KR102609840B1 - Medical suture stretching device using indirect heat - Google Patents

Abstract

The present invention can improve mechanical strength and flexibility by injection molding medical suture and then stretching it. More specifically, the suture made of a biodegradable polymer component that has the property of decomposing upon contact with water is not in contact with water. This relates to a medical suture stretching device using indirect heat that can be stretched using indirect heat.
For this purpose, a medical suture stretching device using indirect heat according to an embodiment of the present invention includes a stretching chamber capable of stretching a suture by introducing indirect heat, and operating in the stretching direction of the suture inside the stretching chamber to stretch the suture. It includes a stretching unit that blows indirect heat from the outside of the stretching chamber to the inside of the stretching chamber.

Description

Medical suture stretching device using indirect heat}

The present invention can improve mechanical strength and flexibility by injection molding medical suture and then stretching it. More specifically, the suture made of a biodegradable polymer component that has the property of decomposing upon contact with water is not in contact with water. This relates to a medical suture stretching device using indirect heat that can be stretched using indirect heat without using a suture.

In general, medical sutures are used to suture incised skin and are mainly used for surgical or cosmetic medical purposes.

Recently, it is also used for beauty purposes by inserting it into the skin to lift the skin.

These sutures are usually made of materials that do not decompose in the human body, such as nylon or prolene, but there is a problem that they must be removed over time.

In addition, if it is inserted into the skin for a long time, it adheres to skin tissue, making removal difficult.

In order to solve the above problems, sutures have recently been manufactured and used using biodegradable materials.

Sutures are generally used by molding threads and cogs by injection. When sutures are molded by injection, it is difficult to mold them to a desired diameter.

In order to solve the above problems, in Prior Literature 1 (Registered Patent No. 10-1926311 Method for manufacturing medical sutures with improved mechanical strength and flexibility through underwater stretching after injection), homogeneous physical properties were obtained by heating and stretching the injection molded sutures in water. A configuration that allows calculation while having is disclosed.

However, in Prior Literature 1, since the suture is stretched while submerged in water, when using a biodegradable polymer, the problem of dissolution by water as it comes into contact with water occurs.

Prior Document 1 (Registered Patent No. 10-1926311 Method for manufacturing medical sutures with improved mechanical strength and flexibility through underwater stretching after injection)

The present invention was developed to solve the above-mentioned problems. In the process of injection molding and stretching a suture made of a biodegradable polymer, the suture is heated using indirect heat while being stretched so that it does not come into contact with water. The purpose of the present invention is to provide a medical suture stretching device using indirect heat that can allow sutures made of biodegradable polymer materials to be stretched evenly without being damaged, and can easily fix and stretch four sutures at the same time.

A medical suture stretching device using indirect heat according to an embodiment of the present invention to solve the above problems includes a stretching chamber capable of stretching a suture by introducing indirect heat, and operating in the stretching direction of the suture within the stretching chamber. It is characterized in that it includes a stretching unit that stretches the suture and an indirect heat blowing unit that blows indirect heat from the outside of the stretching chamber to the inside of the stretching chamber.

Here, the stretching chamber includes a casing with the stretching part built into it to stretch the suture, and an indirect heat filling part formed inside the casing to heat and stretch the suture due to the indirect heat as it is filled with indirect heat. It is characterized by including.

And the stretching part includes a suture fixing part that fixes one end of the injection-molded suture, and a suture stretching part that stretches the suture by pulling it in a fixed state at the other end of the suture fixing part. The upper part and the suture extension part are each provided with a suture fixing jig capable of fixing the suture, and the suture extension part is moved by a ball screw and is capable of stretching the suture.

The medical suture stretching device using indirect heat according to an embodiment of the present invention has the effect of preventing damage such as dissolution due to contact with water by stretching the biodegradable polymer material using indirect heat to prevent it from coming into contact with water. there is.

In addition, by stretching the suture using a precision-driven ball screw structure, there is an effect of stretching the suture evenly at a constant speed.

In addition, when blowing indirect heat, it is not blown directly to the suture, but is blown to the lower part where the suture is stretched, thereby maintaining the temperature inside the stretching chamber through convection, which has the effect of stretching the suture without damage caused by blowing.

Figure 1 is an overall perspective view of a medical suture stretching device using indirect heat according to an embodiment of the present invention.
Figure 2 is an exploded perspective view of a medical suture stretching device using indirect heat according to an embodiment of the present invention.
Figure 3 is a plan view showing in detail a suture extended by a medical suture stretching device using indirect heat according to an embodiment of the present invention.
Figure 4 is a plan view showing a state in which the suture is fixed to the suture fixing unit and the suture stretching unit in the medical suture stretching device using indirect heat according to an embodiment of the present invention.
Figures 5 and 6 are operating state diagrams showing a state in which a suture is stretched by a medical suture stretching device using indirect heat according to an embodiment of the present invention.
Figure 7 is a state diagram showing a state in which an indirect heat downward guide piece is installed in a medical suture stretching device using indirect heat according to an embodiment of the present invention.

The present invention relates to a device that can stretch medical sutures. In particular, medical sutures made of biodegradable polymer materials are stretched using indirect heat to avoid contact with water, thereby preventing dissolution and damage due to the characteristics of the material and uniformly stretching them. It is characterized by being stretchable.

Hereinafter, a medical suture stretching device using indirect heat according to an embodiment of the present invention will be described in detail with reference to the attached drawings.

Figure 1 is an overall perspective view of a medical suture stretching device using indirect heat according to an embodiment of the present invention, and Figure 2 is an exploded perspective view of a medical suture stretching device using indirect heat according to an embodiment of the present invention.

Referring to Figures 1 and 2, the present invention largely includes a stretching chamber 100 that provides a space for the suture 10 to be stretched by indirect heat, and a state in which the suture 10 is accommodated within the stretching chamber 100. It includes a stretching unit 200 that can be stretched as a whole by fixing one end and pulling the other end, and an indirect heat blowing unit 300 that blows indirect heat into the stretching chamber 100. It is composed by:

The stretching chamber 100 includes a casing 110 with a stretching portion 200 built inside to stretch the suture 10, and the stretching chamber 100 is formed inside the casing 110 to fill the casing 110 with indirect heat. It is configured to include an indirect heat filling part 120 that can heat and stretch the suture 10.

Here, the casing 110 is formed in the form of a rectangular box so that the stretching part 200 can be installed and moved in a straight direction, and the stretching part 200 is driven in a straight direction and has a space so that the suture 10 can be stretched. forms.

And the indirect heat filling unit 120, which is the internal space where the suture 10 is stretched, is filled inside when indirect heat is introduced by the indirect heat blowing unit 300, and maintains the temperature of the space where the suture 10 is stretched by raising the temperature. It becomes possible.

An indirect heat inlet hole 130 through which indirect heat can flow into the indirect heat filling unit 120 is formed on one side of the casing 110.

The indirect heat blowing unit 300 is connected to the indirect heat inlet hole 130 and heats air while flowing from the outside into the indirect heat filling unit 120, so that high temperature air flows into the indirect heat filling unit 120. It can be done as much as possible.

At this time, a confirmation window 140 may be installed on the upper part of the indirect heat filling part 120 to prevent indirect heat from leaking while checking the state in which the suture 10 is stretched inside the indirect heat filling part 120. .

The stretching portion 200 is fixedly installed at one end inside the indirect heat filling portion 120 and faces the suture fixing portion 210 capable of fixing the suture 10, and the suture fixing portion 210. It is provided to view and includes a suture stretching portion 220 that moves in the stretching direction while fixing the other end of the suture 10 and stretches the suture 10.

Here, the suture stretching portion 220 is installed on the stretching plate 221 and moves together as the stretching plate 221 moves, allowing the suture 10 to be stretched.

And the suture fixing part 210 and the suture stretching part 220 are each provided with a suture fixing jig 230 capable of fixing the suture 10.

The suture stretching part 220 is operated to stretch the suture 10 by a ball screw 240 provided in the stretching direction inside the casing 110, and an LM guide (LM guide) is installed on one side of the suture stretching part 220. 250) is provided so that the suture 10 can be stretched by precisely moving it in the stretching direction.

In addition, a stretching direction support shaft 260 that can support the stretching plate 221 to move in the stretching direction is provided at the central portion of the suture fixing portion 210 and the suture stretching portion 220.

At this time, the central portion of the stretching plate 221 is coupled so that it can move along the stretching direction support axis 260, and a ball screw 240 is connected to one side to form the ball screw 240. The stretching plate 221 can be driven reciprocally in the stretching direction by the rotation of .

In addition, an LM guide 250 is provided on the stretching plate 221 right next to where the ballscrew 240 is installed, so that the suture 10 can be stretched by moving at a stable and constant speed without movement by the LM guide 250. do.

Meanwhile, the suture fixing jig 230 is formed with four suture fixing frames 231 so that the sutures 10 can be installed in four directions: up, down, left, and right.

And the suture fixing frame 231 is provided with a suture fixing block 232 that can fix the suture 10 to the suture fixing frame 231 and prevent it from being separated.

At this time, a block detachment hole 233 through which the suture fixing block 232 can be detached is formed in the suture fixing frame 231.

Meanwhile, the suture fixing block 232 may be provided with a magnetic attachment portion 232a that can be easily attached without separate fixation by magnetism when detached from the suture fixing frame 231.

The indirect heat blowing unit 300 is installed on the outside of the casing 110 and blows air toward the indirect heat filling unit 120 through the indirect heat inlet hole 130, and the blowing fan 310 ) and a heating unit 320 provided between the indirect heat inlet hole 130 to heat the blown air and introduce it into the indirect heat filling unit 120.

As a result, the suture 10 is heated with indirect heat while it is fixedly installed inside the stretching chamber 100, and the disadvantage of being vulnerable to water due to the nature of the biodegradable material is overcome, making it possible to stretch the suture thread uniformly without damage.

Figure 3 is a plan view showing in detail a suture stretched by a medical suture stretching device using indirect heat according to an embodiment of the present invention.

Referring to Figure 3, the suture 10 is formed with a suture coupling portion 11 extending from both ends that can be fixed to the surgical equipment, and a cog 12 that protrudes at regular intervals or in a specific pattern as needed. is formed.

In addition, during injection molding, the sutures 10 are molded to form one injection molded product by a connecting line 13 that connects the plurality of sutures 10 to one injection molded product.

Figure 4 is a plan view showing a state in which the suture is fixed to the suture fixing unit and the suture stretching unit in the medical suture stretching device using indirect heat according to an embodiment of the present invention.

Referring to FIG. 4, one end of the suture 10 is caught and fixed in the suture fixing jig 230 on the suture fixing unit 210 side, and the other end is fixed to the suture fixing jig on the suture stretching unit 220 side. It is caught at (230) and fixed.

At this time, the connecting line 13 is caught on the suture fixing part 210 and the suture stretching part 220, and both ends of the suture 10 can be fixed respectively.

As described above, the connecting line 13 is caught on the suture fixing jig 230, and in a fixed state, the suture fixing frame 231 is coupled, and the suture 10 can be fixed so that it does not separate during the stretching process.

Figures 5 and 6 are operational state diagrams showing a state in which a suture is stretched by a medical suture stretching device using indirect heat according to an embodiment of the present invention.

Referring to Figure 5, one end of the suture 10 is fixed to the suture fixing unit 210 and the other end is fixed to the suture stretching unit 220, and the indirect heat blowing unit 300 is driven to stretch the suture. Heated air is blown into the indirect heat filling unit 120 inside the chamber 100.

At this time, the upper part of the indirect heat filling part 120 is made of a transparent material to prevent the indirect heat being blown from leaking, and the confirmation window 140 through which the stretching state of the suture inside can be checked is kept closed.

As a result, indirect heat is filled inside the indirect heat filling unit 120 and an appropriate temperature for stretching the suture 10 is maintained.

Referring to FIG. 6, while the suture 10 is fixed, the suture stretching unit 220 moves in the stretching direction by driving the ball screw 240 to stretch the suture 10.

The suture stretching portion 220 is fixed to the stretching plate 221 and slowly moves by the stretching plate 221 to stretch the suture 10.

At this time, the indirect heat filling unit 120 increases the ductility of the suture 10 by heating it to a temperature appropriate for stretching the suture 10 in a state filled with indirect heat, and when the suture stretching unit 220 moves accordingly, the suture 10 (10) is stretched uniformly.

The diameter of the suture 10 stretched as described above is reduced to a diameter appropriate for the procedure and is stretched to facilitate the procedure.

Figure 7 is a state diagram showing a state in which an indirect heat downward guiding piece is installed in a medical suture stretching device using indirect heat according to an embodiment of the present invention.

Referring to FIG. 7, the indirect heat inlet hole 130 may be provided with an indirect heat downward guiding piece 131 that guides the indirect heat downward when the indirect heat flows into the indirect heat filling unit 120.

The indirect heat downward inducing piece 131 guides the indirect heat to flow into the lower part of the indirect heat filling unit 120 when it flows in, so that the temperature inside the indirect heat filling unit 120 is formed evenly throughout the convection phenomenon. .

In addition, when indirect heat flows in, it flows into the suture 10 and prevents the suture 10 from flowing, thereby preventing the suture 10 from flowing due to blowing and becoming unevenly stretched.

The present invention, made as described above, is for stretching medical sutures. A suture made of a biodegradable polymer that dissolves and can be removed from the skin is manufactured by injection molding and stretched using indirect heat to dissolve the suture. It is possible to stretch it to a diameter appropriate for the procedure without it being damaged.

100: stretching chamber 110: casing
120: indirect heat filling part 130: indirect heat inlet hole
131: Indirect heat downward induction section 140: Confirmation window
200: stretching part 210: suture fixing part
220: suture stretching unit 221: stretching plate
230: Suture fixing jig 231: Suture fixing frame
232: Suture fixing block 232a: Magnetic attachment portion
233: Block detachment hole 240: Ball screw
250: LM guide 260: Stretching direction support axis
300: indirect heat blowing unit 310: blowing fan
320: Heating unit 10: Suture
11: suture joint 12: cog
13: connection line

Claims (3)

A stretching chamber 100 capable of stretching the suture 10 by introducing indirect heat;
A stretching unit 200 that operates in the stretching direction of the suture 10 inside the stretching chamber 100 and stretches the suture 10; and
In comprising an indirect heat blowing unit 300 that blows indirect heat from the outside of the stretching chamber 100 to the inside of the stretching chamber 100,
The stretching chamber 100 includes a casing 110 in which the stretching portion 200 is built to stretch the suture 10, and is formed inside the casing 110 to fill indirect heat. The indirect heat filling part 120, which can heat and stretch the suture 10 due to heat, is provided on the upper part of the indirect heat filling part 120 to check the state in which the suture 10 is being stretched inside. Includes a confirmation window 140 to prevent leakage,
The stretching part 200 includes a suture fixing part 210 that fixes one end of the injection molded suture 10, and a suture fixing part 210 that fixes the suture 10 at the other end of the suture fixing part 210. In including a suture stretching portion 220 that is pulled and stretched,
The suture fixing part 210 and the suture stretching part 220 are each provided with a suture fixing jig 230 capable of fixing the suture 10,
The suture fixing jig 230 is formed with four suture fixing frames 231 so that the sutures 10 can be installed in four directions, respectively, up, down, left, and right, and the suture fixing frames 231 are provided with sutures 10. ) is provided with a suture fixing block 232 that can be fixed to the suture fixing frame 231 and fixed so that it does not separate,
The suture fixing frame 231 is formed with a block detachment hole 233 through which the suture fixing block 232 can be detached,
The suture fixing block 232 is provided with a magnetic attachment portion 232a that can be easily attached without separate fixation by magnetism when detached from the suture fixing frame 231,
The suture stretching unit 220 is moved by a ball screw 240 and is capable of stretching the suture 10. A medical suture stretching device using indirect heat.
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