KR101089101B1 - Retract apparatus for laparoscopy surgery - Google Patents

Abstract

PURPOSE: A towing device for laparoscope operation is provided to prevent the damage of a connection part of a port part and a main body part by a surgical instrument and to easily control the surgical instrument which is inserted through the port part. CONSTITUTION: A bushing pack(10) is inserted into the cutting part of a human body. A main body part(30) is combined to the bushing pack. The main body part maintains a traction state of the cutting part. A surgical instrument is inserted into a port part(60). A connection part(50) is installed between the main body member and port part. The connection part movably supports the port part. A port main body is installed in the connection part. A port main body cover is combined to the port main body. A sealing part prevents fluid to be discharged to outside of the port main body and is located between the port main body and the port main body cover.

Description

Laparoscopic Traction Device {RETRACT APPARATUS FOR LAPAROSCOPY SURGERY}

The present invention relates to a traction device for laparoscopic surgery, and more particularly, to a laparoscopic surgery traction device that can support the surgical instrument to be easily manipulated and prevent it from being damaged by the surgical instrument.

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.

Recently, a single laparoscopic surgery has been performed in which a plurality of surgical instruments are inserted into one incision by cutting the navel to minimize the scars remaining on the human body after laparoscopic surgery.

When a single laparoscopic operation is performed, the laparoscopic surgical traction device is installed in the incision, and then a trocar device is installed in the traction device, and a surgical device is inserted into the incision through the trocar to perform single laparoscopic surgery. Will be done.

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.

General laparoscopic traction device is placed adjacent to the incision of the human body and because the port portion is inserted into the surgical instrument to maintain a fixed state can not easily manipulate the surgical instrument inserted through the port portion, a plurality of surgical instruments When inserted, there is a problem that interference occurs between the surgical instruments.

In addition, the general laparoscopic traction device has a problem that the connection between the port portion and the main body portion is easily broken by the operating force of the surgical instrument inserted into the human body through the port portion.

Therefore, there is a need for improvement.

An object of the present invention is to provide a traction device for laparoscopic surgery that can be easily operated by inserting a plurality of surgical instruments through the port portion and can prevent the traction device from being broken by the surgical instruments.

In order to achieve the above object, the present invention, a trocar pack inserted into the incision of the human body, the main body portion is coupled to the trocar pack to maintain the traction state of the incision, the port portion is inserted into the surgical instrument, It is provided between the main body and the port portion and provides a traction device for laparoscopic surgery comprising a connecting portion for supporting the port portion to be movable.

The bushing pack may include a bushing main body inserted into the incision and including a synthetic resin material, an insertion ring installed at one end of the bushing main body, a fixing ring installed at the other end of the bushing main body, and installed in the insertion ring. Characterized in that it comprises a handle portion.

In addition, the bushing body, the insertion ring is formed into a tubular shape so as to maintain a spacing with the incision in the state inserted into the abdominal wall inside the incision portion, characterized in that it comprises a flexible synthetic resin material It is done.

In addition, the main body portion, the first body portion is inserted into the bushing body and the curved body for supporting the inner wall of the bushing body is formed, and the second body portion for pressing the outer wall of the bushing body and coupled to the first body portion And a third body portion for pressing the second body portion toward the curved portion side.

The second main body may include a first coupling ring having a curved cross-sectional shape to be in close contact with the curved portion and a locking portion formed thereon, and a locking jaw assembled with the first coupling ring to form a ring shape and coupled with the locking portion. It characterized in that it comprises a second coupling ring formed additionally.

In addition, the third body portion, a first pressure ring for pressing the second body portion, a second pressure ring rotatably connected to the first pressure ring and pressurizing the second body portion, and the first pressure ring And a restrainer for detachably connecting the second pressing ring.

The port unit may be interposed between the port body installed in the connection unit, the port body cover coupled to the port body, and the port body and the port body cover, and prevent fluid from being discharged to the outside of the port body. And a gap ring interposed between the sealing portion and the sealing portion.

The sealing part may include a first sealing part including a plurality of sealing pieces interposed between the port body cover and the spacer ring and including an elastic material and partially overlapping each other, and the spacer ring and the port. A second sealing portion is formed between the main body and the hole is inserted into the surgical instrument and comprises an elastic material, and a passage part interposed between the port body and the port body cover and inserting the surgical instrument is formed and the elastic material is formed. It characterized by including a third sealing portion made of.

In addition, the outer edge of the sealing piece is formed with a through-hole portion into which the fixing projections of the port body cover are inserted, and an inner portion of the sealing piece is formed with a sealing curved surface that is inclined inwardly into the port body.

The second sealing part may include a sealing body formed concave inside the port body, 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, the reinforcing member is characterized in that it comprises a fiber material.

In addition, the reinforcing member is to be impregnated into the sealing body.

In addition, the third sealing portion is formed to be concave inside the port body, the bottom surface of the third sealing portion is cut in a 'ㅧ' shape to form the passage portion, the bending between the passage body is bent to the outside of the port body It is characterized in that the addition is formed.

The connection part may include a coupling part having a detachable protrusion coupled to the main body part, and an elastic part including a plurality of extension parts formed of an elastic material and fused to the coupling part and provided with the port part. It features.

In addition, the elastic portion, characterized in that formed when the operating fluid is injected into the connection portion is formed in a curved shape protruding convexly toward the outer side of the main body portion so that the extension portion can be opened in the outer direction.

Laparoscopic traction device according to the present invention because the trocar body extends to the outside of the incision of the human body and the distance between the incision and the traction device can be changed according to the taste of the operator and the port portion is supported to be movable, so the incision through the port portion The extent to which the surgical instrument inserted into the negative portion can be moved has an advantage of easily operating the surgical instrument.

In addition, the laparoscopic surgical traction apparatus according to the present invention is connected to the main body and the port portion by a connecting portion including a flexible synthetic resin material, so when the working fluid is filled in the connection portion is a surgical instrument that is inserted through the port portion is opened to the outside There is an advantage that can prevent the interference between, and prevent the breakage of the connection by the contact of the surgical instrument and the connection.

1 is an exploded perspective view showing a traction device for laparoscopic surgery according to an embodiment of the present invention.
Figure 2 is an exploded perspective view showing the connection portion of the traction device for laparoscopic surgery according to an embodiment of the present invention.
Figure 3 is an exploded perspective view showing the port portion of the laparoscopic surgical traction device according to an embodiment of the present invention.
Figure 4 is a cross-sectional view showing the port portion of the traction device for laparoscopic surgery according to an embodiment of the present invention.
Figure 5 is a bottom perspective view showing a sealing piece of the traction device for laparoscopic surgery according to an embodiment of the present invention.
Figure 6 is a bottom perspective view of the second sealing portion of the traction device for laparoscopic surgery according to an embodiment of the present invention.
7 is a cross-sectional view showing a second sealing portion of the traction device for laparoscopic surgery according to an embodiment of the present invention.
8 is a bottom perspective view of the third sealing part of the laparoscopic traction device according to an embodiment of the present invention.
9 is a view showing the insertion state of the trocar body of the traction device for laparoscopic surgery according to an embodiment of the present invention.
10 is a view showing a first main body insertion state of the laparoscopic surgical traction apparatus according to an embodiment of the present invention.
11 is a view showing a second main body connection state of the laparoscopic surgical traction device according to an embodiment of the present invention.
12 is a view showing a state of bending of the body of the laparoscopic surgery traction device according to an embodiment of the present invention.
Figure 13 is an exploded view showing the coupling structure of the body portion and the connecting portion of the traction device for laparoscopic surgery according to an embodiment of the present invention.
14 is a view showing a combined state of the traction device for laparoscopic surgery according to an embodiment of the present invention.
15 is a perspective view showing a combined state of the laparoscopic surgical traction device according to an embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings will be described an embodiment of the traction device for laparoscopic surgery according to the present invention.

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 an exploded perspective view showing a laparoscopic surgical traction device according to an embodiment of the present invention, Figure 2 is an exploded perspective view showing a connection portion of the laparoscopic surgical traction device according to an embodiment of the present invention, Figure 3 4 is an exploded perspective view showing the port portion of the laparoscopic surgical traction apparatus according to an embodiment of the present invention, Figure 4 is a cross-sectional view showing the port portion of the laparoscopic surgical traction apparatus according to an embodiment of the present invention.

In addition, Figure 5 is a bottom perspective view showing a sealing piece of the laparoscopic surgical traction device according to an embodiment of the present invention, Figure 6 is a second sealing portion of the laparoscopic surgical traction device according to an embodiment of the present invention Is a bottom perspective view, Figure 7 is a cross-sectional view showing a second sealing portion of the laparoscopic surgical traction device according to an embodiment of the present invention, Figure 8 is a third sealing of the laparoscopic surgical traction device according to an embodiment of the present invention An additional perspective view of the bottom.

1 to 8, the laparoscopic surgical traction apparatus according to an embodiment of the present invention is coupled to the bushing pack 10 and the bushing pack 10 is inserted into the incision of the human body to the traction state of the incision Main body portion 30 to maintain, the port portion 60 is inserted into the surgical instrument, the port portion 60 is supported to be movable and includes a connecting portion 50 that is detachably coupled to the main body portion 30 .

After inserting the bushing pack 10 into the incision of the human body, the main body 30 is coupled to the bushing pack to maintain the traction state in which the incision opens to a certain size, and when the connecting portion 50 is coupled to the body portion 30, The port part 60 is connected to the main body 30 in a fluid manner.

Since the port part 60 is arranged to be movable while maintaining a predetermined distance from the main body part 30 by the connecting part 50, when the gas is injected into the bushing pack 10 and the connecting part 50, the connecting part 50 expands. While the port 60 is opened in the lateral direction.

Therefore, the surgical instrument inserted into the incision through the port 60 is increased in the radius of the flow that can be flowed in the state inserted into the port 60, the effect can be easily performed single laparoscopic surgery Will appear.

The bushing pack 10 includes a bushing main body 12 inserted into the incision and including a synthetic resin material, an insertion ring 14 installed at one end of the bushing main body 12, and installed at the other end of the bushing main body 12. Fixing ring 16 and the handle portion 18 is installed on the insertion ring (14).

The bushing body 12 is formed in a cylindrical shape so that the fixing ring 16 can maintain the gap with the incision in the state in which the insertion ring 14 is inserted into the abdominal wall inside the incision, and comprises a flexible synthetic resin material. .

The insertion ring 14 is made of an elastic material that can be deformed. Therefore, when the insertion ring 14 is deformed and inserted into the abdominal wall inside the incision, the insertion ring 14 is unfolded by the restoring force, and the ring is formed in the abdominal wall. Is restored.

The bushing main body 12 disposed outside the incision is kept open by the fixing ring 16 of elastic material, and the bushing main body 12 inserted into the abdominal wall is kept open by the insertion ring 14. do.

At this time, the bushing body 12 is formed long enough to extend to the outside of the incision, it is possible to install the body portion 30 in a position that suits the taste of the operator.

If the main body 30 is provided such that a gap is formed between the main body 30 and the cutout, the bushing main body 12 made of a soft synthetic resin material may be bent in a lateral direction so that an operator may adjust the main body (to his liking). 30) can be placed and used to insert the surgical instrument in the desired direction.

The main body portion 30 includes a first body portion 32 which is inserted into the bushing main body 12 and is formed with a curved portion 32a supporting the inner wall of the bushing main body 12, and an outer wall of the bushing main body 12. And a second body portion 33 which is pressed and coupled to the first body portion 32, and a third body portion 34 which presses the second body portion 33 to the curved portion 32a side.

The first body portion 32 is formed in a disk shape, the hole portion through which the surgical instrument passes in the center is formed and the curved surface portion 32a is convexly formed in the outer direction.

Therefore, when the first body portion 32 is inserted into the bushing body 12, the curved portion 32a contacts the inner wall of the bushing body 12, and presses the outer wall of the bushing body 12 toward the curved portion 32a. When the second main body part 33 is coupled to the first main body part 32, the bushing main body 12 is interposed between the second main body part 33 and the curved part 32a, and the towing body 12 is opened. Is maintained.

The second body part 33 is a semi-circular first coupling ring 33a, and a second coupling ring 33b formed in a semicircular shape and assembled with the first coupling ring 33a to be in close contact with the curved surface portion 32a. ).

The first coupling ring 33a and the second coupling ring 33b are formed in a semi-circular shape so that the curved portion 32a is inserted into and closely contacted with each other, and the first coupling ring 33a and the second coupling ring 33b are formed. At both ends, hook-shaped locking portions 33c or locking jaw portions 33d are formed, respectively.

Therefore, when the first coupling ring 33a and the second coupling ring 33b are assembled to face the curved portion 32a of the first body portion 32 outside the bushing body 12, the locking portion 33c and the locking jaw portion While the 33d is engaged, the bushing main body 12 is pressed toward the curved portion 32a.

The third body part 34 includes a first pressure ring 36 for urging the second body part 33 toward the curved surface part 32a, and a second body part rotatably connected to the first pressure ring 36. Restriction parts 38a and 38b for detachably connecting the second pressure ring 38 to press the part 33 toward the curved portion 32a and the first pressure ring 36 and the second pressure ring 38. It includes.

Since the first pressing ring 36 and the second pressing ring 38 are formed in a semicircular shape and one end thereof is rotatably connected to each other, the first pressing ring 36 and the second pressing ring 38 are connected to the second main body. When the first pressure ring 36 and the other end of the second pressure ring 38 are coupled to each other after being disposed to face the outer wall of the 33, the first pressure ring 36 and the second pressure ring 38 are connected to the second pressure ring 38. It comes in close contact with the outer wall of the main body part 33.

At this time, the restraining parts 38a and 38b are operated to connect the other end portions of the first pressing ring 36 and the second pressing ring 38, and the restraining parts 38a and 38b are connected to the first pressing ring 36. And a locking groove portion 36a formed at the other end of the hook portion, and a locking protrusion 38a formed at the other end of the second pressing ring 38 and detachably coupled to the locking groove portion 36a.

Since the cross-sectional shapes of the first pressure ring 36 and the second pressure ring 38 are formed in a curved shape protruding outwardly, the first pressure ring 36 and the second pressure ring 38 are formed in the second body. When coupled to the outer wall of the portion 33, the outer wall of the second body portion 33 is in close contact with the inner wall of the first pressing ring 36 and the second pressing ring 38, the second body portion 33 is curved surface ( 32a).

Before engaging the first pressure ring 36 and the second pressure ring 38, the upper portion of the bushing body 12 interposed between the first body portion 32 and the second body portion 33 is folded downward. After arranging to contact the outer wall of the second body portion 33, the first pressure ring 36 and the second pressure ring 38 are combined to press the outer wall of the bushing body 12 to the second body portion side. A bushing main body 12 is interposed between the main body 33 and the third main body 34.

Thus, the bushing main body 12 passes through the gap between the first main body part 32 and the second main body part 33 and then passes through the gap between the second main body part 33 and the third main body part 34. do.

As described above, the gap between the bushing main body 12 and the main body 30 is sealed twice, so that the gas or fluid filled in the cutout and the bushing main body 12 is filled in the bushing main body 12 and the main body part ( It is possible to prevent the discharge at intervals between the 30).

Since the sealing between the bushing body 12 and the main body 30 is made in two steps as described above, the operator can adjust the height of the main body 30 according to taste.

When the main body 30 is disposed high so as to maintain a gap with the incision, the bushing body 12 including the synthetic resin material may be easily deformed or folded, so that the operator may bend the bushing body 12 laterally to operate the surgical instrument. It can be inserted into the incision through the port portion 60 while lying down.

The port part 60 is interposed between the port body 62 provided in the connecting portion 50, the port cover 64 coupled to the port body 62, and the port body 62 and the port cover 64. And a sealing part 70 for preventing fluid from being discharged to the outside of the port body 62 and a gap ring 66 interposed between the sealing parts 70.

Since the port body 62 is formed in a cylindrical shape and coupled to the connecting portion 50, the surgical instrument inserted through the port body 62 passes through the connecting portion 50 and passes through the first body portion 32 to the incision portion. Is inserted.

The port cover 64 is formed in a ring shape and coupled to the outer end of the port body 62, so that the port cover 64 can support the sealing portion 70 interposed between the port body 62 and the port cover 64.

Therefore, when the surgical instrument is inserted into the port 60, the sealing portion 70 forms a state in close contact with the outer wall of the surgical instrument to prevent the fluid from being discharged along the gap between the port 60 and the surgical instrument. It becomes possible.

The sealing part 70 may include a first sealing part including a plurality of sealing pieces 74 interposed between the port cover 64 and the spacer ring 66 and including an elastic material and partially overlapping each other. 72, a second sealing portion 76 formed between the gap ring 66 and the port body 62 and having a hole into which the surgical instrument is inserted and including an elastic material, and the port body 62 and the port. It includes a third sealing portion 78 is formed between the cover 64 and the passage portion 78a is inserted into the surgical instrument and comprises an elastic material.

When the surgical instrument is inserted along the port portion 60, the first sealing portion 72, the second sealing portion 76, and the third sealing portion 78 made of an elastic material closely adhere to the outer wall of the surgical instrument and thus the port portion ( The fluid is prevented from being discharged along the gap between the head 60 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 fixing projection 64a of the port cover 64 is inserted is formed at the outer edge of the sealing piece 74, and the inner portion of the sealing piece 74 is inclined to be concave inside the port body 62. The sealing curved surface portion 74b 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, and thus, a plurality of sealing pieces 74 are attached to the fixing protrusion 64a formed at the edge of the port cover 64. 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 portion 74b is formed to be concave inside the port body 62, when the surgical instrument is inserted into the port body 62, the sealing piece 74 is easily deformed into the port body 62. When the surgical instrument is slid out of the port body 62, the sealing curved portion 74b is not easily deformed, thereby preventing the fluid from being discharged to the outside of the port body 62 along the surgical instrument.

The second sealing portion 76 is fused to the sealing body 77 and the bottom surface of the sealing body 77, which are formed concave inside the port body 62, the hole portions 77a and 77b are formed, and include an elastic material. It includes a reinforcing member (79).

When the surgical instrument is inserted into the port main body 62, the sealing main body 77 is deformed and the holes 77a and 77b are expanded, so that the surgical body passes. State is achieved.

When the surgical instrument is slid out of the port body 62, the sealing body 77 is deformed to the outside of the port body 62 and maintained in close contact with the outer wall of the surgical instrument.

The sealing body 77 is formed in a shape similar to a hemispherical shape in which a plurality of sealing pieces 74 are overlapped. When the surgical instrument is discharged to the outside of the port body 62, 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 the hole portions 77a and 77b in one structure having a hemispherical shape, the amount of deformation compared to the sealing piece 74 when the surgical instrument is discharged to the outside of the port body 62. This will be a lot.

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 port body 62, a deformation occurs in which the sealing body 77 concavely formed inside the port body 62 is reversed to the outside of the port body 62.

Here, since the reinforcing member 79 is made of a material having a smaller friction coefficient than 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 port body 62, the sealing body ( When 77 is deformed to the outside of the port body 62, the reinforcing member 79 is in contact with the outer wall of the surgical instrument.

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 port body 62. It is possible to prevent the deformation of the body 62 outside more than necessary.

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.

When fabricating the second sealing portion 76, an injection process using an elastic material is performed to produce a bowl-shaped sealing body 77, and then heat-seal the reinforcing member 79 to the bottom of the sealing body 77. The strength of the sealing body 77 is improved.

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 third sealing portion 78 is formed to be concave inside the port body 62, the bottom surface of the third sealing portion 78 is cut in a 'ㅧ' shape to form a passage portion 78a, and a passage portion 78a. Between the port body 62 is bent portion 78b is formed between.

The third sealing portion 78 is formed in a cylindrical shape and a bottom surface is formed at an end facing inward of the port body 62, and the bottom surface is cut in a 'ㅧ' 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 port body 62, 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 port body 62, the vertex forming the passage portion 78a is opened and the surgical instrument is passed. When the surgical instrument is slid out of the port body 62, 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 port body 62.

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 port body 62, the surgical instrument passes through the third sealing portion 78 and the inclined surface (a) when the passage 78a opens. While 78c is in close contact with the inner wall of the port body 62, the passage portion 78a is prevented from spreading beyond the fill.

The connection part 50 includes a coupling part 51 in which a detachable protrusion 51b coupled to the main body part 30 is installed, and an elastic material. The connection part 50 is fused to the coupling part 51 and the port part 60 is It includes an elastic portion 54 is formed a plurality of extension portions (54a) to be installed.

The coupling part 51 is formed in a ring shape, the edge of the extension part 54a is fused, and a coupling ring 52 in which a plurality of coupling protrusions 52a are formed, and a coupling hole in which the coupling protrusion 52a is inserted It includes a support ring 53 is formed and the leaf spring (53a) for pressing the detachable protrusion (51b) in the outward direction.

The detachable protrusion 51b is formed to have a hook extending downward from the bottom of the support ring 53 and to be pressed outwardly of the support ring 53 by the leaf spring 53a.

Therefore, when the detachable protrusion 51b is slidably assembled between the connection ring 52 and the support ring 53, the elastic part 54 is fused to the edge of the connection ring 52 so that the lower end of the elastic part 54 is It is kept open in a circle shape.

The elastic portion 54 is formed in a curved shape projecting convexly toward the outer side of the main body portion 30, the plurality of extension portions 54a extend in the upward direction, and the port portion 60 in each of the extension portions 54a. ) Is installed.

Therefore, when the coupling portion 51 is attached to the main body portion 30, the elastic portion 54 and the extension portion 54a are extended upward to form a glove shape, so that surgical instruments are inserted into the respective port portions 60 to operate. Can be done.

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

9 is a view showing the insertion state of the trocar body of the laparoscopic surgical traction apparatus according to an embodiment of the present invention, Figure 10 is a first body portion insertion state of the laparoscopic surgical traction apparatus according to an embodiment of the present invention 11 is a view showing a second main body connection state of the laparoscopic surgical traction apparatus according to an embodiment of the present invention, Figure 12 is a laparoscopic surgical traction according to an embodiment of the present invention The bent body bending state of the apparatus is shown.

In addition, Figure 13 is an exploded view showing the coupling structure of the body portion and the connecting portion of the laparoscopic surgical traction device according to an embodiment of the present invention, Figure 14 is a combination of the laparoscopic surgical traction device according to an embodiment of the present invention State is a diagram showing, Figure 15 is a perspective view showing a combined state of the traction device for laparoscopic surgery according to an embodiment of the present invention.

1 to 15, the insertion ring 14 is deformed to insert the insertion ring 14 and the bushing main body 12 into the incision of the human body, and then the first main body part 32 inside the bushing main body 12. ) And a second main body part 33 and the first main body part 32 which are disposed outside the body of the bushing body 12 to form a pulled state in which the body of the body body 12 is opened.

Subsequently, when the fixing ring 16 is moved downward while deforming the fixing ring 16 installed at the upper end of the bushing main body 12, the outer wall of the second main body part 33 is folded while the bushing main body 12 is folded downward. At this time, the first body portion 32 is exposed to the outside of the bushing body (12).

When the third main body 34 is coupled to the second main body 33 so as to be in close contact with the outer wall of the bushing main body 12, the bushing main body 12 is disposed between the third main body 34 and the second main body 33. ) Is interposed.

At this time, the height of the body portion 30 can be adjusted according to the convenience of the operator, the position of the first body portion 32 at the height required by the operator when inserting the first body portion 32 into the bushing body 12 After the coupling operation is performed as described above, the bushing main body 12 may be disposed at a height that maintains a gap from the incision of the human body.

When the main body portion 30 is exposed to the outside of the bushing body 12, the coupling portion 51 is seated on the upper surface of the body portion 30, and the detachable protrusion 51b of the coupling portion 51 is the first body portion 32. Inserted into the coupling groove portion 32b of the main body 30 and the connection portion 50 is formed.

As described above, when the traction device is installed, the operation fluid is injected into the connection part 50 through the gas injection pipe 56 installed on the coal tank, and the surgical instrument is inserted through the port part 60 to perform the surgery. do.

When the surgical instrument is inserted into the port part 60, the human body has passed through the first sealing part 72, the second sealing part 76, and the third sealing part 78 to pass through the connecting part 50 and the main body part 30. The surgical instrument is inserted into the incision of the.

At this time, when the surgical instrument passes through the first sealing unit 72, the sealing pieces 74 arranged to overlap each other are formed to be in close contact with the outer wall of the surgical instrument, so that the surgical instrument and the port body 62 The fluid is prevented from being discharged to the outside of the port portion 60 at intervals.

In addition, when the surgical instrument passes through the second sealing portion 76, the sealing body 77 is deformed into the port body 62 while the hole portions 77a and 77b are expanded to pass the surgical instrument, and the sealing body 77 It is maintained in close contact with the outer wall of the surgical instrument.

In addition, when the surgical instrument passes through the third sealing portion 78, the vertex of the passing portion 78a opens outward, and the surgical instrument passes through the third sealing portion 78 and is provided from the bent portion 78b. The vertices of the passage portion 78a are brought into close contact with the outer wall of the surgical instrument by the elastic force.

Since the diameters of the port body 62 and the port cover 64 which are installed in each port part 60 are variously formed, different kinds of surgical instruments may be selectively inserted into the port part 60, and the port part 60 is supported by the elastic part 54 and the extension part 54a which comprise an elastic material so that a flow is possible.

Therefore, when the surgical instrument is inserted into each of the port portions 60 to perform the operation, the port portion 60 freely flows due to the deformation of the elastic portion 54 and the extension portion 54a. It becomes easy to operate.

When the surgical instrument is pulled out of the port 60, the sealing piece 74, the sealing body 77, and the passage 78a are deformed to the outside of the port body 62, and the surgical instrument is slid out of the port.

At this time, the sealing piece 74 is because the surgical instrument is sliding while the overlapping portion of the plurality of sealing pieces 74 is opened, the sealing piece 74 is not damaged and the surgical instrument is discharged.

In addition, since the sealing body 77 is prevented from being damaged by the reinforcing member 79, and the reinforcing member 79 having a relatively small friction coefficient is in contact with the surgical instrument as compared with the sealing body 77, the surgical instrument and the sealing body The friction force between the 77 is reduced to facilitate the withdrawal of the surgical instrument.

In addition, the passage portion 78a is a fluid discharged to the outside through the port body 62 while the vertices are collected in the center of the passage portion 78a by the restoring force provided by the bent portion 78b after the surgical instrument is drawn out. Will be prevented.

Thus, it is possible to provide a traction device for laparoscopic surgery that can support the surgical instrument to be easily manipulated and prevent it from being broken by 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 traction device has been described as an example, but this is merely exemplary, and the traction device of the present invention may be used in other products other than the laparoscopic surgical traction device.

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

10: bushing pack 12: bushing body
14: insert ring 16: fixed ring
18: handle portion 30: body portion
32: first body portion 32a: curved surface portion
32b: coupling groove 33: second body
33a: first coupling ring 33b: second coupling ring
33c: locking portion 33d: locking jaw
34: third body portion 36: the first pressure ring
36a: locking groove 38: second pressing ring
38a: protrusion 50: connection portion
51: coupling part 51a: intermediate ring
51b: detachable protrusion 52: connection ring
52a: engaging protrusion 53: support ring
53a: leaf spring 54: elastic portion
54a: extension part 56: gas injection pipe
60: port portion 62: port body
64: port cover 70: sealing part
72: first sealing portion 74: sealing piece
74a: through hole portion 74b: sealing curved portion
76: second sealing unit 77: sealing body
77a: hole portion 77b: mounting hole portion
77d: reinforcement rib 78: third sealing part
78a: passage portion 78b: bend portion
78c: inclined surface 79: reinforcing member

Claims (15)

Bushing pack is inserted into the incision of the human body;
A main body part coupled to the bushing pack to maintain a traction state of the incision;
A port part into which a surgical instrument is inserted; And
A connection portion provided between the main body portion and the port portion and movably supporting the port portion;
The port portion,
A port body installed at the connection unit;
A port body cover coupled to the port body;
A sealing part interposed between the port body and the port body cover to prevent the fluid from being discharged to the outside of the port body; And
A gap ring interposed between the sealing parts;
The sealing unit,
A first sealing part interposed between the port body cover and the spacing ring and including a plurality of sealing pieces made of an elastic material and partially overlapping each other;
A second sealing part interposed between the gap ring and the port body and having a hole part inserted into a surgical instrument and including an elastic material; And
Laparoscopic traction apparatus for a laparoscopic surgery characterized in that it comprises a third sealing portion which is formed between the port body and the port body cover and is inserted into the surgical instrument is inserted and comprises an elastic material.
According to claim 1, The bushing pack,
A bushing body inserted into the incision and including a synthetic resin material;
An insertion ring installed at one end of the bushing body;
A fixing ring installed at the other end of the bushing body; And
Laparoscopic surgical traction apparatus comprising a handle portion installed in the insertion ring.
The method of claim 2,
The bushing body is formed in a tubular shape so as to maintain a spacing with the incision in the state in which the insertion ring is inserted into the abdominal wall inside the incision portion characterized in that it comprises a flexible synthetic resin material Laparoscopic traction device.
The method of claim 2, wherein the main body portion,
A first body part inserted into the bushing body and having a curved portion supporting an inner wall of the bushing body;
A second body part which presses an outer wall of the bushing body and is coupled to the first body part; And
Laparoscopic surgical traction apparatus comprising a third body portion for pressing the second body portion toward the curved portion side.
The method of claim 4, wherein the second body portion,
A first coupling ring having a curved cross-sectional shape to be in close contact with the curved portion and having a locking portion formed thereon; And
Laparoscopic surgical traction apparatus comprising a second coupling ring is assembled with the first coupling ring to form a ring shape and the engaging jaw portion is coupled to the engaging portion.
The method of claim 4, wherein the third body portion,
A first pressurizing ring pressurizing the second main body;
A second pressurizing ring rotatably connected to the first pressurizing ring and pressurizing the second main body; And
Laparoscopic traction apparatus comprising a restraining portion detachably connecting the first pressure ring and the second pressure ring.
delete delete The method of claim 1,
Laparoscopic traction device, characterized in that the outer periphery of the sealing piece is formed with a through-hole portion into which the fixing protrusion of the port body cover is inserted, and an inner portion of the sealing piece is formed with a sealing curved surface concave inclined toward the inside of the port body. .
The method of claim 1, wherein the second sealing portion,
A sealing body formed concave inside the port body, the hole portion is formed, and includes an elastic material; And
Laparoscopic surgical traction apparatus comprising a reinforcing member fused to the sealing body bottom surface.
The method of claim 10,
The reinforcement member is a laparoscopic surgical traction device characterized in that it comprises a fiber material.
The method of claim 10,
The reinforcing member is pulled device for single fastening surgeries, characterized in that the sealing body is impregnated.
The method of claim 1,
The third sealing part is formed to be concave inside the port body, and the bottom surface of the third sealing part is cut into a 'ㅧ' shape to form the through part, and a bent part is bent to the outside of the port body between the through parts. Traction device for laparoscopic surgery, characterized in that it is.
The method of claim 1, wherein the connection portion,
A coupling part having a detachable protrusion coupled to the main body part; And
Laparoscopic surgical traction apparatus comprising an elastic portion made of an elastic material and fused to the coupling portion and formed with a plurality of extension portions provided with the port portion.
The method of claim 14,
The elastic part, the laparoscopic surgical traction apparatus characterized in that it is formed in a curved shape protruding convexly in the outward direction of the main body portion when the working fluid is injected into the connection portion to open in the outward direction.

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