CN214805029U - Wound contraction auxiliary system - Google Patents

Abstract

The utility model discloses a wound shrink auxiliary system, include: the propelling piece group comprises a first propelling piece and a second propelling piece which are respectively arranged at two sides of the wound, and the propelling piece group is provided with a threading through hole; the metal wire group comprises a first metal wire and a second metal wire, the first metal wire penetrates through the threading through hole of the second propelling piece, and two end parts of the first metal wire penetrate out of the threading through hole of the first propelling piece; the second metal wire penetrates through the threading through hole of the first propelling piece, and the two end parts of the second metal wire penetrate through the threading through hole of the second propelling piece; the metal wire group penetrates through two sides of the wound, the propelling piece group is made to approach each other by pulling two end portions of the metal wire group, and then the size of the wound is reduced, and the propelling piece group is internally provided with a wire locking mechanism which is detachably arranged and used for locking the two end portions of the metal wire group. The utility model discloses a skin wound after propelling part group and the fixed metal wire of book sewing machine structure and shrink can effectively play the effect of reducing the scar, still is favorable to the restoration of wound simultaneously.

Description

Wound contraction auxiliary system

Technical Field

The utility model relates to the technical field of medical equipment, more specifically relates to a wound shrink auxiliary system.

Background

Skin tissue, which is the outermost natural protective layer of the human body, is a common medical operation in medical operation treatment due to various diseases or sudden conditions, and modern medicine generally treats skin wounds by means of needle and thread suturing. However, despite the continuous progress of modern medical technology, scars are left after the wound is healed after the suture with the needle and the thread, which affects the beauty. Especially for wounds with a large area, such as for example after a caesarean section of a parturient, the healed scar remains on the belly, even if it has healed. And because the wound area left on the belly by caesarean section is large and long in size, the area of the healed scar is larger, the size of the scar is also longer, and certain influence is caused on the beauty of the skin of the human body.

In the conventional medical technology, in order to promote the healing of a wound, a skin lesion therapeutic body is generally attached to the wound site. Among them, in the case of a skin wound formed on the belly by a caesarean section, since the skin wound by the caesarean section is transversely cut, a conventional body for treating skin damage is generally attached to the upper and lower surfaces of the skin wound to prevent the skin wound from being re-opened. However, such a body for treating skin lesions cannot reduce the length of the skin wound in the transverse direction, and therefore, a long scar remains on the healed skin wound. In addition, the traditional body for treating skin damage is generally only suitable for skin wounds with regular incisions like caesarean section, and for skin wounds which are complex and have special wound positions, the traditional body for treating skin damage is not well suitable and has unobvious treatment effect. Therefore, the body for treating skin damage can prevent the wound from reopening to some extent. However, the body for treating skin lesions cannot be well adapted to skins of different positions and sizes, and mainly helps the healing of wounds by being attached to the wound site to inhibit the stretching of the skin, but cannot reduce the length or area of scars. In addition, some skin wounds with special wound positions and large or irregular areas are not easy to attach to the wound positions, and the skin injury treatment body cannot help wound healing. Therefore, it is not in accordance with the actual medical needs.

SUMMERY OF THE UTILITY MODEL

The utility model discloses aim at overcoming above-mentioned prior art at least one kind defect (not enough), provide a wound shrink auxiliary system for solve the problem of how to shrink the wound size, reach the effect of reducing the scar.

The utility model adopts the technical proposal that:

a wound retraction assistance system comprising:

the propelling piece group comprises a first propelling piece and a second propelling piece which are respectively arranged at two sides of the wound, and the propelling piece group is provided with a threading through hole;

the metal wire group comprises a first metal wire and a second metal wire, the first metal wire penetrates through the threading through hole of the second propelling piece, and two end parts of the first metal wire penetrate out of the threading through hole of the first propelling piece; the second metal wire penetrates through the threading through hole of the first propelling piece, and the two end parts of the second metal wire penetrate through the threading through hole of the second propelling piece;

the metal wire group penetrates through two sides of the wound, the propelling piece group is made to approach each other by pulling two end portions of the metal wire group, and then the size of the wound is reduced, and the propelling piece group is internally provided with a wire locking mechanism which is detachably arranged and used for locking the two end portions of the metal wire group.

In the technical scheme, the arrangement direction of the wound contraction auxiliary system can be selectively arranged in the longitudinal direction, the transverse direction or other directions of the skin wound as required, so that the wound contraction auxiliary system not only can be arranged in the longitudinal direction of the skin wound to promote wound healing, but also can contract the skin on the wound in the transverse direction of the skin wound to shorten the length of the wound so as to achieve the effect of reducing the length of a scar.

Specifically, because the skin of the human body has elasticity and a self-repairing function, the metal wire groups are arranged on the two sides of the wound to contract the wound, so that the effect of reducing scars in the self-repairing of the skin can be achieved, and particularly the effect of shortening the lengths of the scars can be achieved. Through setting up propelling part group and locking wire mechanism, play the effect of fixed and shrink wire to guarantee that the wire has the contractile force to the wound. Specifically, in the process of slowly repairing the wound, the length of the skin wound can be gradually contracted, and the skin slowly closes the wound under the change of the length of the wound, so that the effect of reducing scars is achieved. The thread locking mechanism is detachably arranged on the propelling part group, when the thread locking mechanism is detached, the thread locking mechanism simultaneously loosens acting force on the metal wire group, the two end parts of the metal wire group are lifted and pulled outwards, the propelling part group on the metal wire group can be pulled to be close to each other, the distance between wounds is reduced, when the thread locking mechanism is fixed on the propelling part group, the metal wire group is also locked on the thread locking mechanism, and therefore the wounds after contraction are fixed, and the size of the wounds is reduced gradually in the wound repairing process by utilizing the elasticity of skin and the self-repairing function.

Wherein, this technical scheme has set up two sets of metal wires and two sets of propulsion pieces, through controlling pulling metal wire and propulsion piece, enables skin shrink more evenly, stable.

Among this technical scheme, the two tip of first metal wire is through the locking wire mechanism chucking on the first propulsion spare, and the locking wire mechanism chucking of second propulsion spare is passed through at the two tip of second metal wire, loosens the back of wire group when locking wire mechanism, through the pulling metal wire, can be with first propulsion spare and second propulsion spare toward the wound and draw close, and then taut skin reduces the size of wound, makes the wound shrink gradually at the repair in-process, and the scar that finally forms is less than the size of original wound.

Furthermore, the interior of the propelling piece group is of a hollow structure, the wire locking mechanism comprises a fixing piece and a first stud, the fixing piece is fixed in the hollow structure, the inner wall of the propelling piece group is provided with threads, and the first stud is in threaded connection with the propelling piece group and abuts against the fixing piece; after the two end parts of the metal wire group penetrate through the threading through holes of the pushing piece group, the metal wire group is locked between the fixing piece and the first stud.

In this technical scheme, the same threading through-hole of first propelling part is passed at the both ends of first metal wire, and a terminal surface of mounting just is located the below of this threading through-hole, and when first double-screw bolt was screwed in first propelling part, contradicted to a terminal surface of mounting to with the both ends chucking of first metal wire between first double-screw bolt and mounting. Similarly, two end parts of the second metal wire penetrate through the same threading through hole of the second propelling part and are clamped between the first stud and the fixing part in the second propelling part.

Furthermore, after threading, the pulling force ends of the first pushing piece are concentrated at the two end parts of the first metal wire, and the pulling force ends of the second pushing piece are concentrated at the two end parts of the second metal wire, so that the pulling forces of the two pushing pieces are more even, and the first pushing piece and the second pushing piece are arranged in a reverse direction. Specifically, the left and right sides of the wound are provided with the position reference datum by the propelling part group, wherein the threading through holes in the propelling part group are sequentially arranged on the propelling part from top to bottom, the pulling force end of the first propelling part is arranged in the first threading through hole above the first propelling part, and the pulling force end of the second propelling part is arranged in the last threading through hole arranged on the second propelling part from top to bottom, so that the stress of the propelling part group is more uniform, the stress of the wound is also uniform, and the contraction and recovery of the wound are more facilitated.

Furthermore, a wire winding mechanism is further arranged inside the propelling piece group, the wire winding mechanism is provided with a threading through hole, and the first metal wire sequentially passes through the second propelling piece and the threading through hole of the wire winding mechanism inside the second propelling piece; the second metal wire sequentially penetrates through the first propelling piece and the threading through holes of the winding mechanism in the first propelling piece, and when the winding mechanism is rotated, the metal wire group is wound on the winding mechanism along with the rotation of the winding mechanism, so that the wound is contracted.

The coiling mechanism can coil the metal wire, and the length of the coiling mechanism coiling the metal wire once is known, so that the metal wire can be shortened more accurately by the arrangement of the coiling mechanism, and the size of a wound is reduced. The wire is retracted by the wire winding mechanism, which also avoids the trouble of adjusting by loosening or tightening the first stud each time. Specifically, after the two end portions of the metal wire are fixed by the first stud and the fixing member for the first time, the metal wire can be subsequently contracted by rotating the wire coiling mechanism.

Further, the length of the winding metal wire is 1-2 mm when the winding mechanism rotates for one circle. The total contraction length of the metal wire can be controlled by controlling the rotation number of the wire coiling mechanism.

Specifically, the first metal wire is wound through a winding mechanism inside the second propelling piece, and the second metal wire is wound through a winding mechanism inside the first propelling piece. Due to the tightening of the metal wire, the skin of the wound is also tightened, which is beneficial to reducing the size of the wound.

Furthermore, an elastic piece is further arranged inside the propelling piece group, and the elastic piece is arranged between the fixing piece and the winding mechanism and used for compressing and fixing the winding mechanism after winding.

In the technical scheme, the elastic piece is a spring, and the elastic piece further compresses the winding mechanism through elasticity, so that the winding mechanism is prevented from rotating under the action of a metal wire after winding.

The winding mechanism is provided with an auxiliary rotating groove, the second stud is provided with a hollow channel, and the hollow channel penetrates through the position of the rotating groove.

The second stud is used for further pressing the wire coiling mechanism. The hollow channel arranged on the second stud facilitates an operator to rotate the wire winding mechanism by using an external auxiliary rotating tool under the condition that the second stud is not detached. The rotation groove on the winding mechanism can be used as a rotation supporting part to assist rotation. After the rotation, the second stud bolt can be further screwed, so that the wire winding mechanism after wire winding is locked to the maximum extent.

Furthermore, the first stud, the fixing part, the elastic part, the winding mechanism and the second stud are sequentially arranged inside the propelling piece group, and two end parts of the first metal wire are locked between the first stud of the first propelling piece and the fixing part and are wound by the winding mechanism of the second propelling piece; and two end parts of the second metal wire are locked between the first stud of the second propelling piece and the fixing piece and are wound through the wire winding mechanism of the first propelling piece.

Furthermore, the winding mechanism comprises a winding part and limiting parts arranged at two ends of the winding part, and the size of each limiting part is larger than that of the winding part and used for limiting the wound metal wire; the wire winding part is provided with a threading through hole.

In the technical scheme, when the first metal wire penetrates into the threading through hole of the second propelling piece, the first metal wire firstly penetrates through the threading through hole on the wire winding part and then penetrates out of the other threading through hole of the second propelling piece. When the second metal wire penetrates into the threading through hole of the first pushing piece, the second metal wire firstly penetrates through the threading through hole on the wire winding part and then penetrates out of the other threading through hole of the first pushing piece. The arrangement of the limiting part prevents the metal wire from falling off from the wire winding part in the wire winding process.

Furthermore, the limiting part adjacent to the elastic part is a bearing part, and the other limiting part is provided with a rotating groove for assisting rotation.

The bearing member is provided to facilitate the rotation of the winding mechanism, thereby making the rotation smoother and preventing the elastic member from being influenced by the winding mechanism to rotate.

Furthermore, the metal wire group is divided into an inner skin section metal wire and an outer skin section metal wire according to whether the metal wire group is in contact with the wound or not, the inner skin section metal wire is positioned between the two propelling pieces, arranged below the wound and enveloped in a suture line of the wound; the skin outer section metal wire is positioned on the outer sides of the two propelling pieces and is positioned on the outer side of the wound.

In the technical scheme, the first metal wire and the second metal wire are arranged between subcutaneous tissues and pass through the subcutaneous tissues in a staggered mode, so that the wound can be contracted, the tension of the metal wire on two sides of the wound can be uniformly transmitted to each position in the middle, the stress on each position of the wound is uniform, and the situation that the tension on two sides of the wound is too large, blood vessels are compressed, and the local skin is malnutrition and is necrotic is avoided. The intradermal section metal wire is enveloped in a suture line of the skin wound, so that arrangement is convenient for arrangement, the wound is more friendly when the metal wire is pulled, and the wound repair is facilitated.

Further, the propelling piece group is provided with at least 3 threading through holes.

In the technical scheme, the number and the positions of the threading through holes in the propelling piece group can be set according to requirements. Preferably, there are 3 or 4 threading holes provided in the set of pushers. In order to make the skin tension above and below the wound more uniform, the first propelling part and the second propelling part are arranged in opposite directions. I.e. the sequence of the threading through holes on the first pusher is in the opposite direction to the sequence of the threading through holes on the second pusher.

For example, when 3 threading through holes are arranged on the pushing element group, the sequence of the 3 threading through holes on the first pushing element from top to bottom is one, two and three, the sequence of the 3 through holes on the second pushing element from top to bottom is three, two and one, the positions of the two threading through holes correspond to the positions of the wire coiling mechanism in the pushing element, and the positions of the three threading through holes correspond to the positions of the fixing element and the first stud; specifically, when the first metal wire passes through one threading through hole on the second pushing member, the first metal wire passes through two winding through holes of the winding mechanism in the second pushing member and finally passes through two threading through holes on the second pushing member, two end portions of the first metal wire are fixed to three threading through holes on the first pushing member, and the same applies to the second metal wire. Therefore, the first metal wire and the second metal wire are arranged up and down between the propelling piece groups, the upper end part and the lower end part of the propelling piece groups are accepted more uniformly, and the two ends of the wound are stressed more uniformly.

For example, when the pushing element group is provided with 4 threading through holes, the sequence of the 4 threading through holes on the first pushing element from top to bottom is one, two, three and four, and the sequence of the 4 through holes on the second pushing element from top to bottom is four, three and one, specifically, after the first metal wire passes through the three threading through holes on the second pushing element, one end of the first metal wire firstly passes through the four threading through holes of the first pushing element, then passes through the threading through hole of the first pushing element from the inside of the first pushing element, and is converged with the other end of the first metal wire, and then is clamped and fixed by the first stud and the fixing element between the threading through holes of the first pushing element. The same applies to the second metal line. Such threading also allows the upper and lower ends of the pusher group to be more evenly stressed. And meanwhile, the work of the wire winding mechanism is not influenced.

Furthermore, one end of the propelling piece group is locked through the first stud and the fixing piece, and the other end of the propelling piece group is wound through the winding mechanism.

Further, still include the rubber sleeve, propulsion piece group and book sewing mechanism are wrapped up in the rubber sleeve jointly, be equipped with the portion that opens and shuts of being convenient for pass the metal wire on the rubber sleeve. The rubber sleeve is arranged to further protect the skin, and the pushing piece and the book sewing mechanism are prevented from contacting the skin and rubbing the skin.

Furthermore, puncture needles for assisting the metal wires in skin puncture are arranged at two end parts of the metal wire set, and the puncture needles can be cut off after puncture so as to avoid the puncture needles from accidentally injuring the skin. Alternatively, an external hollow lead wire may be used to assist the wire in performing the skin puncture.

Furthermore, the mutually abutted surfaces between the first stud and the fixing piece are frosted surfaces. The abrasive surface has a greater friction force to better hold the two ends of the wire set.

Furthermore, the outer end part of the first stud is of an inwards concave structure, and the inwards concave structure is of a polygonal column structure. The concave polygon prism structure is arranged, so that medical staff can insert the polygon prism structure through an external screwing piece to screw the first stud, the first stud can be miniaturized, and the human body can be prevented from feeling that foreign matters collide with the stud to the maximum extent.

Furthermore, one end part of the fixing part, which is in contact with the elastic part, is provided with a concave structure for accommodating the elastic part, and when the elastic part is compressed, at least part of the elastic part is accommodated in the concave structure of the fixing part.

Compared with the prior art, the beneficial effects of the utility model are that:

the utility model discloses a set up two metal wires between the subcutaneous tissue of wound to through the wound after propeller group and the fixed metal wire of book sewing machine construct and shrink, can effectively contract the skin of wound, both can reduce the length of skin wound, can also transmit each position in the middle of the wound with the effort of metal wire from the wound both sides uniformly, make wound shrink and atress even, thereby be favorable to in the wound recovery process, play and reduce the wound and reduce the effect that the scar formed.

Drawings

Fig. 1 is a schematic view of a threading structure in embodiment 1 of the present invention.

Fig. 2 is a schematic view of the internal structure of the propulsion member of the present invention.

Fig. 3 is a schematic view of a threading structure according to embodiment 2 of the present invention.

Fig. 4 is a schematic view of a threading structure according to embodiment 3 of the present invention.

Fig. 5 is a schematic view of a threading structure of embodiment 4.

Detailed Description

The drawings of the present invention are for illustration purposes only and are not to be construed as limiting the invention. For a better understanding of the following embodiments, certain features of the drawings may be omitted, enlarged or reduced, and do not represent the size of an actual product; it will be understood by those skilled in the art that certain well-known structures in the drawings and descriptions thereof may be omitted.

Example 1

As shown in fig. 1, the present embodiment discloses a wound contraction assisting system, which includes a metal wire set and a pushing member set, wherein the metal wire set includes a first metal wire 210 and a second metal wire 220, the pushing member set includes a first pushing member 110 and a second pushing member 120, and the first pushing member 110 and the second pushing member 120 are respectively disposed on two sides of a skin wound and are oppositely disposed. Specifically, with the left and right sides of the skin wound where the pusher assemblies are arranged as reference standards, the upper end of the first pusher 110 is a locking wire end, and the lower end is a coiling wire end; the upper end of the second pushing member 120 is a winding end, and the lower end is a locking end.

Wherein, the inside of the propelling piece group is a hollow structure, and a fixing piece 400 is fixedly arranged inside the locking wire end of the propelling piece group. The first stud 300, the fixing member 400, the elastic member 500, the winding mechanism 600 and the second stud 700 are sequentially arranged inside the first propelling member 110 from top to bottom; the second propelling member 120 is opposite to the first propelling member 110 in direction, that is, the second stud 700, the reeling mechanism 600, the elastic member 500, the fixing member 400 and the first stud 300 are sequentially arranged inside the second propelling member 120 from top to bottom.

In this embodiment, the pushing element group is provided with 3 threading through holes, wherein the 3 threading through holes on the first pushing element 110 are sequentially distributed from top to bottom on the first pushing element 110, and are respectively a first hole a, a second hole B and a third hole C; the 3 threading through holes on the second pushing member 120 are distributed on the second pushing member 120 from top to bottom, and are three holes C, two holes B and one hole a respectively. Wherein, a hole a on the pusher group is correspondingly positioned between the first stud 300 and the fixing member 400; the two holes B and the three holes C on the pusher group correspond to the positions of the wire winding mechanism 600. The winding mechanism 600 includes a winding portion 610 located in the middle and limiting portions disposed at two ends of the winding portion 610, wherein the limiting portion located between the winding portion and the elastic member is a first limiting portion 621, the limiting portion located between the winding portion and the second stud is a second limiting portion 622, and two threading through holes corresponding to two holes B and three holes C on the pusher member set are disposed on the winding portion 610.

Preferably, the size of the threading aperture on the pusher set is larger than the size of the threading aperture on the spool portion 610 to facilitate piercing.

In this embodiment, after the first metal wire 210 penetrates through the three holes of the second pushing member 120, it passes through the threading through hole of the wire winding mechanism 600 in the second pushing member 120, and finally passes through the two holes of the second pushing member 120, so as to connect with the second pushing member 120; after passing through the two holes of the first pushing member 110, the second pushing member 120 passes through the threading through hole of the winding mechanism 600 in the first pushing member 110, and finally passes through the three holes of the first pushing member 110, thereby achieving the fixation with the first pushing member 110. The connection between the first metal wire 210 and the second pushing member 120, and the connection between the second metal wire 220 and the first pushing member 110 can be pre-fixed before leaving the factory, so as to facilitate the use of the medical staff.

Furthermore, puncture needles for assisting skin puncture are arranged at two end parts of the metal wire set. After the first wire 210 is connected to the second pusher 120, the first wire 210 is first inserted through the skin of the wound by the puncture needle, and then both ends of the first wire 210 are gathered and fixed to a hole of the first pusher 110, and the first stud 300 is tightened to abut against the fixing member 400, so that both ends of the first wire 210 are fixed between the first stud 300 and the fixing member 400. After the second wire 220 is connected to the first pusher 110, the puncture needle penetrates through the skin of the wound, and then both ends of the first wire 210 are fixed to a hole of the second pusher 120, and the first stud 300 is tightened to abut against the fixing member 400, so that both ends of the second wire 220 are fixed between the first stud 300 and the fixing member 400.

Preferably, the wire between the two pushers is an inner skin section wire, and the inner skin section wire is positioned below the skin wound; the metal wire outside the two propelling pieces is a skin outer section metal wire, and the skin outer section metal wire is positioned outside the skin. Wherein the intradermal section wire is enveloped within the suture of the wound. The inner skin section metal wire of the first metal wire 210 and the inner skin section metal wire of the second metal wire 220 are arranged up and down under the wound, so that the upper side and the lower side of the wound are stressed more uniformly, and the skin of the wound can be shrunk.

Preferably, the surface of the first stud 300 and the fixing member 400 that interferes with each other is a frosted surface, and the friction of the frosted surface is greater, so that the metal wire between the first stud 300 and the fixing member 400 can be clamped more firmly.

The wire winding mechanism 600 is provided to facilitate fine adjustment of the wire. Preferably, after the two end portions of the metal wire set are locked between the first stud 300 and the fixing member 400 for the first time, each subsequent adjustment can be realized by the wire winding mechanism 600, and the metal wire contracts by 1-2 mm after each rotation of the wire winding mechanism 600, so that the skin of the wound can be adjusted in a small range for multiple times, and the recovery of the wound is facilitated.

An elastic member 500 is provided between the winding mechanism 600 and the fixing member 400 so as to fix the winding mechanism 600 after winding while rotating the winding mechanism 600. Specifically, since the elastic member 500 has elasticity, the elastic member 500 also acts against the wire winding mechanism 600 in the compressed state, thereby tightly fixing the wire winding mechanism 600. Preferably, the elastic member 500 is a spring.

The first limiting portion 621 between the winding portion 610 and the elastic member 500 of the winding mechanism 600 is a bearing member, and the bearing member is disposed to facilitate the winding mechanism 600 to rotate better, so that the rotation is smoother, and the elastic member 500 is prevented from rotating under the influence of the winding mechanism 600. Preferably, the first position-limiting portion 621 is detachably disposed.

One end of the fixing member 400 contacting the elastic member 500 is provided with a concave structure for accommodating the elastic member 500, and when the elastic member 500 is compressed, at least a portion of the elastic member is accommodated in the concave structure of the fixing member 400.

Preferably, the second stud 700 is provided to further compress the reeling mechanism 600, and the friction is greater because the second stud 700 is threaded inside the pusher. Preferably, the second stud 700 is provided with a hollow channel 710, and the contact surface of the wire winding mechanism 600 contacting the second stud 700 is provided with a concave rotating groove 630, so that the wire winding mechanism 600 can be rotated without disassembling the second stud 700. Specifically, the wire winding mechanism 600 can be rotated by an external rotating member passing through the hollow channel 710 and then being caught in the concave rotating groove 630. The external rotatable member may be a rotatable member such as a screw driver.

Preferably, the outer end of the first stud 300 is a concave structure, and the concave structure is a polygonal prism structure. The concave polygon prism structure is arranged, so that medical staff can insert the polygon prism structure through an external screwing piece to screw the first stud 300, the first stud 300 can be miniaturized, and the human body can be prevented from feeling that foreign matters collide with the polygon prism structure to the maximum extent.

Preferably, a rubber sleeve can be further arranged, so that the propelling piece group and the wire locking mechanism are jointly wrapped in the rubber sleeve, and the rubber sleeve is provided with an opening and closing part which is convenient for the metal wire to pass through. The rubber sleeve is arranged to further protect the skin, and the pushing piece and the book sewing mechanism are prevented from contacting the skin and rubbing the skin.

Example 2

As shown in fig. 3, the wound contraction assisting system of the present embodiment is different from embodiment 1 in that 4 threading holes are provided in the pusher group of the present embodiment. The threading through holes on the first pushing member 110 are sequentially one hole, two holes, three holes and four holes from top to bottom on the first pushing member 110, and the threading through holes on the second pushing member 120 are sequentially four holes, three holes, two holes and one hole from top to bottom on the second pushing member 120.

When the first metal wire 210 passes through the three holes of the second propelling member 120, the first metal wire penetrates through the threading through hole of the winding mechanism 600 in the second propelling member 120, and finally penetrates out of the two holes of the second propelling member 120, so that the connection with the second propelling member 120 is realized, and when the second metal wire 220 passes through the two holes of the first propelling member 110, the second metal wire penetrates through the threading through hole of the winding mechanism 600 in the first propelling member 110, and finally penetrates out of the three holes of the first propelling member 110, so that the connection with the first propelling member 110 is realized.

Further, one end of the first metal wire 210 directly penetrates through one hole of the first pushing member 110, and the other end of the first metal wire penetrates through four holes of the first pushing member 110, then penetrates through a hole of the first pushing member 110 from the inner wall of the first pushing member 110, and is converged with one end of the first metal wire 210, and then is locked and fixed together by the first stud 300 and the fixing member 400 in the first pushing member 110. Similarly, one end of the second metal wire 220 directly penetrates through one hole of the second pushing member 120, and the other end of the second metal wire penetrates through four holes of the second pushing member 120, then penetrates through one hole of the second pushing member 120 from the inner wall of the second pushing member 120, and after being converged with one end of the second metal wire 220, the first metal wire and the second metal wire are locked and fixed together through the first stud 300 and the fixing member 400 in the second pushing member 120. The threading mode can enable the upper side and the lower side of the wound to be stressed more uniformly, and is beneficial to wound contraction and wound repair.

In this embodiment, the first stud 300 and the fixing member 400 are disposed on the upper and lower sides of a hole of the driving member set.

Example 3

As shown in fig. 4, the wound contraction assisting system of the present embodiment is different from embodiment 1 in that 4 threading holes are provided in the pusher group of the present embodiment. The threading through holes on the first pushing member 110 are sequentially one hole, two holes, three holes and four holes from top to bottom on the first pushing member 110, and the threading through holes on the second pushing member 120 are sequentially four holes, three holes, two holes and one hole from top to bottom on the second pushing member 120.

When the first metal wire 210 passes through the four holes of the second propelling member 120, the first metal wire penetrates through the threading through hole of the wire winding mechanism 600 in the second propelling member 120, and finally penetrates out of the two holes of the second propelling member 120, so as to realize connection with the second propelling member 120, and when the second metal wire 220 passes through the two holes of the first propelling member 110, the second metal wire penetrates through the threading through hole of the wire winding mechanism 600 in the first propelling member 110, and finally penetrates out of the four holes of the first propelling member 110, so as to realize connection with the first propelling member 110.

Further, after the two end portions of the first metal wire 210 penetrate through the skin on both sides of the wound, the two end portions are gathered in a hole of the first pushing member 110 and are locked and fixed together by the first stud 300 and the fixing member 400 in the first pushing member 110. Similarly, the two ends of the second wire 220 pass through the skin on the two sides of the wound, and then are gathered in a hole of the second pushing member 120, and are locked and fixed together by the first stud 300 and the fixing member 400 in the second pushing member 120.

The technical scheme is suitable for the condition that the wound of the skin is large, and the two holes and the four holes are separated by three holes in the middle, so that the distance between the two holes and the four holes is large, and the technical scheme is suitable for shrinking the skin with the large wound to reduce the size of the wound.

Example 5

As shown in fig. 5, the wound contraction assisting system of this embodiment is different from that of embodiment 1 in that 4 threading holes are provided in the pusher group of this embodiment. The threading through holes on the first pushing member 110 are sequentially one hole, two holes, three holes and four holes from top to bottom on the first pushing member 110, and the threading through holes on the second pushing member 120 are sequentially four holes, three holes, two holes and one hole from top to bottom on the second pushing member 120.

When the first metal wire 210 passes through the three holes of the second propelling member 120, the first metal wire penetrates through the threading through hole of the winding mechanism 600 in the second propelling member 120, and finally penetrates out of the two holes of the second propelling member 120, so that the connection with the second propelling member 120 is realized, and when the second metal wire 220 passes through the two holes of the first propelling member 110, the second metal wire penetrates through the threading through hole of the winding mechanism 600 in the first propelling member 110, and finally penetrates out of the three holes of the first propelling member 110, so that the connection with the first propelling member 110 is realized.

Further, one end of the first metal wire 210 directly penetrates into one hole of the first pushing member 110, and the other end of the first metal wire penetrates through four holes of the first pushing member 110, then penetrates out of the three holes, and then penetrates into one hole of the first pushing member 110 from the outer wall of the first pushing member 110, and after being converged with one end of the first metal wire 210, the first metal wire is locked and fixed together by the first stud 300 and the fixing member 400 in the first pushing member 110. Similarly, one end of the second metal wire 220 directly penetrates through one hole of the second pushing member 120, and the other end of the second metal wire penetrates through four holes of the second pushing member 120, then penetrates through three holes, and then penetrates through an outer wall of the second pushing member 120 to a hole of the second pushing member 120, and after being converged with one end of the second metal wire 220, the first metal wire is locked and fixed together by the first stud 300 and the fixing member 400 in the second pushing member 120. The threading mode can enable the upper side and the lower side of the wound to be stressed more uniformly, and is beneficial to wound contraction and wound repair.

It is obvious that the above embodiments of the present invention are only examples for clearly illustrating the technical solutions of the present invention, and are not limitations to the specific embodiments of the present invention. Any modification, equivalent replacement, and improvement made within the spirit and principle of the present invention shall be included in the protection scope of the present invention.

Claims (10)

1. A wound retraction assistance system comprising:

the propelling piece group comprises a first propelling piece and a second propelling piece which are respectively arranged at two sides of the wound, and the propelling piece group is provided with a threading through hole;

the metal wire group comprises a first metal wire and a second metal wire, the first metal wire penetrates through the threading through hole of the second propelling piece, and two end parts of the first metal wire penetrate out of the threading through hole of the first propelling piece; the second metal wire penetrates through the threading through hole of the first propelling piece, and the two end parts of the second metal wire penetrate through the threading through hole of the second propelling piece;

the metal wire group penetrates through two sides of the wound, the propelling piece group is made to approach each other by pulling two end portions of the metal wire group, skin of the wound is further shrunk, and the size of the wound is reduced.

2. The wound contraction aid system according to claim 1, wherein the inside of the propellant assembly is a hollow structure, the thread locking mechanism includes a fixing member and a first stud, the fixing member is fixed in the hollow structure, the inner wall of the propellant assembly is provided with threads, and the first stud is in threaded connection with the propellant assembly and abuts against the fixing member; after the two end parts of the metal wire group penetrate through the threading through holes of the pushing piece group, the metal wire group is locked between the fixing piece and the first stud.

3. A wound retraction assistance system according to claim 2, characterised in that a winding mechanism is provided within the set of pushers, the winding mechanism being provided with a feed-through aperture, the first wire passing through the feed-through apertures of the second pusher and the winding mechanism within the second pusher in sequence; the second metal wire sequentially penetrates through the first propelling piece and the threading through holes of the winding mechanism in the first propelling piece, and when the winding mechanism is rotated, the metal wire group is wound on the winding mechanism along with the rotation of the winding mechanism, so that the wound is contracted.

4. A wound retraction assistance system according to claim 3 wherein an elastic member is provided within the set of pushing members, the elastic member being disposed between the fixing member and the winding mechanism for compressing the winding mechanism after fixing the winding.

5. A wound contraction aid system according to claim 4, further comprising a second stud provided on the opposite side of the first stud and threadedly connected to the set of pushers and abutting against the winding mechanism, the winding mechanism being provided with a rotation-aid slot, the second stud being provided with a hollow passage extending through the rotation slot.

6. A wound contraction aid system according to claim 5, wherein the first stud, the fixing member, the elastic member, the winding mechanism and the second stud are sequentially arranged inside the propelling member group, and both ends of the first wire are locked between the first stud of the first propelling member and the fixing member and are wound by the winding mechanism of the second propelling member; and two end parts of the second metal wire are locked between the first stud of the second propelling piece and the fixing piece and are wound through the wire winding mechanism of the first propelling piece.

7. A wound retraction assisting system according to claim 4 characterised in that the winding mechanism includes a winding portion and a position limiting portion at each end of the winding portion, the position limiting portion being larger in size than the winding portion and being adapted to limit the wound wire; the wire winding part is provided with a threading through hole.

8. A wound retraction aid system according to claim 7 wherein the abutment adjacent the resilient member is a bearing member and the other abutment is provided with a rotation-aid slot.

9. A wound retraction assisting system according to claim 1 characterised in that the group of wires is divided into an inner sheath wire and an outer sheath wire according to whether they are in contact with the wound, the inner sheath wire being positioned between the two pushers and being arranged below the wound and being enveloped in the suture of the wound; the skin outer section metal wire is positioned on the outer sides of the two propelling pieces and is positioned on the outer side of the wound.

10. A wound retraction assistance system according to claim 1 wherein at least 3 feed-through holes are provided in the set of pushing members.

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