KR20120087588A - Packing unit having syring connected filter needle and injection needle - Google Patents

Abstract

The present invention is configured by assembling the filter needle in the syringe assembly, and by separately providing a syringe needle for injecting the injection liquid to the patient to package the syringe assembly and the syringe needle in a single container, it is possible to actually inject the injection solution to the patient The present invention relates to a syringe packaging unit in which filter needles are assembled to reduce the number of replacement of filter needles and syringe needles for convenience of use, and to reduce pathogen contamination and protect patient health.
The cylinder 22 has a syringe 20 in which a piston 22 is reciprocally received, and an inlet 21a is formed at one end of the cylinder 21 so as to communicate with the inside thereof, and the cylinder inlet of the syringe 20 ( 21a), the filter needle 30 is assembled to filter the glass fragments contained in the injection liquid, and the separate syringe needle 40 together with the syringe 20 to which the filter needle 30 is assembled is a single container. It is characterized by being sealed to 50.

Description

Packing unit having syring connected filter needle and injection needle}

According to the present invention, when a glass ampoule is cut, the injection liquid in the glass ampoule is sucked with a syringe and injected into the human body. The present invention relates to packaging filter needles that can be prevented in advance. In particular, the filter needles are assembled in a syringe to form an assembly, and in addition, a syringe needle for injecting the injection liquid to the patient is provided separately. Packaged in a single container, which facilitates the use by reducing the number of replacement of the filter needle and syringe needle when the injection is actually injected into the patient, and also assembles the filter needle which can protect the health of the patient by reducing pathogen contamination. To a syringe packaging unit.

Injectable solutions are usually stored in glass ampoules or plastic containers. Among them, glass ampoules have a problem of being heavier and brittle than plastic containers. However, glass ampoules are widely used because of the advantages of chemically and stable storage of injection solutions. Plastic containers are light, unbreakable, and easy to move. There is a problem that the additive is eluted.

Therefore, in consideration of storage safety, most of the injection solution is stored and distributed in the glass ampoule. Since the glass ampoule is used by breaking the neck part during use, the minute glass fragments generated during the breakage are sucked into the glass ampoule and sucked into the syringe. There is a serious problem with use that is finally injected into the human body.

Due to these problems, the medical community recently raised suspicions that minute glass fragments generated when opening and breaking a glass ampoule are injected into the human body through a syringe needle, causing blood clots to cause fatal diseases such as myocardial infarction and stroke.

In particular, glass debris once injected into the body is not discharged again, but it moves around the blood vessels and becomes stuck in organs such as the lungs, which impedes the flow of blood. Grabbing will cause fatal side effects on the patient's health.

In fact, after dissecting an animal injected with a glass ampoule injection for a long time through an animal experiment, it has been reported that minute glass fragments were found throughout the viscera of the experimental animal.

In the KFDA research report, glass fragments mixed with glass ampoule injections were also injected into the body via intravenous injection, causing the possibility of pathological changes such as inflammatory reactions and granuloma formation in organs such as lungs, liver and spleen. In particular, the Korea Food and Drug Administration's 2004 research report pointed out that since human lung capillary diameter is 10 μm, insoluble foreign substances such as glass fragments larger than this may cause serious diseases such as pulmonary embolism.

Due to this problem, recently, glass fragments (not shown) of the glass ampule 1 are filtered by the filter needle 3 mounted on the syringe 2 as shown in FIG. 1.

The filter needle (3) is used in the state of being assembled to the opening (2a-1) of the cylinder (2a) of the syringe (2), when the glass ampoule (1) is broken open, protruding to the end of the filter needle (3) Insert the needle (3a) into the glass ampule (1), and then pull the piston (2b) of the syringe (2) to the rear to inject the injection liquid stored in the glass ampule (1) via the filter needle (3) Into the cylinder 2a. In this process, the fine glass fragments generated when the glass ampule 1 is broken are left inside the glass ampule 1, and the glass fragments pass through the filter needle 3 together with the injection solution, but the filter 3b mounted therein is provided. ) Is prevented from being injected into the syringe 2.

After removing the filter needle 3 from the syringe 2 and then insert a new syringe needle (not shown) to be injected directly into the human body in the entrance (2a-1) of the cylinder (2) and then the injection liquid is injected into the patient, The filter needle 3 prevents the glass fragments from being injected into the patient.

However, the filter needle (3) for removing the glass fragments as described above is a very beneficial invention for the patient's health protection, but due to the recent development, since it is packaged and distributed separately from the syringe (2), there are many problems in practical use. have.

That is, since the filter needle (3) is manufactured separately from the syringe (2) as shown in Figure 2, each of the syringe (2) and filter needle (3) is separate from the syringe packaging container (4) and filter needle packaging container (5) It is stored and packaged and distributed individually.

Therefore, when injecting the injection liquid stored in the glass ampoule 1 to the patient using the syringe 2 and the filter needle 3, the syringe needle 6 and the filter needle 3 as shown in FIG. ), Assembly and removal should be performed sequentially.

More specifically, the user first removes the syringe 2 from the syringe packaging container 4 of FIG. 2, and then the cap 7 is covered with the cap 7 at the entrance 2a-1 of the cylinder 2a as shown in FIG. 4A. After removing the needle 6, the filter needle 3 with the cap 8 covered as shown in FIG. 4b is assembled to the inlet 2a-1 of the cylinder 2a, and then the cap 7 is removed as shown in FIG. The filter needle 3 is assembled into 2).

Thereafter, the user breaks the neck of the glass ampule 1 to open the glass ampule 1 as shown in FIG. 4D, and then inserts the filter needle 3 assembled in the syringe 2 into the glass ampule 1 to inject the injection liquid. Is sucked into the syringe (2). At this time, the glass fragments contained in the injection liquid are filtered through the filter 3a of the filter needle 3 and thus are not supplied into the syringe 2.

Subsequently, the user removes the filter needle 3 from which the glass fragments have been filtered from the syringe 2, as shown in FIG. 4E, and then inserts the syringe needle 6 into the syringe 2, which directly injects the injection solution to the actual patient, as shown in FIG. 4F. After assembling, the cap 7 is removed as shown in FIG. 4G to complete the desired injection preparation.

As can be seen above, since the conventional syringe 2 and the filter needle 3 are separately packaged in each packaging container 4 and 5 and distributed separately, in order to supply the injection solution to the patient, FIGS. 4A to 4G. Handling was inconvenient because it had to go through a complicated process up to the step, and there was a problem that takes a long time to supply the injection to the patient.

First of all, the complicated processes from steps 4a to 4g are all manually performed, and the syringe needle 6 which directly injects the injection solution to the patient during frequent replacement of the syringe needle 6 and the filter needle 3 is applied to the pathogen. There is a high risk of infection and serious problems that directly affect the health of the patient if infected.

Accordingly, the present invention is to solve the general problems of the packaging unit, the conventional syringe and the filter needle is separately packaged as described above, the object is to assemble the filter needle in the syringe to form an assembly, injecting the injection liquid to the patient By providing separate syringe needles, these syringe assemblies and syringe needles are packed in a single container, so that the number of replacement of filter needles and syringe needles can be reduced when actual injection of the injection to the patient, and the convenience of use is also contaminated with pathogens. The present invention provides a syringe packaging unit in which filter needles are assembled to reduce and protect the health of patients.

The syringe packaging unit assembled with the filter needle according to the present invention for achieving the above object has a syringe in which the piston is reciprocally received and the outlet is formed at one end in communication with the cylinder, the entrance and exit of the syringe The filter needle is assembled to filter the glass debris contained in the injection liquid, characterized in that a separate syringe needle is sealed in one packaging container together with the syringe assembled with the filter needle.

Here, the configuration of the filter needle is a housing made of a synthetic resin material and the flow passage through the inside so that the injection can pass, the receiving portion is formed in which the entrance of the syringe is inserted into one end of the flow path;

A needle connected to the other end of the flow path of the housing in communication with the flow path; And

Includes a filter is fixed to the flow path of the housing in a heat-adhesive manner, and filters the glass fragments passing through the flow path with the injection liquid,

The heat-sealing fixing of the filter may include inserting the filter into a flow path of the housing, and then heating and melting the inner wall of the flow path in surface contact with the filter edge by heating means, such that the edge of the filter is fused to the melted portion. do.

According to the present invention configured as described above, the syringe housed in the syringe packaging container is composed of an assembly in which filter needles are assembled, so that the filter needle is inserted into the opened glass ampoule immediately and sucked the injection liquid into the syringe while the glass fragment contained in the injection liquid. After filtering with a filter, the used filter needle is removed, and then the syringe needle packaged together separately is assembled into a syringe to inject the injection solution to the patient.

Therefore, in the present invention, since the filter needle removal and the syringe needle assembly only need to be performed once each when the syringe is used, the handling according to the replacement thereof can be facilitated, and thus the convenience of use can be achieved. By drastically reducing the number of injections to the patient, the syringe needle can be prevented from being secondarily infected by frequent contact, and the replacement time of the filter needle and the syringe needle can be drastically reduced. It works.

1 is a perspective view showing a state in which the injection solution of the glass ampoule to the syringe using a syringe equipped with a filter needle
Figure 2 is a perspective view showing a state in which the conventional syringe and the filter needle is packed in each packaging container
3 is a cross-sectional view of the conventional filter needle
Figure 4 is a perspective view sequentially showing the operating state when moving the injection solution of the glass amplifier to the syringe using the syringe and the filter needle of Figure 2
Figure 5 is a perspective view of the packaging unit showing a state in which the filter needle is assembled with the syringe needle and the separate syringe needle is packaged together with the container
FIG. 6 is a perspective view sequentially illustrating an operation state of moving the injection liquid of the glass amplifier to the syringe using the syringe, filter needle and syringe needle of FIG.
7 is a view for explaining a process of fixing the filter inside the filter needle in a thermal adhesive method according to the invention

Hereinafter, with reference to the accompanying drawings will be described in detail the configuration and the method of use of the syringe packaging unit assembled filter needle according to the present invention.

In the syringe packaging unit 10 in which the filter needle 30 according to the present invention is assembled, the filter needle 30 is assembled to the cylinder entrance 21a of the syringe 20 to form an assembly form, as shown in the drawing. The syringe 20 is separately provided with a syringe needle 40 which is assembled to the entrance 21a of the syringe 20 after use of the filter needle 30 and is directly inserted into the patient's skin to supply the injection liquid. The syringe needle 20 and the syringe needle 40, to which the filter needle 30 is assembled, are housed in one packaging container 50, and are sealed.

As such, when the syringe 20 and the syringe needle 40 having the filter needle 30 assembled therein are packaged together in the packaging container 50, the syringe when the injection liquid is moved from the glass ampoule 1 to the syringe 20. Since the 20 and the filter needle 30 are used as it is, the injection liquid from which glass fragments have been removed can be simply moved into the syringe 20 without undergoing a complicated process as shown in FIG. 4.

The syringe 20 is known, and the inlet 21a is formed so that the piston 22 is reciprocally accommodated in the cylinder 21 and the one end of this cylinder 21 communicates inward. The filter needle 30 is packaged in an assembled state at the entrance 21a of the cylinder 21. The reason why the filter needle 30 is packaged in an assembled state of the entrance 21a of the cylinder 21 is that the filter needle 30 is used before the syringe needle 40. More specifically, this will be described in detail when describing the usage procedure of FIG. 6.

The filter needle 30 can be applied as long as it is assembled to the entrance 21a of the syringe 20. Generally, since the syringe 20 is standardized, virtually all filter needles 30 can be used. The end of the filter needle 30 is covered with a cap 60 to prevent the injury of the operator in the distribution process.

An embodiment of the filter needle 30 is shown in FIG. 7, wherein a filter 33 for filtering the glass ampule 1 debris on the inner flow passage 31a of the housing 31 through which the injection liquid passes is provided to the heating means. By heat fusion method.

In more detail, the filter needle 30 is made of a synthetic resin material and the flow passage 31a penetrates inside so that the injection liquid can pass therethrough, and the cylinder entrance / exit of the syringe 20 at one end of the flow passage 31a. A housing 31 in which a receiving portion into which 21a) is fitted is formed;

A needle 32 connected to the other end of the flow path of the housing 31 in communication with the flow path 31a; And

And a filter 33 fixed to the flow path 31a of the housing 31 and filtering the glass fragments passing through the flow path 31a together with the injection liquid.

Here, the thermal adhesive fixing of the filter 33 inserts the filter 33 into the flow path 31a of the housing 31 and then heats the inner wall of the flow path 31a in surface contact with the edge of the filter 33. By heating means, the edge of the filter 33 is fused to this molten portion. As the heating means, an ultrasonic wave generator 34 may be used.

The needle 32 is inserted into one end of the housing 31 and communicates with the flow path 31a. The needle 32 is inserted into the open glass ampoule 1 and functions as a suction port for sucking the injection liquid. The needle 32 may have a sufficient strength to penetrate another container, including the glass ampoule 1, and preferably a stainless material that is easily oxidized and not rusted.

The filter 33 filters the glass fragments of the glass ampule 1, and when the injection liquid is injected into the human body, the glass fragments of the glass ampoule 1 present together with the injection liquid are filtered to inject the glass fragments into the human body. It is a very important factor in preventing things from happening.

The filter 33 should be made of a material that allows the injection solution to pass through, filters the impurities including the glass fragments of the glass ampoule 1, and is supplied with ultrasonic waves to attach to the molten adhesive projection 31d. As the filter 33 used in the present invention, a membrane filter made by US Poles was used. The membrane filter is used having a mesh of 1-10 microns (μm), preferably in consideration of the size of the glass fragments of the glass ampule (1) it is preferable to use a mesh having a 3-7㎛.

A method of thermally fusion of the filter 33 on the flow path 31a of the housing 31 using the ultrasonic wave generator 34 is shown in FIG.

The filter 33 is inserted into the flow path 31a of the housing 31 to be in close contact with the adhesive protrusion 31d. In this state, the ultrasonic generator 34 installed in the opening portion of the flow path 31a of the housing 31, that is, the flange 31c is driven to supply ultrasonic waves along the edge of the filter 33 in the direction of the arrow. When the high temperature thermal energy of the ultrasonic waves passes through the filter 33 to reach the adhesive protrusion 31d, the adhesive protrusion 31d is instantaneously melted to bond the filter 33 in close contact with the adhesive protrusion 31d.

The ultrasonic wave generator 34 used in the present invention supplies heat of about 600 ° C. to the adhesive protrusion 31d in 0.5 to 1 second to melt the adhesive protrusion 31d to attach the filter 33 in a thermal fusion method. Done.

The syringe needle 40 uses a known one, and the end of the syringe needle 40 is covered with a cap 70 to prevent the injury of the operator in the distribution process.

The packaging container 50 uses a transparent one to check the inside. When the transparent packaging container 50 is used as described above, when the doctor or nurse injects the injection solution to the patient in a hospital or the like, the filter needle 30 is assembled to the syringe 20 housed in the packaging container 50. It can be seen visually that the injection solution of the glass ampoule 1 can be supplied to the syringe 20 immediately.

Next, an example of use of the syringe packaging unit 10 in which the filter needle of the present invention is assembled will be described with reference to FIG. 6.

When the packaging container 50 of FIG. 5 is removed for use of the present invention, the filter needle 30 is assembled to the cylinder entrance 21a of the syringe 20. In this state, as shown in FIG. 6A, the cap 60 covered to protect the filter needle 30 is removed. Then, as shown in FIG. 6B, the neck portion of the glass ampule 1 is broken to open the glass ampule 1 to filter the needle 30. ) Is inserted into the glass ampoule 1 to suck the injection into the syringe 20. At this time, the glass fragments contained in the injection liquid are filtered through the filter 33 of the filter needle 30 and thus are not supplied into the syringe 20.

Subsequently, the user continuously removes the filter needle 30, from which the glass fragments are filtered, from the syringe 20, as shown in FIG. 6C, and then inserts the syringe needle 40, which directly injects the injection solution into the actual patient, as shown in FIG. 6D. After fitting into the assembly, it is possible to complete the injection preparation by removing the cap 70.

According to the present invention constituted as described above, the syringe 20 and the syringe needle 40 having the filter needle 30 assembled therein are separately packaged and packaged in the packaging container 50, so that the filter needle 30 is assembled with the syringe ( 20), first, the injection solution of the glass ampoule 1 is transferred to the syringe 20, and in this process, the glass fragment is filtered, and then the syringe needle 40 is assembled to the syringe 20 to inject the injection solution to the patient. Thus, once the replacement of the filter needle 30, removal, the syringe needle 40 can be prepared by injection once assembly.

Therefore, the present invention significantly reduces the number of repetitive replacements of the filter needle 30 and the syringe needle 40 generated in the use process after removing the packaging container 50, thereby simplifying the use and convenience of using the natural law. It can be said to be an advantageous invention having the time utilization efficiency according to the injection time reduction, and the safety to prevent the secondary infection of the pathogen that can occur during the frequent replacement process of the filter needle 30 and the syringe needle (40).

10: packaging unit 20: syringe
30: filter needle 40: syringe needle
50: packaging container

Claims (3)

The cylinder 22 has a syringe 20 in which a piston 22 is reciprocally received, and an inlet 21a is formed at one end of the cylinder 21 so as to communicate with the inside thereof, and the cylinder inlet of the syringe 20 ( 21a), the filter needle 30 is assembled to filter the glass fragments contained in the injection liquid, and the separate syringe needle 40 together with the syringe 20 to which the filter needle 30 is assembled is a single container. A syringe packaging unit assembled with a filter needle, characterized in that it is sealed to (50).
The method according to claim 1, wherein the filter needle 30 is made of a synthetic resin material and the passage 31a penetrates inside so that the injection liquid can pass therethrough, and the opening 21a of the syringe 20 at one end of the passage 31a. A housing 31 into which a receiving portion into which the) is fitted is formed;
A needle (32) connected to the other end of the flow path (31a) of the housing (31) in communication with the flow path (31a); And
It is fixed to the flow path (31a) of the housing 31, the filter 33 for filtering the glass fragments passing through the flow path (31a) with the injection liquid;

Here, the heat adhesive fixing of the filter, the filter is inserted into the flow path (31a) of the housing 31 and then heat-melted the inner wall of the flow path (31a) in surface contact with the edge of the filter 33 by heating means, The syringe packaging unit assembled with the filter needle, characterized in that the rim of the filter 33 is fused to the molten portion.
3. A syringe packaging unit according to claim 1 or 2, characterized in that the filter (33) has a mesh of 1-10 microns (μm).

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