manufacturing a laparoscopy surgical trocar according to an embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings will be described an embodiment of a laparoscopic surgical trocar and a method for manufacturing the same.

In this process, the thickness of the lines or the size of the components shown in the drawings may be exaggerated for clarity and convenience of description.

In addition, terms to be described later are terms defined in consideration of functions in the present invention, which may vary according to a user's or operator's intention or custom.

Therefore, definitions of these terms should be made based on the contents throughout this specification.

1 is a perspective view showing a laparoscopic surgical trocar according to an embodiment of the present invention, Figure 2 is a cross-sectional view showing a laparoscopic surgical trocar according to an embodiment of the present invention, Figure 3 is a view of the present invention Is an exploded perspective view showing a laparoscopic surgical bushing device according to an embodiment.

1 to 3, the laparoscopic surgical trocar according to an embodiment of the present invention is a trocar 10 inserted through the incision of the human body, and inserted into the trocar 10 to be protruding into the abdominal wall A valve portion 30 that is detachably coupled to the penetrating portion 90 and the bushing portion 10, which supports the penetrating portion 90 in a flowable manner, and prevents the fluid from being discharged through the bushing portion 10. It includes.

When performing laparoscopic surgery, a laparoscopic surgical traction device is installed in the incision of the human body to maintain the traction state in which the incision is opened, and the abdominal wall inside the incision is cut by inserting the trocar of the present embodiment into the traction device.

After cutting the abdominal wall, the penetrating unit 90 is separated from the bushing unit 10 and the valve unit 30 to remove the penetrating unit 90, and the surgical instrument is removed by the valve unit 30 and the trocar unit 10. Laparoscopic surgery is performed.

The extract removed from the human body during surgery is discharged to the outside of the incision through the bushing part 10. In this case, the valve unit 30 is separated from the bushing part 10 to secure a passage through which the accumulator is discharged, and then the surgical instrument is removed. By discharging to the outside of the bushing portion 10 can be easily removed.

The valve part 30 prevents the fluid from being discharged at an interval between the bushing part 10 and the bushing part 90 so that safe laparoscopy can be performed.

In addition, the valve unit 30 supports the surgical instruments inserted into the incision through the valve unit 30 in a flowable manner so that the surgical instruments can be easily operated by increasing the radius of the flow.

Bushing portion 10, the tubular insertion portion 12 is inserted through the incision, and the upper end of the insertion portion 12 is made of the expansion and the removable groove portion 16 is formed is coupled to the valve portion 30 is formed And a seat 14.

Insertion portion 12 is formed in a cylindrical shape that is open to the bottom surface is inserted into the incision portion through the insertion portion 12, the penetrating portion 90 or surgical instruments may be inserted into the incision portion.

The seating portion 14 is formed by extending the upper diameter of the insertion portion 12, the gas injection pipe 18 is supplied to one side of the operating fluid is injected during surgery, the gas injection pipe 18 is opened and closed An opening / closing member 18a for performing the operation is provided.

Figure 4 is an exploded perspective view showing a valve portion of the laparoscopic surgical bushing apparatus according to an embodiment of the present invention, Figure 5 is a cross-sectional view showing the valve portion of the laparoscopic surgical bushing device according to an embodiment of the present invention, Figure 6 is a partial cross-sectional view showing a first support ring mounting structure of the laparoscopic bushing apparatus according to an embodiment of the present invention, Figure 7 is a second support ring of a laparoscopic surgery trocar device according to an embodiment of the present invention Partial cross-sectional view of the mounting structure is shown.

8 is a bottom perspective view illustrating a mounting structure of the first sealing portion of the laparoscopic bushing device according to an embodiment of the present invention, and FIG. 9 is a sectional view of the laparoscopic bushing device according to an embodiment of the present invention. 10 is a bottom perspective view showing the sealing portion, Figure 10 is a cross-sectional view showing a second sealing portion of the laparoscopic bushing apparatus according to an embodiment of the present invention, Figure 11 is a laparoscopic surgical bushing according to an embodiment of the present invention A bottom perspective view showing the third sealing portion of the device.

3 to 11, the valve unit 30 of the present embodiment, the case 32, 34 to be inserted into the seating portion 14, and the surgical instruments inserted into the case (32, 34) in the horizontal direction or Support parts 42, 50, and 58 that are slidably and rotatably supported in an up and down direction, and inner cases 36, 38, and 39 that are fixed to the support parts 42, 50, and 58 and coupled to the cases 32 and 34, respectively. And a sealing part 70 installed on the support parts 42, 50, and 58 and tightly attached to the penetrating part 90, and a detachable part 80 coupled to the detachable groove part 16.

Cases 32 and 34 are formed in the center of the hole portion 90 is inserted into the penetrating portion 90 or surgical instruments, so when the valve portion 30 is coupled to the seating portion 14 and the hole portion formed in the center of the valve portion 30 and The insertion part 12 communicates with each other so that the penetrating part 90 can be inserted into the cutout part through the valve part 30 and the insertion part 12.

When the cases 32 and 34 are seated on the upper end of the seating part 14, the detachable part 80 is coupled to the detachable groove part 16 of the seating part 14, so that the valve part 30 and the bushing part 10 are coupled to each other. do.

Subsequently, when the penetrating portion 90 is inserted through the insertion portion 12 through the valve portion 30 and the sealing portion 70 is in close contact with the circumferential surface of the penetrating portion 90, the penetrating portion 90 and the valve It is possible to prevent the fluid from being discharged at intervals between the parts 30.

After the immersion unit 90 is separated from the valve unit 30, the surgical instrument is inserted through the valve unit 30 to perform the operation. In this case, the support units 42, 50, and 58 may move the surgical instrument to the left or right direction or the like. Since the support is slidable and rotatable in the vertical direction, the effect of increasing the width of the radius in which the surgical instrument flows is exhibited.

Therefore, the operator holding the surgical instrument to perform the operation can be easily performed while sliding and rotating the surgical instrument in the left and right direction or up and down direction.

The cases 32 and 34 include an upper case 32 to which the penetrating portion 90 is detachably coupled, and a top case 32 which is seated on the seating portion 14 and penetrates through the inner cases 36, 38 and 39. It includes a lower case 34 is formed a coupling protrusion (34a) that is pressed into.

The upper case 32 is formed in a ring shape so that the penetrating portion 90 is inserted, and a pair of detachable portions 80 are installed on the circumferential surface thereof, so that the detachable portion 80 is detachable groove 16 of the seating portion 14. When coupled to the valve 30 and the bushing 10 is in close contact.

The lower case 34 is formed in a ring shape that is coupled to the bottom of the upper case 32 and maintains a constant gap, and a plurality of coupling protrusions 34a are formed in an upward direction, and the inner case 36 is coupled to the coupling protrusion 34a. , 38, 39, supports 42, 50, 58 and sealing 70 penetrate.

The support parts 42, 50, 58 are rotatably installed in the rotary rings 50 and the inner cases 36, 38, and 39 that are rotatably installed in the inner cases 36, 38, and 39. Support ring 42 for rotatably supporting the rotation ring 50, and the elastic support portion coupled to the inner case (36, 38, 39) to support the rotatable ring 50 in a horizontal direction or up and down direction ( 58).

Since the rotary ring 50 is rotatably installed in the inner cases 36, 38, and 39, the surgical instrument is rotatably supported by the rotary ring 50 when the surgical instrument is inserted into the valve unit 30. When operating the surgical instrument to rotate the rotary ring 50 inside the inner case (36, 38, 39) so that the radius of the surgical instrument flows.

In addition, the rotary ring 50 is installed in the inner case (36, 38, 39) to be slidable in the left-right direction by the support ring 42, so when the surgical instrument is inserted into the rotary ring 50, the operator inside the surgical instrument After sliding in the lateral direction inside the case (36, 38, 39) it is possible to perform the operation by rotating the surgical instruments.

Therefore, the surgical instrument supported by the rotary ring 50 is widened in the radius of the flow in the inserted state in the incision.

The rotary ring 50 has a mounting portion 52a to which the sealing portion 70 is coupled and an insertion hole portion 52c are formed, and the first curved portion 52b rotatably seated in the inner cases 36, 38, and 39. The first rotary ring 52 is formed, and the second rotary ring formed through the sealing portion 70, the insertion projection (54a) coupled to the insertion hole (52c) and the second curved portion 54b is formed. 54 and a gap ring 56 interposed between the sealing portion 70.

Since the first curved portion 52b is formed on the bottom surface of the first rotary ring 52, when the first rotary ring 52 is inserted into the inner cases 36, 38, and 39, the first curved portion 52b is formed by the first curved portion 52b. Since the edge of the first rotary ring 52 flows in the up and down direction, after the surgical instrument is inserted into the first rotary ring 52, the handle of the surgical instrument is moved to the left and right directions so that the first rotary ring 52 flows to the incision. The inner end of the surgical instrument inserted therein is moved left and right.

Since the second curved portion 54b is formed on the upper surface of the second rotary ring 54, the second curved portion 54b is supported by the support ring 42 for pressing the upper surface of the second rotary ring 54 to be movable.

In addition, the first rotating ring 52 having a first curved portion 52b formed on the bottom thereof is disposed below, and the second rotating ring 54 having a second curved portion 54b formed thereon is disposed above. Combining the first rotary ring 52 and the second rotary ring 54 so as to form a shape similar to the rotary sphere.

The gap ring 56 interposed between the first rotary ring 52 and the second rotary ring 54 is between the sealing part 70 interposed between the first rotary ring 52 and the second rotary ring 54. The member is installed to maintain the distance of the, and the through hole portion 56a through which the insertion protrusion 54a is formed at the edge of the spacer ring 56.

Therefore, the second sealing portion 76 to be described later is seated on the mounting portion 52a of the first rotary ring 52, and the spacer ring 56 is seated on the upper surface of the second sealing portion 76. The first sealing portion 72 to be described later on the upper surface of the) and the second rotary ring 54 inserted into the elastic support 58 is pressed on the upper surface of the first sealing portion 72 when the insertion projection (54a) Is pressed into the insertion hole portion 52c of the first rotary ring 52 through the elastic support 58, the first sealing portion 72, the spacer ring 56, the second sealing portion 76 and the rotary ring ( 50) will be assembled.

When the assembly is completed, the sealing unit 70 is installed and the rotary ring 50 formed in the shape of a rotary sphere forms a shape connected to the elastic support 58.

The support ring 42 is installed on the inner cases 36, 38, and 39 in a slidable direction, and includes a first support ring 44 and a second curved surface for slidably supporting the first curved portion 52b. A second support ring 46 having a flow portion 47 slidably seated in the portion 54b and a jaw portion 48 slidably inserted in the left and right directions in the inner cases 36, 38, and 39 are formed. It includes.

The first support ring 44 is slidably installed in the inner cases 36, 38, and 39 in a left and right direction, and rotatably supports the first curved portion 52b of the first rotation ring 52. Rotating ring 50 formed as is supported by the first rotary ring 52 to be slidable in the left and right direction in the inner case (36, 38, 39) and flowable in the vertical direction.

In addition, since the flow portion 47 for pressurizing the second curved portion 54b of the second rotary ring 54 is formed on the bottom surface of the second support ring 46, the rotary ring 50 may be flowable. The jaw portion 48 is fixed to the upper surface of the second support ring 46 and slidably installed in the left and right directions on the inner cases 36, 38, and 39.

Accordingly, the lower end of the rotary ring 50 is supported by the first support ring 44 to be slidable in the left and right direction and flowable in the vertical direction, and the upper end of the rotary ring 50 is connected to the second support ring 46. It is slidable in the left and right directions and is supported to be movable in the vertical direction.

The elastic support 58 is formed in a cylindrical shape and includes an elastic material, and an upper connection hole 58a through which the coupling protrusion 34a penetrates is formed at an upper end of the inner case 36, 38, or 39. At the lower end interposed between the second rotary ring 54 and the spacer ring 56, a lower connection hole 58b through which the insertion protrusion 54a penetrates is formed.

Accordingly, the second rotary ring 54 is disposed inside the elastic support 58, and the insertion protrusion 54 a protruding downward through the lower connection hole 58 b of the elastic support 58 includes the first sealing part ( 72, the gap ring 56 and the second sealing portion 76 penetrate the first rotary ring 52.

Since the diameter and length of the resilient support 58 are relatively small and short compared to the inner cases 36, 38 and 39, the resilient support 58 is inserted into the inner cases 36, 38 and 39, and the rotary ring ( 50 is supported to be movable in the left and right or up and down direction in the inner case (36, 38, 39).

The inner cases 36, 38, and 39 have a first inner case 36 through which the accommodating part 36a in which the first support ring 44 is accommodated and the engaging protrusion 34a penetrates, and the engaging protrusion 34a. ) Is interposed between the second inner case 38 and the first inner case 36 and the second inner case 38 having a fixing groove 38a through which the removable portion 80 is rotatably inserted. And a fixing case 39 in which a step 39a on which the jaw portion 48 is seated is formed.

The first inner case 36 is formed in a cylindrical shape and the receiving portion 36a formed in a ring shape is press-fitted to the bottom of the first support ring 44 so as to be slidable in the left and right directions.

The upper end of the first inner case 36 is bent in an outward direction so that the elastic support 58, the fixed case 39, and the second inner case 38 are seated.

On the inner edge of the fixed case 39, the step portion 39a for slidingly engaging the jaw portion 48 of the second support ring 46 and pressing the flow portion 47 of the second support ring 46 to flow is provided. Is formed.

The detachable portion 80 includes a locking piece 82 having a rotating shaft 86 rotatably inserted into the fixing groove 38a and a hook portion 84 caught by the detachable groove 16. And an elastic portion 88 extending from 82 and pressing the second inner case 38 to provide rotational force to the hook portion 84.

When the lower case 34 and the upper case 32 is coupled to the lower case 34 and the upper case 32 by inserting the rotary shaft 86 into the fixing groove 38a of the second inner case 38 The upper case 32 presses the rotation shaft 86 so that the locking piece 82 is rotatably installed in the cases 32 and 34.

Since the elastic part 88 presses the second inner case 38 downward, the locking piece 82 is rotated into the detachable groove 16 of the bushing part 10 about the rotation shaft 86.

Therefore, when the valve portion 30 is inserted into the seating portion 14, the elastic portion 88 is deformed while the hook portion 84 is opened in the outward direction, and the coupling is made. When the coupling is completed, the restoring force of the elastic portion 88 is completed. By the locking piece 82 is rotated by the hook portion 84 is caught by the removable groove 16.

The sealing unit 70 includes a plurality of sealing pieces 74 interposed between the first rotary ring 52 and the spacer ring 56 and including an elastic material and partially overlapping each other. The second sealing portion 76 is formed between the portion 72, the spacing ring 56 and the second rotary ring 54, and the hole portion (77a, 77b) is inserted into the surgical instrument and comprises an elastic material And a third sealing part 78 interposed between the cases 32 and 34 and the inner cases 36, 38 and 39 and having a passage portion 78a through which the surgical instrument is inserted and including an elastic material. do.

When the surgical instrument is inserted along the valve unit 30, the first sealing unit 72, the second sealing unit 76, and the third sealing unit 78 made of an elastic material closely adhere to the outer wall of the surgical instrument, thereby providing a valve unit ( The fluid is prevented from being discharged along the gap between 30) and the surgical instrument.

At this time, since the sealing piece 74 is installed so that a plurality of overlapping with each other, when the surgical instrument passes through the first sealing portion 72, the sealing piece 74 is opened to each other while the hole portion through which the surgical instrument passes, becomes large, the sealing piece By the restoring force of 74, a plurality of sealing pieces 74 are maintained in close contact with the outer wall of the surgical instrument.

A through-hole portion 74a through which the insertion protrusion 54a passes is formed in the outer edge of the sealing piece 74, and an inner portion of the sealing piece 74 is inclined to be recessed inwardly into the bushing portion 10. ) Is formed.

When the edges of the sealing piece 74 in which the through-hole portion 74a is formed are connected to each other, one ring shape is formed, so that a plurality of sealing pieces 74 are inserted into the insertion protrusion 54a formed in the second rotary ring 54. When inserted, a hemispherical first sealing part 72 is formed.

At this time, the sealing curved surface portion 74b is disposed to overlap with other sealing pieces 74 which are disposed adjacent to each other, and the sealing piece 74 is formed in the center portion does not overlap each other to form a hole through which the surgical instrument passes.

In addition, since the sealing curved surface portion 74b is formed to be concave inside the bushing portion 10, when the surgical instrument is inserted into the valve portion 30, the sealing piece 74 is easily deformed into the bushing portion 10. When the surgical instrument is slid out of the valve unit 30, the sealing curved surface portion 74b is not easily deformed, thereby preventing the fluid from being discharged to the outer side of the valve unit 30 along the surgical instrument.

The second sealing portion 76 is formed into a concave inside the bushing portion 10, a hole portion is formed, the sealing body 77 made of an elastic material and the reinforcing member 79 fused to the bottom surface of the sealing body 77 ).

When the surgical instrument is inserted into the valve unit 30, the sealing body 77 is deformed while the holes 77a and 77b are expanded, and the surgical instrument passes therethrough, so that the sealing body 77 made of an elastic material is in close contact with the outer wall of the surgical instrument. State is achieved.

When the surgical instrument is slid out of the valve unit 30, the sealing body 77 is deformed to the valve unit 30 to maintain the state in close contact with the outer wall of the surgical instrument.

The sealing body 77 is formed similarly to a hemispherical shape in which a plurality of sealing pieces 74 are overlapped, and when the surgical instrument is discharged to the outside of the valve unit 30, the sealing pieces 74 overlap each other. Because of the loss, the amount of deformation is relatively small in comparison with the sealing body 77.

On the other hand, since the sealing body 77 is formed by forming a hole in one structure having a hemispherical shape, the amount of deformation is increased in comparison with the sealing piece 74 when the surgical instrument is discharged to the outside of the valve unit 30.

Therefore, when the insertion or discharge of the surgical instrument is repeated, the deformation of the sealing body 77 may be repeated and broken. That is, the sealing body 77 is damaged by the reinforcing member 79 installed on the bottom surface of the sealing body 77. It becomes possible to prevent it.

In addition, when the surgical instrument is discharged to the outside of the valve unit 30, a deformation occurs in which the sealing body 77 concave inside the valve unit 30 is reversed to the outside of the valve unit 30.

Here, since the reinforcing member 79 is made of a material having a smaller friction coefficient than that of the sealing body 77 and is fused to the bottom surface of the sealing body 77, when the surgical instrument is slid out of the valve unit 30, the sealing body ( When the deformation of 77 is reversed to the outside of the valve unit 30, the reinforcing member 79 contacts the surgical instrument outer wall.

Since the reinforcing member 79 is made of a fiber material, the deformation of the sealing body 77 is suppressed by the reinforcing member 79 when the surgical instrument is slid out of the valve unit 30 so that the sealing body 77 is valved. It is possible to prevent deformation more than necessary outside the portion 30.

Since the reinforcing member 79 made of a fiber material has a high strength compared to the sealing body 77 made of an elastic material such as silicone, it is possible to prevent the sealing body 77 from being damaged by the appearance of surgical instruments.

In addition, since the reinforcing member 79 in contact with the outer wall of the surgical instrument is a fiber material having a small friction coefficient compared to the sealing body 77, the surgical instrument can be easily slid out of the port body 62.

Since the reinforcing member 79 is impregnated into the sealing body 77 and one surface of the reinforcing member 79 is exposed to the bottom surface of the sealing body 77, an external force generated when the surgical instrument slides while contacting the reinforcing member 79. The reinforcing member 79 can be prevented from being separated from the sealing body 77.

The third sealing portion 78 is formed to be concave inside the bushing portion 10, the bottom surface of the third sealing portion 78 is cut in a '×' shape to form a passage portion 78a, and a passage portion 78a. Between the bent portion 10, the bent portion 78b is formed.

The third sealing portion 78 is formed in a cylindrical shape and a bottom surface is formed at an end facing inwardly of the valve portion 30, and the bottom surface is cut in a '×' shape to form a passage portion 78a.

Therefore, when the surgical instruments are inserted, four vertices arranged in close contact with each other in the center of the passage 78a are opened to the outside, and the surgical instruments pass through the third sealing portion 78.

Since the bent portion 78b is formed between the pass portions 78a and is bent to the outside of the valve portion 30, an elastic force for driving four vertices constituting the pass portion 78a to the center of the third sealing portion 78. Will be provided.

When the surgical instrument is inserted into the valve unit 30, the vertex forming the passage 78a is opened, and the surgical instrument is passed. When the surgical instrument is slid out of the valve unit 30, the surgical instrument is provided by the bent portion 78b. The vertices are driven to the center by the elastic force to prevent the fluid from being discharged to the outside of the valve unit 30.

In addition, since the outer diameter of the third sealing portion 78 is formed to be substantially the same or smaller than the inner diameter of the seating portion 14, when the surgical instrument is inserted and the passage portion 78a opens outward, the passage portion 78a is opened. While being in close contact with the inner wall of the seating portion 14, the passage portion 78a is prevented from spreading more than necessary.

Since the inclined surface 78c is formed at the outer end of the passage 78a to be in close contact with the inner wall of the seating portion 14, the surgical instrument passes through the third sealing portion 78 to allow the passage 78a to be opened. 78c is in close contact with the inner wall of the seating portion 14 to prevent the passage portion 78a from being widened beyond the fill.

12 is an exploded perspective view showing the penetrating portion of the laparoscopic surgical trocar according to an embodiment of the present invention.

3, 4, 7 and 12, the penetrating portion 90 of the present embodiment includes an insertion tube 92 which penetrates the valve portion 30 and is coupled to the bushing portion 10. A blade portion 94 installed at the lower end of the tube 92 and including a transparent material, and a coupling portion 96a installed at the upper end of the insertion tube 92 and detachably connected to the valve portion 30 are installed. And a head portion 96 to be used.

In the center of the upper case (97) and the lower case (98) forming the external appearance of the head portion 96 is formed a hole for inserting the surgical instrument, the hole portion and the insertion tube 92 is in communication with the head portion 96 When a surgical instrument such as laparoscopic is inserted into the incision through the blade portion 94 made of a transparent material, the operation can be performed.

Therefore, the operator can perform the operation while visually confirming the site cut by the blade portion 94, the effect that can reduce the misoperation appears.

Between the upper case 97 and the lower case 34, a coupling part 96a is detachably assembled to the groove of the upper case 32, and a guide tube 96b into which the insertion tube 92 is fitted is installed. The guide tube 96b is provided with an O-ring 96c for supporting the insertion tube 92.

Looking at the operation of the laparoscopic bushing device according to an embodiment of the present invention configured as described above are as follows.

First, when the valve unit 30 is seated on the seating part 14 of the bushing part 10 to assemble the bushing device, the hook piece 84 is rotated while the locking piece 82 is rotated by the restoring force of the elastic part 88. Is coupled to the removable groove portion 16 of the seating portion 14 is the coupling between the bushing portion 10 and the valve portion 30 is made.

Subsequently, when the insertion tube 92 and the blade portion 94 of the penetrating portion 90 are inserted into the insertion portion 12 of the bushing portion 10 through the valve portion 30, the coupling portion 96a is formed. It is coupled to the groove of the upper case 32 to form a coupling of the penetrating portion 90, the valve portion 30 and the bushing portion 10.

At this time, the blade portion 94 is formed to protrude to the lower end of the insertion portion 12, when assembling the bushing device in the towing device blade portion 94 is inserted into the incision to be able to perform the abdominal wall incision.

Since the blade portion 94 is made of a transparent material, when the laparoscope is inserted into the insertion tube 92 through the head portion 96, the operator operates the blade portion 94 while visually checking the inside of the incision portion. Can be done.

At this time, since the sealing piece 74, the sealing body 77, and the passage portion 78a of the third sealing portion 78 are in close contact with the outer wall of the insertion tube 92, the insertion tube 92 and the valve portion It is possible to prevent the fluid from being discharged at intervals between the 30.

After the cutting operation by the blade portion 94 is finished, the penetrating portion 90 is separated and discharged to the outside. At this time, when the insertion tube 92 slides outside the valve portion 30, the sealing piece 74 is The bottom surface of the sealing curved surface portion 74b is in close contact with the outer wall of the insertion tube 92 while being deformed in the outward direction of the valve unit 30, and the sealing body 77 and the reinforcing member 79 are in close contact with the outer wall of the insertion tube 92. The passage portion 78a of the third sealing portion 78 is in close contact with the outer wall of the insertion tube 92.

As described above, since the three sealing portions 70 are in close contact with the outer wall of the insertion tube 92, the fluid flows along the insertion tube 92 and the blade portion 94 discharged to the outside. ) It is possible to prevent the discharge to the outside.

After the piercing unit 90 is separated, the surgical instrument is inserted into the valve unit 30 and the bushing unit 10 to perform the operation. When the operator moves the surgical instrument in one direction, the rotary ring supporting the surgical instrument 50 ) And the support ring 42 is moved laterally while the rotary ring 50 is rotated from the support ring 42 to move the surgical instrument laterally.

Surgical instruments inserted through the rotary ring 50 may be flown in the horizontal direction or the vertical direction by the operating force of the operator.

The rotary ring 50 of the present embodiment is slid in the lateral direction by the support ring 42, flows in the vertical direction by the connection configuration of the rotary ring 50 and the support ring 42, the elastic support 58 By the left and right or up and down direction.

Therefore, the rotary ring 50 of the present embodiment is to allow the surgical instrument to increase the width of the flow radius to facilitate the operation.

When taking out the incisions cut out from the inside of the incision during surgery, when the operator presses the catching piece 82, the elastic portion 88 is compressed and rotated about the rotating shaft 86, the hook portion 84 is detachable groove 16 And the valve portion 30 can be separated from the seat 14.

When the valve unit 30 is separated from the seating unit 14, the extract can be easily discharged through the inserting unit 12 and the seating unit 14.

Figure 13 is a flow chart illustrating a method of manufacturing a laparoscopy surgical trocar according to an embodiment of the present invention.

3, 4, 7 and 13, the manufacturing method of the laparoscopy surgical trocar according to an embodiment of the present invention is a manufacturing method of a laparoscopy surgical trocar according to an embodiment of the present invention Forming a sealing body 77 coupled to the rotation ring 50 rotatably supporting the surgical instrument inserted into the incision of step S10 and fusing the reinforcing member 79 to the sealing body 77. (S20), the step of forming the first hole (77a) in the sealing body 77 and the reinforcing member (S30), and applying the sealing body 77 of the elastic material to the first hole (77a) Step S40 and the step (S50) of forming a relatively small second hole portion (77b) in the sealing body 77 compared to the first hole portion (77a).

After the injection process using an elastic material is made to produce a bowl-shaped sealing body 77, the reinforcing member 79 is thermally fused to the bottom of the sealing body 77 to improve the strength of the sealing body 77. Let's do it.

At this time, since the sealing body 77 is made of an elastic material including silicon, the reinforcing member 79 made of a fiber material is impregnated into the sealing body 77 while the sealing body 77 is melted by heat.

Therefore, it is possible to prevent the reinforcing member 79 from being separated from the sealing body 77 by an external force generated when the sealing body 77 is deformed by the surgical instrument.

In the center of the sealing body 77 to process the second hole portion (77b) so that the insertion tube 92 or surgical instruments can pass.

Subsequently, the second hole portion 77b is coated with an elastic material forming the sealing body 77 to close the second hole portion 77b, and the first hole portion having a smaller diameter than the second hole portion 77b ( Process 77a).

When the second hole 77b is closed, a reinforcing rib 77d is formed on the interface between the sealing body 77 and the reinforcing member 79.

The reinforcement ribs 77d form a buccal shape from the edge of the first hole portion 77a, and a plurality of reinforcement ribs 77 are formed to maintain a constant interval and are orthogonal to the boundary surface of the sealing body 77 and the reinforcement member 79.

Therefore, it is possible to prevent the second hole 77b constituting the interface between the sealing body 77 and the reinforcing member 79 from being damaged when the surgical instrument is mounted through the first hole 77a.

The sealing body 77 is formed in a concave shape in the shape of a bowl, and a first hole portion 77a is formed at the center portion, and a mounting hole portion 77c through which the insertion protrusion 54a penetrates is formed at the outer edge thereof.

In addition, the sealing body 77 is coated with a reinforcing member 79 from the outer edge to the second hole portion 77b, and without the reinforcing member 79 from the edge of the second hole portion 77b to the first hole portion 77a. Only the main body 77 is located.

Here, since the reinforcing member 79 is made of a fiber material, the reinforcing member 79 has a higher strength and a smaller friction coefficient than the sealing body 77 made of an elastic material such as silicon.

Therefore, when the insertion tube 92 or the surgical instrument is inserted into the incision of the human body through the second sealing portion 76, the first hole 77a of the sealing body 77 on the outer wall of the insertion tube 92 or the surgical instrument ) Is in close contact with the sealing body 77 and the insertion tube 92 or to prevent the discharge of fluid at the interval between the surgical instrument and the reinforcing member 79 to prevent the sealing body 77 from being damaged.

In addition, when the insertion tube 92 or the surgical instrument is discharged to the outside of the valve unit 30, the sealing body 77 is deformed in the direction of the valve unit 30, the bottom surface is in close contact with the insertion tube 92 or the outer wall of the surgical instrument. At this time, the reinforcing member 79 applied to the bottom surface of the sealing body 77 has a small friction coefficient compared to the sealing body 77, so that the insertion tube 92 or the surgical instrument can be easily discharged.

As a result, it is possible to provide a laparoscopic surgical trocar and a method for manufacturing the same, which can easily discharge the surgical extract and support the surgical instrument.

Although the present invention has been described with reference to one embodiment shown in the drawings, this is merely exemplary, and various modifications and equivalent other embodiments are possible to those skilled in the art. Will understand.

In addition, the laparoscopic surgical trocar and a manufacturing method thereof have been described as an example, but this is merely exemplary, and the laparoscopic trocar and the manufacturing method of the present invention can be used in other products other than the trocar and the manufacturing method. have.

Therefore, the true technical protection scope of the present invention will be defined by the claims below.

10: bushing portion 12: insertion portion
14: seating portion 16: removable groove
18 gas injection pipe 18a opening and closing member
30: valve portion 32: upper case
34: lower case 34a: coupling protrusion
36: first inner case 36a: housing
38: second inner case 38a: fixing groove
39: fixed case 39a: step
42: support ring 44: first support ring
46: second support ring 47: flow part
48: jaw 50: rotation ring
52: first rotating ring 52a: mounting portion
52b: first curved portion 52c: insertion hole
54: second rotation ring 54a: insertion protrusion
54b: second curved portion 56: gap ring
56a: through-hole 58: elastic support
58a: upper connection hole 58b: lower connection hole
70: sealing part 72: first sealing part
74: sealing piece 74a: through hole
74b: sealing curved surface portion 76: second sealing portion
77: sealing body 77a: the first hole
77b: second hole 77c: mounting hole
78: third sealing portion 78a: passage portion
78b: bend portion 79: reinforcing member
80: removable portion 82: locking piece
84: hook portion 86: rotation axis
88: elastic portion 90: penetrating portion
92: insertion tube 94: blade portion
96 head portion 96a coupling portion
96b: Guide tube 96c: O-ring
97: upper case 98: lower case

Claims (19)

A trocar inserted through the incision of the human body;
A penetrating portion which is inserted into the bushing portion to be protruding and cuts the abdominal wall; And
A valve portion detachably coupled to the bushing portion and movably supporting the penetration portion;
The bushing portion,
A tubular insert inserted through the incision; And
An upper end of the insertion part is expanded and includes a seating part in which a detachable groove part is formed to which the valve part is coupled;
The valve unit,
A case inserted into the seating part;
A support part slidably and rotatably supporting the surgical instrument inserted into the case in left and right directions or in a vertical direction;
An inner case fixed to the support and coupled to the case;
A sealing part installed on the support part and in close contact with the penetrating part and formed of a plurality of pieces; And
A detachable part coupled to the detachable groove part;
The case,
An upper case to which the penetrating portion is detachably coupled; And
And a lower case seated on the seating portion and having a coupling protrusion penetrated into the upper case through the inner case;
The support portion,
A rotating ring rotatably installed in the inner case;
A support ring slidably installed in the inner case in a lateral direction and rotatably supporting the rotary ring; And
And a resilient support coupled to the rotary ring in a lateral direction or in a vertical direction and coupled to the inner case;
The rotating ring,
A first rotating ring having a mounting portion and an insertion hole portion coupled to the sealing portion and having a first curved portion rotatably seated on the inner case;
A second rotary ring penetrating through the sealing portion to form an insertion protrusion coupled to the insertion hole and having a second curved portion formed thereon; And
Laparoscopic surgical bushing device comprising a gap ring interposed between the sealing portion made of a plurality.
delete delete delete delete delete The method of claim 1, wherein the support ring,
A first support ring slidably installed in the inner case and slidably supporting the first curved portion; And
Laparoscopic surgical bushing device characterized in that it comprises a second support ring is formed in the second curved portion is slidably seated and a jaw portion is formed to be slidably inserted in the left and right in the inner case.
The method of claim 7, wherein
The elastic support portion is formed in a cylindrical shape and includes an elastic material, and an upper connection hole portion through which the coupling protrusion penetrates is formed at an upper end of the inner case and is interposed between the second rotation ring and the spacing ring. Laparoscopic surgical trocar device characterized in that the lower connecting hole is formed through the insertion protrusion is formed.
The method of claim 8, wherein the inner case,
A first inner case in which the accommodating part accommodating the first support ring is coupled and the coupling protrusion penetrates;
A second inner case formed with a fixing groove through which the coupling protrusion passes and the detachable part is rotatably inserted; And
Laparoscopic surgical bushing device, characterized in that it comprises a fixed case which is interposed between the first inner case and the second inner case and the step is formed to seat the jaw portion.
The method of claim 9, wherein the removable portion,
A locking piece having a rotating shaft rotatably inserted into the fixed groove, and a hook portion engaged with the detachable groove; And
Laparoscopic surgical bushing device, characterized in that it comprises an elastic portion extending from the engaging piece to provide a rotational force to the hook portion by pressing the second inner case.
The method of claim 1, wherein the sealing portion,
A first sealing part interposed between the first rotating ring and the spacer ring and including a plurality of sealing pieces formed of an elastic material and partially overlapping each other;
A second sealing part interposed between the spacing ring and the second rotation ring and having a hole part into which a surgical instrument is inserted and including an elastic material; And
Laparoscopic surgical bushing device which is interposed between the case and the inner case and includes a third sealing portion is formed and comprises an elastic material and a passage portion is inserted into the surgical instrument.
The method of claim 11,
A laparoscopic surgical bushing device, characterized in that the outer periphery of the sealing piece is formed with a through-hole portion through which the insertion protrusion passes, and an inner portion of the sealing piece is formed with a sealing curved surface that is inclined inwardly into the bushing portion.
The method of claim 11, wherein the second sealing portion,
A sealing body formed concave inwardly of the bushing part, the hole part being formed, and including an elastic material; And
Laparoscopic surgical bushing device characterized in that it comprises a reinforcing member fused to the sealing body bottom surface.
The method of claim 13,
Laparoscopic surgical bushing, characterized in that the reinforcing rib is formed on the interface between the sealing body and the reinforcing member.
The method of claim 13,
The reinforcing member is a laparoscopic surgical bushing comprising a fiber material.
The method of claim 11,
The third sealing part is formed to be concave inside the bushing part, and a bottom portion of the third sealing part is cut in a '×' shape to form the through part, and a bent part is bent to the outside of the bushing part between the through parts. Laparoscopic surgical bushing device, characterized in that.
The method of claim 1, wherein the penetrating portion,
An insertion tube penetrating the valve unit and coupled to the tube unit;
A blade portion installed at a lower end of the insertion tube and including a transparent material; And
Laparoscopic surgical bushing device, characterized in that it comprises a head portion is installed on the upper end of the insertion tube and the coupling portion detachably connected to the valve unit.
(A) forming a sealing body of the elastic material coupled to the rotary ring rotatably supporting the surgical instrument inserted into the incision of the human body;
(b) fusing a reinforcing member to the sealing body;
(c) forming a first hole in the sealing body and the reinforcing member;
(d) applying the sealing body to the first hole; And
(e) a method of manufacturing a laparoscopic surgical bushing device, comprising molding a second hole portion relatively smaller than the first hole portion in the sealing body.
The method of claim 18,
In step (d), the method of manufacturing a laparoscopic surgical bushing device, characterized in that the reinforcing rib orthogonal to the second hole portion is formed.

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