CN210761415U - Vacuum packaging machine for large-capacity infusion bag - Google Patents

Abstract

The utility model discloses a large capacity infusion bag vacuum packaging machine, including the frame and install in the last membrane unwinding device of frame, lower membrane unwinding device, forming device, heat seal closing device, cutting device and conveyer, lower membrane unwinding device, forming device, heat seal closing device and cutting device set gradually, go up membrane unwinding device and set up in heat seal closing device's top. The utility model discloses an outer bag of repackaging after the inner bag is irritated to evacuation simultaneously, then disinfect, dry, vanning in proper order. The infusion bag produced by the production process has the advantages that the infusion bag can be directly used without being sterilized when being used in clean environments such as an operating room and the like, and the work of medical staff is reduced; when in use, the outer package is directly torn off, thereby avoiding pollution and being convenient to use. The utility model discloses a large capacity infusion bag vacuum packaging machine is the key that realizes this new technology, utilizes the utility model discloses a vacuum packaging machine can be fast, the outer bag packing work of efficient completion, and the practicality is strong.

Description

Vacuum packaging machine for large-capacity infusion bag

Technical Field

The utility model relates to a medical treatment pharmaceutical equipment field, in particular to a large capacity infusion bag vacuum packaging machine for making infusion bag extranal packing.

Background

At present, the production process of a large-capacity infusion bag is roughly preparing water for pharmacy, preparing concentrated solution, preparing diluted solution, making the infusion bag, filling, sealing, sterilizing, drying, inspecting by a lamp and packaging in a paper box. The conventional infusion bag generally only has one bag body, and is sterilized after encapsulation, wherein the sterilization is only performed on liquid medicine in the infusion bag, and manual boxing and other operations are required after the sterilization is finished, so that bacteria and the like cannot be prevented from adhering to the surface of the infusion bag. Therefore, when the existing infusion bag is transported to a clean environment such as an operating room of a hospital for use, medical staff can disinfect and sterilize the infusion bag again before use to remove bacteria on the surface of the infusion bag, so that the existing infusion bag is very inconvenient to use, and the labor intensity of the medical staff is increased.

SUMMERY OF THE UTILITY MODEL

The utility model aims at providing a large capacity infusion bag vacuum packaging machine can solve one of above-mentioned problem at least.

In order to achieve the above object, according to one aspect of the present invention, there is provided a vacuum packaging machine for large-capacity infusion bags, comprising a frame, and an upper film unwinding device, a lower film unwinding device, a forming device, a heat sealing device, a cutting device and a conveying device mounted on the frame, wherein the lower film unwinding device, the forming device, the heat sealing device and the cutting device are sequentially arranged, and the upper film unwinding device is arranged above the heat sealing device;

the upper film unreeling device is configured to unreel an upper film;

the lower film unreeling device is configured to unreel a lower film;

the conveying device is configured to convey the upper film and the lower film;

the forming device is configured to process the lower film conveyed by the conveying device, and a plurality of concave placing cavities for placing the infusion bags are manufactured by using the lower film;

the heat sealing device is configured to heat seal the upper film conveyed from the upper film unreeling device and the lower film conveyed from the forming device and extract air in the placing cavity;

the cutting device is configured to cut the upper film and the lower film fed from the heat sealing apparatus.

Therefore, the utility model discloses a large capacity infusion bag vacuum packaging machine's working process does: firstly, a lower film is processed through a forming device to manufacture a plurality of placing cavities, then an infusion bag (namely an inner bag) which is filled and sealed is placed in the placing cavities manually or automatically through a mechanical arm, then an upper film is covered above the lower film and the inner bag through a heat sealing device, the periphery of the inner bag is sealed, the upper film and the lower film are bonded to form an outer bag which surrounds the inner bag, and finally a plurality of products are cut into single products through a cutting device to be output.

The utility model discloses a production technology of large capacity infusion bag is outer bag of repackaging after the inner bag is irritated to evacuation simultaneously, then in proper order sterilize, dry, the vanning can. The infusion bag produced by the production process has the advantages that the infusion bag can be directly used without being sterilized when being used in clean environments such as an operating room and the like, and the work of medical staff is reduced; when in use, the outer package is directly torn off, thereby avoiding pollution and being convenient to use.

The utility model discloses a large capacity infusion bag vacuum packaging machine is the key that realizes this new technology, utilizes the utility model discloses a vacuum packaging machine can be fast, the outer bag packing work of efficient completion, and the practicality is strong.

In some embodiments, the molding device comprises an upper mold, a lower mold and a vacuum pump, the upper mold is fixedly installed on the frame, the lower mold is movably installed on the frame, the vacuum pump is installed on the frame, a groove matched with the placing cavity is formed in the lower mold, the vacuum pump is connected with the groove through a pipeline, a heater is arranged on the upper mold, and the upper mold is matched with the lower mold. From this, forming device's theory of operation does, and the back is put in place to the lower mould, and the lower mould is upward movement under the drive of driving pieces such as cylinder for the lower membrane is compressed tightly between last mould and lower mould, and last mould heating and lower mould begin the evacuation simultaneously, and lower membrane adsorbs in the recess of lower mould, forms and places the chamber.

In some embodiments, the cutting device comprises a transverse cutting device and a longitudinal cutting device, the longitudinal cutting device is arranged behind the transverse cutting device, the transverse cutting device is used for transverse cutting, and the longitudinal cutting device is used for longitudinal cutting. Therefore, the utility model discloses a cutting device divide into crosscut and rip cutting two sets ofly, and the cutting is efficient, and the product specification that forms after the cutting is unified.

In some embodiments, the transverse cutting device comprises a transverse cutting mechanism and a bearing mechanism, wherein the transverse cutting mechanism and the bearing mechanism are arranged on the machine frame, and the bearing mechanism is arranged below the transverse cutting mechanism;

the transverse cutting mechanism comprises a first driving piece, a transverse cutter and an installation frame, the installation frame is fixedly installed on the rack and located above the upper film, the first driving piece is installed on the installation frame, the transverse cutter is installed at the lower end of the first driving piece, and the first driving piece is used for driving the transverse cutter to move up and down;

bear the mechanism and include sword groove fixed plate, sword groove fixed plate movable mounting in the frame and lie in the below of lower membrane, first sword groove has been seted up to the up end of sword groove fixed plate, and first sword groove cooperatees with the cross-cutter.

The operating principle of the crosscutting device is thus: when the materials are conveyed in place, the cutter groove fixing plate moves upwards to a designated position, and the transverse cutter moves downwards under the driving of the first driving piece and is matched with the first cutter groove below to cut the materials.

In some embodiments, the bearing mechanism further includes a vertical shaft, a mounting plate, a connecting plate, and a second driving member, the knife slot fixing plate is fixedly mounted above the mounting plate through the connecting plate, the vertical shaft is mounted in the frame, two ends of the mounting plate are sleeved on the periphery of the vertical shaft through sliding blocks, a connecting block is disposed in the middle of the lower surface of the mounting plate, one end of the second driving member is connected with the connecting block, and the mounting plate drives the knife slot fixing plate to move up and down under the driving of the second driving member. Therefore, the working principle of the bearing mechanism is as follows: when the materials are conveyed in place, the second driving piece drives the mounting plate to slide upwards along the vertical shafts at the two ends, so that the knife groove fixing plate is driven to move upwards to the position below the lower membrane, and the first knife groove of the knife groove fixing plate is aligned to the transverse cutter above the knife groove fixing plate to wait for cutting.

In some embodiments, the longitudinal cutting device comprises a third driving part, a longitudinal cutter shaft, a supporting plate and a movable cutter frame, wherein the supporting plate is installed on the frame and positioned at two ends of the longitudinal cutter shaft;

the third driving piece is arranged on the outer side of one of the supporting plates and connected with one end of the longitudinal cutter shaft for driving the longitudinal cutter shaft to rotate.

Thus, the cutting principle of the slitting device is as follows: the material after the crosscut device cutting is carried to the rip cutting device, and the material back that targets in place, the movable cutter frame upward movement arrives the assigned position under the drive of driving pieces such as cylinders for the second sword groove is located the below of disc blade, and the third driving piece drive is indulged the arbor and is rotated, drives the disc blade rotation, and rotatory disc blade cuts off the material with the cooperation of second sword groove.

In some embodiments, the conveying device includes a transmission chain, a transmission shaft and a fourth driving member, the transmission shaft is mounted at two ends of the rack through bearings, the transmission chain is sleeved on the periphery of the transmission shaft, and the fourth driving member is in transmission connection with the transmission shaft and is used for driving the transmission shaft to rotate. From this, the both ends of material can be installed in drive chain through anchor clamps, and the fourth drive piece drives drive chain rotatory, and then drives the material motion, accomplishes the transportation of material.

In some embodiments, the vacuum packaging machine for large-capacity infusion bags further comprises a coding device, the coding device is installed on the frame and located between the lower film unwinding device and the forming device, and the coding device is used for printing production information on the lower film. From this, beat the sign indicating number device and can be with production date, model, specification etc. production novel printing in lower membrane, the subsequent packing of being convenient for.

In some embodiments, the vacuum packaging machine for large-capacity infusion bags further comprises a waste edge collecting device, the waste edge collecting device is mounted on the frame and located behind the cutting device, and the waste edge collecting device is used for collecting waste edges generated after cutting by the cutting device;

the slitter edge collecting device comprises a winding roller and a speed reducing motor, and the speed reducing motor is connected with the winding roller and used for driving the winding roller to rotate.

Therefore, continuous waste edges can be left on two sides of the material after the transverse cutting device and the longitudinal cutting device are cut, and the waste edges can be collected through the waste edge collecting device, so that the environment is prevented from being dirty and resources are prevented from being wasted; the utility model discloses a slitter edge collection device's theory of operation does: after the slitter edge is in place, one end of the slitter edge is manually fixed on the winding roller, then the speed reduction motor is started to drive the winding roller to rotate, and the slitter edge is wound on the winding roller.

In some embodiments, the vacuum packaging machine for large-capacity infusion bags further comprises a control device and a touch display screen, wherein the upper film unwinding device, the lower film unwinding device, the forming device, the heat sealing device, the cutting device and the conveying device are electrically connected with the control device, and the touch display screen is arranged on the rack and electrically connected with the control device.

Therefore, the utility model discloses a controlling means can be closed-loop control system, including servo motor, PLC controller, sensor etc. control system adopts the advanced pneumatic drive technique of the closed-loop control technique cooperation that the world leads, and reliable mechanical transmission of stable performance in addition, but accurate control equipment chain walks membrane, seals-in, alleviates the equipment maintenance expense by a wide margin. The display adopts a true color touch display screen, so that the monitoring is convenient, and the program input and the instant operation are convenient.

The utility model has the advantages that:

the utility model discloses a large capacity infusion bag vacuum packaging machine's working process does: firstly, a lower film is processed through a forming device to manufacture a plurality of placing cavities, then an infusion bag (namely an inner bag) which is filled and sealed is placed in the placing cavities manually or automatically through a mechanical arm, then an upper film is covered above the lower film and the inner bag through a heat sealing device, the periphery of the inner bag is sealed, the upper film and the lower film are bonded to form an outer bag which surrounds the inner bag, and finally a plurality of products are cut into single products through a cutting device to be output.

The utility model discloses a large capacity infusion bag vacuum packaging machine is the key that realizes this new technology, utilizes the utility model discloses a vacuum packaging machine can be fast, the outer bag packing work of efficient completion, and the practicality is strong.

Drawings

Fig. 1 is a schematic structural view of a large-capacity infusion bag vacuum packaging machine according to an embodiment of the present invention;

fig. 2 is a schematic diagram of the movement tracks of an upper film and a lower film when the vacuum packaging machine for large-capacity infusion bags shown in fig. 1 works;

fig. 3 is an enlarged schematic view of the large-capacity infusion bag vacuum packaging machine A shown in fig. 2;

fig. 4 is a schematic structural view of an upper mold of the forming device of the vacuum packaging machine for large-volume infusion bags shown in fig. 1;

fig. 5 is a structural schematic diagram of a lower die of the forming device of the vacuum packaging machine for large-capacity infusion bags shown in fig. 1;

fig. 6 is a schematic structural view of a transverse cutting device of the large-capacity infusion bag vacuum packaging machine shown in fig. 1;

FIG. 7 is a schematic view of a carriage mechanism of the cross-cutting apparatus of FIG. 6;

fig. 8 is a schematic structural view of a slitting device of the vacuum packaging machine for large-volume infusion bags shown in fig. 1;

fig. 9 is a schematic structural view of a finished product produced by the vacuum packaging machine for large-capacity infusion bags of the present invention.

Reference numerals in FIGS. 1 to 9: 1-a frame; 2, a film feeding and unwinding device; 3, a film feeding and unwinding device; 4-a forming device; 5-heat sealing the sealing device; 6-a cutting device; 7-a conveying device; 8-a coding device; 9-a slitter edge collecting device; 10-touch display screen; 20-coating a film; 30-lower membrane; 40-slitter edge; 41-upper mould; 42-lower mold; 43-vacuum pump; 50-an inner bag; 60-outer bag; 61-a transverse cutting device; 62-a slitting device; 71-a drive chain; 72-a drive shaft; 73-a fourth drive; 91-a wind-up roll; 411-a heater; 421-groove; 611-a transverse cutting mechanism; 612-a carrier mechanism; 621-a third driver; 622-longitudinal cutter shaft; 623-a support plate; 624-movable tool post; 625 — a disk blade; 6111-first driving member; 6112-transverse cutter; 6113-mounting rack; 6121-knife groove fixing plate; 6122-vertical shaft; 6123-mounting plate; 6124-connecting plate; 6125-connecting block; 6126-slide block; 6241-a second sipe; 6121 a-first sipe.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings.

Fig. 1 to 9 schematically show a large-capacity infusion bag vacuum packaging machine according to an embodiment of the present invention.

As shown in fig. 1 to 9, the vacuum packaging machine for large-capacity infusion bags comprises a frame 1, and an upper film unwinding device 2, a lower film unwinding device 3, a forming device 4, a heat sealing device 5, a cutting device 6 and a conveying device 7 which are arranged on the frame 1. The lower film unreeling device 3, the forming device 4, the heat seal sealing device 5 and the cutting device 6 are sequentially arranged. The upper film unreeling device 2 is arranged above the heat seal sealing device 5.

The upper film unreeling device 2 is configured to unreel the upper film 20;

the lower film unreeling device 3 is configured to unreel the lower film 30;

the conveying device 7 is configured to convey the upper film 20 and the lower film 30;

the forming device 4 is configured to process the lower film 30 conveyed by the conveying device 7, and a plurality of concave placing cavities for placing infusion bags (inner bags 50) are formed by the lower film 30;

the heat sealing device 5 is configured to heat seal the upper film 20 conveyed from the upper film unreeling device 2 and the lower film 30 conveyed from the forming device 4 and extract air in the placing cavity;

the cutting device 6 is configured to cut the upper film 20 and the lower film 30 fed from the heat-seal sealing device 5.

The vacuum packaging machine for large-volume infusion bags of the present embodiment further includes a control device and a touch display screen 10. The upper film unwinding device 2, the lower film unwinding device 3, the forming device 4, the heat sealing device 5, the cutting device 6 and the conveying device 7 are electrically connected with the control device, and the touch display screen 10 is arranged on the rack 1 and is electrically connected with the control device. The control device of the embodiment can be a closed-loop control system, comprises a motor, a PLC (programmable logic controller), a sensor and other commercially available products, adopts a world-leading closed-loop control technology to be matched with an advanced pneumatic driving technology, and can accurately control the film running and sealing of an equipment chain by virtue of stable and reliable mechanical transmission, so that the maintenance cost of the equipment is greatly reduced. The display adopts a true color touch display screen 10, which is not only convenient for monitoring, but also convenient for inputting programs and instant operation.

As shown in fig. 1 and 4 to 5, the molding apparatus 4 of the present embodiment includes an upper mold 41, a lower mold 42, and a vacuum pump 43. The upper mold 41 is fixed to the frame 1 by a fastener such as a screw and positioned above the lower film 30. The lower mold 42 is movably mounted to the frame 1 below the lower film 30. The vacuum pump 43 is fixedly mounted to the frame 1. The lower mold 42 is provided with a groove 421 matching with the placing cavity. The vacuum pump 43 is connected to the groove 421 through a pipe. The structure of the forming device 4 of the utility model is almost the same as that of the existing transfusion bag making device. The upper mold 41 is provided with a heater 411, and the heater 411 may be a combination of a heating rod and a thermocouple. The upper die 41 is fitted with the lower die 42. Therefore, the working principle of the forming device 4 is that after the lower film is in place, the lower mold 42 is driven by a driving element such as an air cylinder to move upwards, so that the lower film is pressed between the upper mold 41 and the lower mold 42, the upper mold 41 is heated, and simultaneously the lower mold 42 starts to be vacuumized, and the lower film is adsorbed in the groove 421 of the lower mold 42 to form a placing cavity.

The heat sealing device 5 of the present embodiment has substantially the same structure as the molding device 4, except that the heater 411 is located at a different position, and the sealing device heats the packaging film around the infusion bag. The heat sealing apparatus 5 of the present embodiment may share one vacuum pump 43 with the molding apparatus 4. The heat sealing device 5 is connected with a vacuum pump 43 for pumping the air in the outer bag 60 formed by heat sealing the upper and lower films into a vacuum state.

As shown in fig. 1, the cutting device 6 of the present embodiment includes a transverse cutting device 61 and a longitudinal cutting device 62. The slitting device 62 is arranged behind the crosscutting device 61, the crosscutting device 61 is used for transverse cutting, and the slitting device 62 is used for longitudinal cutting. Therefore, the utility model discloses a cutting device 6 divide into crosscut and rip cutting two sets ofly, and the cutting is efficient, and the product specification that forms after the cutting is unified.

As shown in fig. 6 and 7, the crosscutting apparatus 61 includes a crosscutting mechanism 611 and a carrying mechanism 612. The cross cutting mechanism 611 and the bearing mechanism 612 are disposed on the frame 1, and the bearing mechanism 612 is disposed below the cross cutting mechanism 611.

The cross cutting mechanism 611 includes a first driving member 6111, a cross cutting blade 6112 and an installation frame 6113. The mounting bracket 6113 is fixedly mounted on the frame 1 and located above the upper film 20. The first driving member 6111 is installed on the mounting frame 6113, and the first driving member 6111 is an air cylinder. The transverse cutter 6112 is installed at the lower end of the first driving member 6111, and the first driving member 6111 is used for driving the transverse cutter 6112 to move up and down.

The bearing mechanism 612 includes a knife slot fixing plate 6121, a vertical shaft 6122, a mounting plate 6123, a connecting plate 6124 and a second driving member (not shown in the figure). The knife slot fixing plate 6121 is movably mounted on the frame 1 and located below the lower membrane 30. The upper end surface of the knife groove fixing plate 6121 is provided with a first knife groove 6121a, and the first knife groove 6121a is matched with the transverse knife 6112. The knife slot fixing plate 6121 is fixedly mounted above the mounting plate 6123 through a connecting plate 6124. The vertical shaft 6122 is fixedly arranged on the frame 1 and positioned at two sides of the lower film. The two ends of the mounting plate 6123 are sleeved on the periphery of the vertical shaft 6122 through a sliding block 6126. A connecting block 6125 is arranged in the middle of the lower surface of the mounting plate 6123, and one end of the second driving member is connected with the connecting block 6125. The second driver of the present embodiment may be a cylinder. Under the driving of the second driving member, the mounting plate 6123 drives the knife slot fixing plate 6121 to move up and down. The operating principle of the crosscutting device 61 is: the second driving member drives the mounting plate 6123 to slide upwards along the vertical shaft 6122 at both ends, so as to drive the knife slot fixing plate 6121 to move upwards together below the lower film 30, the first knife slot 6121a of the knife slot fixing plate 6121 aligns with the transverse cutter 6112 above, and the transverse cutter 6112 moves downwards under the driving of the first driving member 6111 and is matched with the first knife slot 6121a below to cut the material.

As shown in fig. 8, the slitting device 62 of the present embodiment includes a third driving member 621, a slitting shaft 622, a support plate 623, and a movable blade holder 624. The supporting plate 623 is fixedly mounted on the frame 1 and located at two ends of the longitudinal knife shaft 622, and two ends of the longitudinal knife shaft 622 are mounted on the supporting plate 623 through bearings. At least two disc blades 625 are fixedly sleeved on the outer periphery of the vertical knife shaft 622, and the number of the disc blades 625 in the present embodiment is 5. Therefore, 4 products can be obtained by cutting once by the slitting device 62, and the cutting efficiency is high. Movable tool rest 624 is movably disposed on frame 1, and movable tool rest 624 may be similar in structure to carriage mechanism 612. The upper end surface of the movable tool rest 624 is provided with a second tool groove 6241, and the second tool groove 6241 is matched with the disc blade 625.

The third driving member 621 is fixedly disposed at an outer side of one of the supporting plates 623, and the third driving member 621 of this embodiment may be a motor. The output end of the third driving element 621 is coupled to one end of the longitudinal knife shaft 622 through a coupling or the like, and is used for driving the longitudinal knife shaft 622 to rotate.

Thus, the slitting device 62 cuts on the principle of: the material cut by the crosscutting device 61 is conveyed to the longitudinal cutting device 62, and after the material is in place, the movable knife rest 624 can move upwards to reach a designated position under the driving of a cylinder and other driving elements, so that the second knife groove 6241 is positioned below the disc blade 625, the third driving element 621 drives the longitudinal knife shaft 622 to rotate, the disc blade 625 is driven to rotate, and the rotating disc blade 625 and the second knife groove 6241 are matched to cut the material.

As shown in fig. 1 and 6, the conveying device 7 includes a drive chain 71, a drive shaft 72, and a fourth drive member 73. The transmission shafts 72 are mounted at two ends of the frame 1 through bearings, and the transmission chains 71 are sleeved on the peripheries of the transmission shafts 72. The fourth driving member 73 of the present embodiment may be a motor, and an output end of the fourth driving member 73 is in transmission connection with the transmission shaft 72 through a belt or the like, and is used for driving the transmission shaft 72 to rotate. From this, the both ends of material can be installed in drive chain 71 through anchor clamps, and fourth drive piece 73 drives drive chain 71 and rotates, and then drives the material motion, accomplishes the transportation of material.

The vacuum packaging machine for the large-capacity infusion bag further comprises a coding device 8, and the coding device 8 can be a commercially available coding machine. The coding device 8 is installed on the frame 1 and located between the lower film unreeling device 3 and the forming device 4, and is used for printing production information on the lower film 30. The coding device 8 is electrically connected with the control device. From this, beat sign indicating number device 8 can be with production date, model, specification etc. production novel printing in lower membrane 30, the subsequent packing of being convenient for.

The large-capacity infusion bag vacuum packaging machine further comprises a waste edge collecting device 9, and the waste edge collecting device 9 is installed on the machine frame 1 and is located behind the cutting device 6. The waste edge collecting device 9 is used for collecting the waste edge 40 generated after the cutting device 6 cuts.

The slitter edge collecting device 9 comprises a winding roller 91 and a speed reducing motor (shown in the figure), and the speed reducing motor is connected with the winding roller 91 and is used for driving the winding roller 91 to rotate. The speed reducing motor is electrically connected with the control device.

Therefore, after the transverse cutting device 61 and the longitudinal cutting device 62 are cut, continuous waste edges are left on two sides of the material and can be collected through the waste edge collecting device 9, so that the environment is prevented from being dirty and resources are prevented from being wasted; the utility model discloses a slitter edge collection device 9's theory of operation does: after the slitter edge 40 is in place, one end of the slitter edge 40 is manually fixed on the winding roller 91, then the speed reduction motor is started to drive the winding roller 91 to rotate, and the slitter edge 40 is wound on the winding roller 91.

As shown in fig. 2 and 3, the vacuum packaging machine for large-capacity infusion bags of the present invention has the following specific working processes:

s1, unwinding the lower film: the lower film coiled material is arranged on a lower film unreeling shaft, the clamp on the transmission chain 71 clamps the edge of the lower film 30, and the lower film 30 is driven to move forwards through the operation of the transmission chain 71.

S2, coding: the code printing device 8 prints codes on the lower film 30, and prints information such as production date, batch number, specification and the like on the lower film 30.

S3, lower film forming: when the lower film 30 is moved to the molding device 4, the lower film 30 is preheated by the heater 411 of the upper mold 41, and then vacuum suction molding is performed by the lower mold 42, so that a placing cavity is formed.

S4, feeding an infusion bag: the infusion bag after encapsulation is placed in each placing cavity manually or automatically by a mechanical arm.

S5, film feeding and unwinding: the upper film coiled material is arranged on an upper film unreeling shaft, and is converged and heat-sealed together with the lower film 30 at the heat sealing device 5 through a guide roller to wrap the inner bag 50, and a tension adjusting device can be arranged at the unreeling position in order to ensure the stability of the tension of the upper film 20 in the operation process.

S6, heat sealing and sealing: after the upper and lower films are converged, the upper and lower films around the infusion bag are sealed by the heat sealing device 5 to form an outer bag, air in the outer bag is pumped into a vacuum state by the vacuum pump 43, and then the films are heated by the heat sealing plate of the heat sealing device 5, so that the upper and lower films are heat-sealed together under the action of pressure, and the air leakage of the product after leaving the heat sealing plate is ensured.

S7, cutting: the whole film of the products with the inner bags needs to be cut in two different directions by two cutting devices 6, namely a transverse cutting device 61 and a longitudinal cutting device 62, and a plurality of products after the outer package is finished are cut into single products.

The cut individual products are conveyed to a sterilization tank for sterilization by manual operation or automatically by a conveyor belt.

The utility model discloses a large capacity infusion bag vacuum packaging machine is multiple functional, and degree of automation is high, especially when medical products such as packing infusion bag, not only clean health, difficult pollution that causes pack efficiently moreover, neat tight, finished product specification is unified.

The utility model discloses a production technology of large capacity infusion bag is outer bag 60 of repackaging after the inner bag 50 is irritated to evacuation simultaneously, then in proper order sterilize, dry, the vanning can. The infusion bag produced by the production process has the advantages that the infusion bag can be directly used without being sterilized when being used in clean environments such as an operating room and the like, and the work of medical staff is reduced; when in use, the outer package is directly torn off, thereby avoiding pollution and being convenient to use.

The utility model discloses a large capacity infusion bag vacuum packaging machine is the key that realizes this new technology, utilizes the utility model discloses a vacuum packaging machine can be fast, the outer bag 60 packing work of efficient completion, and the practicality is strong.

What has been described above are only some embodiments of the invention. For those skilled in the art, without departing from the inventive concept, several modifications and improvements can be made, which are within the scope of the invention.

Claims (10)

1. The large-capacity infusion bag vacuum packaging machine is characterized by comprising a rack (1), an upper film unwinding device (2), a lower film unwinding device (3), a forming device (4), a heat sealing device (5), a cutting device (6) and a conveying device (7), wherein the upper film unwinding device (2), the lower film unwinding device (3), the forming device (4), the heat sealing device (5) and the cutting device (6) are arranged in sequence, and the upper film unwinding device (2) is arranged above the heat sealing device (5);

the upper film unreeling device (2) is configured to unreel an upper film (20);

the lower film unreeling device (3) is configured to unreel a lower film (30);

the conveying device (7) is configured to convey an upper film (20) and a lower film (30);

the forming device (4) is configured to process the lower film (30) conveyed by the conveying device (7), and a plurality of concave placing cavities for placing the infusion bags are manufactured by using the lower film (30);

the heat sealing device (5) is configured to heat seal the upper film (20) conveyed from the upper film unreeling device (2) and the lower film (30) conveyed from the forming device (4) and extract air in the placing cavity;

the cutting device (6) is configured to cut the upper film (20) and the lower film (30) fed from the heat sealing and sealing device (5).

2. The vacuum packaging machine for large-capacity infusion bags according to claim 1, wherein the forming device (4) comprises an upper die (41), a lower die (42) and a vacuum pump (43), the upper die (41) is fixedly mounted on the frame (1), the lower die (42) is movably mounted on the frame (1), the vacuum pump (43) is mounted on the frame (1), a groove (421) matched with the placing cavity is formed in the lower die (42), the vacuum pump (43) is connected with the groove (421) through a pipeline, a heater (411) is arranged on the upper die (41), and the upper die (41) is matched with the lower die (42).

3. The vacuum packaging machine for large-volume infusion bags according to claim 1, wherein the cutting device (6) comprises a transverse cutting device (61) and a longitudinal cutting device (62), the longitudinal cutting device (62) is arranged behind the transverse cutting device (61), the transverse cutting device (61) is used for transverse cutting, and the longitudinal cutting device (62) is used for longitudinal cutting.

4. The vacuum packaging machine for large-volume infusion bags according to claim 3, characterized in that the transverse cutting device (61) comprises a transverse cutting mechanism (611) and a bearing mechanism (612), the transverse cutting mechanism (611) and the bearing mechanism (612) are arranged on the frame (1), and the bearing mechanism (612) is arranged below the transverse cutting mechanism (611);

the transverse cutting mechanism (611) comprises a first driving piece (6111), a transverse cutter (6112) and an installation frame (6113), the installation frame (6113) is fixedly installed on the rack (1) and located above the upper film (20), the first driving piece (6111) is installed on the installation frame (6113), the transverse cutter (6112) is installed at the lower end of the first driving piece (6111), and the first driving piece (6111) is used for driving the transverse cutter (6112) to move up and down;

the bearing mechanism (612) comprises a knife groove fixing plate (6121), the knife groove fixing plate (6121) is movably mounted on the rack (1) and located below the lower film (30), a first knife groove (6121a) is formed in the upper end face of the knife groove fixing plate (6121), and the first knife groove (6121a) is matched with the transverse cutter (6112).

5. The vacuum packaging machine for large-capacity infusion bags according to claim 4, wherein the bearing mechanism (612) further comprises a vertical shaft (6122), an installation plate (6123), a connection plate (6124) and a second driving member, the knife slot fixing plate (6121) is fixedly installed above the installation plate (6123) through the connection plate (6124), the vertical shaft (6122) is installed on the machine frame (1), two ends of the installation plate (6123) are sleeved on the periphery of the vertical shaft (6122) through sliders (6126), a connection block (6125) is arranged in the middle of the lower surface of the installation plate (6123), one end of the second driving member is connected with the connection block (6125), and the installation plate (6123) drives the knife slot fixing plate (6121) to move up and down under the driving of the second driving member.

6. The vacuum packaging machine for large-capacity infusion bags according to claim 3, wherein the slitting device (62) comprises a third driving part (621), a longitudinal knife shaft (622), a supporting plate (623) and a movable knife rest (624), the supporting plate (623) is mounted on the frame (1) and located at two ends of the longitudinal knife shaft (622), two ends of the longitudinal knife shaft (622) are mounted on the supporting plate (623) through bearings, at least two disc blades (625) are fixedly sleeved on the periphery of the longitudinal knife shaft (622), the movable knife rest (624) is movably arranged on the frame (1), a second knife groove (6241) is formed in the movable knife rest (624), and the second knife groove (6241) is matched with the disc blades (625);

the third driving part (621) is arranged on the outer side of one of the supporting plates (623), and the third driving part (621) is connected with one end of the longitudinal cutter shaft (622) and is used for driving the longitudinal cutter shaft (622) to rotate.

7. The vacuum packaging machine for large-volume infusion bags according to claim 1, wherein the conveying device (7) comprises a transmission chain (71), a transmission shaft (72) and a fourth driving part (73), the transmission shaft (72) is mounted at two ends of the frame (1) through bearings, the transmission chain (71) is sleeved on the periphery of the transmission shaft (72), and the fourth driving part (73) is in transmission connection with the transmission shaft (72) and is used for driving the transmission shaft (72) to rotate.

8. The vacuum packaging machine for large-capacity infusion bags according to any one of claims 1 to 7, further comprising a coding device (8), wherein the coding device (8) is installed on the frame (1) and located between the lower film unwinding device (3) and the forming device (4), and the coding device (8) is used for printing production information on the lower film (30).

9. The vacuum packaging machine for large-capacity infusion bags according to any one of claims 1 to 7, characterized by further comprising a waste edge collecting device (9), wherein the waste edge collecting device (9) is mounted on the frame (1) and located behind the cutting device (6), and the waste edge collecting device (9) is used for collecting waste edges (40) generated after cutting by the cutting device (6);

slitter edge collection device (9) include wind-up roll (91) and gear motor, gear motor is connected with wind-up roll (91) for drive wind-up roll (91) are rotatory.

10. The vacuum packaging machine for large-capacity infusion bags according to any one of claims 1 to 7, further comprising a control device and a touch display screen (10), wherein the upper film unwinding device (2), the lower film unwinding device (3), the forming device (4), the heat sealing device (5), the cutting device (6) and the conveying device (7) are electrically connected with the control device, and the touch display screen (10) is arranged on the frame (1) and electrically connected with the control device.

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