阅读说明：本技术 一种切割球囊及其自动化生产工艺 (Cutting balloon and automatic production process thereof ) 是由 涂真金 黄佩佩 涂坚慧 于 2021-08-20 设计创作，主要内容包括：本发明公开了一种切割球囊及其自动化生产工艺,属于医疗器械技术领域,一种切割球囊,包括手柄、导线和切割球囊囊体,所述手柄的一端与导线的一端连接,所述切割球囊囊体套设在导线上；解决了现有技术中刀片固定在球囊的外表面,会影响球囊的折翼收缩,存在刀片划伤球囊的风险,此外,由于刀片是和底座一起粘接在球囊表面,会导致球囊的厚度和整体轮廓尺寸较大,产品通过血管的能力不佳。(The invention discloses a cutting balloon and an automatic production process thereof, belonging to the technical field of medical instruments, the cutting balloon comprises a handle, a lead and a cutting balloon body, wherein one end of the handle is connected with one end of the lead, and the cutting balloon body is sleeved on the lead; the problem of among the prior art the blade fix the surface at the sacculus, can influence the flap shrink of sacculus, have the risk of blade fish tail sacculus, in addition, because the blade bonds on the sacculus surface with the base together, can lead to the thickness and the whole overall dimension of sacculus great, the product is not good through vascular ability.)

1. A cutting balloon is characterized by comprising a handle (101), a lead (102) and a cutting balloon body (103), wherein one end of the handle (101) is connected with one end of the lead (102), and the cutting balloon body (103) is sleeved on the lead (102).

2. The automated production process of a cutting balloon according to claim 1, comprising the steps of:

s1, arranging a fixing frame (1), a balloon conveying belt (2), a handle conveying belt (3), a clamping mechanism (5), a driving mechanism (4), a traction mechanism (7), a limiting mechanism (6) and a blanking conveying belt (8), firstly, placing a plurality of balloons and handles (101) on the balloon conveying belt (2) and the handle conveying belt (3), sequentially moving a cutting balloon capsule body (103) and the handles (101) to be under the clamping mechanism (5) through the balloon conveying belt (2) and the handle conveying belt (3), and then limiting the cutting balloon capsule body (103) and the handles (101) through the limiting mechanism (6);

s2, vertically moving downwards into the limiting mechanism (6) through the clamping mechanism (5), opening the clamping mechanism (5) to clamp the cutting balloon capsule body (103) and the handle (101) in the limiting mechanism (6) after the movement is finished, and vertically moving upwards through the clamping mechanism (5) after clamping to clamp the cutting balloon capsule body (103) and the handle (101) out of the limiting mechanism (6);

s3: when the clamping mechanism (5) clamps and takes out the cutting balloon capsule body (103) and the handle (101), the cutting balloon capsule body (103) and the handle (101) are in the same level, then the traction mechanism (7) is opened and horizontally moved to the joint of the handle (101) and the lead (102), the lead (102) is slightly clamped by the traction mechanism (7), and after slight clamping, the traction mechanism (7) transversely moves to the other end of the lead (102) and clamps the lead (102), so that the other end of the lead (102) corresponds to one end of the cutting balloon capsule body (103);

s4, after the other end of the lead (102) corresponds to one end of the cutting balloon body (103), the driving mechanism (4) is opened to enable the cutting balloon body (103) and the handle (101) to move relatively, and the traction mechanism (7) and the lead (102) move simultaneously to draw the lead (102) into the cutting balloon body (103);

s5: after the lead (102) is dragged into the cutting balloon body (103), the traction mechanism (7) repeatedly moves transversely to enable the lead (102) to penetrate through the cutting balloon body (103) and extend out of the other end of the cutting balloon body (103), the traction mechanism (7) is moved away from the lead (102) after the cutting balloon body is completed, the clamping mechanism (5) is pushed to move to the position right above one end of the blanking conveying belt (8) by opening the driving mechanism (4), and the lead (102) and the handle (101) which are completely penetrated and led are placed on the blanking conveying belt (8) by opening the clamping mechanism (5).

3. The automated manufacturing process of a cutting balloon of claim 2, wherein: the handle conveying belt (3) and the balloon conveying belt (2) are arranged at one end in the fixed frame (1) side by side, one side of the handle conveying belt (3) is connected with the inner side wall of one corresponding side in the fixed frame (1), the other end of the balloon conveying belt (2) is connected with the inner side wall of the other corresponding side in the fixed frame (1), the limiting mechanism (6) is arranged at the top of one end of the balloon conveying belt (2) and the handle conveying belt (3), the two ends of the limiting mechanism (6) are connected with the inner side walls of the two sides of the fixed frame (1) in a sliding manner, the driving mechanism (4) is arranged at the top end in the fixed frame (1), the driving mechanism (4) is connected with the top of the fixed frame (1) in a sliding manner, the clamping mechanisms (5) are arranged in two groups, and the two groups of the clamping mechanisms (5) are symmetrically arranged at the two ends of the driving mechanism (4), and every group the top of fixture (5) all with fixed frame (1) in the top sliding connection, drive mechanism (7) set up the one end at handle conveyer belt (3), unloading conveyer belt (8) set up the one side at drive mechanism (7).

4. The automated manufacturing process of a cutting balloon of claim 2, wherein: the top of the fixed frame (1) is provided with a sliding chute (11), and two L-shaped sliding chutes (12) are symmetrically arranged on two sides of the sliding chute (11).

5. The automated manufacturing process of a cutting balloon of claim 4, wherein: the balloon conveying belt (2) and one end of the handle conveying belt (3) are provided with a limiting block (13), and two ends of the limiting block (13) are connected with the inner side walls of two sides of the fixing frame (1).

6. The automated manufacturing process of a cutting balloon of claim 5, wherein: actuating mechanism (4) includes first fixed motor (41), connecting block (42), first dwang (43), head rod (44), first moving motor (45), second dwang (46) and two second connecting rods (47), first moving motor (45) set up the one end at spout (11), just top sliding connection of first moving motor (45) and fixed frame (1), connecting block (42) set up in first moving motor (45) one side, first fixed motor (41) interval sets up the one side at first moving motor (45), the one end of first dwang (43) rotates with the output of first fixed motor (41) to be connected, head rod (44) set up between connecting block (42) and head rod (43), the one end and connecting block (42) of head rod (44) rotate to be connected, just the other end of first connecting rod (44) rotates with the other end of first dwang (43) to be connected, second dwang (46) set up in fixed frame (1), just second dwang (46) top is connected, two with the output of first moving motor (45) the one end of second connecting rod (47) rotates with the one end of second dwang (46) respectively and is connected.

7. The automated manufacturing process of a cutting balloon of claim 6, wherein: each group of clamping mechanisms (5) comprises a fixed block (51), a first rotating motor (52), an air cylinder (53), a moving block (54), two first clamping arms (55) and two first rotating gears (56), wherein the air cylinder (53) is arranged above one end of a second rotating rod (46), the fixed block (51) is arranged below one end of the second rotating rod (46), the output end of the air cylinder (53) penetrates through the top of the second rotating rod (46) and extends to the bottom of the second rotating rod (46) to be connected with the top of the fixed block (51), the two first clamping arms (55) are symmetrically arranged on the fixed block (51), each first clamping arm (55) is rotatably connected with the fixed block (51), the two first rotating gears (56) are symmetrically arranged on one side of the fixed block (51), and each first rotating gear (56) is respectively connected with the top end of one first clamping arm (55), the two first rotating gears (56) are meshed, the first rotating motor (52) is arranged at the other end of the fixed block (51), the output end of the first rotating motor (52) penetrates through one side of the fixed block (51) and extends to the other side of the fixed block (51) to be connected with one first rotating gear (56), the moving block (54) is arranged at the top end of the fixed block (1), and the bottom end of the moving block (54) penetrates through the L-shaped sliding groove (12) to be connected with the top end of the air cylinder (53).

8. The automated manufacturing process of a cutting balloon of claim 7, wherein: the limiting mechanism (6) comprises a second fixed motor (61), a fixed plate (62), a limiting plate (63), a fixed rod (64) and a rotating disc (65), the fixing plate (62) is arranged above one ends of the balloon conveying belt (2) and the handle conveying belt (3), and both ends of the fixing plate (62) are connected with the inner side walls at both sides of the fixing frame (1), the second fixed motor (61) is arranged on one side of the fixed plate (62), and the output end of the second fixed motor (61) penetrates through one side of the fixed plate (62) and extends to the other side of the fixed plate (62) to be connected with one side of the rotating disc (65), the fixed rod (64) is arranged at one side of the rotating disc (65), the limit plate (63) is arranged at one end of the fixed rod (64), the top end of the limit plate (63) is rotatably connected with one end of the fixed rod (64), and the two ends of the limiting plate (63) are in sliding connection with the inner side walls of the two sides of the fixed frame (1).

9. The automated manufacturing process of a cutting balloon of claim 8, wherein: the traction mechanism (7) comprises a support frame (71), a driving motor (72), a rack (73), a second rotating gear (74), a second moving motor (75), a sliding block (76), a screw rod (77), a sliding plate (78) and a traction assembly (79), wherein the bottom of the support frame (71) is in sliding connection with the bottom in the fixed frame (1), the screw rod (77) is arranged in the support frame (71), the driving motor (72) is arranged on one side of the support frame (71), the output end of the driving motor (72) penetrates through the support frame (71) and extends into the support frame (71) to be connected with one end of the screw rod (77), the sliding block (76) is arranged on the screw rod (77), the sliding block (76) is in threaded connection with the screw rod (77), the sliding plate (78) is arranged at the top end of the sliding block (76), and the traction assembly (79) is arranged on one side of the sliding plate (78), the second mobile motor (75) is arranged at the bottom of the inner side wall of the support frame (71), the output end of the second mobile motor (75) penetrates through the inner side wall of the support frame (71) and extends to the outer side of the support frame (71) to be connected with one side of the second rotating gear (74), the rack (73) is arranged on one side of the support frame (71), and the rack (73) is meshed with the second rotating gear (74).

10. The automated manufacturing process of a cutting balloon of claim 9, wherein: the traction assembly (79) comprises a second rotating motor (791), a rotating block (792), two supporting blocks (793) and two second clamping arms (794), wherein the second clamping arms (794) are symmetrically arranged on one side of the sliding plate (78), the second clamping arms (794) are connected with one side of the sliding plate (78) in a sliding mode, the second rotating motor (791) is arranged on one side of the sliding plate (78), the output end of the second rotating motor (791) penetrates through one side of the sliding plate (78) and extends to the other side of the sliding plate (78) to be connected with one side of the rotating block (792), one ends of the supporting blocks (793) are respectively rotatably arranged at one end of the rotating block (792), and the other end of each supporting block (793) is connected with one side of one second clamping arm (794).

Technical Field

The invention relates to the technical field of medical instruments, in particular to a cutting balloon and an automatic production process thereof.

Background

Endovascular intervention has been for more than 30 years, and since 1977, when a human firstly uses a balloon dilatation catheter to perform coronary artery stenosis intervention, related new instruments are continuously evolved and developed, and balloon cutting is an intervention method developed on the basis of traditional balloon intracavity angioplasty. The cutting saccule mainly utilizes the saccule with a miniature blade to expand and cut atherosclerotic plaques on the inner wall of a blood vessel, and can generally achieve satisfactory effect on the cutting saccule for a narrow blood vessel which cannot be expanded by a conventional saccule.

When the saccule is pre-expanded, the injury to the blood vessel is irregular, which often causes excessive injury or blood vessel interlayer, and the cutting saccule can concentrate the expansion force of the saccule on the blade fixed on the surface of the saccule, so that the stenotic blood vessel can be expanded by generating less injury to the blood vessel. Because of the 'force gathering' expansion effect, the cutting saccule can expand a diseased blood vessel by using smaller expansion pressure compared with a common saccule, in the prior art, the cutting saccule mainly adopts the design of installing a blade on a base and then bonding the base on the outer circumferential surface of the saccule, the structure and the process of the cutting saccule are complex due to the design, and the risk of infirm fixation of the blade and the outer surface of the saccule exists. Since the blades are fixed on the outer surface of the balloon, the contraction of the flaps of the balloon can be influenced, and the risk that the blades scratch the balloon exists. In addition, because the blades are adhered to the surface of the balloon together with the base, the thickness and the overall contour size of the balloon are large, and the product has poor capability of passing through blood vessels.

And the cutting sacculus among the prior art usually processes the part through machinery when producing the back, passes the cutting sacculus with the wire of handle by the manual work and assembles, because cutting sacculus part is less, all manual works assemble the degree of difficulty and beat, machining efficiency is low.

Disclosure of Invention

The embodiment of the invention provides a cutting balloon and an automatic production process thereof, which aim to solve the problem that in the prior art, a lead of a handle is generally manually assembled by penetrating through the cutting balloon during production of a cutting balloon capsule, so that the processing efficiency is low.

The embodiment of the invention adopts the following technical scheme: a cutting sacculus comprises a handle, a wire and a cutting sacculus utricule, wherein one end of the handle is connected with one end of the wire, and the cutting sacculus utricule is sleeved on the wire.

An automatic production process of a cutting balloon comprises the following steps:

s1, arranging a fixing frame, a balloon conveying belt, a handle conveying belt, a clamping mechanism, a driving mechanism, a traction mechanism, a limiting mechanism and a blanking conveying belt, firstly placing a plurality of balloons and handles on the balloon conveying belt and the handle conveying belt, sequentially moving a cutting balloon body and the handles to be under the clamping mechanism through the balloon conveying belt and the handle conveying belt, and then limiting the cutting balloon body and the handles by the limiting mechanism;

s2, vertically moving downwards into the limiting mechanism through the clamping mechanism, opening the clamping mechanism to clamp the cutting balloon body and the handle in the limiting mechanism after the movement is finished, and vertically moving upwards through the clamping mechanism to clamp and take out the cutting balloon body and the handle from the limiting mechanism;

s3: when the clamping mechanism takes out the cutting balloon body and the handle clamp, the cutting balloon body and the handle are in the same level, then the traction mechanism is opened and horizontally moved to the joint of the handle and the wire, the traction mechanism slightly clamps the wire, the traction mechanism transversely moves to the other end of the wire after slight clamping, and clamps the wire, so that the other end of the wire corresponds to one end of the cutting balloon body;

s4, after the other end of the lead corresponds to one end of the cutting saccule utricule, the driving mechanism is opened to lead the cutting saccule utricule and the handle to move relatively, and the traction mechanism and the lead move simultaneously to draw the lead into the cutting saccule utricule;

s5: after the wire is drawn into the cutting balloon body, the traction mechanism performs repeated transverse movement to enable the wire to penetrate through the cutting balloon body and extend out of the other end of the cutting balloon body, the traction mechanism is moved away from the wire after the wire is completed, the clamping mechanism is pushed to move to the position right above one end of the blanking conveying belt by opening the driving mechanism, and the wire and the handle after the threading are placed on the blanking conveying belt by opening the clamping mechanism.

Further, the handle conveying belt and the balloon conveying belt are arranged at one end in the fixing frame in parallel, one side of the handle conveying belt is connected with the inner side wall at one corresponding side in the fixed frame, the other end of the balloon conveying belt is connected with the inner side wall at the other corresponding side in the fixed frame, the limiting mechanism is arranged at the top of the balloon conveying belt and one end of the handle conveying belt, and the two ends of the limiting mechanism are connected with the inner side walls of the two sides of the fixed frame in a sliding way, the driving mechanism is arranged at the top end in the fixed frame, the driving mechanism is connected with the top of the fixed frame in a sliding way, two groups of clamping mechanisms are arranged, the two groups of clamping mechanisms are symmetrically arranged on two ends of the driving mechanism, and every group fixture's top all with fixed frame in the top sliding connection, drive mechanism sets up the one end at the handle conveyer belt, the unloading conveyer belt sets up the one side at drive mechanism.

Further, the top of fixed frame is equipped with a spout, just the bilateral symmetry of spout is equipped with two L type spouts.

Further, a limiting plate is arranged at one end of the balloon conveying belt and one end of the handle conveying belt, and two ends of the limiting block are connected with the inner side walls of two sides in the fixing frame.

Further, the driving mechanism comprises a first fixed motor, a connecting block, a first rotating rod, a first connecting rod, a first moving motor, a second rotating rod and two second connecting rods, the first moving motor is arranged at one end of the sliding groove, the first moving motor is connected with the top of the fixed frame in a sliding manner, the connecting block is arranged on one side of the first moving motor, the first fixed motor is arranged on one side of the first moving motor at an interval, one end of the first rotating rod is connected with the output end of the first fixed motor in a rotating manner, the first connecting rod is arranged between the connecting block and the first rotating rod, one end of the first connecting rod is connected with the connecting block in a rotating manner, the other end of the first connecting rod is connected with the other end of the first rotating rod in a rotating manner, the second rotating rod is arranged in the fixed frame, and the top of the second rotating rod is connected with the output end of the first moving motor, and one end of each second connecting rod is respectively and rotatably connected with one end of the second rotating rod.

Further, each group of clamping mechanisms comprises a fixed block, a first rotating motor, a cylinder, a moving block, two first clamping arms and two first rotating gears, the cylinder is arranged above one end of a second rotating rod, the fixed block is arranged below one end of the second rotating rod, the output end of the cylinder penetrates through the top of the second rotating rod and extends to the bottom of the second rotating rod to be connected with the top of the fixed block, the two first clamping arms are symmetrically arranged on the fixed block, each first clamping arm is rotatably connected with the fixed block, the two first rotating gears are symmetrically arranged on one side of the fixed block, each first rotating gear is respectively connected with the top end of one side of one first clamping arm and is meshed with the two first rotating gears, the first rotating motor is arranged at the other end of the fixed block, and one side of the output end of the first rotating motor, which penetrates through the fixed block, extends to the other side of the fixed block and is connected with one of the first rotating gears, the moving block is arranged at the top end of the fixing frame, and the bottom end of the moving block penetrates through the L-shaped sliding groove to be connected with the top end of the air cylinder.

Further, stop gear includes the fixed motor of second, fixed plate, limiting plate, dead lever and rolling disc, the fixed plate sets up in the top of the one end of sacculus conveyer belt and handle conveyer belt, just the both ends of fixed plate are connected with the inside wall of fixed frame interior both sides, the fixed motor of second sets up in one side of fixed plate, just the fixed motor output of second runs through one side of fixed plate and extends to one side of the opposite side of fixed plate and be connected with one side of rolling disc, the dead lever sets up the one side at the rolling disc, the limiting plate sets up the one end at the dead lever, the top of limiting plate is rotated with the one end of dead lever and is connected, just the both ends of limiting plate and the inside wall sliding connection of fixed frame both sides.

Further, the traction mechanism comprises a support frame, a driving motor, a rack, a second rotating gear, a second moving motor, a sliding block, a screw rod, a sliding plate and a traction assembly, wherein the bottom of the support frame is slidably connected with the bottom in the fixed frame, the screw rod is arranged in the support frame, the driving motor is arranged on one side of the support frame, the output end of the driving motor penetrates through the support frame and extends into the support frame to be connected with one end of the screw rod, the sliding block is arranged on the screw rod and is in threaded connection with the screw rod, the sliding plate is arranged at the top end of the sliding block, the traction assembly is arranged on one side of the sliding plate, the second moving motor is arranged at the bottom of the inner side wall of the support frame, the output end of the second moving motor penetrates through the inner side wall of the support frame and extends to the outer side of the support frame to be connected with one side of the second rotating gear, the rack is arranged on one side of the support frame, and the rack is engaged with the second rotating gear.

Furthermore, the traction assembly comprises a second rotating motor, a rotating block, two supporting blocks and two second clamping arms, the two second clamping arms are symmetrically arranged on one side of the sliding plate and are in sliding connection with one side of the sliding plate, the second rotating motor is arranged on one side of the sliding plate, the output end of the second rotating motor penetrates through one side of the sliding plate and extends to the other side of the sliding plate to be connected with one side of the rotating block, one end of each of the two supporting blocks is rotatably arranged at one end of the rotating block, and the other end of each of the supporting blocks is connected with one side of one second clamping arm.

The embodiment of the invention adopts at least one technical scheme which can achieve the following beneficial effects:

firstly, the cutting saccule utricule and the handle are moved into the limiting mechanism by the feeding of the saccule conveying belt and the handle, then two clamping mechanisms are opened to clamp the cutting saccule utricule in the limiting mechanism and the handle, a traction mechanism is opened to slightly clamp along one end of the handle after clamping, the wire is transversely moved along one end of the handle after clamping to clamp the wire and prevent the wire from falling off, a driving mechanism is opened again to relatively move the cutting saccule utricule and the handle, the traction mechanism synchronously moves along the wire of the handle, one section of the wire is pulled into one end of the cutting saccule utricule by the matching of the traction mechanism and the driving mechanism, the wire passes through the cutting saccule utricule by repeated transverse movement of the traction mechanism, the wire extends out from the other end of the cutting saccule, the traction mechanism is loosened and moved away from the wire after traction is finished, and the driving mechanism is opened again to drive the clamping mechanism, so that the clamping mechanism drives the cutting balloon sac body and the handle to move to the top end of the blanking conveying belt, and the clamping mechanism is opened again to place the cutting balloon sac body and the handle on the blanking conveying belt, so that the problem that the cutting balloon sac body is assembled by manually penetrating a wire of the handle through the cutting balloon sac body during production in the prior art is solved, and the processing efficiency is low.

Secondly, the screw rod is driven to rotate by the driving motor, the screw rod drives the sliding block and the sliding plate to move, after the sliding plate moves the traction component to the joint of the handle and the lead, the traction component is opened to slightly clamp the lead and then transversely move, the traction component moves to the other end of the lead along the joint of the lead and the handle and clamps the lead, the traction component and the lead synchronously move, the lead is pulled into the cutting balloon body by the traction component, then the screw rod is driven to repeatedly rotate by the driving motor, the sliding block drives the sliding plate and the traction component to repeatedly transversely move, the lead passes through the cutting balloon body and extends out from the other end of the cutting balloon body, after the process is finished, the second rotating gear and the supporting frame are driven by the second moving motor to move along the direction of the rack, the traction component is moved away from the lead, and when the handle is prevented from being clamped, causing the wire to fall vertically and fail to pass through the cutting balloon.

Drawings

The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and together with the description serve to explain the invention and not to limit the invention. In the drawings:

FIG. 1 is a perspective view of the present invention;

FIG. 2 is an internal structural view of the present invention in use;

FIG. 3 is an enlarged view taken at A in FIG. 2;

FIG. 4 is a right side view of the present invention;

FIG. 5 is an enlarged view at B in FIG. 4;

FIG. 6 is an enlarged view at C of FIG. 4;

FIG. 7 is a perspective view of the traction mechanism of the present invention;

FIG. 8 is an enlarged view taken at D in FIG. 7;

fig. 9 is a schematic view of the product of the present invention.

Reference numerals

A handle 101, a wire 102, a cutting balloon capsule 103, a fixed frame 1, a chute 11, an L-shaped chute 12, a stopper 13, a balloon conveyor belt 2, a handle conveyor belt 3, a driving mechanism 4, a first fixed motor 41, a connecting block 42, a first rotating rod 43, a first connecting rod 44, a first moving motor 45, a second rotating rod 46, a second connecting rod 47, a clamping mechanism 5, a fixed block 51, a first rotating motor 52, a cylinder 53, a moving block 54, a first clamping arm 55, a first rotating gear 56, a stopper mechanism 6, a second fixed motor 61, a fixed plate 62, a stopper plate 63, a fixed rod 64, a rotating disc 65, a traction mechanism 7, a support frame 71, a driving motor 72, a rack 73, a second rotating gear 74, a second moving motor 75, a slide block 76, a screw 77, a sliding plate 78, a traction assembly 79, a second rotating motor 791, a rotating block 792, a support block 793, a second clamping arm 794, a balloon conveyor belt 3, a first rotating mechanism 4, a second rotating block 52, a first rotating mechanism 52, a second rotating mechanism 53, a second rotating mechanism 54, a second rotating mechanism, a second, Blanking conveyer belt 8.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the technical solutions of the present invention will be clearly and completely described below with reference to the specific embodiments of the present invention and the accompanying drawings. It is to be understood that the described embodiments are merely exemplary of the invention, and not restrictive of the full scope of the invention. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

The technical solutions provided by the embodiments of the present invention are described in detail below with reference to the accompanying drawings.

Referring to fig. 9, the cutting balloon comprises a handle 101, a wire 102 and a cutting balloon capsule 103, wherein one end of the handle 101 is connected with one end of the wire, and the cutting balloon capsule 103 is sleeved on the wire.

Referring to fig. 1-9, an embodiment of the invention provides an automatic production process of a cutting balloon, which includes a fixed frame 1, a balloon conveyor belt 2, a handle conveyor belt 3, a clamping mechanism 5, a driving mechanism 4, a traction mechanism 7, a limiting mechanism 6 and a blanking conveyor belt 8, wherein the handle conveyor belt 3 and the balloon conveyor belt 2 are arranged at one end in the fixed frame 1 in parallel, one side of the handle conveyor belt 3 is connected with the corresponding inner side wall at one side in the fixed frame 1, the other end of the balloon conveyor belt 2 is connected with the corresponding inner side wall at the other side in the fixed frame 1, the limiting mechanism 6 is arranged at the top of one ends of the balloon conveyor belt 2 and the handle conveyor belt 3, two ends of the limiting mechanism 6 are connected with the inner side walls at two sides of the fixed frame 1 in a sliding manner, the driving mechanism 4 is arranged at the top end in the fixed frame 1, and the driving mechanism 4 is connected with the top of the fixed frame 1 in a sliding manner, the two groups of clamping mechanisms 5 are arranged, the two groups of clamping mechanisms 5 are symmetrically arranged at two ends of the driving mechanism 4, the top end of each group of clamping mechanisms 5 is connected with the top in the fixed frame 1 in a sliding manner, the traction mechanism 7 is arranged at one end of the handle conveying belt 3, the blanking conveying belt 8 is arranged at one side of the traction mechanism 7, the saccule and the handle are moved into the limiting mechanism 6 through the saccule conveying belt 2 and the handle feeding, after the two clamping mechanisms 5 are opened to respectively clamp the cutting saccule capsule 103 in the limiting mechanism 6 and the handle, the traction mechanism 7 is opened to slightly clamp along one end of the handle, after clamping, the wire 102 is transversely moved along one end of the handle, the wire 102 is clamped to prevent the wire 102 from falling, the driving mechanism 4 is opened to relatively move the cutting saccule capsule 103 and the handle 101, and the traction mechanism 7 synchronously moves along the wire 102 of the handle 101, one section of the lead 102 is dragged into one end of the cutting balloon capsule 103 through the matching of the traction mechanism 7 and the driving mechanism 4, the lead 102 penetrates through the cutting balloon capsule 103 through repeated transverse movement of the traction mechanism 7, the lead 102 extends out from the other end of the cutting balloon capsule 103, the traction mechanism 7 is loosened and moved away from the lead 102 after the traction is completed, the driving mechanism 4 is opened to drive the clamping mechanism 5, the clamping mechanism 5 drives the cutting balloon capsule 103 and the handle 101 to move to the top end of the blanking conveying belt 8, and the cutting balloon capsule 103 and the handle 101 are placed on the blanking conveying belt 8 after the clamping mechanism 5 is opened.

Specifically, referring to fig. 2, the top of the fixing frame 1 is provided with a sliding chute 11, and two L-shaped sliding chutes 12 are symmetrically arranged on two sides of the sliding chute 11.

Specifically, as shown in fig. 2, a limiting block 13 is arranged at one end of the balloon conveying belt 2 and one end of the handle conveying belt 3, and two ends of the limiting block 13 are connected with the inner side walls of two sides in the fixing frame 1.

Specifically, referring to fig. 1-4, the driving mechanism 4 includes a first fixed motor 41, a connecting block 42, a first rotating rod 43, a first connecting rod 44, a first moving motor 45, a second rotating rod 46 and two second connecting rods 47, the first moving motor 45 is disposed at one end of the sliding chute 11, the first moving motor 45 is slidably connected to the top of the fixed frame 1, the connecting block 42 is disposed at one side of the first moving motor 45, the first fixed motor 41 is disposed at one side of the first moving motor 45 at intervals, one end of the first rotating rod 43 is rotatably connected to the output end of the first fixed motor 41, the first connecting rod 44 is disposed between the connecting block 42 and the first rotating rod 43, one end of the first connecting rod 44 is rotatably connected to the connecting block 42, and the other end of the first connecting rod 44 is rotatably connected to the other end of the first rotating rod 43, the second rotating rod 46 is arranged in the fixed frame 1, the top of the second rotating rod 46 is connected with the output end of the first moving motor 45, one end of each of the two second connecting rods 47 is respectively connected with one end of the second rotating rod 46 in a rotating manner, when in use, the first moving motor 45 rotates to drive the two ends to drive the second connecting rods 47 to move, so that the two second connecting rods 47 respectively drive one group of clamping mechanisms 5 to move along the arrangement direction of the L-shaped chute 12 at the top of the fixed frame 1, the handle 101 on one group of clamping mechanisms 5 penetrates through the cutting balloon capsule 103 on the other group of clamping mechanisms 5, after the completion, the first fixed motor 41 drives one end of the first rotating rod 43 to rotate, the other end of the first rotating rod 43 drives the first connecting rod 44 to move, the first connecting block 42 and the first moving motor 45 to move back and forth, so that the handle 101 and the cutting balloon capsule 103 after the completion of the clamping mechanisms 5 move to the upper part of the blanking conveying belt 8,

specifically, referring to fig. 4 to 5, each group of clamping mechanisms 5 includes a fixed block 51, a first rotating motor 52, an air cylinder 53, a moving block 54, two first clamping arms 55 and two first rotating gears 56, the air cylinder 53 is disposed above one end of the second rotating rod 46, the fixed block 51 is disposed below one end of the second rotating rod 46, an output end of the air cylinder 53 extends to the bottom of the second rotating rod 46 through the top of the second rotating rod 46 and is connected with the top of the fixed block 51, the two first clamping arms 55 are symmetrically disposed on the fixed block 51, each first clamping arm 55 is rotatably connected with the fixed block 51, the two first rotating gears 56 are symmetrically disposed on one side of the fixed block 51, and each first rotating gear 56 is respectively connected with the top end of one side of one first clamping arm 55, and the two first rotating gears 56 are engaged with each other, the first rotating motor 52 is arranged at the other end of the fixed block 51, the output end of the first rotating motor 52 penetrates through one side of the fixed block 51 and extends to the other side of the fixed block 51 to be connected with one first rotating gear 56, the moving block 54 is arranged at the top end of the fixed frame 1, and the bottom end of the moving block 54 penetrates through the L-shaped chute 12 and is connected with the top end of the cylinder 53, when in use, the cylinder 53 drives the fixed block 51 and the first clamping arm 55 to vertically move downwards, and when moving to the position, the first rotating motor 52 is turned on to drive one of the first gears and the clamping arms to rotate, so that the first gear drives the other first gear to rotate relative to the clamping arms, the clamping arms are turned on to clamp the cutting balloon capsule 103 or the arm between the clamping arms, the movable block 54 and the air cylinder 53 are driven by the opening drive mechanism 4 to move along the direction of the L-shaped chute 12, and the handle 101 and the cutting balloon capsule 103 are connected together.

Specifically, referring to fig. 2 and 6, the limiting mechanism 6 includes a second fixed motor 61, a fixed plate 62, a limiting plate 63, a fixed rod 64 and a rotating disc 65, the fixed plate 62 is disposed above one end of the cutting balloon capsule 103 conveyor belt 2 and the handle conveyor belt 3, two ends of the fixed plate 62 are connected to the inner side walls of two sides of the fixed frame 1, the second fixed motor 61 is disposed on one side of the fixed plate 62, an output end of the second fixed motor 61 penetrates through one side of the fixed plate 62 and extends to the other side of the fixed plate 62 to be connected to one side of the rotating disc 65, the fixed rod 64 is disposed on one side of the rotating disc 65, the limiting plate 63 is disposed on one end of the fixed rod 64, a top end of the limiting plate 63 is rotatably connected to one end of the fixed rod 64, two ends of the limiting plate 63 are slidably connected to the inner side walls of two sides of the fixed frame 1, and the rotating disc 65 is driven by the second fixed motor 61 to rotate, the rotating disc 65 drives the fixing rod 64 to rotate, so that the fixing rod 64 drives the limiting plate 63 to vertically move upwards, and a cutting balloon capsule 103 or a handle 101 moves to a position between the limiting plate 63 and the limiting block.

Specifically, as shown in fig. 6 to 8, the traction mechanism 7 includes a support frame 71, a driving motor 72, a rack 73, a second rotating gear 74, a second moving motor 75, a slider 76, a screw 77, a sliding plate 78 and a traction assembly 79, the bottom of the support frame 71 is slidably connected with the bottom of the fixed frame 1, the screw 77 is disposed in the support frame 71, the driving motor 72 is disposed at one side of the support frame 71, an output end of the driving motor 72 extends into the support frame 71 through the support frame 71 and is connected with one end of the screw 77, the slider 76 is disposed on the screw 77, the slider 76 is in threaded connection with the screw 77, the sliding plate 78 is disposed at a top end of the slider 76, the traction assembly 79 is disposed at one side of the sliding plate 78, the second moving motor 75 is disposed at the bottom of an inner side wall of the support frame 71, and an output end of the second moving motor 75 extends to an outer side of the support frame 71 through the inner side wall of the support frame 71 and is connected with the second rotating gear One side of the moving gear 74 is connected, the rack 73 is arranged on one side of the support frame 71, the rack 73 is meshed with the second rotating gear 74, the screw 77 is driven by the driving motor 72 to rotate, the screw 77 drives the slider 76 and the sliding plate 78 to move, after the sliding plate 78 moves the traction assembly 79 to the joint of the handle 101 and the lead 102, the traction assembly 79 is opened to slightly clamp the lead 102 and then transversely move, after the traction assembly 79 moves to the other end of the lead 102 along the joint of the lead 102 and the handle 101 and clamps the lead 102, the traction assembly 79 and the lead 102 synchronously move, the lead 102 is pulled into the cutting balloon body 103 by the traction assembly 79, the screw 77 is driven by the driving motor 72 to repeatedly rotate repeatedly, the slider 76 drives the sliding plate 78 and the traction assembly 79 to repeatedly transversely move, so that the lead 102 passes through the cutting balloon body 103 and extends out from the other end of the cutting balloon body 103, after the completion, the second moving motor 75 drives the second rotating gear 74 and the supporting frame 71 to move along the setting direction of the rack 73, so as to move the pulling assembly 79 away from the wire 102.

Specifically, referring to fig. 6 to 8, the drawing assembly 79 includes a second rotating motor 791, a rotating block 792, two supporting blocks 793 and two second clamping arms 794, the two second clamping arms 794 are symmetrically disposed on one side of the sliding plate 78, and both the two second clamping arms 794 are slidably connected to one side of the sliding plate 78, the second rotating motor 791 is disposed on one side of the sliding plate 78, and an output end of the second rotating motor 791 extends through one side of the sliding plate 78 to the other side of the sliding plate 78 to be connected to one side of the rotating block 792, one end of each of the two supporting blocks 793 is rotatably disposed at one end of the rotating block 792, and the other end of each of the supporting blocks 793 is connected to one side of one second clamping arm 794, the rotating block 792 is driven by the second rotating motor 791 to rotate, the rotating block 792 drives the two supporting blocks 793 to rotate, the two supporting blocks 793 drive the two second clamping arms 794 to relatively slide along the side wall of the sliding block, such that the wire 102 is clamped between the two second clamping arms 794.

The above description is only an example of the present invention, and is not intended to limit the present invention. Various modifications and alterations to this invention will become apparent to those skilled in the art. Any modification, equivalent replacement, improvement, etc. made within the spirit and principle of the present invention should be included in the scope of the claims of the present invention.