CN116922741A - Medical sacculus apparatus for producing - Google Patents

Abstract

The invention discloses a medical balloon production device, which comprises a base, wherein split heating mechanisms are symmetrically arranged at two sides of the bottom of the base, and split cooling mechanisms are arranged at the center of the top of the base and at one side of the top of the base; the cooling jacket and the heating jacket are respectively designed in a split mode, the semicircular design is suitable for dies with different diameters, and the application range of the equipment is enlarged; the heat absorption of the surface of the die is carried out through the arc-shaped heat conducting plate, heat is transferred to the radiating fins, the radiating fins exchange heat with cooling water, rapid cooling is achieved, the contact area between the radiating fins and cooling liquid is increased through the design of the radiating fins, and radiating efficiency is improved.

Description

Medical sacculus apparatus for producing

Technical Field

The invention relates to the technical field of balloon production equipment, in particular to a medical balloon production device.

Background

The biggest application field of current medical sacculus is percutaneous transluminal coronary angioplasty, the application of medicine support brings revolutionary progress to PTCA operation, so that the main application of current medical sacculus is changed from vasodilation to plastic deformation to support transportation and expansion, the medical sacculus on the market at present is in the production process, the raw material of the sacculus in a mould needs to be heated and softened, then the injection molding technology is utilized to carry out blow molding of the sacculus, cooling water is utilized to carry out cooling molding after the blow molding, however, the heating jacket and the cooling jacket of the existing medical sacculus production equipment are arranged together, when the cooling jacket is utilized to cool after the blow molding, the mould and the product are cooled to the room temperature, and the heating jacket is also cooled to the room temperature, so that the heating jacket needs to be heated again from the room temperature during mass production, the energy consumption during the mass production is increased, the production cost is increased, and meanwhile, the cooling jacket of the existing equipment is fixedly arranged, only the mould with single size can be applied, the practicality of the equipment is greatly reduced, and the existing cooling jacket utilizes cooling water to carry out heat exchange, thereby cooling the mould, however, the cooling rate of the existing equipment is poor, and the cooling rate of the existing equipment is low.

Disclosure of Invention

The invention aims to provide a medical balloon production device which aims to solve the problems in the background technology.

In order to achieve the above purpose, the present invention provides the following technical solutions: the utility model provides a medical sacculus apparatus for producing, includes the base, split type heating mechanism is installed to base bottom bilateral symmetry, and split type cooling mechanism is installed to base top center and top one side, and four supporting legs are installed to base bottom four corners symmetry.

Preferably, four mounting plates are symmetrically arranged on two sides of the top of the base, two fixing plates are arranged on the tops of the four mounting plates and are symmetrically distributed, two sliding rails are arranged in the centers of the tops of the two fixing plates, two sliding blocks are connected with the centers of the tops of the two sliding rails in a sliding manner, two fixing blocks are arranged on the tops of the two sliding blocks, and two stretching blocks are arranged in the centers of the two fixing blocks.

Preferably, two hydraulic telescopic rods are installed at the bottom of one side of each fixing block, two hydraulic telescopic rod output ends are welded and fixed with the bottom of one side of each fixing block, two side blocks are installed at two hydraulic telescopic rod fixed ends, two side blocks are symmetrically installed on one side of the top of each fixing plate, two installation seats are installed on the other side of the top of each fixing plate, and production dies are installed at the centers of the opposite sides of the two installation seats.

Preferably, the split type heating mechanism comprises a servo motor, a top plate, a mounting arm, a movable rod, bearing blocks, screw rods, movable blocks, guide rods, a heating jacket and a heating pipe, wherein two mounting arms are symmetrically mounted on two sides of the center of the bottom of the base, two servo motors are mounted on one side top of each of the two mounting arms, the output ends of the two servo motors movably penetrate through one side top of each of the mounting arms, two screw rods are mounted on the output ends of the two servo motors, one end of each of the two screw rods is rotationally connected with two bearing blocks, two top plates are mounted on the tops of the two bearing blocks, and the two top plates are mounted on the tops of the two mounting arms.

Preferably, two movable blocks are sleeved at the centers of the screw rods, the two movable blocks are connected with the two screw rods in a matched manner through ball nuts, two guide rods are movably penetrated at the middle lower parts of the two movable blocks, the two movable blocks are slidably connected with the two guide rods, one ends of the two guide rods are fixedly connected with the tops of one sides of the two mounting arms, and the other ends of the two guide rods are fixedly connected with the bottoms of one sides of the two bearing blocks.

Preferably, two movable rods are installed at the bottoms of the two movable blocks, two heating jackets are installed at one ends of the two movable rods, heating pipes are installed inside the two heating jackets, and the heating pipes are electrically connected with the electric heating controller.

Preferably, the split type cooling mechanism comprises a first telescopic cylinder, a push rod, reinforcing angle irons, stand columns, a second telescopic cylinder, a water storage tank, a shunt pipe, a first rubber hose, a cooling jacket, a water pump and a second rubber hose, wherein the second telescopic cylinder is arranged in the center of the top of the base, the stand columns are arranged on one side of the top of the base, the push rod is arranged on the top of the stand columns, the reinforcing angle irons are arranged between the push rod and the stand columns, and the first telescopic cylinder is arranged on one side of the bottom of the push rod.

Preferably, the cooling jacket is all installed to first flexible cylinder and the flexible cylinder output of second, and two first rubber hose are installed to two cooling jacket one sides, and two first rubber hose and two cooling jacket inside intercommunication, and two first rubber hose one end install the shunt tubes, the storage water tank is installed to the shunt tubes bottom, and the water pump is installed to storage water tank inside ground one side, water pump output and shunt tubes one end fixed connection, two second rubber hose are installed to two cooling jacket opposite sides, and two second rubber hose and two cooling jacket inside intercommunication, two second rubber hose one end and storage water tank top one side fixed connection.

Preferably, two arc-shaped heat conducting plates are arranged on the inner circumference of the two cooling jackets, and a plurality of radiating fins are arranged at the bottoms of the two arc-shaped heat conducting plates and are positioned in the cooling jackets.

Compared with the prior art, the invention has the beneficial effects that:

1. according to the invention, the heating jacket and the cooling jacket are separately designed, and are sequentially heated and cooled, so that the heating jacket is prevented from being cooled when the die and the balloon are cooled, and is not required to be reheated from room temperature when being reheated, the energy waste is reduced, and the energy utilization rate is improved;

2. according to the invention, the cooling jacket and the heating jacket are respectively designed in a split mode, the air cylinder and the screw rod are used for driving, so that the mold is attached and detached, the semicircular design is suitable for molds with different diameters, the application range of equipment is enlarged, and the practicability of the equipment is improved;

3. according to the invention, heat absorption of the surface of the die is carried out through the arc-shaped heat-conducting plate, heat is transferred to the radiating fins, and the radiating fins exchange heat with cooling water, so that rapid cooling is realized, and compared with a traditional water-cooling radiating mechanism, the contact area of the radiating fins and cooling liquid is increased through the design of the radiating fins, and the radiating efficiency is improved.

Drawings

FIG. 1 is a perspective front plan view of the overall structure of the present invention;

FIG. 2 is an enlarged schematic view of area A of FIG. 1 in accordance with the present invention;

FIG. 3 is a perspective rear plan view of the overall structure of the present invention;

FIG. 4 is a front cross-sectional view of the cooling jacket of the present invention;

FIG. 5 is a front cross-sectional view of the water storage tank of the present invention;

FIG. 6 is a front elevational view of the overall structure of the present invention;

FIG. 7 is a side cross-sectional view of the overall structure of the present invention;

FIG. 8 is an enlarged schematic view of area B of FIG. 7 in accordance with the present invention;

FIG. 9 is an enlarged schematic view of area C of FIG. 7 in accordance with the present invention;

in the figure: 1. a base; 2. support legs; 3. a split heating mechanism; 4. a side block; 5. a split cooling mechanism; 6. a mounting plate; 7. a slide block; 8. a fixing plate; 9. a slide rail; 10. a hydraulic telescopic rod; 11. stretching the block; 12. a fixed block; 13. producing a mold; 14. a mounting base; 15. an arc-shaped heat conducting plate; 16. a heat radiation fin; 301. a servo motor; 302. a top plate; 303. a mounting arm; 304. a movable rod; 305. a bearing block; 306. a screw rod; 307. a movable block; 308. a guide rod; 309. a heating jacket; 310. heating pipes; 501. a first telescopic cylinder; 502. a push rod; 503. reinforcing angle iron; 504. a column; 505. the second telescopic cylinder; 506. a water storage tank; 507. a shunt; 508. a first rubber hose; 509. a cooling jacket; 510. a water pump; 511. and a second rubber hose.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

Referring to fig. 1-9, an embodiment of the present invention is provided: the utility model provides a medical balloon apparatus for producing, including base 1, four mounting panels 6 are installed to base 1 top bilateral symmetry, and two fixed plates 8 are installed at four mounting panel 6 tops, two fixed plates 8 are the symmetric distribution, and two slide rail 9 are installed to two fixed plate 8 top centers, two slide rail 9 top center sliding connection has two sliders 7, and two fixed blocks 12 are installed at two slider 7 tops, two stretching blocks 11 are installed at two fixed block 12 centers, two hydraulic telescoping rods 10 are installed to two fixed block 12 one side bottoms, and two hydraulic telescoping rod 10 output and two fixed block 12 one side bottoms welded fastening, two side blocks 4 are installed to two hydraulic telescoping rod 10 stiff ends, and two side blocks 4 are installed at two fixed plate 8 top one sides symmetrically, two mount pad 14 are installed to two fixed plate 8 top opposite sides, and the center of the opposite sides of the two mounting seats 14 is provided with a production mould 13 which is favorable for stretching in the balloon production process through the hydraulic telescopic rod 10, the two sides of the bottom of the base 1 are symmetrically provided with a split type heating mechanism 3, the split type heating mechanism 3 comprises a servo motor 301, a top plate 302, a mounting arm 303, a movable rod 304, a bearing block 305, a screw rod 306, a movable block 307, a guide rod 308, a heating jacket 309 and a heating pipe 310, the two sides of the center of the bottom of the base 1 are symmetrically provided with two mounting arms 303, the top of one side of each of the two mounting arms 303 is provided with two servo motors 301, the output ends of the two servo motors 301 movably penetrate through the top of one side of each of the mounting arms 303, the output ends of each of the two servo motors 301 are provided with two screw rods 306, one end of each of the two screw rods 306 is rotationally connected with two bearing blocks 305, the top plates 302 are arranged at the top of each of the two bearing blocks 305, and the two top plates 302 are arranged at the top of the tops of the two mounting arms 303, the centers of the two screw rods 306 are sleeved with two movable blocks 307, the two movable blocks 307 and the two screw rods 306 are connected in a matched manner through ball nuts, the middle lower parts of the two movable blocks 307 are movably penetrated with two guide rods 308, the two movable blocks 307 are slidably connected with the two guide rods 308, one ends of the two guide rods 308 are fixedly connected with the tops of one sides of the two mounting arms 303, the other ends of the two guide rods 308 are fixedly connected with the bottoms of one sides of the two bearing blocks 305, the bottoms of the two movable blocks 307 are provided with two movable rods 304, one ends of the two movable rods 304 are provided with two heating jackets 309, heating pipes 310 are respectively arranged in the two heating jackets 309, the heating pipes 310 are electrically connected with an electric heating controller, the split type cooling mechanism 5 is arranged at the top center and the top side of the base 1, the split type heating mechanism 3 is beneficial to realizing the heating of the production mold 13, the split cooling mechanism 5 comprises a first telescopic cylinder 501, a push rod 502, a reinforcing angle iron 503, a column 504, a second telescopic cylinder 505, a water storage tank 506, a shunt tube 507, a first rubber hose 508, a cooling jacket 509, a water pump 510 and a second rubber hose 511, wherein the second telescopic cylinder 505 is arranged at the center of the top of the base 1, the column 504 is arranged on one side of the top of the base 1, the push rod 502 is arranged on the top of the column 504, the reinforcing angle iron 503 is arranged between the push rod 502 and the column 504, the first telescopic cylinder 501 is arranged on one side of the bottom of the push rod 502, the cooling jackets 509 are arranged at the output ends of the first telescopic cylinder 501 and the second telescopic cylinder 505, two first rubber hoses 508 are arranged on one side of the two cooling jackets 509, the two first rubber hoses 508 are communicated with the inside of the two cooling jackets 509, the shunt tube 507 is arranged at one end of the two first rubber hoses 508, the water storage tank 506 is arranged at the bottom of the shunt tube 507, and water pump 510 is installed to the inside ground one side of storage water tank 506, water pump 510 output and shunt tubes 507 one end fixed connection, two second rubber hose 511 are installed to two cooling jacket 509 opposite sides, and two second rubber hose 511 and the inside intercommunication of two cooling jackets 509, two arc heat-conducting plate 15 are installed to two cooling jacket 509 one end and storage water tank 506 top one side fixed connection, and a plurality of radiating fins 16 are all installed to two arc heat-conducting plate 15 bottoms, radiating fins 16 are located cooling jacket 509 inside, be favorable to realizing the quick cooling of production mould 13 through split type cooling mechanism 5, four supporting legs 2 are installed to base 1 bottom quadrangle symmetry.

Working principle: in the use process of the invention, firstly, balloon production raw materials are placed into a production mould 13, then the production mould 13 is installed on an installation seat 14, meanwhile, two ends of balloon materials are respectively installed on a stretching block 11, at the moment, the production mould 13 is heated by utilizing a split type heating mechanism 3, at the moment, a servo motor 301 in the split type heating mechanism 3 is started, the output end of the servo motor 301 starts to rotate, then a screw rod 306 is driven to rotate, as the screw rod 306 and a movable block 307 are connected in a matched manner through a ball nut, the movable block 307 is driven to move along the direction of the screw rod 306 towards a bearing block 305, then a movable rod 304 is driven to move towards the direction of the bearing block 305, then a heating jacket 309 is driven to move towards the direction of the production mould 13 until two heating jackets 309 are respectively attached to two sides of the production mould 13, at the moment, a heating pipe 310 is opened, the heating pipe 310 heats the production mould 13, the production mould 13 heats the balloon material in the production mould 13, after the heating is finished, the hydraulic telescopic rod 10 is opened, the output end of the hydraulic telescopic rod 10 starts to shrink, the fixed block 12 is driven to move towards the hydraulic telescopic rod 10, the stretching block 11 is driven to move towards the hydraulic telescopic rod 10, the heated balloon is stretched, meanwhile, the blowing machine blows the balloon inside, the balloon is tightly attached to the production mould 13, the blow molding production is carried out according to the shape of the production mould 13, the servo motor 301 is reversed, the heating jacket 309 is driven to be far away from the production mould 13 under the action of the servo motor 301, the first telescopic cylinder 501 and the second telescopic cylinder 505 in the split cooling mechanism 5 are opened, the output ends of the first telescopic cylinder 501 and the second telescopic cylinder 505 start to stretch, the cooling jacket 509 is driven to move, the cooling jacket 509 is ensured to be attached to the periphery of the production mold 13, at the moment, the water pump 510 is turned on, the water pump 510 conveys the cooling liquid in the water storage tank 506 to the shunt pipe 507, then the cooling liquid enters the first rubber hose 508 after being shunted by the shunt pipe 507, the first rubber hose 508 conveys the cooling liquid to the cooling jacket 509, at the moment, the heat of the production mold 13 is transferred to the arc-shaped heat conducting plate 15, the heat is absorbed by the arc-shaped heat conducting plate 15 and then transferred to the heat radiating fins 16, the heat radiating fins 16 exchange heat with the cooling liquid, the production mold 13 is rapidly radiated, the arc-shaped heat conducting plate 15 and the heat radiating fins 16 are made of brass, the cooling liquid after heat absorption flows back to the second rubber hose 511, and enters the water storage tank 506 through the second rubber hose 511 to form circulating heat radiation, the quick cooling forming of the production mould 13 is realized, after the production is finished, the finished balloon product in the production mould 13 is taken out, the supporting leg 2 is used for supporting the base 1, the base 1 is used for installing the split type heating mechanism 3 and the split type cooling mechanism 5, the mounting plate 6 is used for installing the fixing plate 8, the fixing plate 8 is used for fixing the sliding rail 9, the sliding rail 9 is used for installing the sliding block 7, the upright post 504 is used for installing the ejector rod 502, the ejector rod 502 is used for fixing the first telescopic cylinder 501, the reinforced angle iron 503 is used for reinforcing the structural strength between the ejector rod 502 and the upright post 504, the installation arm 303 is used for installing the servo motor 301, the installation arm 303 is used for fixing the top plate 302, the top plate 302 is used for fixing the bearing block 305, the bearing block 305 is used for fixing the guide rod 308, and the guide rod 308 is used for limiting the movable block 307.

It will be evident to those skilled in the art that the invention is not limited to the details of the foregoing illustrative embodiments, and that the present invention may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. The present embodiments are, therefore, to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Claims (9)

1. The utility model provides a medical sacculus apparatus for producing, includes base (1), its characterized in that: split type heating mechanism (3) are installed to base (1) bottom bilateral symmetry, and split type cooling mechanism (5) are installed at base (1) top center and top one side, and four supporting legs (2) are installed to base (1) bottom four corners symmetry.

2. The medical balloon production device according to claim 1, wherein: four mounting plates (6) are symmetrically arranged on two sides of the top of the base (1), two fixing plates (8) are arranged on the tops of the four mounting plates (6), the two fixing plates (8) are symmetrically distributed, two sliding rails (9) are arranged in the centers of the tops of the two fixing plates (8), two sliding blocks (7) are slidably connected to the centers of the tops of the two sliding rails (9), two fixing blocks (12) are arranged on the tops of the two sliding blocks (7), and two stretching blocks (11) are arranged in the centers of the two fixing blocks (12).

3. A medical balloon production device according to claim 2, characterized in that: two hydraulic telescopic rods (10) are installed to two fixed block (12) one side bottoms, and two hydraulic telescopic rods (10) output and two fixed block (12) one side bottoms welded fastening, two side piece (4) are installed to two hydraulic telescopic rods (10) stiff end, and two side piece (4) symmetry are installed in two fixed plate (8) top one side, two mount pad (14) are installed to two fixed plate (8) top opposite side center, and production mould (13) are installed to two mount pad (14) opposite side center.

4. The medical balloon production device according to claim 1, wherein: the split type heating mechanism (3) comprises a servo motor (301), a top plate (302), an installation arm (303), a movable rod (304), bearing blocks (305), screw rods (306), movable blocks (307), guide rods (308), a heating jacket (309) and a heating pipe (310), wherein two installation arms (303) are symmetrically installed on two sides of the center of the bottom of the base (1), two servo motors (301) are installed on one side top of each installation arm (303), the output ends of the two servo motors (301) movably penetrate through one side top of each installation arm (303), two screw rods (306) are installed on the output ends of the two servo motors (301), one ends of the two screw rods (306) are rotationally connected with the two bearing blocks (305), two top plates (302) are installed on the tops of the two bearing blocks (305), and the two top plates (302) are installed on the tops of the two installation arms (303).

5. The medical balloon production device according to claim 4, wherein: two movable blocks (307) are sleeved at the centers of the screw rods (306), the two movable blocks (307) are connected with the two screw rods (306) in a matched mode through ball nuts, two guide rods (308) are movably penetrated through the middle lower portions of the two movable blocks (307), the two movable blocks (307) are slidably connected with the two guide rods (308), one ends of the two guide rods (308) are fixedly connected with the tops of one sides of the two mounting arms (303), and the other ends of the two guide rods (308) are fixedly connected with the bottoms of one sides of the two bearing blocks (305).

6. The medical balloon production device according to claim 5, wherein: two movable rods (304) are installed at the bottoms of the two movable blocks (307), two heating jackets (309) are installed at one ends of the two movable rods (304), heating pipes (310) are installed inside the two heating jackets (309), and the heating pipes (310) are electrically connected with an electric heating controller.

7. The medical balloon production device according to claim 1, wherein: the split type cooling mechanism (5) comprises a first telescopic cylinder (501), a push rod (502), a reinforcing angle iron (503), a stand column (504), a second telescopic cylinder (505), a water storage tank (506), a shunt pipe (507), a first rubber hose (508), a cooling jacket (509), a water pump (510) and a second rubber hose (511), wherein the second telescopic cylinder (505) is arranged in the center of the top of the base (1), the stand column (504) is arranged on one side of the top of the base (1), the push rod (502) is arranged on the top of the stand column (504), the reinforcing angle iron (503) is arranged between the push rod (502) and the stand column (504), and the first telescopic cylinder (501) is arranged on one side of the bottom of the push rod (502).

8. The medical balloon production device according to claim 7, wherein: the cooling jacket (509) is installed at the output ends of the first telescopic cylinder (501) and the second telescopic cylinder (505), two first rubber hoses (508) are installed on one sides of the two cooling jackets (509), the two first rubber hoses (508) are communicated with the inside of the two cooling jackets (509), the shunt tubes (507) are installed at one ends of the two first rubber hoses (508), the water storage tank (506) is installed at the bottom of the shunt tubes (507), the water pump (510) is installed on one side of the ground inside the water storage tank (506), the output end of the water pump (510) is fixedly connected with one end of the shunt tube (507), two second rubber hoses (511) are installed on the other sides of the two cooling jackets (509), one ends of the two second rubber hoses (511) are fixedly connected with one side of the top of the water storage tank (506).

9. The medical balloon production device according to claim 8, wherein: two arc-shaped heat conducting plates (15) are arranged on the inner circumference of the two cooling jackets (509), a plurality of radiating fins (16) are arranged at the bottoms of the two arc-shaped heat conducting plates (15), and the radiating fins (16) are located inside the cooling jackets (509).