CN110496851B - Medical infusion package treatment facility - Google Patents

Abstract

The invention relates to extrusion crushing equipment, in particular to medical infusion packaging treatment equipment which comprises an installation support frame, a flattening device, a feeding device, a crushing device and a crushing transmission device, wherein a used packaging shell rubber tube and the like are compressed into a sheet through the flattening device, then the sheet is sent to a feeding buckle of the crushing device through the feeding device and then continuously pushed forwards, the crushing device cuts and crushes the sheet material and then discharges the crushed material out of a box, and the crushing transmission device provides functions of power, transmission direction and the like during crushing, and is characterized in that: the flattening device is fixedly installed on the installation supporting frame, the feeding device is fixedly installed on the installation supporting frame, the crushing device is fixedly installed on the installation supporting frame, and the crushing transmission device is fixedly installed on the crushing device.

Description

Medical infusion package treatment facility

Technical Field

The invention relates to extrusion crushing equipment, in particular to medical infusion packaging and processing equipment.

Background

With the improvement of the existing living conditions, patients can go to hospitals to see medical treatment as long as the body is uncomfortable, after some serious diseases are treated, a period of medical care is selected in the hospitals, and transfusion is needed during the nursing, so that a large number of rubber bags and rubber tubes for containing transfusion are generated, if the patients are not properly treated, the occupied space is also polluted, and resources are wasted, so that the medical transfusion packaging and processing equipment is invented.

Disclosure of Invention

The invention relates to extrusion crushing equipment, in particular to medical infusion packaging treatment equipment, which compresses a used packaging shell rubber tube and the like into sheets through a flattening device, then sends the sheets to a feeding buckle of a crushing device through a feeding device and continuously pushes the sheets forwards, the crushing device cuts and crushes the sheets and then discharges the crushed materials out of a box, and a crushing transmission device provides functions of power, transmission direction and the like during crushing.

In order to solve the technical problems, the invention relates to an extrusion crushing device, in particular to a medical infusion packaging processing device, which comprises an installation support frame, a flattening device, a feeding device, a crushing device and a crushing transmission device, wherein a used packaging shell rubber tube and the like are compressed into a sheet by the flattening device, then the sheet is sent to a feeding buckle of the crushing device by the feeding device and then continuously pushed forwards, the crushing device cuts and crushes the sheet material and then discharges the crushed material out of a box, and the crushing transmission device provides functions of power, transmission direction and the like during crushing, and is characterized in that: the flattening device is fixedly installed on the installation supporting frame, the feeding device is fixedly installed on the installation supporting frame, the crushing device is fixedly installed on the installation supporting frame, and the crushing transmission device is fixedly installed on the crushing device.

As a further optimization of the technical scheme, the mounting support frame of the medical infusion packaging treatment equipment comprises a fixed floor, a flattening device mounting rod, a feeding device mounting rod and a crushing device mounting rod, wherein the flattening device mounting rod is mounted and fixed on the fixed floor, the feeding device mounting rod is mounted and fixed on the fixed floor, and the crushing device mounting rod is mounted and fixed on the fixed floor.

As a further optimization of the technical scheme, the flattening device of the medical transfusion packaging processing equipment comprises a collecting pressure-variable box, a feeding port, a discharging port, a rotating shaft, a bevel gear, an extrusion column, a transmission gear, a first extrusion column, a second rotating gear, a second transmission shaft, a third extrusion column, a third transmission gear, a motor, a first bevel gear, a double-circular-groove mounting and double-circular-groove mounting, wherein the collecting pressure-variable box is fixedly arranged on a flattening device mounting rod, the feeding port is arranged on the collecting pressure-variable box, the discharging port is arranged on the collecting pressure-variable box, the rotating shaft is movably arranged in the collecting pressure-variable box, the bevel gear is fixedly arranged on the rotating shaft, the transmission gear is fixedly arranged on the rotating shaft, the first transmission gear is fixedly arranged on the rotating shaft, and the first rotating shaft is movably arranged in the collecting pressure-variable box, the installation of the first extrusion column is fixed on the first rotating shaft, the installation of the second rotating gear is fixed on the first rotating shaft, the second rotating gear is meshed with the transmission gear, the second transmission shaft is movably installed inside the collecting pressure-variable box, the third extrusion column is installed and fixed on the second transmission shaft, the third transmission gear is meshed with the first transmission gear, the motor is installed and fixed on the collecting pressure-variable box, the first bevel gear is installed and fixed on the motor, the first bevel gear is meshed with the transmission gear, the installation of the double circular grooves is arranged inside the collecting pressure-variable box, and the installation of the double circular grooves is arranged inside the collecting pressure-variable box.

As a further optimization of the technical scheme, the feeding device of the medical infusion packaging treatment equipment comprises a feeding installation box, a feeding hole I, a rotating shaft III, a bevel gear II, a power transmission column, a motor III, a bevel gear III, a fixed shaft, a rotating cylinder, a rotating crawler, a fixed square cylinder, a spring, a moving block, a moving column, an auxiliary wheel installation seat, an auxiliary wheel installation shaft, an auxiliary wheel, a fixed cylinder, a spring I, a sliding plate, a moving connecting rod, a connecting plate I, a fixed shaft I and a rotating cylinder I, wherein the feeding installation box is fixedly arranged on a feeding device installation rod, the feeding hole I is arranged on the feeding installation box, the rotating shaft III is movably arranged on the feeding installation box, the bevel gear II is fixedly arranged on the rotating shaft III, the power transmission column is fixedly arranged on the rotating shaft III, the motor III is fixedly arranged on the feeding installation box, and the bevel gear III is fixedly arranged on the motor III, the fixed shaft is fixedly arranged on the feeding installation box, the rotating cylinder is movably arranged on the fixed shaft, the rotating crawler belt is arranged on the power transmission column, the rotating crawler belt is arranged on the rotating cylinder, the rotating crawler belt is arranged on the auxiliary wheel installation shaft, the fixed square cylinder is fixedly arranged in the feeding installation box, the spring is movably arranged in the fixed square cylinder, the moving block is movably arranged in the fixed square cylinder, the moving column is fixedly arranged on the moving block, the auxiliary wheel installation seat is fixedly arranged on the moving column, the auxiliary wheel installation shaft is movably arranged on the feeding installation box, the auxiliary wheel is fixedly arranged on the auxiliary wheel installation shaft, the fixed cylinder is fixedly arranged on the feeding installation box, the spring I is movably arranged on the fixed cylinder, the sliding plate is movably arranged on the fixed cylinder, the moving connecting rod is fixedly arranged on the sliding plate, the connecting plate I is fixedly, the first rotating cylinder is movably arranged on the first fixed shaft.

As a further optimization of the technical scheme, the crushing device of the medical transfusion packaging treatment equipment comprises a crushing box, a fourth feeding port, a fourth discharging port, a fourth rotating shaft, a receiving gear, an inner cutter connecting rod, an inner cutter, a fourth transmission gear, an inner toothed ring, an outer cutter connecting rod swinging groove, a transmission gear mounting shaft and a fifth transmission gear, wherein the crushing box is fixedly mounted on a crushing device mounting rod, the fourth feeding port is arranged on the crushing box, the fourth discharging port is arranged on the crushing box, the fourth rotating shaft is movably mounted on the crushing box, the receiving gear is fixedly mounted on the fourth rotating shaft, the inner cutter connecting rod is fixedly mounted on the fourth rotating shaft, the inner cutter is fixedly mounted on the inner cutter connecting rod, the fourth transmission gear is fixedly mounted on the fourth rotating shaft, the inner toothed ring is fixedly mounted on the outer cutter connecting rod, the outer cutter connecting rod is slidably mounted in the swinging groove of the outer cutter connecting rod, the outer cutter is fixedly arranged on an outer cutter connecting rod, an outer cutter connecting rod swinging groove is formed in the crushing box, a transmission gear mounting shaft is fixedly arranged in the outer cutter connecting rod swinging groove, a transmission gear five is movably arranged on the transmission gear mounting shaft and meshed with an inner toothed ring, and the transmission gear five is meshed with a transmission gear four.

As a further optimization of the technical scheme, the crushing transmission device of the medical infusion packaging treatment equipment comprises a connecting frame, a motor V, an output belt wheel, a transmission belt, a rotating shaft V, a receiving belt wheel, a rotating disc, a poking rod, a fixed shaft V, a sector gear swinging rod and a strip-shaped groove, wherein the connecting frame is fixedly arranged on a crushing box, the motor V is fixedly arranged on the connecting frame, the output belt wheel is fixedly arranged on the motor V, the transmission belt is arranged on the output belt wheel, the transmission belt is arranged on the receiving belt wheel, the rotating shaft V is movably arranged on the connecting frame, the receiving belt wheel is fixedly arranged on the rotating shaft V, the rotating disc is fixedly arranged on the rotating shaft V, the poking rod is fixedly arranged on the rotating disc, the poking rod is in clearance fit with the strip-shaped groove, the fixed shaft V is fixedly arranged on the crushing box, the sector gear swinging rod is movably arranged on the fixed shaft V, the sector gear oscillating rod is meshed with the receiving gear, and the strip-shaped groove is formed in the sector gear oscillating rod.

As a further optimization of the technical scheme, the number of the fixed shafts and the rotating cylinders of the feeding device of the medical infusion packaging treatment equipment is nine, the number of the fixed square cylinders, the number of the springs, the number of the moving blocks, the number of the moving columns, the number of the auxiliary wheel mounting seats, the number of the auxiliary wheel mounting shafts and the number of the auxiliary wheels are two, the number of the fixed cylinders, the number of the first springs, the number of the sliding plates and the number of the moving connecting rods are ten, the number of the first connecting plates is two, and the number of the fixed shafts and the number of the first rotating cylinders are four.

The medical infusion package treatment equipment has the beneficial effects that:

the invention relates to extrusion crushing equipment, in particular to medical infusion packaging treatment equipment, which realizes the functions of compressing used packaging shell rubber tubes and the like into sheets through a flattening device, then conveying the sheets to a feeding buckle of a crushing device through a feeding device, continuously pushing the sheets forwards, cutting and crushing the sheets by the crushing device, then discharging the crushed sheets out of a box, providing power and transmission direction during crushing by a crushing transmission device and the like.

Drawings

The invention is described in further detail below with reference to the accompanying drawings and specific embodiments.

Fig. 1 is a schematic view of the overall structure of the present invention.

Fig. 2 is a schematic view of the overall structure of the present invention.

Fig. 3 is a schematic structural diagram of the mounting support frame of the present invention.

Fig. 4 is a first structural schematic diagram of the flattening device of the invention.

FIG. 5 is a schematic view of a second embodiment of the present invention.

Fig. 6 is a third schematic structural view of a flattening device according to the present invention.

Fig. 7 is a fourth schematic structural view of the flattening apparatus of the present invention.

Fig. 8 is a fifth structural schematic view of the flattening device of the present invention.

Fig. 9 is a first structural schematic diagram of the feeding device of the present invention.

Fig. 10 is a second schematic structural diagram of the feeding device of the present invention.

Fig. 11 is a third schematic structural diagram of the feeding device of the present invention.

Fig. 12 is a first structural schematic diagram of the crushing device of the invention.

Fig. 13 is a schematic structural diagram of a crushing device of the present invention.

Fig. 14 is a third structural schematic diagram of the crushing device of the invention.

Fig. 15 is a fourth schematic structural view of the crushing device of the invention.

Fig. 16 is a schematic structural diagram of a crushing device of the invention.

Fig. 17 is a first structural schematic diagram of the crushing transmission device of the invention.

Fig. 18 is a structural schematic diagram of a crushing transmission device of the invention.

In the figure: mounting a support frame 1; 1-1 of a fixed floor; a flattening device mounting rod 1-2; a feeding device is provided with a rod 1-3; a crushing device mounting rod 1-4; a flattening device 2; collecting a pressure variable box 2-1; a feeding port 2-2; 2-3 of a discharge port; 2-4 of a rotating shaft; 2-5 of bevel gears; 2-6 parts of an extrusion column; transmission gears 2-7; a first transmission gear 2-8; rotating the first shaft 2-9; 2-10 parts of an extrusion column I; rotating the second gear 2-11; 2-12 parts of a second transmission shaft; 2-13 parts of an extrusion column III; transmission gears three 2-14; 2-15 of a motor; bevel gears one 2-16; installing double circular grooves 2-17; mounting a first double circular groove 2-18; a feeding device 3; a feeding installation box 3-1; a first feeding hole is 3-2; rotating a third shaft by 3-3; 3-4 parts of a bevel gear II; 3-5 of a power transmission column; 3-6 parts of a motor III; bevel gears III 3-7; 3-8 parts of a fixed shaft; 3-9 of a rotary drum; rotating the crawler 3-10; 3-11 parts of a fixed square barrel; 3-12 parts of a spring; moving blocks 3-13; moving columns 3-14; auxiliary wheel mounting seats 3-15; auxiliary wheel mounting shafts 3-16; auxiliary wheels 3-17; a fixed cylinder 3-18; 3-19 parts of a first spring; a slide plate 3-20; 3-21 of a movable connecting rod; 3-22 of a first connecting plate; a first fixed shaft 3-23; rotating the first cylinder by 3-24; a crushing device 4; 4-1 of a crushing box; a feed inlet IV is 4-2; a fourth discharge port 4-3; rotating the shaft four 4-4; receiving gear 4-5; 4-6 parts of an inner cutter connecting rod; 4-7 parts of inner cutter; transmission gear four 4-8; 4-9 parts of an inner gear ring; 4-10 parts of an outer cutter connecting rod; 4-11 parts of outer cutter; 4-12 swing grooves of the outer cutter connecting rod; a transmission gear mounting shaft 4-13; five transmission gears 4-14; a crushing transmission 5; a connecting frame 5-1; 5-2 parts of a motor; 5-3 of an output belt wheel; 5-4 parts of a transmission belt; 5-5 of a rotating shaft; receiving belt wheels 5-6; rotating the disc 5-7; 5-8 parts of a poke rod; 5-9 parts of a fixed shaft; 5-10 of a sector gear swing rod; and 5-11 of strip-shaped grooves.

Detailed Description

The first embodiment is as follows:

in order to solve the technical problems described above with reference to fig. 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, and 18, the present invention relates to an extrusion crushing apparatus, and more particularly to an apparatus for infusion including an installation support frame 1, a flattening device 2, a feeding device 3, a crushing device 4, and a crushing transmission device 5, wherein the used rubber tube of a packaging shell is compressed into a sheet by the flattening device, and then the sheet is fed to a feeding buckle of the crushing device by the feeding device and then continuously pushed forward, the crushing device cuts and crushes the sheet and then discharges the sheet out of the box, and the crushing transmission device provides power and transmission direction during crushing, and is characterized in that: the flattening device 2 is fixedly installed on the installation support frame 1, the feeding device 3 is fixedly installed on the installation support frame 1, the crushing device 4 is fixedly installed on the installation support frame 1, and the crushing transmission device 5 is fixedly installed on the crushing device 4.

The second embodiment is as follows:

the following describes the present embodiment with reference to fig. 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, and 18, and the present embodiment further describes the first embodiment, in which the mounting support frame 1 includes a fixed floor 1-1, a flattening device mounting bar 1-2, a feeding device mounting bar 1-3, and a crushing device mounting bar 1-4, the flattening device mounting bar 1-2 is mounted and fixed on the fixed floor 1-1, the feeding device mounting bar 1-3 is mounted and fixed on the fixed floor 1-1, and the crushing device mounting bar 1-4 is mounted and fixed on the fixed floor 1-1.

The third concrete implementation mode:

the first embodiment is further described below with reference to fig. 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18. the first embodiment is further described, the crushing device 2 comprises a collecting pressure-variable box 2-1, a feeding port 2-2, a discharging port 2-3, a rotating shaft 2-4, a bevel gear 2-5, an extrusion column 2-6, a transmission gear 2-7, a transmission gear I2-8, a rotating shaft I2-9, an extrusion column I2-10, a rotating gear II 2-11, a transmission shaft II 2-12, an extrusion column III 2-13, a transmission gear III 2-14, a motor 2-15, a bevel gear I2-16, a double circular groove 2-17, a double circular groove I2-18, the material to be processed is put into the collecting pressure-variable box 2-1 of the crushing device 2, then a motor 2-15 drives a bevel gear I2-16 to rotate, the bevel gear I2-16 drives a bevel gear 2-5 to rotate, the bevel gear 2-5 drives a rotating shaft 2-4 to rotate, the rotating shaft 2-4 drives a transmission gear 2-7 to rotate, the rotating shaft 2-4 drives an extrusion column 2-6 to rotate, the rotating shaft 2-4 drives a transmission gear I2-8 to rotate, the transmission gear 2-7 drives a rotating gear II 2-11 to rotate, the rotating gear II 2-11 drives the rotating shaft I2-9 to rotate, the rotating shaft I2-9 drives the extrusion column I2-10 to rotate, the rotating extrusion column 2-6 and the extrusion column I2-10 flatten materials and then bring the materials into a collecting pressure variable box 2-1, and then the transmission gear I2-8 drives a transmission gear III 2-14 to rotate, a third transmission gear 2-14 drives a second transmission shaft 2-12 to rotate, the second transmission shaft 2-12 drives a third extrusion column 2-13 to rotate, the third extrusion column 2-13 and the second extrusion column 2-6 discharge the extruded material from a discharge port 2-3, a collecting pressure change box 2-1 is fixedly arranged on a flattening device mounting rod 1-2, a feeding port 2-2 is arranged on the collecting pressure change box 2-1, a discharge port 2-3 is arranged on the collecting pressure change box 2-1, a rotating shaft 2-4 is movably arranged in the collecting pressure change box 2-1, a bevel gear 2-5 is fixedly arranged on a rotating shaft 2-4, the extrusion column 2-6 is fixedly arranged on the rotating shaft 2-4, a transmission gear 2-7 is fixedly arranged on the rotating shaft 2-4, and a first transmission gear 2-8 is fixedly arranged on the rotating shaft 2-4, a first rotating shaft 2-9 is movably arranged inside a first collecting pressure change box 2-1, a first extrusion column 2-10 is fixedly arranged on the first rotating shaft 2-9, a second rotating gear 2-11 is fixedly arranged on the first rotating shaft 2-9, the second rotating gear 2-11 is meshed with a first transmission gear 2-7, a second transmission gear 2-12 is movably arranged inside the first collecting pressure change box 2-1, a third extrusion column 2-13 is fixedly arranged on the second transmission gear 2-12, a third transmission gear 2-14 is fixedly arranged on the second transmission gear 2-12, the third transmission gear 2-14 is meshed with the first transmission gear 2-8, a motor 2-15 is fixedly arranged on the first collecting pressure change box 2-1, a first bevel gear 2-16 is fixedly arranged on the motor 2-15, and the first bevel gear 2-16 is meshed with the second transmission gear 2-7, the installation double circular grooves 2-17 are arranged inside the collection pressure change box 2-1, and the installation double circular grooves I2-18 are arranged inside the collection pressure change box 2-1.

The fourth concrete implementation mode:

the first embodiment is further described below with reference to fig. 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17 and 18. the first embodiment is further described, where the feeding device 3 includes a feeding installation box 3-1, a feeding inlet one 3-2, a rotating shaft three 3-3, a bevel gear two 3-4, a power transmission column 3-5, a motor three 3-6, a bevel gear three 3-7, a fixed shaft 3-8, a rotating cylinder 3-9, a rotating crawler 3-10, a fixed square cylinder 3-11, a spring 3-12, a moving block 3-13, a moving cylinder 3-14, an auxiliary wheel installation seat 3-15, an auxiliary wheel installation shaft 3-16, an auxiliary wheel 3-17, a fixed cylinder 3-18, a spring one 3-19, a spring, A sliding plate 3-20, a moving connecting rod 3-21, a connecting plate 3-22, a fixed shaft 3-23 and a rotating cylinder 3-24 enter a feed inlet 3-2 of a feeding device 3, a motor 3-6 drives a bevel gear 3-7 to rotate, the bevel gear 3-7 drives a bevel gear 3-4 to rotate, the bevel gear 3-4 drives a rotating shaft 3-3 to rotate, the rotating shaft 3-3 drives a power transmission column 3-5 to rotate, the power transmission column 3-5 drives a rotating crawler 3-10 to rotate on the rotating cylinder 3-9, a spring 3-12 in a fixed square cylinder 3-11 pushes a moving block 3-13 to move outwards, the moving block 3-13 drives a moving column 3-14, the moving column 3-14 drives an auxiliary wheel mounting seat 3-15, the auxiliary wheel mounting seat 3-15 drives the auxiliary wheel 3-17 to push the rotating crawler 3-10 to be tight through the auxiliary wheel mounting shaft 3-16 so as to prevent the rotating crawler 3-10 from slipping during rotation, then the spring I3-19 of the fixed cylinder 3-18 pushes the sliding plate 3-20 to move outwards, the sliding plate 3-20 drives the moving connecting rod 3-21 to move outwards, the moving connecting rod 3-21 drives the connecting plate I3-22 to move, the connecting plate I3-22 drives the fixed shaft I3-23 to move, the fixed shaft I3-23 drives the rotating cylinder I3-24 to move and then extrude the materials, the friction between the materials and the rotating crawler 3-10 is increased so as to facilitate the feeding, the feeding mounting box 3-1 is mounted and fixed on the feeding device mounting rod 1-3, the feeding port I3-2 is arranged on the feeding mounting box 3-1, a third rotating shaft 3-3 is movably arranged on a feeding installation box 3-1, a second bevel gear 3-4 is fixedly arranged on the third rotating shaft 3-3, a power transmission column 3-5 is fixedly arranged on the third rotating shaft 3-3, a third motor 3-6 is fixedly arranged on the feeding installation box 3-1, a third bevel gear 3-7 is fixedly arranged on the third motor 3-6, a fixed shaft 3-8 is fixedly arranged on the feeding installation box 3-1, a rotating cylinder 3-9 is movably arranged on the fixed shaft 3-8, a rotating crawler 3-10 is arranged on the power transmission column 3-5, the rotating crawler 3-10 is arranged on the rotating cylinder 3-9, the rotating crawler 3-10 is arranged on an auxiliary wheel installation shaft 3-16, and a fixed square cylinder 3-11 is fixedly arranged in the feeding installation box 3-1, the springs 3-12 are movably arranged inside the fixed square barrel 3-11, the moving block 3-13 is movably arranged inside the fixed square barrel 3-11, the moving column 3-14 is fixedly arranged on the moving block 3-13, the auxiliary wheel mounting seat 3-15 is fixedly arranged on the moving column 3-14, the auxiliary wheel mounting shaft 3-16 is movably arranged on the feeding mounting box 3-1, the auxiliary wheel 3-17 is fixedly arranged on the auxiliary wheel mounting shaft 3-16, the fixed cylinder 3-18 is fixedly arranged on the feeding mounting box 3-1, the spring I3-19 is movably arranged on the fixed cylinder 3-18, the sliding plate 3-20 is movably arranged on the fixed cylinder 3-18, the moving connecting rod 3-21 is fixedly arranged on the sliding plate 3-20, the connecting plate I3-22 is fixedly arranged on the moving connecting rod 3-21, the first fixed shaft 3-23 is fixedly arranged on the first connecting plate 3-22, and the first rotating cylinder 3-24 is movably arranged on the first fixed shaft 3-23.

The fifth concrete implementation mode:

the embodiment is described below with reference to fig. 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, and 18. the embodiment further describes the embodiment, where the crushing device 4 includes a crushing box 4-1, a feed inlet four 4-2, a discharge outlet four 4-3, a rotation shaft four 4-4, a receiving gear 4-5, an inner cutter connecting rod 4-6, an inner cutter 4-7, a transmission gear four 4-8, an inner toothed ring 4-9, an outer cutter connecting rod 4-10, an outer cutter 4-11, an outer cutter connecting rod swinging groove 4-12, a transmission gear mounting shaft 4-13, and a transmission gear five 4-14, the receiving gear 4-5 drives the rotation shaft four 4-4 to rotate in a reciprocating manner, the rotation shaft four 4-4 drives the inner cutter connecting rod 4-6 to rotate in a reciprocating manner, the rotating shaft IV 4-4 drives the transmission gear IV 4-8 to rotate in a reciprocating manner, the inner cutter connecting rod 4-6 drives the inner cutter 4-7 to rotate in a reciprocating manner, the transmission gear IV 4-8 drives the inner toothed ring 4-9 to rotate in a reciprocating manner through the transmission gear V4-14, but the rotating directions of the inner toothed ring 4-9 and the inner cutter connecting rod 4-6 are opposite, the inner toothed ring 4-9 drives the outer cutter connecting rod 4-10 to rotate in a reciprocating manner, the outer cutter connecting rod 4-10 drives the outer cutter 4-11 to rotate in a reciprocating manner, the moving directions of the outer cutter 4-11 and the inner cutter 4-7 are opposite, when the outer cutter 4-11 and the inner cutter 4-7 are to be superposed, a material is cut, the cut material is discharged from the discharge port IV 4-3, the crushing box 4-1 is fixedly arranged on the crushing device mounting rod 1-4, a feeding port IV 4-2 is arranged on the crushing box 4-1, a discharging port IV 4-3 is arranged on the crushing box 4-1, a rotating shaft IV 4-4 is movably arranged on the crushing box 4-1, a receiving gear 4-5 is fixedly arranged on the rotating shaft IV 4-4, an inner cutter connecting rod 4-6 is fixedly arranged on the rotating shaft IV 4-4, an inner cutter 4-7 is fixedly arranged on the inner cutter connecting rod 4-6, a transmission gear IV 4-8 is fixedly arranged on the rotating shaft IV 4-4, an inner gear ring 4-9 is fixedly arranged on an outer cutter connecting rod 4-10, the outer cutter connecting rod 4-10 is slidably arranged in an outer cutter connecting rod swinging groove 4-12, an outer cutter 4-11 is fixedly arranged on the outer cutter connecting rod 4-10, the outer cutter connecting rod swinging groove 4-12 is arranged in the crushing box 4-1, the transmission gear mounting shaft 4-13 is fixedly arranged inside the outer cutter connecting rod swinging groove 4-12, the transmission gear five 4-14 is movably arranged on the transmission gear mounting shaft 4-13, the transmission gear five 4-14 is meshed with the inner toothed ring 4-9, and the transmission gear five 4-14 is meshed with the transmission gear four 4-8.

The sixth specific implementation mode:

the embodiment is described below with reference to fig. 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, and 18, and the embodiment further describes the embodiment, where the crushing transmission device 5 includes a connecting frame 5-1, a motor five 5-2, an output pulley 5-3, a transmission belt 5-4, a rotating shaft five 5-5, a receiving pulley 5-6, a rotating disk 5-7, a poking rod 5-8, a fixed shaft five 5-9, a sector gear swinging rod 5-10, and a strip-shaped groove 5-11, where the material enters a feed inlet four 4-2 of the crushing device 4, the motor five 5-2 drives the output pulley 5-3 to rotate, the output pulley 5-3 drives the receiving pulley 5-6 to rotate through the transmission belt 5-4, the receiving belt wheel 5-6 drives the rotating shaft five 5-5 to rotate, the rotating shaft five 5-5 drives the rotating disc 5-7 to rotate, the rotating disc 5-7 drives the poke rod 5-8 to rotate, the poke rod 5-8 enables the sector gear swinging rod 5-10 to swing on the fixed shaft five 5-9 in a reciprocating mode through the strip-shaped groove 5-11 on the sector gear swinging rod 5-10, the sector gear swinging rod 5-10 is meshed with the receiving gear 4-5, the sector gear swinging rod 5-10 drives the receiving gear 4-5 to rotate in a reciprocating mode, the connecting frame 5-1 is fixedly installed on the crushing box 4-1, the motor five 5-2 is fixedly installed on the connecting frame 5-1, the output belt wheel 5-3 is fixedly installed on the motor five 5-2, and the transmission belt 5-4 is installed on the output belt wheel 5-3, the transmission belt 5-4 is installed on the receiving belt wheel 5-6, the rotating shaft five 5-5 is movably installed on the connecting frame 5-1, the receiving belt wheel 5-6 is installed and fixed on the rotating shaft five 5-5, the rotating disc 5-7 is installed and fixed on the rotating shaft five 5-5, the poking rod 5-8 is installed and fixed on the rotating disc 5-7, the poking rod 5-8 is in clearance fit with the strip-shaped groove 5-11, the fixing shaft five 5-9 is installed and fixed on the crushing box 4-1, the sector gear swinging rod 5-10 is movably installed on the fixing shaft five 5-9, the sector gear swinging rod 5-10 is meshed with the receiving gear 4-5, and the strip-shaped groove 5-11 is arranged on the sector gear swinging rod 5-10.

The seventh embodiment:

the present embodiment will be described with reference to fig. 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, and 18, and the fourth embodiment will be further described, the number of the fixed shafts 3-8 and the rotating cylinders 3-9 of the feeding device 3 is nine, the number of the fixed square cylinders 3-11, the number of the springs 3-12, the number of the moving blocks 3-13, the number of the moving columns 3-14, the number of the auxiliary wheel mounting seats 3-15, the number of the auxiliary wheel mounting shafts 3-16 and the number of the auxiliary wheels 3-17 are two, the number of the fixed cylinders 3-18, the number of the springs I3-19, the number of the sliding plates 3-20 and the number of the moving connecting rods 3-21 are ten, the number of the connecting plates I3-22 is two, and the number of the fixed shafts I3-23 and the number of the rotating cylinders I3-24 are fourteen.

The working principle of the invention is as follows:

a medical transfusion package processing device has the working principle that before use, whether the connection condition between the devices meets requirements is checked, a material to be processed is put into a pressure collecting variable box 2-1 of a flattening device 2, then a motor 2-15 drives a bevel gear I2-16 to rotate, the bevel gear I2-16 drives a bevel gear 2-5 to rotate, the bevel gear 2-5 drives a rotating shaft 2-4 to rotate, the rotating shaft 2-4 drives a transmission gear 2-7 to rotate, the rotating shaft 2-4 drives an extrusion column 2-6 to rotate, the rotating shaft 2-4 drives a transmission gear I2-8 to rotate, the transmission gear 2-7 drives a rotating gear II 2-11 to rotate, the rotating gear II 2-11 drives the rotating shaft I2-9 to rotate, the rotating shaft I2-9 drives the extrusion column I2-10 to rotate, the rotating extrusion column 2-6 and the extrusion column I2-10 flatten materials and then bring the materials into the collecting pressure-variable box 2-1, then the transmission gear I2-8 drives the transmission gear III 2-14 to rotate, the transmission gear III 2-14 drives the transmission shaft II 2-12 to rotate, the transmission shaft II 2-12 drives the extrusion column III 2-13 to rotate, the extrusion column III 2-13 and the extrusion column 2-6 discharge the extruded materials from the discharge port 2-3, then at the feed port I3-2 of the feeding device 3, the motor III 3-6 drives the bevel gear III 3-7 to rotate, the bevel gear III 3-7 drives the bevel gear II 3-4 to rotate, the bevel gear II 3-4 drives the rotating shaft III 3-3 to rotate, the rotating shaft III 3-3 drives the power transmission column 3-5 to rotate, the power transmission column 3-5 drives the rotating crawler 3-10 to rotate on the rotating cylinder 3-9, the spring 3-12 in the fixed square cylinder 3-11 pushes the moving block 3-13 to move outwards, the moving block 3-13 drives the moving column 3-14, the moving column 3-14 drives the auxiliary wheel mounting seat 3-15, the auxiliary wheel mounting seat 3-15 drives the auxiliary wheel 3-17 through the auxiliary wheel mounting shaft 3-16 to push the rotating crawler 3-10 to be tight, so as to prevent the rotating crawler 3-10 from slipping during rotation, then the spring I3-19 of the fixed cylinder 3-18 pushes the sliding plate 3-20 to move outwards, the sliding plate 3-20 drives the moving connecting rod 3-21 to move outwards, and the moving connecting rod 3-21 drives the connecting plate I3-22 to move, the connecting plate I3-22 drives the fixed shaft I3-23 to move, the fixed shaft I3-23 drives the rotating cylinder I3-24 to move and then extrude the materials, the friction between the materials and the rotating crawler belt 3-10 is increased to facilitate feeding, then the materials enter a feed inlet IV 4-2 of the crushing device 4, the motor V5-2 drives the output belt wheel 5-3 to rotate, the output belt wheel 5-3 drives the receiving belt wheel 5-6 to rotate through the transmission belt 5-4, the receiving belt wheel 5-6 drives the rotating shaft V5-5 to rotate, the rotating shaft V5-5 drives the rotating disc 5-7 to rotate, the rotating disc 5-7 drives the poking rod 5-8 to rotate, the poking rod 5-8 enables the fan tooth swinging rod 5-10 to swing on the fixed shaft V5-9 in a reciprocating mode through the strip-shaped grooves 5-11 on the fan tooth swinging rod 5-10, the sector-tooth swinging rod 5-10 is meshed with the receiving gear 4-5, the sector-tooth swinging rod 5-10 drives the receiving gear 4-5 to rotate in a reciprocating manner, the receiving gear 4-5 drives the rotating shaft four 4-4 to rotate in a reciprocating manner, the rotating shaft four 4-4 drives the inner cutter connecting rod 4-6 to rotate in a reciprocating manner, the rotating shaft four 4-4 drives the transmission gear four 4-8 to rotate in a reciprocating manner, the inner cutter connecting rod 4-6 drives the inner cutter 4-7 to rotate in a reciprocating manner, the transmission gear four 4-8 drives the inner gear ring 4-9 to rotate in a reciprocating manner through the transmission gear five 4-14, but the rotating directions of the inner gear ring 4-9 and the inner cutter connecting rod 4-6 are opposite, the inner gear ring 4-9 drives the outer cutter connecting rod 4-10 to rotate in a reciprocating manner, and the outer cutter connecting rod 4-10 drives the outer cutter 4-11 to rotate in a reciprocating manner, the moving directions of the outer knife 4-11 and the inner knife 4-7 are opposite, when the outer knife 4-11 and the inner knife 4-7 are about to be overlapped, the material is cut, and the cut material is discharged from the discharge port IV 4-3.

It is to be understood that the above description is not intended to limit the present invention, and the present invention is not limited to the above examples, and that various changes, modifications, additions and substitutions which are within the spirit and scope of the present invention and which may be made by those skilled in the art are also within the scope of the present invention.

Claims (2)

1. The utility model provides a medical infusion package treatment facility, includes erection bracing frame (1), flattens device (2), material feeding unit (3), breaker (4), broken transmission (5), its characterized in that: the flattening device (2) is fixedly installed on the installation support frame (1), the feeding device (3) is fixedly installed on the installation support frame (1), the crushing device (4) is fixedly installed on the installation support frame (1), and the crushing transmission device (5) is fixedly installed on the crushing device (4);

the mounting support frame (1) comprises a fixed floor (1-1), a flattening device mounting rod (1-2), a feeding device mounting rod (1-3) and a crushing device mounting rod (1-4), wherein the flattening device mounting rod (1-2) is fixedly mounted on the fixed floor (1-1), the feeding device mounting rod (1-3) is fixedly mounted on the fixed floor (1-1), and the crushing device mounting rod (1-4) is fixedly mounted on the fixed floor (1-1);

the flattening device (2) comprises a collecting pressure change box (2-1), a feeding port (2-2), a discharging port (2-3), a rotating shaft (2-4), a bevel gear (2-5), an extrusion column (2-6), a transmission gear (2-7), a transmission gear I (2-8), a rotating shaft I (2-9), an extrusion column I (2-10), a rotating gear II (2-11), a transmission shaft II (2-12), an extrusion column III (2-13), a transmission gear III (2-14), a motor (2-15), a bevel gear I (2-16), a mounting double circular groove (2-17) and a mounting double circular groove I (2-18), wherein the collecting pressure change box (2-1) is fixedly mounted on a flattening device mounting rod (1-2), the feeding port (2-2) is arranged on the collecting pressure-variable box (2-1), the discharging port (2-3) is arranged on the collecting pressure-variable box (2-1), the rotating shaft (2-4) is movably arranged in the collecting pressure-variable box (2-1), the bevel gear (2-5) is fixedly arranged on the rotating shaft (2-4), the extrusion column (2-6) is fixedly arranged on the rotating shaft (2-4), the transmission gear (2-7) is fixedly arranged on the rotating shaft (2-4), the transmission gear I (2-8) is fixedly arranged on the rotating shaft (2-4), the rotating shaft I (2-9) is movably arranged in the collecting pressure-variable box (2-1), the extrusion column I (2-10) is fixedly arranged on the rotating shaft I (2-9), the rotating gear II (2-11) is fixedly arranged on the rotating shaft I (2-9), a rotating gear II (2-11) is meshed with a transmission gear (2-7), a transmission shaft II (2-12) is movably arranged inside a collecting pressure variable box (2-1), an extrusion column III (2-13) is fixedly arranged on the transmission shaft II (2-12), a transmission gear III (2-14) is fixedly arranged on the transmission shaft II (2-12), the transmission gear III (2-14) is meshed with a transmission gear I (2-8), a motor (2-15) is fixedly arranged on the collecting pressure variable box (2-1), a bevel gear I (2-16) is fixedly arranged on the motor (2-15), the bevel gear I (2-16) is meshed with the transmission gear (2-7), a double circular groove (2-17) is arranged inside the collecting pressure variable box (2-1), and a double circular groove I (2-18) is arranged inside the collecting pressure variable box (2-1);

the feeding device (3) comprises a feeding installation box (3-1), a feeding hole I (3-2), a rotating shaft III (3-3), a bevel gear II (3-4), a power transmission column (3-5), a motor III (3-6), a bevel gear III (3-7), a fixed shaft (3-8), a rotating cylinder (3-9), a rotating crawler belt (3-10), a fixed square cylinder (3-11), a spring (3-12), a moving block (3-13), a moving column (3-14), an auxiliary wheel installation seat (3-15), an auxiliary wheel installation shaft (3-16), an auxiliary wheel (3-17), a fixed cylinder (3-18), a spring I (3-19), a sliding plate (3-20), a moving connecting rod (3-21), A first connecting plate (3-22), a first fixed shaft (3-23) and a first rotating cylinder (3-24), wherein a first feeding installation box (3-1) is fixedly installed on a first feeding device installation rod (1-3), a first feeding hole (3-2) is arranged on the first feeding installation box (3-1), a third rotating shaft (3-3) is movably installed on the first feeding installation box (3-1), a second bevel gear (3-4) is fixedly installed on the third rotating shaft (3-3), a power transmission column (3-5) is fixedly installed on the third rotating shaft (3-3), a third motor (3-6) is fixedly installed on the first feeding installation box (3-1), a third bevel gear (3-7) is fixedly installed on the third motor (3-6), and a fixed shaft (3-8) is fixedly installed on the first feeding installation box (3-1), the rotary cylinder (3-9) is movably arranged on the fixed shaft (3-8), the rotary crawler (3-10) is arranged on the power transmission column (3-5), the rotary crawler (3-10) is arranged on the rotary cylinder (3-9), the rotary crawler (3-10) is arranged on the auxiliary wheel installation shaft (3-16), the fixed square cylinder (3-11) is fixedly arranged in the feeding installation box (3-1), the spring (3-12) is movably arranged in the fixed square cylinder (3-11), the moving block (3-13) is movably arranged in the fixed square cylinder (3-11), the moving column (3-14) is fixedly arranged on the moving block (3-13), the auxiliary wheel installation seat (3-15) is fixedly arranged on the moving column (3-14), the auxiliary wheel installation shaft (3-16) is movably arranged on the feeding installation box (3-1), the auxiliary wheel (3-17) is fixedly arranged on an auxiliary wheel mounting shaft (3-16), the fixed cylinder (3-18) is fixedly arranged on the feeding mounting box (3-1), the first spring (3-19) is movably arranged on the fixed cylinder (3-18), the sliding plate (3-20) is movably arranged on the fixed cylinder (3-18), the movable connecting rod (3-21) is fixedly arranged on the sliding plate (3-20), the first connecting plate (3-22) is fixedly arranged on the movable connecting rod (3-21), the first fixed shaft (3-23) is fixedly arranged on the first connecting plate (3-22), and the first rotating cylinder (3-24) is movably arranged on the first fixed shaft (3-23);

the crushing device (4) comprises a crushing box (4-1), a feeding port IV (4-2), a discharging port IV (4-3), a rotating shaft IV (4-4), a receiving gear (4-5), an inner cutter connecting rod (4-6), an inner cutter (4-7), a transmission gear IV (4-8), an inner toothed ring (4-9), an outer cutter connecting rod (4-10), an outer cutter (4-11), an outer cutter connecting rod swinging groove (4-12), a transmission gear mounting shaft (4-13) and a transmission gear V (4-14), wherein the crushing box (4-1) is fixedly arranged on a crushing device mounting rod (1-4), the feeding port IV (4-2) is arranged on the crushing box (4-1), and the discharging port IV (4-3) is arranged on the crushing box (4-1), a rotating shaft IV (4-4) is movably arranged on the crushing box (4-1), a receiving gear (4-5) is fixedly arranged on the rotating shaft IV (4-4), an inner cutter connecting rod (4-6) is fixedly arranged on the rotating shaft IV (4-4), an inner cutter (4-7) is fixedly arranged on the inner cutter connecting rod (4-6), a transmission gear IV (4-8) is fixedly arranged on the rotating shaft IV (4-4), an inner gear ring (4-9) is fixedly arranged on an outer cutter connecting rod (4-10), the outer cutter connecting rod (4-10) is slidably arranged in an outer cutter connecting rod swinging groove (4-12), an outer cutter (4-11) is fixedly arranged on the outer cutter connecting rod (4-10), the outer cutter connecting rod swinging groove (4-12) is arranged in the crushing box (4-1), a transmission gear mounting shaft (4-13) is fixedly arranged in the outer cutter connecting rod swinging groove (4-12), a transmission gear five (4-14) is movably arranged on the transmission gear mounting shaft (4-13), the transmission gear five (4-14) is meshed with an inner gear ring (4-9), and the transmission gear five (4-14) is meshed with a transmission gear four (4-8);

the crushing transmission device (5) comprises a connecting frame (5-1), a motor five (5-2), an output belt wheel (5-3), a transmission belt (5-4), a rotating shaft five (5-5), a receiving belt wheel (5-6), a rotating disc (5-7), a poking rod (5-8), a fixing shaft five (5-9), a sector gear oscillating rod (5-10) and a strip-shaped groove (5-11), wherein the connecting frame (5-1) is fixedly arranged on a crushing box (4-1), the motor five (5-2) is fixedly arranged on the connecting frame (5-1), the output belt wheel (5-3) is fixedly arranged on the motor five (5-2), the transmission belt (5-4) is arranged on the output belt wheel (5-3), the transmission belt (5-4) is arranged on the receiving belt wheel (5-6), a rotating shaft five (5-5) is movably arranged on the connecting frame (5-1), a receiving belt wheel (5-6) is fixedly arranged on the rotating shaft five (5-5), a rotating disc (5-7) is fixedly arranged on the rotating shaft five (5-5), a poke rod (5-8) is fixedly arranged on the rotating disc (5-7), the poke rod (5-8) is in clearance fit with the strip-shaped groove (5-11), a fixed shaft five (5-9) is fixedly arranged on the crushing box (4-1), a sector gear swinging rod (5-10) is movably arranged on the fixed shaft five (5-9), a sector gear swinging rod (5-10) is meshed with the receiving gear (4-5), and the strip-shaped groove (5-11) is arranged on the sector gear swinging rod (5-10).

2. The medical infusion package handling device of claim 1, wherein: the number of the fixed shafts (3-8) and the rotating cylinders (3-9) of the feeding device (3) is nine, the number of the fixed square cylinders (3-11), the number of the springs (3-12), the number of the moving blocks (3-13), the number of the moving columns (3-14), the number of the auxiliary wheel mounting seats (3-15), the number of the auxiliary wheel mounting shafts (3-16) and the number of the auxiliary wheels (3-17) are two, the number of the fixed cylinders (3-18), the number of the springs (3-19), the number of the sliding plates (3-20) and the number of the moving connecting rods (3-21) are ten, the number of the connecting plates (3-22) is two, and the number of the fixed shafts (3-23) and the rotating cylinders (3-24) is fourteen.

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