CN212238039U - Intravascular stent processing device - Google Patents

Abstract

The utility model relates to the technical field of vascular stent processing device, in particular to a vascular stent processing device, which comprises a leading-in mechanism, a transmission mechanism, a reaction vessel and a clamping mechanism, the leading-in mechanism leads a vascular stent to be processed into the transmission mechanism, the first end of the vascular stent is clamped by the transmission mechanism and a traction force is given to the vascular stent, so as to pull the vascular stent to pass through the clamping mechanism and the reaction vessel in sequence, when the vascular stent passes through the clamping mechanism, the clamping mechanism is in a first clamping state, the clamping mechanism gives a first clamping force which is smaller than the traction force to the vascular stent passing through, so that the vascular stent is tensioned and suspended in the reaction vessel, when reagent is injected into the reaction vessel and is solidified through ultraviolet irradiation, the automatic adhesive colloidal coating on the outer surface of the vascular stent can be realized, the processing efficiency can be ensured, and the outer surface of the vascular stent is not contacted with the wall of the, can ensure the uniform distribution of the colloidal coating on the outer surface of the intravascular stent.

Description

Intravascular stent processing device

Technical Field

The utility model relates to a vascular support processing apparatus technical field especially relates to a vascular support processing apparatus.

Background

The stent implantation is widely used in clinic, and blood circulation of a blood vessel can be successfully recovered through the stent implantation. Before the vascular stent is used, a coating needs to be arranged on the outer surface of the vascular stent, and the medicinal composition in the coating can prevent the vascular stent from being restenosis during use.

For providing a gel-like coating on the outer surface of a stent, the outer surface of the stent is usually soaked in a container containing a solution by a manual operation and irradiated by an ultraviolet lamp to solidify the solution into a gel, but the operation method has the following disadvantages:

1) the processing quality is difficult to ensure, and the contact between the outer surface of the intravascular stent and the side wall of the container is easy to occur, so that the coating is uneven;

2) the processing efficiency of manual operation is low, and after production is finished each time, the container needs to be cleaned, so that the processing efficiency is further reduced;

3) in order to ensure the coating effect of the vascular stent, a larger container needs to be used, which results in the waste of the solution.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide a: the utility model provides a vascular stent processing apparatus to solve in the related art through the manual work the surface that appears the vascular stent easily and the lateral wall contact of container, lead to the problem of coating inequality and the problem that production efficiency is low.

The utility model provides a vascular stent processing apparatus, this vascular stent processing apparatus includes:

including leading-in mechanism, transport mechanism, reaction vessel and fixture:

the leading-in mechanism can guide the blood vessel support to the transmission mechanism, the transmission mechanism can clamp the first end of the blood vessel support and give traction force to the blood vessel support so as to pull the blood vessel support to move, the blood vessel support can sequentially pass through the clamping mechanism and the reaction container, a reagent for soaking the blood vessel support is arranged in the reaction container, and the reagent can be solidified on the outer surface of the blood vessel support under the irradiation of ultraviolet rays;

the clamping mechanism has a first clamping state, when the clamping mechanism is in the first clamping state, the clamping mechanism gives a first clamping force to the vascular stent passing through the clamping mechanism, so that the vascular stent is tensioned and suspended in the reaction vessel, and the first clamping force is smaller than the traction force.

As a preferred technical scheme of the blood vessel support processing device, the blood vessel support processing device further comprises a guiding-out mechanism, the clamping mechanism, the reaction container and the guiding-out mechanism are sequentially arranged along the conveying direction of the conveying mechanism, and the guiding-out mechanism is used for receiving the blood vessel support with the reagent coagulated on the outer surface.

As a preferable embodiment of the stent graft treatment device, the derivation mechanism includes:

the bearing plate is arranged at the output end of the transmission mechanism and is arranged at a first set angle with the transmission mechanism;

the first extrusion mechanism is arranged at one end, close to the transmission mechanism, of the bearing plate and is used for extruding the blood vessel support to the bearing plate.

As a preferable embodiment of the stent graft treatment device, the introduction mechanism includes:

the grid plate is provided with a guide groove for placing the vascular stent, the guide groove inclines by a second set angle relative to the transmission mechanism, the bottom of the guide groove is connected with a guide pipe, and the diameter of the guide pipe is matched with the outer diameter of the vascular stent;

the vibration mechanism is connected with the grid plate and is used for enabling the blood vessel stent to enter the guide tube from the guide slot position;

and the second extrusion mechanism is positioned between the guide tube and the transmission mechanism and is used for conveying the vascular stent to the transmission mechanism.

As a preferable technical scheme of the vascular stent processing device, the transmission mechanism comprises a chain transmission assembly and a clamping assembly arranged on the chain transmission assembly, and the clamping assembly is used for clamping the first end of the vascular stent and can pull the vascular stent to move under the driving of the chain transmission assembly.

As a preferable technical solution of the blood vessel stent processing device, the reaction vessel is a flat glass box, a chamber with two open ends is arranged on the glass box, the chamber has an a end and a B end which are oppositely arranged, the clamping mechanism is arranged at the a end, the clamping mechanism further has a second clamping state, when the clamping mechanism is in the second clamping state, the clamping mechanism clamps the second end of the blood vessel stent and gives a second clamping force to the blood vessel stent, and the second clamping force is greater than the traction force;

the chain transmission assembly comprises a chain and a chain wheel, the clamping assembly is arranged on the chain, an elastic plate is arranged on the chain, the chain can drive the elastic plate and the clamping assembly to sequentially enter the cavity from the end A, when the elastic plate is located at the end B, the elastic plate seals the end B, and the clamping mechanism is in the second clamping state and seals the end A.

As a preferable technical solution of the blood vessel stent processing device, the clamping assembly includes a connecting plate disposed on the chain, and an elastic body disposed on the connecting plate, the elastic body has an opening, and the elastic body is provided with a through hole for allowing the blood vessel stent to pass through;

when the elastomer is positioned outside the reaction vessel, the opening is opened, and the introduction mechanism can guide the blood vessel stent to the opening and pass through the through hole; when the elastic body is positioned in the reaction vessel, the elastic body is pressed by the inner wall of the reaction vessel to clamp the vascular stent.

As a preferred technical scheme of the intravascular stent treatment device, the clamping mechanism comprises a first driving part, a second driving part, a first clamping block and a second clamping block, the first clamping block and the second clamping block are oppositely arranged at two sides of the reaction container, the first clamping block and the second clamping block are both in sliding fit with the outer end face of the end B of the cavity, the first clamping block can be driven by the first driving part to move, and the second clamping block can be driven by the second driving part to move;

the intravascular stent can pass through the first clamping block and the second clamping block, and when the clamping mechanism is in the first clamping state, the first clamping block and the second clamping block are both abutted to the intravascular stent and are arranged at intervals; when the clamping mechanism is in the second clamping state, the first clamping block and the second clamping block are abutted and attached to the vascular stent.

As a preferable technical scheme of the blood vessel stent processing device, the blood vessel stent processing device further comprises a scraper component arranged on the chain transmission component, the scraper component is positioned at the upstream of the clamping component along the conveying direction of the conveying mechanism, and when the blood vessel stent is positioned in the reaction container, the scraper component is positioned at the outer part of the reaction container;

the scraper component comprises a first scraper, the area of the first scraper is the same as the size of the cross-sectional area of the interior of the reaction container, and the chain transmission component can drive the first scraper to pass through the reaction container.

As a preferable technical scheme of the blood vessel stent processing device, the scraper component further comprises a second scraper arranged on the chain transmission component, the area of the second scraper is smaller than that of the first scraper, and the chain transmission component can drive the second scraper and the first scraper to sequentially pass through the reaction container.

The utility model has the advantages that:

the utility model provides a vascular stent processing device, the vascular stent to be processed is guided into conveying mechanism through the guiding-in mechanism, conveying mechanism can grip the first end of vascular stent and give a traction force to the vascular stent, so as to pull the vascular stent to pass through the clamping mechanism and the reaction vessel in turn, when the vascular stent passes through the clamping mechanism, the clamping mechanism is in the first clamping state, and the clamping mechanism gives a first clamping force smaller than the traction force to the vascular stent passing through the clamping mechanism, so that the vascular stent is tensioned and suspended in the reaction vessel, when reagent is injected into the reaction vessel and solidified through ultraviolet irradiation, the automatic adhesion of colloidal coating on the outer surface of the vascular stent can be realized, the automatic processing of the vascular stent can be realized, the processing efficiency can be ensured, and the outer surface of the vascular stent is not contacted with the vessel wall of the reaction vessel, can ensure the uniform distribution of the colloidal coating on the outer surface of the intravascular stent.

Drawings

Fig. 1 is a schematic structural view of a vascular stent treatment device according to an embodiment of the present invention;

fig. 2 is a schematic structural diagram of an introduction mechanism in an embodiment of the present invention;

FIG. 3 is a schematic structural view of the chain, the clamping assembly, the elastic plate and the scraper assembly according to an embodiment of the present invention;

FIG. 4 is an exploded view of a link according to an embodiment of the present invention;

FIG. 5 is a first schematic structural view of a clamping assembly according to an embodiment of the present invention (the clamping assembly is located outside the reaction vessel);

FIG. 6 is a schematic structural diagram II of the holding assembly according to the embodiment of the present invention (the holding assembly is located in the reaction vessel);

FIG. 7 is a schematic structural diagram of an elastic body according to an embodiment of the present invention;

fig. 8 is a first schematic structural diagram of a clamping mechanism according to an embodiment of the present invention;

fig. 9 is a second schematic structural view of the clamping mechanism in the embodiment of the present invention;

fig. 10 is a schematic structural view of a clamping block according to an embodiment of the present invention.

In the figure:

1. a lead-in mechanism; 11. a grid plate; 111. a guide groove; 12. a guide tube; 13. a second extrusion mechanism;

21. a chain drive assembly; 211. a chain; 2111. a connecting section; 2112. a tab; 2113. a rotating shaft; 212. a sprocket; 22. a clamping assembly; 221. a connecting plate; 222. an elastomer; 2221. a through hole; 2222. an opening; 2223. a protrusion; 223. a guide plate;

3. a reaction vessel; 31. a chamber;

4. a clamping mechanism; 41. a first driving member; 42. a second driving member; 43. a first clamping block; 431. avoiding holes; 432. a clamping groove; 44. a second clamp block;

5. a bearing plate;

6. an elastic plate;

7. a squeegee assembly; 71. a first squeegee; 72. a second squeegee;

100. a vascular stent;

Detailed Description

The technical solution of the present invention will be described clearly and completely with reference to the accompanying drawings, and obviously, the described embodiments are some, but not all embodiments of the present invention. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

In the description of the present invention, it should be noted that the terms "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and simplification of description, but do not indicate or imply that the device or element referred to must have a specific orientation, be constructed and operated in a specific orientation, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first," "second," and the like are used for descriptive purposes only and are not to be construed as indicating or implying relative importance. Where the terms "first position" and "second position" are two different positions, and where a first feature is "over", "above" and "on" a second feature, it is intended that the first feature is directly over and obliquely above the second feature, or simply means that the first feature is at a higher level than the second feature. A first feature being "under," "below," and "beneath" a second feature includes the first feature being directly under and obliquely below the second feature, or simply meaning that the first feature is at a lesser elevation than the second feature.

In the description of the present invention, it is to be noted that, unless otherwise explicitly specified or limited, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meaning of the above terms in the present invention can be understood in specific cases to those skilled in the art.

Reference will now be made in detail to embodiments of the present invention, examples of which are illustrated in the accompanying drawings, wherein like reference numerals refer to the same or similar elements or elements having the same or similar function throughout. The embodiments described below with reference to the drawings are exemplary only for the purpose of explaining the present invention, and should not be construed as limiting the present invention.

Referring to fig. 1 to 10, the present embodiment provides a blood vessel stent processing device, which is used for disposing a gel coating on an outer surface of a blood vessel stent 100. Specifically, the blood vessel stent processing device comprises an introducing mechanism 1, a conveying mechanism, a reaction vessel 3 and a clamping mechanism 4. The introducing mechanism 1 can guide the blood vessel support 100 to the transmission mechanism, the transmission mechanism can clamp the first end of the blood vessel support 100 and give traction force to the blood vessel support 100 so as to draw the blood vessel support 100 to move, the blood vessel support 100 can sequentially pass through the clamping mechanism 4 and the reaction container 3, a reagent for soaking the blood vessel support 100 is arranged inside the reaction container 3, and the reagent can be solidified on the outer surface of the blood vessel support 100 under the irradiation of ultraviolet rays so as to form a colloidal coating. The clamping mechanism 4 has a first clamping state, when the clamping mechanism 4 is in the first clamping state, the clamping mechanism 4 gives a first clamping force to the vascular stent 100 passing through the clamping mechanism 4, so that the vascular stent 100 is tensioned and suspended in the reaction vessel 3, and the first clamping force is smaller than the traction force. Wherein, the reagent is the prior art and is not described in detail herein.

When the intravascular stent processing device is used, a to-be-processed intravascular stent 100 can be placed in the introducing mechanism 1 and is introduced into the transmission mechanism from the introducing mechanism 1, the first end of the to-be-processed intravascular stent 100 is clamped and pulled into the reaction vessel 3 through the transmission mechanism, and at the moment, the clamping mechanism 4 is in a loose state; after the first end of the blood vessel support 100 enters the reaction vessel 3, the clamping mechanism 4 is in the first clamping state. It can be understood that the first clamping force provided by the clamping mechanism 4 is not enough to prevent the transmission mechanism from pulling the blood vessel stent 100 to move continuously, but the blood vessel stent 100 can be suspended in the reaction vessel 3 under the combined action of the first clamping force and the traction force, and after the reagent is injected into the reaction vessel 3 and solidified by ultraviolet irradiation, the automatic adhesion of the colloidal coating on the outer surface of the blood vessel stent 100 can be realized, so that the automatic treatment of the blood vessel stent 100 can be realized, the treatment efficiency can be ensured, and the outer surface of the blood vessel stent 100 is not in contact with the vessel wall of the reaction vessel 3, so that the uniform distribution of the colloidal coating on the outer surface of the blood vessel stent 100 can be ensured.

Optionally, the blood vessel stent processing device further comprises a guiding-out mechanism, the clamping mechanism 4, the reaction vessel 3 and the guiding-out mechanism are arranged in sequence along the conveying direction of the conveying mechanism, and the guiding-out mechanism is used for receiving the blood vessel stent 100. After the reagent is solidified, the blood vessel support 100 is processed, the blood vessel support 100 can be continuously pulled out of the reaction vessel 3 by the transmission mechanism, the blood vessel support 100 is separated from the clamping mechanism 4 and is conveyed to the leading-out mechanism, and the processed blood vessel support 100 is received by the leading-out mechanism. The transport direction of the transport mechanism is shown in the direction from m to n in fig. 1.

Specifically, the lead-out mechanism includes the receiving plate 5 and a first extrusion mechanism (not shown in the drawings). The bearing plate 5 is arranged at the output end of the transmission mechanism and is arranged at a first set angle with the transmission mechanism; the first extruding mechanism is arranged at one end of the bearing plate 5 close to the conveying mechanism and is used for extruding the treated blood vessel stent 100 to the bearing plate 5. The first extrusion mechanism comprises a first driving roller and a first driven roller which are arranged at intervals, the transmission mechanism can convey the processed vascular stent 100 to a position between the first driving roller and the first driven roller, and the first driving roller and the second driving roller are matched to continuously convey the processed vascular stent 100 to the bearing plate 5. As shown in fig. 1, the first set angle between the receiving plate 5 and the transferring mechanism is α, in this embodiment, the receiving plate 5 is horizontally disposed, and the transferring mechanism is inclined upward relative to the receiving plate 5. It will be appreciated that the stent 100 has a degree of stiffness arranged to facilitate movement of the treated stent 100 towards the adaptor plate 5 under the influence of gravity. In other embodiments, the first setting angle can be set according to actual requirements.

The introducing mechanism 1 includes a grid 11, a vibrating mechanism, and a second extruding mechanism 13. Specifically, the grid plate 11 is provided with a guide groove 111 for placing the blood vessel stent 100, and the guide groove 111 is inclined at a second set angle relative to the transmission mechanism. The bottom of the guide groove 111 is connected with a guide tube 12, the diameter of the guide tube 12 is matched with the outer diameter of the blood vessel support 100, and the stable direction and the orderly arrangement of the blood vessel support 100 when being conveyed to a conveying mechanism can be ensured. The vibration mechanism is connected to the grid plate 11, and the vibration mechanism makes the stent 100 enter the guide tube 12 from the guide slot 111 by vibration, and the vibration mechanism may include a hollow cup or a motor, etc., which is prior art and will not be described herein. The second extruding mechanism 13 is located between the guide tube 12 and the transmission mechanism, and the second extruding mechanism 13 is used for conveying the vascular stent 100 to the transmission mechanism, in this embodiment, the second extruding mechanism 13 includes a second driving roller and a second driven roller which are arranged at intervals, and the vascular stent 100 can be continuously conveyed to the transmission mechanism through the rolling of the second driving roller and the second driven roller. Wherein, as shown in fig. 1, the second set angle is β, in this embodiment, the guiding groove 111 is inclined upward relative to the transmission mechanism, and the transmission mechanism is arranged obliquely; in other embodiments, the second setting angle can be set according to actual needs.

Optionally, the transmission mechanism comprises a chain transmission assembly 21, and a clamping assembly 22 arranged on the chain transmission assembly 21, wherein the clamping assembly 22 is used for clamping the first end of the blood vessel stent 100 and can pull the blood vessel stent 100 to move under the driving of the chain transmission assembly 21. The introduction mechanism 1 can guide the blood vessel stent 100 to be treated to the holding member 22 and is held by the holding member 22.

In this embodiment, the reaction container 3 is a flat glass box, and can be supported and fixed by the support, and a chamber 31 penetrating through the glass box and having two open ends is disposed on the glass box, as shown in fig. 1, the chamber 31 has an a end and a B end disposed oppositely, the clamping mechanism 4 is disposed at the a end, the clamping mechanism 4 further has a second clamping state, when the clamping mechanism 4 is in the second clamping state, the clamping mechanism 4 clamps the second end of the blood vessel support 100 and provides a second clamping force to the blood vessel support 100, and the second clamping force is greater than the traction force. The chain transmission assembly 21 comprises a chain 211 and a chain wheel 212, the clamping assembly 22 is arranged on the chain 211, an elastic plate 6 is arranged on the chain 211, the elastic plate 6 is located at the downstream of the clamping assembly 22, the chain 211 can drive the elastic plate 6 and the clamping assembly 22 to enter the cavity 31 from the end A in sequence, when the elastic plate 6 is located at the end B, the end B is blocked by the elastic plate 6, and the clamping mechanism 4 is in a second clamping state and blocks the end A. It is understood that the cross-sectional shape and size of the elastic plate 6 are adapted to the cross-sectional shape and size of the cavity 31, so that the elastic plate 6 can close the opening 2222 at the B end of the cavity 31, and the material of the elastic plate 6 is preferably silicon rubber, but may also be rubber.

In this embodiment, when the elastic plate 6 moves to the end B, the clamping mechanism 4 is switched from the first clamping state to the second clamping state, at this time, the intravascular stent 100 is located in the chamber 31 except for the end clamped by the clamping mechanism 4, and the elastic plate 6 and the clamping mechanism 4 cooperate to close the end a and the end B of the chamber 31, so as to facilitate the subsequent injection of the reagent into the reaction vessel 3. Specifically, the top of the reaction vessel 3 is provided with an injection hole for injecting a reagent, the injection hole communicates with the chamber 31, and the reagent can be injected into the chamber 31 through the injection hole. In addition, since the blood vessel support 100 can be tensioned and suspended in the cavity 31 of the reaction vessel 3, only the cross-sectional dimension of the cavity 31 is slightly larger than the outer diameter of the blood vessel support 100, so that the flat reaction vessel 3 can be adopted in the embodiment, and thus the reagent consumption can be reduced. After the reagent is solidified, the clamping mechanism 4 can be switched from the second clamping state to the clamping force-free state, and at this time, the clamping mechanism 4 is separated from the blood vessel support 100 without any force therebetween, so that the chain 211 pulls the treated blood vessel support 100 out of the chamber 31 through the clamping assembly 22.

Specifically, referring to fig. 3 and 4, in the present embodiment, the transmission mechanism includes two chain transmission assemblies 21, the two chain transmission assemblies 21 are arranged side by side and spaced apart, each chain transmission assembly 21 includes two chain wheels 212 and a chain 211 tensioned on the two chain wheels 212, wherein one chain wheel 212 can be in transmission connection with a motor, and the motor can drive the chain 211 to rotate. The chain 211 is ring-shaped and is formed by a plurality of chain links which are sequentially pivoted and pivoted end to end. The chain links comprise groove joints and connecting joints 2111, and in two adjacent chain links, the groove joint of one chain link is pivoted with the connecting joint 2111 of the other chain link. The slot section comprises two connecting pieces 2112 which are arranged side by side and at intervals, the two connecting pieces 2112 are pivoted to two opposite sides of the connecting section 2111 through a rotating shaft 2113, so that a tooth slot is formed between the two connecting pieces 2112, and the chain wheel 212 can be meshed with the tooth slot. In this embodiment, the length directions of the clamping assembly 22 and the elastic plate 6 are perpendicular to the transmission direction of the chain 211, two ends of the clamping assembly 22 in the length direction are fixedly connected with the connecting joints 2111 of the two chains 211 respectively, and two ends of the elastic plate 6 in the length direction are fixedly connected with the two connecting joints 2111 respectively, so that the clamping assembly 22 and the elastic plate 6 are not hindered from passing through the sprocket 212.

Alternatively, referring to fig. 5 to 7, the clamping assembly 22 includes a connecting plate 221 disposed on the chain 211, and an elastic body 222 disposed on the connecting plate 221, the elastic body 222 has an opening 2222, and the elastic body 222 is provided with a through hole 2221 for allowing the blood vessel stent 100 to pass through; when the elastic body 222 is positioned outside the reaction vessel 3, the opening 2222 is opened, and the introduction mechanism 1 can guide the blood vessel stent 100 to the opening 2222 and pass through the through hole 2221; when the elastic body 222 is located in the reaction vessel 3, the elastic body 222 is pressed by the inner wall of the reaction vessel 3 to clamp the vascular stent 100. Specifically, when the elastic body 222 is located outside the reaction container 3, the opening 2222 is in an open state, and at this time, the elastic body 222 has no clamping force on the blood vessel stent 100, when the chain 211 drives the clamping assembly 22 to enter the chamber 31, the elastic body 222 and the blood vessel stent 100 can slide relatively, when the chain 211 drives the clamping assembly 22 to enter the chamber 31, the elastic body 222 is pressed by the inner wall of the reaction container 3, the opening 2222 is closed, and the elastic body 222 clamps the blood vessel stent 100 and drives the blood vessel stent 100 to enter the reaction container 3 under the traction of the chain 211. After the blood vessel stent 100 is processed, the chain 211 drives the elastic plate 6 and the clamping assembly 22 to sequentially come out of the chamber 31, at this time, the opening 2222 of the elastic body 222 is opened, the elastic body 222 loosens the processed blood vessel stent 100, and at this time, the blood vessel stent 100 enters between two rollers of the first extrusion mechanism and is conveyed to the receiving plate 5 by the first extrusion mechanism. It is understood that, when the introduction mechanism 1 introduces the blood vessel stent 100 into the clamping assembly 22, the chain drive assembly 21 is in a stop state, and the clamping assembly 22 is located at an initial position, at which the clamping assembly 22 is located at the upstream of the reaction vessel 3, the introduction mechanism 1 can introduce the blood vessel stent 100 into the elastic body 222 of the clamping assembly 22.

Alternatively, the opening 2222 of the elastic body 222 is V-shaped, and the elastic body 222 may be made of rubber or silicone. The elastic body 222 has an open end and a connecting end which are oppositely arranged, the connecting end is connected with the connecting plate 221, the open end is used for clamping the blood vessel support 100, and the elastic body 222 enters the cavity 31 from the connecting end, so that the elastic body 222 can be ensured to smoothly enter the cavity 31. Preferably, the clamping assembly 22 further includes a guide plate 223, the guide plate 223 and the connecting plate 221 are disposed on two sides of the elastic body 222, and along the conveying direction of the conveying mechanism, the guide plate 223 is located upstream of the connecting plate 221, a guide hole is disposed on the guide plate 223, a guide hole is also disposed on the connecting plate 221, the introducing mechanism 1 can drive the blood vessel support 100 to be processed to penetrate through the guide hole on the guide plate 223, and sequentially pass through the opening 2222 of the elastic body 222 and the through hole 2221 of the elastic body 222, and then penetrate out of the guide hole of the connecting plate 221, and continue to move for a distance L1 until abutting against the elastic plate 6. This is because the elastic body 222 needs to enter the cavity 31 from outside the cavity 31 before clamping the blood vessel stent 100, and assuming that the elastic body 222 is located at the initial position from the clamping assembly 22 and moves to the position where the elastic body 222 just enters the cavity 31, the moving distance of the elastic body 222 is L2, and L2 is smaller than L1, which can ensure that the elastic body 222 can clamp the blood vessel stent 100.

Optionally, a plurality of protrusions 2223 are provided on the inner surface of the opening 2222 of the elastic body 222, and when the elastic body 222 clamps the blood vessel stent 100, the plurality of protrusions 2223 contact the blood vessel stent 100 to ensure the stability of clamping of the elastic body 222 to the blood vessel stent 100.

Referring to fig. 9 to 10, the clamping mechanism 4 includes a first driving member 41, a second driving member 42, a first clamping block 43 and a second clamping block 44. The first driving member 41 and the second driving member 42 are oppositely disposed on two opposite sides of the reaction vessel 3, the first clamping block 43 and the second clamping block 44 are oppositely disposed and attached to the outer end face of the end B of the chamber 31, the first clamping block 43 can be driven by the first driving member 41 to move, and the second clamping block 44 can be driven by the second driving member 42 to move. As shown in fig. 9, when the first clamping block 43 and the second clamping block 44 are moved away from each other, the clamping assembly 22 can pull the stent 100 through between the first clamping block 43 and the second clamping block 44. As shown in fig. 10, the first clamping block 43 and the second clamping block 44 can be driven by the first driving member 41 and the second driving member 42 to approach each other and apply a first clamping force to the blood vessel stent 100, and at this time, the first clamping block 43 and the second clamping block 44 are arranged at an interval, and the clamping mechanism 4 is in a first clamping state; when the elastic plate 6 moves to the end B of the cavity 31, the first clamping block 43 and the second clamping block 44 are engaged with each other and apply a second clamping force to the blood vessel stent 100 under the driving of the first driving element 41 and the second driving element 42, and the clamping mechanism 4 is in a second clamping state; since the first clamping block 43 and the second clamping block 44 are both attached to the outer end face of the B end of the cavity 31, the B end of the cavity 31 can be blocked by the first clamping block 43 and the second clamping block 44. The first driving member 41 and the second driving member 42 may be an electric push rod or an air cylinder, and the first clamping block 43 and the second clamping block 44 are made of an elastic material, such as rubber or silicone. When the reagent is solidified, the second clamping state is switched to the non-clamping state, and both the first clamping block 43 and the second clamping block 44 are separated from the blood vessel support 100.

Optionally, referring to fig. 10, in the embodiment, the first clamping block 43 and the second clamping block 44 have the same structure, taking the first clamping block 43 as an example, the first clamping block 43 is provided with two clearance holes 431 allowing the chain 211 to pass through, the first clamping block 43 has a clamping surface clamping the vascular stent 100, the clamping surface is provided with an arc-shaped clamping groove 433, the clamping groove 433 can be attached to the outer circumferential surface of the vascular stent 100, and the clamping stability of the vascular stent 100 can be ensured by providing the clamping groove 433.

Optionally, referring to fig. 3, the blood vessel stent processing device further comprises a scraper component 7 disposed on the chain transmission component 21, the scraper component 7 is located upstream of the clamping component 22 along the conveying direction of the conveying mechanism, and when the blood vessel stent 100 is located in the reaction vessel 3, the scraper component 7 is located outside the reaction vessel 3; the scraper component 7 comprises a first scraper 71, the area of the first scraper 71 is the same as the cross-sectional area of the inside of the reaction vessel 3, and the chain transmission component 21 can drive the first scraper 71 to pass through the reaction vessel 3. After the reagent is irradiated into the gel by the ultraviolet ray, the chain 211 drives the elastic plate 6 and the clamping assembly 22 to sequentially come out of the chamber 31, but a part of the gel remains in the inner wall of the reaction container 3, at this time, the chain 211 continues to rotate, drives the first scraper 71 to enter the reaction container 3, and cleans the gel remaining in the inner wall of the reaction container 3 out of the chamber 31. It will be appreciated that the profile and dimensions of the cross-section of the first scraper 71 are adapted to the cross-section and dimensions of the chamber 31, respectively, so as to ensure a cleaning effect.

Optionally, with continued reference to fig. 3, the scraper assembly 7 further includes a second scraper 72 disposed on the chain drive assembly 21, the second scraper 72 is located downstream of the first scraper 71, the area of the second scraper 72 is smaller than that of the first scraper 71, and the chain drive assembly 21 can drive the second scraper 72 and the first scraper 71 to pass through the reaction vessel 3 in sequence. With the arrangement, a part of jelly can be removed by the second scraper 72, and then the other part of jelly attached to the wall of the reaction container 3 is removed by the first scraper 71, so that the cleaning amount of the first scraper 71 can be reduced, and the cleaning effect is ensured. Preferably, the number of the second scrapers 72 is plural, the plural second scrapers 72 are arranged at intervals in order in the conveying direction of the conveying mechanism, and the sectional areas of the plural second scrapers 72 decrease in order in the conveying direction of the conveying mechanism, so that the cleaning effect can be further ensured. The present embodiment exemplarily shows a case where the number of the second squeegees 72 is two.

Optionally, the blood vessel stent processing device further comprises an irradiation mechanism for irradiating ultraviolet rays to the reaction vessel 3 so that the reagent forms a layer of colloid on the surface of the blood vessel stent 100. It should be noted that the ultraviolet rays emitted from the irradiation mechanism can cover the entire reaction container 3.

Optionally, a plurality of guiding grooves 111 are arranged on the grid plate 11, guiding tubes 12 are connected to bottoms of the plurality of guiding grooves 111 in a one-to-one correspondence manner, so that the guiding mechanism 1 can guide a plurality of to-be-treated vascular stents 100 into the guiding plate 223 at the same time, a plurality of guiding holes are arranged on the guiding plate 223 and the connecting plate 221, a plurality of through holes 2221 are arranged on the elastic body 222, the plurality of vascular stents 100 can penetrate through the plurality of guiding holes on the guiding plate 223 in a one-to-one correspondence manner, then penetrate through the plurality of through holes 2221 in a one-to-one correspondence manner, and then penetrate through the plurality of guiding holes on the connecting plate 221 in a one-to-one correspondence manner, when the elastic body 222 enters into the chamber 31, the elastic body 222 can clamp the plurality of vascular stents 100 at the same time and draw the vascular. It should be noted that the plurality of guiding holes on the guiding plate 223 or the plurality of guiding holes on the connecting plate 221 may be communicated with each other or spaced from each other; the plurality of through holes 2221 of the elastic body 222 are spaced apart from each other to ensure that the plurality of vascular stents 100 are not in contact with each other when they are tensioned.

The operation method of the blood vessel stent treatment device comprises the following steps:

s1: and (5) an importing step. The conveying mechanism is static, the clamping assembly 22 is located at the initial position, the blood vessel support 100 to be processed is placed in the guide groove 111 of the grid plate 11, the vibrating mechanism is started to enable the grid plate 11 to shake, the blood vessel support 100 enters the guide pipe 12 through shaking, the blood vessel support 100 is extruded out of the guide pipe 12 through the second extruding mechanism 13, and the blood vessel support 100 sequentially passes through the guide plate 223, the elastic body 222 and the connecting plate 221 and is abutted against the elastic plate 6.

S2: and (5) a transmission step. The chain 211 drives the elastic plate 6 and the clamping assembly 22 to enter the reaction vessel 3 from the end a of the chamber 31 in sequence, the clamping mechanism 4 is in a first clamping state, at this time, the clamping mechanism 4 provides a first clamping force to the blood vessel stent 100, and the blood vessel stent 100 is suspended in the chamber 31 of the reaction vessel 3, when the elastic plate 6 is adjacent to the end portion of the end B of the chamber 31, the chain transmission assembly 21 stops, and at this time, the elastic plate 6 blocks the end B.

S3: injecting liquid and sealing. Injecting a reagent into the reaction container 3 through the injection hole, after the reaction container 3 is filled with the reagent, switching the clamping mechanism 4 to a second clamping state, wherein the clamping mechanism 4 gives a second clamping force to the second end of the blood vessel support 100, plugging the A end of the cavity 31 by the clamping mechanism 4, and then injecting the reagent into the cavity 31 through the injection hole.

S4: and (5) curing. The irradiation mechanism is turned on, and the reaction vessel 3 is irradiated with ultraviolet rays, so that the solution forms a layer of colloid on the surface of the stent 100.

S5: and (3) a derivation step: the clamping mechanism 4 is completely opened and is in a state without clamping force, the chain 211 drives the clamping assembly 22 and pulls the treated vascular stent 100 to move towards the outside of the reaction vessel 3, when the clamping assembly 22 moves to the outside of the reaction vessel 3, the opening 2222 of the elastic body 222 is opened and releases the vascular stent 100, and at the moment, the vascular stent 100 moves to the first extrusion mechanism of the leading-out mechanism and is output to the bearing plate 5 by the first extrusion mechanism.

S6: cleaning: the chain 211 is continuously operated, the chain 211 drives a plurality of scrapers of the scraper component 7 to sequentially enter from the end A of the chamber 31 and exit from the end B, the scraper component 7 is remained outside all the reaction containers 3 of the colloid in the reaction containers 3 to complete cleaning, the chain 211 is continuously operated, the chain 211 drives the clamping component 22 to move to the initial position, and the next production process can be carried out.

It is obvious that the above embodiments of the present invention are only examples for clearly illustrating the present invention, and are not intended to limit the embodiments of the present invention. Other variations and modifications will be apparent to persons skilled in the art in light of the above description. And are neither required nor exhaustive of all embodiments. Any modification, equivalent replacement, and improvement made within the spirit and principle of the present invention should be included in the protection scope of the claims of the present invention.

Claims (10)

1. A vascular stent treatment device is characterized by comprising an introduction mechanism (1), a transmission mechanism, a reaction vessel (3) and a clamping mechanism (4):

the introduction mechanism (1) can guide a blood vessel support (100) to the transmission mechanism, the transmission mechanism can clamp the first end of the blood vessel support (100) and give traction force to the blood vessel support (100) so as to pull the blood vessel support (100) to move, the blood vessel support (100) can sequentially pass through the clamping mechanism (4) and the reaction container (3), a reagent for soaking the blood vessel support (100) is arranged inside the reaction container (3), and the reagent can be solidified on the outer surface of the blood vessel support (100) under the irradiation of ultraviolet rays;

the clamping mechanism (4) has a first clamping state, when the clamping mechanism (4) is in the first clamping state, the clamping mechanism (4) gives a first clamping force to the vascular stent (100) passing through the clamping mechanism (4), so that the vascular stent (100) is tensioned and suspended in the reaction vessel (3), and the first clamping force is smaller than the traction force.

2. The stent processing device according to claim 1, further comprising a guiding mechanism, wherein the holding mechanism (4), the reaction vessel (3) and the guiding mechanism are arranged in sequence along the conveying direction of the conveying mechanism, and the guiding mechanism is used for receiving the stent (100) with a reagent coagulated on the outer surface.

3. The stent management device of claim 2, wherein the derivation mechanism comprises:

the bearing plate (5) is arranged at the output end of the transmission mechanism and is arranged at a first set angle with the transmission mechanism;

the first extrusion mechanism is arranged at one end, close to the transmission mechanism, of the bearing plate (5) and used for extruding the vascular stent (100) to the bearing plate (5).

4. The stent treatment device according to claim 1, wherein the introduction mechanism (1) comprises:

the grid plate (11) is provided with a guide groove (111) for placing the vascular stent (100), the guide groove (111) inclines for a second set angle relative to the transmission mechanism, the bottom of the guide groove (111) is connected with a guide pipe (12), and the diameter of the guide pipe (12) is matched with the outer diameter of the vascular stent (100);

the vibration mechanism is connected with the grid plate (11) and is used for enabling the blood vessel stent (100) to enter the guide tube (12) from the guide groove (111);

a second extrusion mechanism (13) located between the guide tube (12) and the delivery mechanism, the second extrusion mechanism (13) being for delivering the vascular stent (100) to the delivery mechanism.

5. The vessel stent processing device according to claim 1, characterized in that the transmission mechanism comprises a chain transmission assembly (21), and a clamping assembly (22) arranged on the chain transmission assembly (21), wherein the clamping assembly (22) is used for clamping the first end of the vessel stent (100) and can pull the vessel stent (100) to move under the driving of the chain transmission assembly (21).

6. The vessel stent processing device according to claim 5, wherein the reaction vessel (3) is a flat glass box provided with a chamber (31) with two open ends, the chamber (31) has an A end and a B end which are oppositely arranged, the clamping mechanism (4) is arranged at the A end, the clamping mechanism (4) further has a second clamping state, when the clamping mechanism (4) is in the second clamping state, the clamping mechanism (4) clamps the second end of the vessel stent (100) and gives a second clamping force to the vessel stent (100), and the second clamping force is larger than the traction force;

chain drive subassembly (21) include chain (211) and sprocket (212), centre gripping subassembly (22) set up in chain (211), be equipped with elastic plate (6) on chain (211), chain (211) can drive elastic plate (6) with centre gripping subassembly (22) are followed in proper order A end gets into cavity (31), works as elastic plate (6) are located during the B end, elastic plate (6) will the B end shutoff, just fixture (4) are in the second presss from both sides tight state and will the A end shutoff.

7. The vascular stent treatment device according to claim 6, wherein the clamping assembly (22) comprises a connecting plate (221) arranged on the chain (211), and an elastic body (222) arranged on the connecting plate (221), wherein the elastic body (222) is provided with an opening (2222), and the elastic body (222) is provided with a through hole (2221) for allowing the vascular stent (100) to pass through;

when the elastic body (222) is positioned outside the reaction vessel (3), the opening (2222) is opened, and the introduction mechanism (1) can guide the blood vessel stent (100) to the opening (2222) and penetrate through the through hole (2221); when the elastic body (222) is positioned in the reaction container (3), the elastic body (222) is pressed by the inner wall of the reaction container (3) to clamp the blood vessel stent (100).

8. The intravascular stent treatment device according to claim 6, wherein the clamping mechanism (4) comprises a first driving member (41), a second driving member (42), a first clamping block (43) and a second clamping block (44), the first clamping block (43) and the second clamping block (44) are oppositely arranged at two sides of the reaction vessel (3), the first clamping block (43) and the second clamping block (44) are in sliding fit with the outer end face of the B end of the cavity (31), the first clamping block (43) can be driven by the first driving member (41) to move, and the second clamping block (44) can be driven by the second driving member (42) to move;

the blood vessel stent (100) can pass through the first clamping block (43) and the second clamping block (44), and when the clamping mechanism (4) is in the first clamping state, the first clamping block (43) and the second clamping block (44) are abutted to the blood vessel stent (100) and are arranged at intervals; when the clamping mechanism (4) is in the second clamping state, the first clamping block (43) and the second clamping block (44) are abutted against the vascular stent (100) and are mutually attached.

9. The vascular stent treatment device according to claim 5, further comprising a scraper assembly (7) arranged on the chain transmission assembly (21), wherein the scraper assembly (7) is located upstream of the clamping assembly (22) along the conveying direction of the conveying mechanism, and the scraper assembly (7) is located outside the reaction vessel (3) when the vascular stent (100) is located in the reaction vessel (3);

the scraper component (7) comprises a first scraper (71), the area of the first scraper (71) is the same as the cross-sectional area of the inside of the reaction vessel (3), and the chain transmission component (21) can drive the first scraper (71) to pass through the reaction vessel (3).

10. The intravascular stent treatment device according to claim 9, wherein the scraper assembly (7) further comprises a second scraper (72) disposed on the chain drive assembly (21), the area of the second scraper (72) is smaller than the area of the first scraper (71), and the chain drive assembly (21) can drive the second scraper (72) and the first scraper (71) to pass through the reaction vessel (3) in sequence.

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