KR101485399B1 - anti-particle injector - Google Patents

Abstract

The present invention relates to a filter syringe, which comprises a cylinder (1) formed as a hollow inner space and storing a predetermined amount of injection liquid, a piston (3) vertically operated to induce suction or discharge of the injection liquid in the inner space of the cylinder, , A model body which adopts a filter (20) on a path along which the injection liquid travels so that the foreign substances in the injection liquid sucked from the needle (4) are removed in the discharging process, and a tie- And a neck portion 2 to which the neck portion 2 is applied. The first stretching member 10 is connected to one end of the neck portion 2 of the cylinder at one side, A slide packing (30) placed in communication with the filter and pierced through the discharge hole (31) up and down with respect to the inner central region for discharging the injection liquid; And a second stretching member (50) that presses the flow port and keeps the overlapping state with the discharge hole. The filter (20) is arranged between the tip of the cylinder neck portion (2) The first elastic member 10 supported by the first elastic member 10 is pressed in one direction so that the position fixing can be performed on the upper surface of the slide packing 30. [

Description

BACKGROUND OF THE INVENTION Field of the Invention [0001] The present invention relates to a position variable filter assembly by a piston stroke,

The present invention relates to a filter syringe configured to simplify a structure by improving the structure of a conventional syringe, to reduce manufacturing cost caused thereby and to maximize efficiency of operation.

More particularly, the present invention relates to a method for producing an injection solution from a vial made of a glass material ampoule or other rubber material due to the improvement of the filtering-related structure, It is possible to stably provide an injection solution in which insoluble substances such as glass fragments and rubber fragments are not incorporated when administered to a human body, and furthermore, it is possible to provide an injection solution sucking the injection solution while inducing the injection solution only in a section excluding the filtering region The present invention relates to a position variable filter assembly using a piston stroke in which foreign matter contained in an injection solution is discharged in a completely filtered state by smoothly sucking an injection liquid by inducing the injection fluid to be discharged only to the filtering region, and a filter syringe using the same .

Generally, a syringe includes a cylindrical cylinder having a space formed therein for storing an injection liquid therein, a piston for sucking or discharging the injection liquid while moving back and forth in a chamber formed inside the cylinder, And a needle coupled to the tip of the needle holder.

In using such a conventional syringe, an upper portion of an ampoule containing an injection liquid is broken, the injection needle is drawn into the opened portion, and the piston is retracted so that the injection liquid in the ampoule is sucked into the cylinder, When the patient is pushed into the affected part and the piston is advanced, the injection fluid in the cylinder is injected into the patient through the injection needle.

However, when the upper portion of the ampoule is opened in the process of inhalation of the injection liquid as described above, the glass fragments are scattered and a part of the glass fragments is introduced into the ampoule. The glass fragments introduced into the ampoule are mixed with the injection liquid, And thus can have a catastrophic adverse effect on the patient.

This is due to the KFDA's 2004 'Safety Measures for the Contamination of Glass Particles in the Use of Ampoule Injection', 'Analysis of the Economic Impact of Safe Use of Containment Containers in 2009', published in September 2010 The guidelines for safe use of injectable products indicate that glass ampoules in injectable containers can detect glass fragments of up to 870 μm (0.001 mm) in size when blended with glass powder when opened. Considering that the diameter of the blood vessel is the smallest among the blood vessels in the human body and its diameter is about 10 μm, the risk of glass fragments of a maximum 870 μm size detected in the KFDA research service should not be overlooked. The glass fragments travel around the blood vessels and cause tissue necrosis, lung granuloma, phlebitis and thrombosis. Particularly, since the glass fragments injected through the vertebral injection may penetrate into the brain through the vertebrae, the KFDA recommends that children and elderly people use a glass ampule injector at each medical institution and use a syringe with a filter .

In order to solve such a problem, for example, in Korean Patent Registration No. 10-981586, before injecting an injection liquid into a syringe, a filter tip having a filter inside the syringe is inserted into the neck portion of the cylinder, Whereby the glass fragments contained in the injection liquid are pre-filtered by the filter.

However, in the above-mentioned prior art, when the injection liquid is sucked into the syringe, the filter tip is inserted. When injecting the injection liquid of the syringe into the patient, the filter tip is removed and a new syringe tip is connected to the syringe Therefore, the process of sucking and injecting the injectate is troublesome and the suction of the injectate is not smoothly performed due to the filter pressure applied by the filter in the process of sucking the injectate into the syringe, which is not efficient in use. It is pointed out that the manufacturing cost is increased due to the production.

Although the use of the syringe with the filter can prevent the inclusion of the glass fragments, the sterilizer has a problem of inconvenience in use and is not commercialized due to another reason that the cost is more than four times that of the conventional syringe. .

The present invention has been made in order to more positively solve the above problems, and it is an object of the present invention to provide a medical device, which is produced by injecting glass fragments or rubber debris, which are produced through respective inhalation processes in ampules and vials, It is an object to be solved to provide an associated assembly that allows filtering to be carried out in a more improved manner using pressure differences due to piston strokes so that they are not to be administered to the patient.

In addition, since all the components related to the filtering are simplified, it is possible to prevent the incorporation of the insoluble matter completely at the lowest cost as well as the ease of assembly by giving the injection route of the injection liquid and the injection route of the injection solution differently in one model Another challenge is to make it possible.

In particular, it is another challenge to provide an associated structure so that the filtering of the injection liquid can be actively operated without fixing all the components of the filtering assembly including the filter by separate bonding means.

In order to accomplish the above object, there is provided a position variable filter assembly using a piston stroke and a filter syringe using the same,

The position variable filter assembly of the present invention comprises: a first stretching member (10) provided with an elastic force from a cylinder neck portion (2); A filter (20) for filtering foreign matter mixed in the injection liquid; A slide packing 30 in which the discharge hole 31 is vertically penetrated; A flow port (40) for controlling the flow of the injection liquid; The injected liquid injected through the needle 4 according to whether or not the piston 3 is moved moves along the outer side of the slide packing 30 by the second elastic member 50 provided with the elastic force, The injected liquid in the cylinder interior space is introduced into the discharge hole 31 of the slide packing through the filter 20 while being injected into the cylinder body 1 through the gap between the flow passage 40 and the outside of the model body To be discharged.

Meanwhile, the filter syringe using the position variable filter assembly includes a cylinder 1 formed as a hollow inner space and storing a predetermined amount of injected liquid, a piston 3 vertically operated to induce suction or discharge of the injected liquid from the inner space of the cylinder , A model body which adopts a filter (20) on a path through which the injection liquid travels so that the foreign substances in the injection liquid sucked from the needle (4) are removed in the discharging process, A first elastic member (10) having one end connected to the tip end of the neck portion (2) of the cylinder, and a neck portion (2) A slide packing (30) arranged in a manner to be connected to the filter and pierced through the discharge hole (31) up and down with respect to the inner central region for discharging the injection liquid; And a second stretching member (50) that presses the flow port so as to maintain the superposition state with the discharge hole, and the filter (20) is arranged in the cylinder neck The first elastic member 10 supported at the tip of the part 2 is unidirectionally pressed so that the positional fixation can be performed on the upper surface of the slide packing 30. [

In addition, the model body includes a needle holder 100 integrally coupled with a needle 4 for sucking or discharging an injection liquid.

In addition, the model body includes a connector 200 for guiding interlocking engagement with the needle holder 100 to which the needle 4 is coupled.

The first space unit 110 may include a first space unit 110 and a second space unit 120. The first space unit 110 may have a narrower inner space than the second space unit 120, And the second elastic member 50 and the flow port 40 are stacked from the bottom of the first space part 120 and the filter 20 and the first and second elastic members 50 and 40 are disposed in the second space part 120 from the slide packing 30, The first and second elastic members 50 and 50 are formed in the same manner as the first and second elastic members 50 and 50. The elastic members 10 are sequentially stacked, Is formed to have an expanded diameter relative to each of the inner slide packing (30), the filter (20) and the first elastic member (10).

The slide packing 30 is formed to have a diameter larger than that of the first space 110 and abuts against the first space 110 having a tapered shape in a boundary region between the second space 120 and the first space 110. [ So that the first space portion and the second space portion can be completely blocked from each other by the slide packing and the flow port (40).

As the contraction of the first elastic member 10 and the tension of the second elastic member 50 are simultaneously induced due to the pressure change caused by the synergistic action of the piston 3, the slide packing 30 is moved upward and downward The discharge hole 31 is blocked by the filter 20 and the flow port 40 so that the discharge hole 31 is moved upward in the collective upward direction, The gap between the slide packing and the second space portion is provided by causing the slide packing 30 to rise, and the injection liquid is sucked into the cylinder 1 through the gap.

As the second elastic member 50 is contracted due to the pressure change caused by the lowering action of the piston 3, the filter 20 is pressed from the upper end of the discharge hole 31, While the flow port 40 is moved downward by the contraction of the second elastic member to open the lower portion of the discharge hole 31 as the flow port is spaced apart from the slide packing so as to be stored in the cylinder 1 The injection liquid is guided to the discharge hole through the filter 20, and is discharged to the outside of the model body through the gap with the flow port 40.

In addition, the model body may further include a detachable type barrier membrane in an inner space formed by hollowing.

The fixing grooves 2a and 100a for accommodating one side of the first stretching member 10 and the second stretching member 50 are roundly formed on the end portion of the cylinder neck portion 2 and the inner bottom surface of the model body, .

Further, a fixing groove 30a is further provided on the upper surface of the slide packing 30 so that the filter 20 can be received and accommodated.

According to the present invention having the above-described constitution, when an injectable solution is administered from a vial made of a glass-made injection solution ampoule or other rubber material and administered to a human body, insoluble matter such as glass fragments or rubber fragments Since the filter is provided in a state in which it is not mixed with the injection liquid, safety can be ensured and the suction and discharge paths are separately provided in one space, so that the filtering function is further maximized as compared with the conventional structure.

Further, by inducing the filtration to be performed in a more improved manner by using the pressure difference due to the piston stroke, all the components of the filtering assembly related thereto are remarkably simplified, Since the structure of the filtering assembly including the filter can be operated without any problem even when the components are not fixed by the separate joining means, it is possible to omit the ultrasonic bonding process or microfabrication process such as bonding as usual, It is possible to completely prevent the inclusion of the insoluble matter even at a minimum cost.

In addition, the filtering assembly of the present invention is a simplified structure that can be applied to a needle holder integrally connected to an inhalation or an outlet for injecting an injection liquid or to a conventional connector for guiding mutual fixed engagement of a syringe and a needle holder , There is an advantage that it can be selectively used according to the situation, so that it can be used more widely.

1 is a perspective view of a filter syringe according to a preferred embodiment of the present invention;
Fig. 2 is an exploded perspective view of the filtering assembly, which is shown in detail from the main part of Fig. 1; Fig.
Fig. 3 is an exemplary sectional view of the filtering assembly showing the coupling relationship of Fig. 1 in detail. Fig.
Figure 4 illustrates an example of the operation of a filtering assembly upon switching to a suction process in the state of Figure 3;
Fig. 5 is an example of the operation of the filtering assembly in switching from the state of Fig. 3 to the discharge process; Fig.
6 is a perspective view of a filter syringe constructed in accordance with another embodiment of the present invention.
FIG. 7 is an exploded perspective view of the filtering assembly, detailing the main part of FIG. 6; FIG.
FIG. 8 is an exemplary cross-sectional view of a filtering assembly showing the coupling relationship of FIG. 6 in detail. FIG.
Fig. 9 is an example of the operation of the filtering assembly in switching from the state of Fig. 8 to the suction process; Fig.
Figure 10 is an example of the operation of a filtering assembly upon switching to a discharge process in the state of Figure 8;

The present invention relates to a method for obtaining an injection solution from a vial made of an ampule of a glass material or a rubber material and injecting the injection solution in a state in which insoluble substances such as glass fragments and rubber fragments are not mixed, Lt; RTI ID = 0.0 > syringe. ≪ / RTI >

BRIEF DESCRIPTION OF THE DRAWINGS The above and other objects, features and advantages of the present invention will be more apparent from the following detailed description taken in conjunction with the accompanying drawings, in which: FIG.

In addition, advantages and features of the present invention and methods of achieving them will be apparent from and elucidated with reference to the embodiments described hereinafter in detail with reference to the accompanying drawings. However, it is to be understood that the present invention is not limited to the disclosed embodiments, but may be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. It is intended that the disclosure of the present invention be limited only by the terms of the appended claims. And, throughout the specification, like reference numerals refer to like elements.

FIG. 1 is a perspective view of a filter syringe according to a preferred embodiment of the present invention. FIG. 2 is an exploded perspective view of a filtering assembly taken in detail from FIG. 1, Fig.

The filter syringe of the present invention is characterized in that the filtering function is strengthened by improving the assemblability and workability and improving the filtering related structure through minimizing all the components as in the drawing. For this purpose, when the inhaled injection liquid is discharged while sucking the injection liquid by only the section except the filtering region, it is guided to discharge only the injection liquid to the filtering region only, so that the foreign substance contained in the injection liquid is completely filtered And a filter syringe using the position variable filter assembly.

Generally, in order to fill the inner space of the cylinder, the tip of the needle is inserted into the injection liquid filled in the ampoule or the vial to fill the injection liquid through the suction force due to the rise of the piston. In the process of breaking the tip of the ampoule, Fine glass powder or rubber debris is inevitably settled in the injection solution. In this case, fine glass powder or rubber debris deposited may be injected into the inner space of the cylinder together with the injection solution, The present invention proposes a filter syringe having a structure that can be utilized not only as a needle integrated type but also as a connector type while the filtering function is improved as well as the related structure is simplified compared with the related art.

The filtering assembly according to the present invention comprises a plurality of elastic members 10, 50, a filter 20, a slide packing 30, And a flow port 40, and it is preferable that the components thereof are interposed in one model body.

Specifically, a first elastic member (10) provided with an elastic force from a cylinder neck portion (2) as a starting point; A filter (20) for filtering foreign matter mixed in the injection liquid; A slide packing 30 in which the discharge hole 31 is vertically penetrated; A flow port (40) for controlling the flow of the injection liquid; The injected liquid injected through the needle 4 according to whether or not the piston 3 is moved moves along the outer side of the slide packing 30 by the second elastic member 50 provided with the elastic force, The injected liquid in the cylinder interior space is introduced into the discharge hole 31 of the slide packing through the filter 20 while being injected into the cylinder body 1 through the gap between the flow passage 40 and the outside of the model body Gt; filtering < / RTI > assembly.

The model assembly in which the filtering assembly is interposed is a needle holder 100 integrally coupled with a needle 4 for sucking or discharging an injection solution or a needle holder 100 having a needle 4 attached thereto And may be a conventional connector 200 employed in the space between the needle holder and the neck portion to induce fixed engagement.

FIG. 4 is an exemplary operational view of the filtering assembly in the transition from the state of FIG. 3 to the inhalation process, and FIG. 5 is an exemplary operational view of the filtering assembly in the transition from the state of FIG. 3 to the evacuation process.

As shown in FIGS. 4 to 5, the filter syringe using the position variable filter assembly of the present invention includes a cylinder 1 formed as a hollow inner space and storing a predetermined amount of injected liquid, A piston 3 which is vertically operated to induce the discharge and a filter 20 on the path through which the injection liquid travels so as to allow the foreign substances of the injection liquid sucked from the needle 4 to be removed in the discharge process, And a neck portion 2 which is tapered at its tip end and is engaged with the model body. Particularly, in the above-mentioned model body, a first stretching member 10 (one end of the neck portion 2) A filter 20 disposed in communication with the other end of the first elastic member 20, and a filter 20 disposed adjacent to the filter and pierced through the discharge hole 31 with respect to the inner central region for discharging the injection liquid, And a second stretching member (50) for pressing the flow port to maintain the overlapping state with the discharge hole, wherein the slide member (30) And is sequentially intervened.

At this time, the filter 20 is configured to be positionally fixed on the upper surface of the slide packing 30 as it is pressed in one direction by the first stretching member 10 supported at the tip of the cylinder neck portion 2 .

Such a structure can actively operate the filtering of the injection liquid without fixing all the components of the filtering assembly including the filter by separate joining means, so that it is possible to omit the ultrasound, As a result, workability and efficiency can be maximized, so that the inclusion of insoluble matter can be completely prevented even at a minimum cost.

In addition, as described above, the model body of the present invention not only includes the needle holder 100 integrally connected to the needle 4 for sucking or discharging the injectable solution, but also includes the needle holder (needle holder) 100 of the present invention. The accompanying drawings are described in detail with reference to Figs. 6 to 10 below.

The model body may include a first space unit 110 and a second space unit 120.

The first space portion 110 is formed to have a narrower internal space than the second space portion 120 and the second stretching member 50 and the flow port 40 are stacked from the lower end, (20) and a first elastic member (10) are sequentially stacked from a slide packing (30) connected to a flow port in the first space part (120), and the first space part (110) And the second space portion 120 is formed to have an expanded diameter as compared with the inner slide packing 30 and the filter 20 and the first elastic member 10 respectively .

As shown in FIG. 3, the slide packing 30 is formed to have a larger diameter than the first space 110, and the first space 110 and the second space 120, which are tapered, So that the first space portion and the second space portion can be completely blocked by the slide packing and the flow port (40).

3, the slide packing 30 is configured such that the pressure of the slide 3 due to the upward movement of the piston 3 causes the first and second elastic members 31, As the shrinkage of the first elastic member 10 and the tension of the second elastic member 50 are simultaneously induced, the discharge hole 31 is upwardly moved by the filter 20 and the flow hole 40, The gap between the slide packing and the second space is provided by causing the slide packing 30 to be lifted in a state of being mounted in the boundary area between the space part 110 and the second space part 120, So that the injection liquid is sucked into the cylinder 1. In the figure, a large arrow indicates that the position of all components due to the rise of the piston is adjusted upward, and a small arrow shows the direction of suction flow of the injected liquid.

3, the slide packing 30 is moved in the direction of the second piston 3 in the second direction due to the pressure change due to the lowering action of the piston 3, As the shrinkage of the elastic member 50 is induced, the filter 20 is kept pressed at the upper end of the discharge hole 31, while the flow hole 40 is moved downward by the contraction of the second elastic member, The injected liquid stored in the cylinder 1 is guided to the discharge hole through the filter 20 and discharged to the outside of the model body through the gap between the discharge hole 31 and the flow port 40. [ To be discharged. In the figure, a large arrow indicates that the flow port due to the descent of the piston and the position of the second elastic member are adjusted downward, and the small arrow shows the discharge flow direction of the injected liquid.

6 is a perspective view of a filter syringe constructed in accordance with another embodiment of the present invention, FIG. 7 is an exploded perspective view of a filter assembly taken in detail from an excerpt of FIG. 6, and FIG. 1 is a cross-sectional illustration of a filtering assembly.

As shown in Figs. 6 to 8, the filtering assembly of the present invention is integrally formed in a connector and is universally usable. The detailed configuration in this respect is the same as that of the above-described embodiment, and thus will not be described.

However, in order to apply the filtering assembly of the present invention to the needle holder, the needle for sucking or discharging the injection fluid may be applied to the needle holder integrally coupled to the needle holder, In order to emphasize the characteristic of a simplified structure that can be applied to all the conventional connectors for providing the advantages of the present invention.

Fig. 9 is an operational example of the filtering assembly in the state of Fig. 8 when switching to the inhalation process, and Fig. 10 is an operational example of the filtering assembly in switching from the state of Fig. 8 to the discharging process.

9 to 10 In addition, as shown in Fig. 9, in the same manner as in Figs. 4 to 5 of the above-described embodiment, the slide packing 30 is moved in the direction of the pressure change due to the synergistic action of the piston 3 The contraction of the first elastic member 10 and the tension of the second elastic member 50 are concurrently induced so that the discharge hole 31 is blocked by the filter 20 and the flow hole 40 in the vertical direction The slide packing 30 is lifted in a state of being held in a boundary area between the first space part 110 and the second space part 120 so that the slide packing 30 is lifted up to the space between the slide packing and the second space part. A gap may be provided and the injection liquid may be sucked into the cylinder 1 through the gap. 10, as the second elastic member 50 is shrunk due to the pressure change caused by the lowering action of the piston 3, the filter 20 is discharged to the discharge hole 31 While the flow port 40 is moved downward by the contraction of the second elastic member to open the lower portion of the discharge hole 31 as the flow port is spaced apart from the slide packing, The injection liquid stored in the injection port 1 is guided to the discharge hole through the filter 20 and discharged to the outside of the model body through the gap with the flow port 40.

Likewise, the large arrows in Fig. 9 show that the position of all components due to the rise of the piston is upwardly adjusted, while the small arrows show the suction flow direction of the injection liquid, while the large arrows in Fig. The position of the flow port and the position of the second elastic member due to the descent of the piston is adjusted downward, and the small arrow shows the discharge flow direction of the injected liquid.

In addition, although not shown in the drawing, the model body of the present invention may further include a detachable type barrier membrane in an inner space punched in the hollow. This is because, in order to protect the components housed inside the model body before assembly with the cylinder neck portion from being detached from the outside, the barrier film may be a thin film made of a normal film material, And may be attached on the upper end of the model body or may be attached to the inner space of the model body so as to be recessed.

In addition, fixing grooves (2a, 100a) for accommodating one side of the first stretching member (10) and the second stretching member (50) are roundly formed on the end portion of the cylinder neck portion (2) And another fixing groove 30a may be further provided on the upper surface of the slide packing 30 so that the filter 20 can be received and accommodated. This structure also enhances the cohesion strength between the components, so that the components housed inside the model body before the mutual assembly with the cylinder neck portion are protected from being detached from the outside, while being provided for easier workability during assembling.

According to the present invention, which is implemented with the above-described structure, when an injectable solution is obtained from a vial made of a glass-made injection solution ampoule or other rubber material and administered to a human body, insoluble substances such as glass fragments and rubber fragments Is provided in a state in which it is not mixed with the injection liquid, safety can be ensured, and the suction and discharge paths are separately provided in one space, so that the filtering function is further maximized as compared with the conventional structure.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, Should be clarified. Therefore, it is intended that the present invention cover the modifications and variations of this invention provided they come within the scope of the appended claims and their equivalents.

1. Cylinder 2. Neck part
2a. Fixing groove 3. Piston
4. Needle 10. First elastic member
20. Filter 30. Slide packing
30a. Fixing groove 31. Discharge hole
40. Flowing port 50. Second elastic member
100. Needle holder 100a. Fixing groove
110. First space part 120. Second space part
200. Connector

Claims (11)

A first stretching member (10) provided with an elastic force from a cylinder neck portion (2) as a starting point; A filter (20) for filtering foreign matter mixed in the injection liquid; A slide packing 30 in which the discharge hole 31 is vertically penetrated; A flow port (40) for controlling the flow of the injection liquid; The injected liquid injected through the needle 4 according to whether or not the piston 3 is moved moves along the outer side of the slide packing 30 by the second elastic member 50 provided with the elastic force, The injected liquid in the cylinder interior space is introduced into the discharge hole 31 of the slide packing through the filter 20 while being injected into the cylinder body 1 through the gap between the flow passage 40 and the outside of the model body Characterized in that the syringe is a syringe.
A cylinder 1 formed as a hollow inner space and storing a predetermined amount of injected liquid; a piston 3 vertically operated to induce suction or discharge of the injected liquid from the inner space of the cylinder; And a neck portion 2 which is provided in a tapered shape at the tip of the cylinder so as to be engaged with the model body to be engaged with the body portion, In the filter syringe configured,
A first elastic member (10) having one side connected to one end of a neck portion (2) of the cylinder; a filter (20) disposed in connection with the other side of the first elastic member; A slide packing (30) in which a discharge hole (31) is perforated vertically through the inner central region for discharging the injection liquid; a flow hole (40) overlapping or spaced from the discharge hole of the slide packing; And the filter 20 includes a first elastic member 10 supported at the tip of the cylinder neck portion 2 as a starting point, and the second elastic member 50, So that the positional fixation can be achieved at the top surface of the slide packing (30).
3. The method according to claim 1 or 2,
Wherein the model body is a needle holder (100) integrally coupled with a needle (4) for sucking or discharging an injection liquid.
3. The method according to claim 1 or 2,
Wherein the model body is a connector (200) for guiding interlocking engagement with a needle holder (100) having a needle (4) attached thereto.
3. The method according to claim 1 or 2,
The first space unit 110 includes a first space unit 110 and a second space unit 120. The first space unit 110 has a smaller inner space than the second space unit 120, The second elastic member 50 and the flow port 40 are stacked from the lower end and the slide 20 is connected to the filter 20 through the slide packing 30, The first space portion 110 is formed to have an expanded diameter or the same diameter as that of the second elastic member 50 inserted therein and the second space portion 120 is formed to have an inner diameter Is formed with an expanded diameter relative to each of the slide packing (30), the filter (20) and the first elastic member (10).
6. The method of claim 5,
The slide packing 30 is formed to have a diameter larger than that of the first space 110 and abuts on the boundary region between the first space 110 and the second space 120, So that the first space portion and the second space portion can be completely blocked from each other by the slide packing and the flow port (40).
6. The method of claim 5,
The slide packing 30 is moved upward and downward as the shrinkage of the first elastic member 10 and the tension of the second elastic member 50 are simultaneously induced due to the pressure change due to the upward action of the piston 3, 20 and the flow hole 40 are upwardly moved in a state in which the discharge hole 31 is blocked so that the slide packing (the slide packing) in the state of being mounted in the boundary area between the first space part 110 and the second space part 120 Wherein the gap between the slide packing and the second space is provided to allow the injection liquid to be sucked into the cylinder through the gap. 2. The filter syringe according to claim 1,
6. The method of claim 5,
The slide 20 is retracted from the upper end of the discharge hole 31 as the second elastic member 50 is contracted due to the pressure change due to the lowering action of the piston 3, While the flow port 40 is moved downward due to the contraction of the second elastic member and the flow port is spaced apart from the slide packing so that the lower part of the discharge hole 31 is opened so that the injection liquid stored in the cylinder 1 And the filter syringe is guided to the discharge hole through the filter (20), and is discharged to the outside of the model body through a gap between the filter syringe and the flow hole (40).
3. The method according to claim 1 or 2,
Wherein the model body further includes a detachable type barrier membrane in an inner space formed by hollowing the filter body.
3. The method according to claim 1 or 2,
Fixing grooves 2a and 100a for accommodating one side of the first stretching member 10 and the second stretching member 50 are formed in a round shape on the end portion of the cylinder neck portion 2 and the inner bottom surface of the model body, respectively A filter syringe using a positionally variable filtering assembly.
3. The method according to claim 1 or 2,
And a fixing groove (30a) is further provided on the upper surface of the slide packing (30) so that the filter (20) can be received and accommodated.

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