KR102659085B1 - Connecting port of dual injection type for medical solution bag - Google Patents

Abstract

The present invention relates to a double injection type connection port for an infusion bag. To be described in more detail, the port body 10 having a central hole (H) is first injection molded using a double injection mold, and then the port body ( 10) In addition, by second injection molding the soft elastic blocking cap (20) that blocks the central hole (H), a new structure of the double injection type connection port for the IV bag can be used to significantly reduce the manufacturing cost, time required, and defect occurrence rate. It's about.

Description

Connecting port of dual injection type for medical solution bag}

The present invention relates to a double injection type connection port for an infusion bag. To be described in more detail, the port body 10 having a central hole (H) is first injection molded using a double injection mold, and then the port body ( 10) In addition, by second injection molding the soft elastic blocking cap (20) that blocks the central hole (H), a new structure of the double injection type connection port for the IV bag can be used to significantly reduce the manufacturing cost, time required, and defect occurrence rate. It's about.

In general, intravenous fluids such as saline solution and glucose used in hospitals that treat patients or perform surgery are stored in intravenous fluid containers with certain specifications, and these intravenous fluid containers include an intravenous fluid bottle made of glass and an intravenous fluid made of synthetic resin. It is largely distinguished by a hundred. Among these, IV bottles have hygienic advantages, but have the disadvantage of being heavy, so recently, IV bags made of polypropylene, which are light in weight and easy to handle, are widely used.

The fluid stored in the fluid bag is usually injected into the patient's body through a fluid line equipped with a spike. Therefore, the IV bag has a spike port that inserts the spike and discharges the drug, and an injection port that injects drugs such as antibiotics, anticancer drugs, and anesthetics into the IV bag using a typical syringe. It is installed.

The spike port and injection port may be directly sealed to the edge of the IV bag when manufacturing the IV bag, or may be inserted into the connecting tube after sealing the connecting tube to the IV bag. Hereinafter, the spike port and injection port are collectively referred to as the ‘access port’. Previously, Public Utility Model No. 20-2009-0000486 (January 16, 2009), Public Patent No. 10-2017-0026051 (March 8, 2017), and Public Patent No. 10-2021-0101530 (2021) (August 19, 2018) introduces connection ports of various structures.

Attached Figure 1 cites the connection port of Patent Publication No. 10-2021-0101530, which includes a connector 100, a rubber stopper 200, and a capping member 300. The connector 100 has a lower insertion portion 110 inserted into the connection tube of the IV bag, and the rubber stopper 200 is installed inside the upper support portion 120 of the connector 100 to store the IV fluid stored in the IV bag. Stop the leak.

The capping member 300 is coupled to the outside of the upper support portion 120 of the connector 100 to prevent the rubber stopper 200 from being separated. When the connection port is used as a spike port, a spike for discharging fluid is inserted into the rubber stopper 200, and when used as an injection port, a syringe for drug injection is inserted into the rubber stopper 200. Descriptions of other non-illustrated reference numerals in FIG. 1 are omitted.

Open Utility Model No. 20-2009-0000486 (January 16, 2009) Public Patent No. 10-2017-0026051 (March 8, 2017) Publication Patent No. 10-2021-0101530 (August 19, 2021)

As observed above, the connection port for the conventional infusion bag is formed by separately molding the connector 100, the rubber stopper 200, and the capping member 300, and then inserting a rubber stopper ( It is manufactured through an assembly process in which 200) is placed and a capping member 300 is placed on the outside of the upper support portion 120.

At this time, the connector 100 is injection molded from a typical medical polypropylene resin, and the rubber stopper 200 is manufactured by mixing various additives such as a vulcanizing agent with natural rubber or synthetic rubber and then press molding the mixture. In this way, since the connector 100 and the rubber stopper 200 are dissimilar materials and lack compatibility, their interfaces do not closely adhere to each other. Therefore, in order to prevent the rubber stopper 200 from coming off and leaking, the capping member 300 is placed on the top of the connector 100 and fixed.

Conventional prefabricated connection ports manufactured using this method have the following problems. First, since the connector 100, the rubber stopper 200, and the capping member 300 must be molded separately, multiple injection molds must be prepared, and inventory management for injection products is cumbersome.

Second, because it must go through an injection process and an assembly process, it requires a relatively large amount of equipment and space, and the time required for manufacturing is long. In particular, there is a high risk of defective products such as assembly defects or contamination of foreign substances during the assembly process.

Third, if the hardness of the rubber stopper 200 is less than 35A, it is difficult to mold and assemble, so a rubber material with high hardness is used. If the hardness increases, rubber fragments may be generated when inserting a spike or syringe. , there is a disadvantage that the choice of material for the rubber stopper 200 is very limited because the elastic restoring force is low and there is a risk of leakage.

Accordingly, the purpose of the present invention is to create a new structure that can promote simplicity and efficiency of work in the manufacturing process by molding a plurality of component parts constituting the connection port for the IV bag in one mold rather than separately injection molding each. It provides an injection-type connection port.

Another object of the present invention is to reduce the manufacturing cost and shorten the manufacturing time by not using a capping member or going through an assembly process in the connection port for the infusion bag, and to develop a new dual structure that can further reduce the risk of defective products. It provides an injection-type connection port.

Hereinafter, in the present invention, the component corresponding to the connector 100 of FIG. 1 is referred to as ‘port body 10’, and the component corresponding to the rubber stopper 200 is referred to as ‘elastic blocking cap 20’.

The double injection type connection port for the infusion bag according to the present invention,

One side is provided with a connection pipe portion 11 connected to an IV bag or an IV line, and the other side is provided with a connection pipe portion 12 through which a spike or syringe enters, and the connection pipe portion 11 and the connection pipe portion 12 First injection mold the port body 10, which has a structure connected to each other through the central hole (H),

It is manufactured by secondary injection molding a soft elastic blocking cap (20) that blocks the central hole (H) inside the connection pipe portion (12) of the port body (10),

The port body 10 is made of polypropylene resin, and the elastic blocking cap 20 is made of a medical thermoplastic elastomer that has excellent compatibility with polypropylene resin and has a Shore hardness of 25 to 45A.

The double injection type connection port for an IV bag according to the present invention can reduce manufacturing costs and shorten the time required by not using a capping member or undergoing an assembly process, and further fundamentally reducing the risk of defective products. It works.

Figure 1 is a cross-sectional view illustrating the structure of a connection port for a conventional infusion bag;
Figure 2 is a perspective view of a double injection type connection port according to the present invention;
Figure 3 is a cross-sectional view of a double injection type connection port according to the present invention;
Figure 4 is a perspective view (A) and a cross-sectional view (B) of the port body 10 constituting the double injection type connection port according to the present invention;
Figure 5 shows an example of a double injection mold for test injection of the double injection type connection port according to the present invention.

Hereinafter, the present invention will be described in detail using the attached drawings. However, since the attached drawings show preferred embodiments of the present invention, the scope of the present invention is not limited by these drawings. In addition, even if the configuration is essential for carrying out the present invention, detailed description will be omitted for configurations that belong to the known technology or that can be easily implemented by a person skilled in the art from the known technology.

In the present invention, ‘double injection’ means molding one article by sequentially injecting two types of resins of different materials or colors in one injection mold. Additionally, the ‘connection port’ includes both a spike port for fluid drainage and an injection port for drug injection.

As shown in Figures 2 and 3, the double injection type connection port for an infusion bag according to the present invention is made by first injection molding the port body 10 in one mold, and then forming the elastic blocking cap 20 into two molds. By secondary injection molding, the port body 10 and the elastic blocking cap 20 are manufactured through a single double injection process without a separate assembly process.

First, the port body 10 is provided with a connector 11 on one side and a connector 12 on the other side, and the connector 11 and the connector 12 have a central hole (H ) has a structure that is connected to each other through. The material of the port body 10 can typically be medical polypropylene resin.

The connecting pipe portion 11 may be directly sealed to the rim of a typical transfusion bag, or may be inserted into a connection tube (not shown in the drawing) sealed to the rim of the transfusion bag. Then, a spike for draining sap or a syringe for drug injection enters the connection pipe portion 12.

Next, the elastic blocking cap 20 blocks the central hole (H) of the connection pipe portion 12 and supports it when a syringe or spike is inserted and functions to prevent liquid leakage in the injection mold. Without separating the port body 10, the central hole (H) is secondarily injection molded inside.

The elastic blocking cap 20 is preferably made of a medical thermoplastic elastomer with a Shore hardness of 25 to 45A. If the shore hardness of the thermoplastic elastomer is less than 25A, injection molding of the elastic blocking cap 20 is difficult. Conversely, if it exceeds 45A, there is a risk of rubber debris or leakage occurring when inserting the syringe, and furthermore, the spike or syringe This is not desirable because it makes insertion difficult.

The medical thermoplastic elastomer constituting the elastic blocking cap 20 is a rubber substitute material with excellent compatibility with the polypropylene constituting the port body 10, and is specifically a hydrogenated SIBS (styrene-isoprene-butadiene block). copolymer), hydrogenated SBS (styrene-butadiene-styrene copolymer), hydrogenated SIS (styrene-isoprene-styrene copolymer), hydrogenated SEBS (styrene-ethylene-butadiene block copolymer), hydrogenated SEPS (styrene-ethylene-propylene block) copolymer), hydrogenated SEEPS (styrene-ethylene-ethylene-propylene block copolymer), hydrogenated SBC (styrene-butadiene block copolymer), hydrogenated SBPS (styrene-ethylene-propylene-styrene copolymer) or any of these It can be done in combination.

According to an embodiment of the present invention, as shown in Figures 2 and 3, an inward locking protrusion (12a) protrudes toward the central hole (H) on the inner wall of the connection pipe portion (12) of the port body (10). It is desirable. The inward locking protrusion (12a) functions to prevent the elastic blocking cap (20) from coming off and to block sap leakage.

In addition, it is preferable that a reinforcing peripheral wall 13 spaced apart at a predetermined interval is provided on the outer circumference of the connecting pipe portion 12. The connecting pipe portion 12 and the reinforcing peripheral wall 13 are connected to each other by the upper connecting portion 14. The reinforcing peripheral wall 13 preferably has a cylindrical cross section, but may also have a polygonal shape.

The reinforcing peripheral wall 13 physically reinforces the bearing capacity of the connecting pipe portion 12, and also provides an insertion length of the connecting pipe portion 11 when sealing the connecting pipe portion 11 in an IV bag or inserting it into a connecting tube. It functions as a stopper to limit.

As shown in the attached FIG. 4, the upper connection part 14 may be provided with a resin passage 15 for injecting molten resin to form the elastic barrier cap 20 into the central hole H during the second injection. . The resin passage 15 is filled with the elastomer during secondary injection.

In addition, a plurality of spacing supports 16 may be installed along the circumferential direction between the connection pipe portion 12 and the reinforcing peripheral wall 13 of the port body 10. It is preferable that 4 to 8 spacing supports 16 are installed at equal intervals along the circumferential direction. The resin passage 15 may be installed to penetrate the spacing support 16.

For reference, if a predetermined gap is not provided between the connection pipe portion 12 and the reinforcing peripheral wall 13, the thickness of the connection pipe portion 12 may become too thick, resulting in dimensional shrinkage during injection. Therefore, a structure that can secure sufficient bearing capacity with a relatively thin thickness was adopted by leaving a thin space between the connection pipe portion 12 and the reinforcing peripheral wall 13.

Meanwhile, attached FIG. 5 illustrates a double injection mold capable of test injection of a connection port for a transfusion bag according to the present invention, and the double injection mold consists of an upper mold 100 and a lower mold 200.

The upper mold 100 and the lower mold 200 each have a first cavity (C1) for primary injection for injection molding the port body 10 and a secondary injection molding agent for injection molding the elastic blocking cap 20. 2 There are four cavities (C2) each.

And on the upper surface of the lower mold 200, a first runner (R1) for supplying polypropylene resin to the first cavity (C1), and a second runner (R1) for supplying elastomer to the second cavity (C2), respectively ( R2) is installed.

A runner switch (R3) is installed between the first runner (R1) and the second runner (R2) to change the movement path of the resin for injection. The runner switch (R3) blocks the second runner (R2) during the first injection and blocks the first runner (R1) during the second injection.

In addition, inside the first cavity (C1) of the upper mold (100) and the lower mold (200), a first hole pin (P1) for forming a central hole (H) inside the port body (10) protrudes, respectively. 2 A second hole pin (P2) protrudes from the cavity (C2) for inserting the central hole (H) of the first formed port body (10).

When explaining the method of manufacturing the connection port of the present invention using the double injection mold, first, in the state where the upper mold 100 and the lower mold 200 are combined, the first cavity (C1) is formed through the first runner (R1). ) to each supply polypropylene molten resin to mold the pot body 10, which is the first injection product.

Next, the upper mold 100 and the lower mold 200 are separated, each port body 10 is withdrawn from the first cavity (C1), and the port bodies 10 are respectively inserted into the second cavity (C2). And then combine the upper mold 100 and the lower mold 200 again.

In this way, the central hole (H) of the port body (10) is disposed inside the second cavity (C2) with each being inserted into the second hole pin (P2) of the second cavity (C2), and the second hole pin ( A third cavity (no reference numeral) in which the elastic blocking cap 20 can be formed is provided between P2) and the second cavity C2 of the upper mold 100.

In this state, a molten resin made of an elastic polymer is injected into the third cavity through the second runner (R2) to form an elastic blocking cap (20) inside the connection pipe portion (12) of the port body (10). At this time, the molten resin injected through the second runner (R2) is injected into the third cavity formed in the central hole (H) through the resin passage 15 formed in the upper connection part 14 of the pot body 10. .

Finally, the upper mold 100 and the lower mold 200 are separated, and the connection port of the present invention, which is a secondary injection molded product, is pulled out. Since the double injection mold in Figure 5 is proposed for test injection, it is configured to move the port body (10), which was first injected in the first cavity (C1), to the second cavity (C2) and then perform the second injection. reveal.

For reference, when mass producing the connection port of the present invention, an automated double injection mold can be used. In this automatic double injection mold, the upper mold 100 is separated into a first upper mold 100a with a first cavity C1 installed and a second upper mold 100b with a second cavity C2 installed, and the lower mold (200) can be installed on a turn table.

Then, the port body 10 is first injected while the first upper mold 100a is coupled to the lower mold 200, and the first upper mold 100a is separated and the lower mold 200 is injected using a turn table. ) can be configured to move the position of the second upper mold (100b) on the lower mold (200) to perform secondary injection of the elastic blocking cap (20).

At this time, the first hole pin (P1) is installed in the lower mold 200 during the first injection, and the second hole pin (P2) is installed in the lower mold 200 during the second injection. Using this automated double injection mold, the double injection type connection port for the infusion bag according to the present invention can be mass-produced quickly and at a lower cost.

Lastly, in the present invention, the term ‘sapbaekyong’ was added to the name of the invention for convenience, but this use does not limit the scope of the present invention. The connection port according to the present invention can be used in IV sets in addition to IV bags.

(10) Port body (11) Connector part
(12) Connection pipe part (12a) Inward locking jaw
(13) Reinforced perimeter wall (14) Top connection
(15) Resin passage (16) Separation support killing
(H) Central hole (20) Elastic blocking cap
(100) Upper mold (200) Lower mold
(C1,C2) Cavity (R1,R2) Runner
(R3) Runner switch (P1,P2) Hole pin

Claims (6)

One side is provided with a connection pipe portion 11 connected to an IV bag or an IV line, and the other side is provided with a connection pipe portion 12 through which a spike or syringe enters, and the connection pipe portion 11 and the connection pipe portion 12 First injection mold the port body 10, which has a structure connected to each other through a central hole (H),
It is manufactured by secondary injection molding a soft elastic blocking cap (20) that blocks the central hole (H) inside the connection pipe portion (12) of the port body (10),
The port body 10 is made of polypropylene resin, and the elastic blocking cap 20 is made of a medical thermoplastic elastomer with a Shore hardness of 25 to 45A,
The port body 10 is provided with a reinforcing peripheral wall 13 spaced apart at a predetermined interval around the outer circumference of the connecting pipe portion 12, and the connecting pipe portion 12 and the reinforcing peripheral wall 13 are formed at the upper connection portion. (14) A double injection type connection port for an IV bag, characterized in that it has a structure connected to each other by (14).
The method of claim 1, wherein the medical thermoplastic elastomer constituting the elastic barrier cap 20 is hydrogenated SIBS (styrene-isoprene-butadiene block copolymer), hydrogenated SBS (styrene-butadiene-styrene copolymer), and hydrogenated SIS ( Styrene-isoprene-styrene copolymer), hydrogenated SEBS (styrene-ethylene-butadiene block copolymer), hydrogenated SEPS (styrene-ethylene-propylene block copolymer), hydrogenated SEEPS (styrene-ethylene-ethylene-propylene block copolymer), A double injection type connection port for an IV bag, characterized in that it is made of one selected from hydrogenated SBC (styrene-butadiene block copolymer) and hydrogenated SBPS (styrene-ethylene-propylene-styrene copolymer) or a combination thereof.
The double injection type connection port for an IV fluid bag according to claim 1, wherein an inward locking protrusion (12a) protrudes from the inner wall of the connection pipe portion (12) toward the central hole (H).
delete The method of claim 1, wherein the upper connecting portion (14) is provided with a resin passage (15) through which molten resin for molding the elastic barrier cap (20) is injected into the central hole (H) during the second injection. Double injection type connection port for infusion bag.
According to claim 1, wherein a plurality of spacing supports (16) are installed along the circumferential direction between the connecting pipe portion (12) and the reinforcing peripheral wall (13) of the port body (10). Double injection type connection port.