KR100427220B1 - Manufacture device of non-p.v.c bag - Google Patents

Abstract

The present invention relates to a device for manufacturing a NON-PVC pack for a ringer, the film supply unit for supplying a film; A printing unit which prints on the supplied film; A hole punching part for punching holes in the printed film; A heating part for thermally bonding the perforated film into a plurality of pocket packs connected in series; A cooling unit for cooling the pack heated by heat bonding; A cutting portion for independently cutting a plurality of consecutive cooled packs; A first conveying part for conveying the pack cut back from the cutting part; A plate-shaped second conveying unit for conveying the pack conveyed from the first conveying unit to the rear again; A conveyor for moving while circulating the pack conveyed from the second conveying unit, and inserting a hose into the open side of the pack during movement; A hose cutting and supplying unit for cutting a hose and supplying the same to a conveyor; A third conveying part which opens the one side of the pack supplied to the conveyor so as to feed the pack of the second conveying part to the conveyor and the conveyor inserts a hose into the open side of the pack; Heat-sealing the pack on the conveyor, the hose is inserted, the first, second, and third heating unit for heat-sealing and sealing the open portion; characterized in that it comprises a, it is effective to automatically mass-produce the pack for ringer.

Description

MANUFACTURE DEVICE OF NON-P.V.C BAG}

The present invention relates to an N0N-PVC pack manufacturing apparatus, and more particularly, the entire manufacturing process of the N0N-PVC pack for storing a ringer injection solution (such as saline or glucose) which is a kind of medical drug (film supply, printing) , Perforation, heating, cooling, cutting, hose supply, heating, and transfer) relates to an N0N-PVC pack manufacturing apparatus that enables simple, easy, hygienic and efficient manufacturing by an unmanned automated method.

In general, the ringer injection is a kind of medicine used in medical fields such as various hospitals, and is mainly supplied to the body through blood vessels for long-term inpatients or patients who need water supplementation due to nutrient supply and exhaustion. Lose.

The ringer injection solution is stored in a glass bottle or a ringer injection solution storage container made of PVC (hereinafter referred to as N0N-PVC pack), and the glass bottles and PVC currently used are DHPE (DOP) eluted. This is a tendency to prefer the N0N-PVC pack made of PP material, which is lightweight, portable and easy to use, with less risk of breakage than glass bottles which are beautiful and have a high risk of breakage and are heavy.

On the other hand, the manufacturing apparatus for manufacturing the above N0N-PVC pack is not known in Korea yet, the currently used N0N-PVC pack is due to the total amount of imports, causing a lot of economic losses.

The apparatus for manufacturing the N0N-PVC pack as described above is currently being developed and used in Germany and Japan, the German N0N-PVC pack manufacturing apparatus in the production of N0N-PVC pack in the roll-type film supply and printing process and The heating and cutting process is made by an automated method, but manual work is required for the cooling process, transfer and hose insertion process, and the Japanese N0N-PVC pack manufacturing equipment is used for the overall manufacturing of printing, heating, cutting, cooling, and conveying. The process is completely different from the German N0N-PVC pack making machine.

Therefore, the German N0N-PVC pack manufacturing apparatus is not efficient because the entire process is not made in an automated manner and requires manual labor by manpower in manufacturing the N0N-PVC pack. The transportation and transportation of the plant is cumbersome and has the problem of not being able to achieve continuous mass production.

In the present invention, in the manufacture of N0N-PVC pack, the N0N-PVC pack, which is dependent on the import of N0N-PVC pack, which enables continuous mass production by automating the whole process according to N0N-PVC pack manufacturing by an unmanned automation method. In addition to minimizing the economic loss caused by imports, as well as to provide a new type of N0N-PVC pack manufacturing equipment that can be supplied at a low price by lowering the production cost due to manufacturing the N0N-PVC pack.

In order to achieve the above object, the present invention is a device for manufacturing a non-PVC (N0N-PVC) pack, the film supply unit for supplying the roll rolled N0N-PVC film while rotating; A printing unit for printing and coating the upper surface of the film supplied from the film supply unit while the printing mold is driven up and down by a cylinder and a link device; A plurality of perforated pins are formed in an upper mold formed at equal intervals on one side of the bottom surface, and a through hole corresponding to the perforated pins of the upper mold is formed, and is made of a lower mold that is engaged with the upper mold while being raised and lowered. A hole punching part for punching a hole in the center of one edge of the printed film; The heating part which heat-bonds the film which was perforated by the said hole perforation into the several pocket-shaped (one side open type) pack connected continuously by the heating mold which a heater was built up and down by the cylinder and a link apparatus installed below. Wow; By interlocking with each other by the operation of the auxiliary cylinder, the occlusal cooling of the film (film formed with a plurality of packs) heated in the heating unit, and the horizontal transport of the cooled film while reciprocating left and right along the guide rail by the cylinder A cooling unit provided with upper and lower compression plates to be provided; A cutting mold having a blade portion having a predetermined shape on its bottom surface is driven up and down by a linking device operated by a cylinder, and cuts a film in which a plurality of continuous packs are transported from the cooling unit and cuts the film. A cutting unit converting the two packs into a plurality of independent packs; A plurality of air adsorption pads having a suction sucker on the lower surface thereof are respectively mounted on the upper side, and horizontally installed cylinders are connected to one side and ball screws installed rearward, respectively, and are folded and left along the guide rail during operation of the cylinder. After moving to the right, the plurality of independent packs in the cutting unit is adsorbed by the air adsorption pad, and then horizontally moved to the other side, the first transfer unit is provided with a link device for transporting the sucked pack backwards when the ball screw is operated in succession Wow; Located at the lower rear side of the first conveying part, a plurality of packs transported from the first conveying part is seated, and when a ball screw installed to face backward on one side is operated, the plurality of packs are reciprocated along the rearward guide rail, A plate-shaped second conveying portion for conveying the pack backward; A plurality of air adsorption pads provided on the upper surface of the suction sucker, and a plurality of hose fixing pins to which the hoses are fitted are formed inwards, and have a hose insertion rod that extends and contracts from one side of the air absorption pads, and is fixed by a driving motor. A conveyor for horizontally transporting the plurality of packs transferred from the second conveying unit by an air adsorption pad while circulating in a track; When the cutting blade is cut to a certain length from a hose supplied from a plurality of winding rollers on which the hose is wound, the hose is inserted into a hose fixing pin formed on the hose insertion rod of the conveyor before the plurality of packs are transferred to the conveyor. Hose cutting and feeding section; A pack suction sucker sucker seated on the second transfer part is connected to a plurality of air suction pads provided on the lower surface and the air suction pad, and installed in the rear from the upper portion of the second transfer part to be long, and absorbs air along the guide rails. An air adsorption pad having a ball screw for transporting the pad backwards, the air adsorption pad transported backward by the ball screw interacts with the air adsorption pad of the conveyor, so that the hose fixing pin of the conveyor is inserted into the suction pack. A third transfer part for opening the open side of the pack; 1, 2, 3 having an upper body and a lower body with a built-in heater, which are driven up and down by respective cylinders, and heat-sealing the openings of the pack opened by the third conveying part and the conveyor. The heating unit is characterized in that it is provided. In the present invention as described above, the cooling water circulation hole is perforated so that the cooling water is circulated in the lower compression plate of the cooling unit, the hose cutting and the supply end has a 'V' shape The hose is cut by the cutting blade and turned by the turning pin which is rotated by 180 ° by the electric motor.

1 is a front schematic view showing a N0N-PVC pack manufacturing apparatus according to the present invention,

Figure 2 is a plan view showing a N0N-PVC pack manufacturing apparatus according to the present invention,

3 is a front view showing a cooling unit of the N0N-PVC pack manufacturing apparatus according to the present invention,

4 is a front view showing the hose cutting and supply of the N0N-PVC pack manufacturing apparatus according to the present invention,

5 is an enlarged plan sectional view of a body portion having a hose insertion rod shown in FIG.

<Explanation of symbols for the main parts of the drawings>

1: N0N-PVC Pack Manufacturing Equipment 10: Film Supply Unit

20: Printing part 30: Hole punching part

40: heating part 50: cooling part

60: cutting section 70: first feed section

80: second transfer unit 90: third transfer unit

100: conveyor 110: hose cutting and supply

120: 1st heating part 130: 2nd heating part

140: 3rd heating part

Hereinafter, the present invention will be described in more detail with reference to the accompanying drawings. FIG. 1 is a front schematic view illustrating a N0N-PVC pack manufacturing apparatus according to the present invention, and FIG. 2 is N0N- according to the present invention. 3 is a plan view schematically illustrating a PVC pack manufacturing apparatus, and FIG. 3 is a front view illustrating a cooling unit of the N0N-PVC pack manufacturing apparatus according to the present invention. FIG. 4 is a view illustrating a hose cutting and supply of the N0N-PVC pack manufacturing apparatus according to the present invention. 5 is an enlarged planar cross-sectional view of a body part having a hose insertion rod shown in FIG. 4. As shown in FIGS. 1 and 2, the present invention provides a film supply unit 10 for supplying a film; A printing unit 20 which prints on the supplied film; A hole punching part 30 for punching holes in the printed film; A heating part 40 for thermally bonding the perforated film into a plurality of pocket-shaped packs (one open pocket) connected in series; And a cooling unit 50 for cooling the pack heated by heat bonding. The cutting unit 60 may independently cut a plurality of cooled consecutive packs; A first transfer unit 70 for transferring the pack cut at the cutting unit 60 to the rear; And a plate-shaped second conveying unit 80 for conveying the pack conveyed from the first conveying unit 70 to the rear. Also, the pack conveyed from the second conveying unit 80 is moved while circulating. Conveyor 100 for inserting the hose into the open side of the pack when moving; And a hose cutting and supplying unit 110 for cutting the hose and supplying it to the conveyor 100. Finally, the pack of the second transfer unit 80 is supplied to the conveyor 100, and at the same time, the conveyor ( A third transfer part 90 for opening one side of the pack supplied to the conveyor 100 so as to insert the hose into the open side of the pack; Heat-bonding the pack on the conveyor 100, the hose is inserted, 1, 2, 3rd heating unit (120, 130, 140) for heat-sealing and sealing the open portion; characterized in that it comprises a. The film supply unit 10 to the first, second, and tertiary heating units 120, 130, and 140 are sequentially disposed. Here, the features of the present invention will be described in detail in detail. 2, the rollers 2 and 2 ′ are supplied to the printing unit 20 while the rollers 2 and 2 ′ are rotated as shown in FIG. 2. In this case, the film supplied by the film supply unit 10 The two films are overlapped and supplied. The printing unit 20 is supplied from the film supply unit 10 while the printing mold 22 is driven up and down by the cylinder CY1 and the link device R1. The upper surface of the film is printed and coated. Here, the printing mold 22 of the printing unit 20 is the upper and lower molds as shown. 22a, 22b, and the upper and lower molds 22a, 22b are engaged with each other by the link device R1 that is folded and lifted as the cylinder CY1 is operated. At this time, the cylinder CY1 is As shown in the drawing, the link device R1 is installed in connection with each other, and the link device R1 is horizontally installed to be foldable. Of course, the upper and lower molds 22a and 22b are interlocked with each other, and the non-FIVC The stationery necessary for the pack is printed on the surface of the film. On the other hand, the transfer paper used for printing on the film surface is rolled and rotated and supplied by the driving roller 24 and the driven roller 26 by a predetermined length for printing. Subsequently, as shown in FIGS. 1 and 2, the hole punching part 30 includes a top mold 32 having a plurality of perforation pins 34 formed at equal intervals on one side of a bottom surface thereof, and the top mold ( The through hole corresponding to the perforated pin 34 of the 32 is formed, and the lower part that engages with the upper mold 32 while lifting up and down. It is made of a die 36, and when the bite is perforated a hole on one side of the film printed by the printing portion 20. Here, as shown in the hole perforation 30, the horizontal cylinder (CY1 ') and It is preferable that the link device R1 'is provided so that the upper and lower molds 32, 36 engage with each other by the operation of the cylinder CY1' and the link device R1 '. Preferably, the molds 32 and 36 are configured to operate in the same manner as the upper and lower molds 22a and 22b of the printing unit 20 described above. Therefore, the molds 32 and 36 are supplied by the operation of the upper and lower molds 32 and 36. Holes are drilled in one edge of the finished film, and this hole is drilled in the center of one of the pocket-shaped edges of the pocket as described below. Of course, this hole is used to hang the non-fivCpack for Ringer on an appropriate device. This hole is inserted and hooked into a separate ringer fixing hook, not shown. Again, heating As shown in Figs. 1 and 2, the heating mold 44 in which the heater 42 is built is driven up and down by a cylinder CY2 and a linkage device R2 provided below, as shown in Figs. The perforated film 30 is thermally bonded to a plurality of rectangular pocket-shaped (one side open) packs connected in succession. At this time, the heating mold 44 is the above-described hole punching unit 30. ) Is composed of upper and lower molds (44a, 44b), the upper and lower molds (44a, 44b) are driven up and down by the cylinder (CY2) and the link device (R2) to drive up and down, Of course, thermal bonding is performed at the time of engagement of the upper and lower molds 44a and 44b, and the film is formed with a plurality of pocket packs (one open type) connected in series due to the thermal bonding. A plurality of ringer packs, one side of which is open (not thermally bonded), are successively formed. Pack heat-sealed by heating is cooled in the cooling unit 50 continuously installed in the heating unit 40, the cooling unit 50 is to operate the auxiliary cylinder (CY3 '), as shown in Figs. By interlocking with each other, and cooling the film (film formed with a plurality of packs) heated in the heating unit 40 at the time of occlusion, cooled by reciprocating left and right along the guide rail 52 by the cylinder (CY3) It consists of upper and lower pressing plates 54 and 56 for horizontally conveying the film. At this time, the lower pressing plate 56 is formed with a cooling water circulation hole 58 as shown in FIG. 3 so that the cooling water is circulated. After the film is cooled by the cooling unit 60, the film is transferred to the cutting unit 60, which is the next process, and the transfer is performed by the operation of the cylinder CY3 described above, and the upper and lower press plates 54 and 56. Is formed in the state where the film is pressed. That is, the upper and lower press plates 54 and 56 are pressed into the cylinder CY3 while the film is pressed. The film is transferred to the cutting unit 60, which is the next process. Therefore, the upper and lower press plates 54 and 56 are transported while pulling the film, so that the film of the film supply unit 10 is continuously supplied. As the upper and lower compression plates 54 and 56 pull the film, the rollers 2 and 2 'of the film supply part 10 rotate, and thus the film is continuously supplied. As shown in FIGS. 1 and 2, the cutting part 60 supplied with the film has a cutting mold 64 having a blade part 62 having a predetermined shape at its bottom, and is operated by the cylinder CY4. Driven up and down by the linkage devices R4 and R5, the film having a plurality of continuous packs conveyed from the cooling unit 50 is cut to convert the plurality of continuous packs into independent plurality of packs. The cutting mold 64 is composed of upper and lower molds 64a and 64b as shown, and the cylinder CY4 is the cooling unit 50 described above. When the film is supplied, the film is operated to raise the lower mold 64b. Thus, the pack supplied from the cooling unit 50 is placed on the lower mold 64b, and when the pack is thus placed, the cooling unit 50 Then, when the cooling unit 50 returns, the upper and lower molds 64a and 64b separately separate a plurality of ring packs for successive ringers, respectively. 64a and 64b cut around the heat-adhesive portion of the continuous ringer pack and separate the pack. Thus, the separated pack is moved horizontally by the first transfer part 70, and then back again. The first transfer part 70 is equipped with a plurality of air adsorption pads 74 having a suction sucker 74a on a lower surface thereof, respectively, and a cylinder CY5 horizontally installed on one side thereof, and a rearward portion thereof. The installed ballscrews 71 are connected to each other, and are folded while operating the cylinder CY5. After moving left and right along the rails 72, the plurality of packs independent from the cutting unit 60 are adsorbed by the air adsorption pads 74, and then horizontally moved to the opposite sides, and then the ball screws 71 are continuously operated. It is composed of a linkage device R6 for transporting the adsorbed pack backwards. Therefore, when the cylinder CY5 is extended, the linkage device R6 is gathered, so that the air adsorption pad 74 is also gathered. The adsorption pad 74 adsorbs the plurality of separate ringer packs. When the pack is adsorbed, the cylinder CY5 contracts and the pack is transferred to the first transfer part 70 in the drawing. As the contraction is contracted, the link device R6 is pulled toward the first transport part 70, so that the pack is transported, and the link device R6 is unfolded during transport. Therefore, the air adsorption pad 74 of the gathered link device R6 is expanded. Is again unfolded as shown in FIG. 1, whereby a plurality of packs are also separated from each other. That is, the plurality of packs are gathered from each other in the above-described heating unit 40 to the cutting unit 60, but are spaced apart from each other in the first transfer unit 70. The packs thus spaced apart by the first transfer unit 70 The first conveying unit 70 is conveyed to the rear as the ball screw 71 is operated. In other words, the first conveying unit 70 moves the plurality of packs horizontally. Afterwards, the second conveying unit 80 installed at the rear of the first conveying unit 70 is formed in a plate shape and positioned at the lower rear side of the first conveying unit 70 as shown in FIG. 2. On the upper surface, a plurality of packs conveyed from the first conveying part 70 are seated (secured by the air adsorption pad of the first conveying part losing its adsorption force). At this time, the second conveying part 80 is shown on one side. As shown, the ball screw 81 and the guide rail 82 facing backwards are installed, and when the ball screw 81 is operated, A plurality of packs conveyed from the first conveying part 70 are again conveyed to the rear while reciprocating along the guide rails 82 facing the upper part. On the other hand, the rear of the second conveying part 80 is as shown in FIG. 2. The suction sucker 101a has a plurality of air adsorption pads 101 provided on the upper surface, and is circulated in a predetermined track by the driving motor 102 while air is supplied to the plurality of packs transferred from the second transfer part 80. The conveyor 100 is provided to suck the suction pad 101 and to transport it horizontally. The hose 100 includes a plurality of hose fixing pins to which hoses are fitted as shown in FIGS. 2, 4, and 5. 104 is formed inward, and the hose insertion rod 106 is installed to expand and contract from one side of the air adsorption pad 101. Here, the hose insertion rod 106 has an end portion as shown in FIG. Part of the body 108 is configured to be shot by the compression spring (SP) At this time, the hose insertion rod 106 is made of a magnetic body (magnetic body), is coupled to the center of the inner surface of the body portion 108, the electromagnet (EM: electromagnet) in the form of a stick at a predetermined distance from the front Therefore, when a magnetic force is generated in the electromagnet EM, the hose insertion rod 106 moves by the generated attraction force and inserts the hose into the opening of the pack which will be described later. That is, the hose insertion rod 106 5 inserts the hose fixing pin 104 into the opening of the pack as shown by the dotted line in FIG. 5. Meanwhile, the hose fixing pin 104 of the hose inserting rod 106 is shown in FIGS. 2 and 4. The hose is fitted by the hose cutting and supply unit 110 as described above. The hose cutting and supply unit 110 is a cutting blade 114 is a fixed length of the hose supplied from a plurality of winding rollers 112 wound the hose. If cut, this section before plural packs are transported to conveyor 100 The hose is inserted into the hose fixing pin 104 formed on the hose insertion rod 106 of the conveyor 100. Such a hose cutting and supply 110 is a 'V' for cutting the hose, as shown in FIG. A cutting blade 114 having a shaped end portion; An electric motor 116 horizontally installed; One end is fitted with a hose cut from the cutting blade 114, the other end is fixed to the rotating shaft of the electric motor 116, the direction switching pin is rotated by 180 ° according to the drive of the electric motor 116 And, the hose insertion opening (119a) receiving the hose from the horizontal turning pin 118 is moved horizontally is formed, the block 119b which is installed on the opposite side of the cutting blade (114) and And a telescopic lifting cylinder CY9 installed at the lower part of the block 119b to fix the hose supplied to the block 119b and lifting the block 119b, and the lifting cylinder CY9 has a hose. The first rod CY9-1 for pressing and fixing the hose supplied to the hose insertion hole 119a by raising and lowering through the lower surface of the insertion hole 119a, and the upper end portion is fixedly attached to the lower part of the block 119b. Thus, the hose lift 119 composed of the second rod (CY9-2) for elevating the block 119b. In addition, while the hose lifter 119 horizontally moves the hose lifter 119 to the direction changer pin 118 so that the hose feeder 119 receives the hose from the turnover pin 118, the hose lifter 119 is supplied with the hose. And a lift reciprocating cylinder (CY9 ') for moving the hose lifter (119) to the hose retaining pin (104) so that the hose is fitted to the hose retaining pin (104) of the conveyor (100). When the hose supplied horizontally from the winding roller 112 is inserted into the turning pin 118, the cutting and supplying part 110 cuts the hose 114. Then, the turning pin 118 is driven. It is rotated to the opposite side by the motor 116 as shown in Figure 4, and at the same time the elevator reciprocating cylinder (CY9 ') is operated to move the hose elevator 119 horizontally to the direction switching pin 118. The hose fitted to the direction turning pin 118 is a hose insertion hole 11 formed in the block 119b of the hose lifter 119. 9a), and when the hose is inserted, the lifting cylinder CY9 moves up and down to raise the block 119b with the hose fixed. (At this time, the first rod CY9-1 is fastened to fix the hose. Slightly raised-slightly protruding from the hose insert of the block-the block 119b is raised to correspond to the hose fixing pin 104 of the conveyor 100, so that when the block 119b is raised, the tactical The hose insertion rod 106 operates as described above. That is, the hose insertion rod 106 reciprocates to insert the hose fixing pin 104 into the hose insertion hole 119a of the block 119b. A hose is inserted into the pin 104, and at the same time, the lifting cylinder CY9 of the hose cutting and supply unit 110 lowers the first rod CY9-1. Subsequently, the magnetic force of the hose insertion rod 106 The force is released, and thus the hose insertion rod 106 is returned to its original position, and the hose fixing pin 104 is disposed in FIG. 4. As shown in the drawing, the hose is held in the fitted state. Meanwhile, the hose of the hose fixing pin 104 is inserted into the open side of the ringer pack by the conveyor 100 and the third transfer part 90. The third transfer unit 90 is connected to a plurality of air adsorption pads 94 and air adsorption pads 94 provided with a pack adsorption sucker 94a seated on the second transfer unit 80 on a lower surface thereof. It is provided with a ball screw 91 which is installed in the upper portion of the upper portion of the conveying portion 80 to the rear, and conveys the air adsorption pad 94 to the rear along the guide rail 92. At this time, the rear side by the ball screw 91 The conveyed air adsorption pad 94 interacts with the air adsorption pad 101 of the conveyor 100 so that the hose fixing pin 104 of the conveyor 100 into which the hose is fitted into the adsorbed pack is inserted. The open side of the pack is opened. That is, the bottom surface of the pack is absorbed by the air adsorption pad 101 of the conveyor 100, and the top of the pack The surface is adsorbed by the air adsorption pad 94 of the third transfer unit 90. Accordingly, the ringer pack having one side opened is opened, and the hose insertion rod 106 provided on the conveyor 100 is opened at this open side. The hose fixing pin 104 is inserted as shown by the broken line in Fig. 5. Thus, when the hose is inserted into the pack, the third transfer unit 90 returns to the second transfer unit 80, the hose is inserted The pack is transferred to the first, second and third heating units 120, 130 and 140 which are the next processes by the conveyor 100. Here, the first, second and third heating units 120, 130 and 140 are shown in FIG. As shown in FIG. 1 and FIG. 2, each of the cylinders CY6 and CY7 has an upper body 124, 134, 144 and a lower body 126, 136, 146 in which heaters 122, 132, and 142 are embedded. And CY8). The openings of the pack opened by the third transfer section 90 and the conveyor 100 are then heated and sealed by heat bonding. Ringgereu the packs are sealed with the adhesive, the heat due to bonding is integrally attached to the hose also pack, that is, ringgereu pack is completed by the first, second, third heating element (120, 130, 140).

In the N0N-PVC pack manufacturing apparatus as described above, the cylinder driving and linking apparatus and the electric signal system for driving the same are not known in detail because of the general known technology used in the automation system.

As such, according to the manufacture of the N0N-PVC pack for storing the ringer injection liquid using the N0N-PVC pack manufacturing apparatus according to the present invention, by automating the entire process according to the N0N-PVC pack manufacturing by an unmanned automation method It enables mass production and at the same time enables the production of N0N-PVC packs that depend on all imports in Korea, minimizing economic losses from imports, and lowering the production cost of manufacturing N0N-PVC packs. It can supply, which is economic effect.

Claims (3)

In the apparatus for manufacturing the N0N-PVC pack, A film supply unit 10 for supplying the N0N-PVC film wound in a roll shape while the rollers 2 and 2 'rotate; A printing unit 20 for printing and coating the upper surface of the film supplied from the film supply unit 10 while the printing mold 22 is driven up and down by the cylinder CY1 and the link device R1; A plurality of perforated pins 34 are formed in the upper mold 32 at equal intervals on one side of the bottom surface, and through holes corresponding to the perforated pins 34 of the upper mold 32 are formed, and the upper mold 32 is raised and lowered. And a lower mold 36 to be combined with the lower mold 36, and a hole perforating part 30 for punching a hole in one edge of the film printed by the printing part 20 at the time of occlusion; The heating die 44 in which the heater 42 is built up and down is driven up and down by the cylinder CY2 and the linkage device R2 provided below, so that the perforated film is continuously connected to the hole hole 30. A heating part 40 thermally bonded to a plurality of pocket-shaped (one side open type) packs; Occlusion with each other by the operation of the auxiliary cylinder (CY3 '), when the occlusal cools the film (film formed with a plurality of packs) heated in the heating unit 40, the guide rail 52 by the cylinder (CY3) A cooling unit 50 provided with upper and lower compression plates 54 and 56 for horizontally conveying the cooled film while reciprocating left and right along it; The cooling part 50 is driven while the cutting mold 64 having the blade portion 62 having a predetermined shape on the bottom thereof is driven up and down by the link devices R4 and R5 operated by the cylinder CY4. A cutting unit 60 which cuts a film in which a plurality of continuous packs are transported and converts the plurality of continuous packs into independent plurality of packs; A plurality of air adsorption pads 74 having a suction sucker 74a on the lower surface thereof are respectively mounted on the upper side thereof, and a cylinder CY5 installed horizontally on one side and a ball screw 71 installed rearward are respectively connected to the cylinder. During the operation of the (CY5) is folded and moved to the left and right along the guide rail 72, the plurality of packs independent from the cutting unit 60 is adsorbed with the air adsorption pad 74 and then horizontally moved to the opposite side. When the ball screw 71 is operated in succession, the first transfer unit 70 is provided with a link device (R6) for transferring the adsorbed pack to the rear; Located in the lower rear side of the first conveying part 70, a plurality of packs transported from the first conveying part 70 is seated, and when the ball screw 81 installed to face the rear on one side is operated, the rearward facing A plate-shaped second conveying unit 80 for conveying the plurality of packs backward while reciprocating along the guide rails 82; A plurality of air adsorption pads 101 provided at the upper surface of the suction sucker 101a, and a plurality of hose fixing pins 104 to which the hoses are fitted are formed inward to expand and contract from one side of the air adsorption pads 101. It has a hose insertion rod 106, while circulating in a constant track by the drive motor 102, the plurality of packs transported from the second conveying unit 80 is sucked by the air adsorption pad 101 to transport horizontally A conveyor 100; When the cutting blades 114 cut the hoses supplied from the plurality of winding rollers 112 in which the hoses are wound to a certain length, before the plurality of packs are transferred to the conveyor 100, the cut hoses are conveyed to the conveyor 100. Hose cutting and supply portion 110 to be fitted to the hose fixing pin 104 formed on the hose insertion rod 106 of the); The pack adsorption sucker 94a seated on the second transfer part 80 is connected to the plurality of air adsorption pads 94 and the air adsorption pads 94 provided on the lower surface thereof, and the second transfer part 80 is provided. It is installed long from the top of the rear, has a ball screw 91 for conveying the air adsorption pad 94 to the rear along the guide rail 92, the air adsorption pad 94 conveyed back by the ball screw 91 ) Interacts with the air adsorption pad 101 of the conveyor 100 to open the open side of the pack so that the hose fixing pin 104 of the conveyor 100 into which the hose is fitted into the adsorbed pack is inserted. A third transfer unit 90; The heaters 122, 132, and 142 have upper bodies 124, 134, and 144 with built-in and lower bodies 126, 136, and 146, and are driven up and down by respective cylinders CY6, CY7, and CY8. The first, second and third heating parts 120, 130, and 140 for sealing the openings of the pack opened by the third transfer part 90 and the conveyor 100 by heat bonding; are provided. N-NV-PVC pack manufacturing apparatus. The method of claim 1, The lower press plate (56) of the cooling unit (50) is a non-PVC (N0N-PVC) pack manufacturing apparatus, characterized in that the cooling water circulation hole (58) perforated so that the cooling water is circulated. The method of claim 1, wherein the hose cutting and supply unit 110, A cutting blade 114 having an 'V' shaped end for cutting the hose; An electric motor 116 horizontally installed; One end is fitted with a hose cut from the cutting blade 114, the other end is fixed to the rotary shaft of the electric motor 116, the direction is rotated by ∠180 ° according to the drive of the electric motor 116 A switching pin 118; A hose insertion opening 119a receiving a hose from the direction change pin 118 that is horizontally moved is formed horizontally so that the block 119b is installed on the opposite side of the cutting blade 114 and the lower portion of the block 119b. And a telescopic lifting cylinder CY9 for elevating the block 119b while fixing the hose supplied to the block 119b, and the lifting cylinder CY9 has a lower surface of the hose insertion hole 119a. The first rod CY9-1 for pressurizing and fixing the hose supplied to the hose insertion hole 119a and the upper end portion are integrally attached and fixed to the lower portion of the block 119b by penetrating up and down, thereby elevating the block 119b. Hose elevator 119 including a second rod (CY9-2) to be; When the hose lifter 119 horizontally moves the hose lifter 119 to the turning pin 118 so that the hose lifter 119 receives the hose from the turning pin 118, the hose lifter 119 is supplied with the hose. And a lift reciprocating cylinder (CY9 ') for moving the hose elevator 119 to the hose fixing pin 104 so that the hose is fitted to the hose fixing pin 104 of the conveyor 100. FN pack manufacturing equipment.