KR102160304B1 - Filter for Medical Infusion Line and Manufacturing Method Thereof - Google Patents

Abstract

The present invention is applied to an infusion line used for a patient who cannot eat food or needs additional treatment while injecting an infusion solution into a patient or needs an emergency without consciousness. Or, in the case of additional injection of antibiotics, foreign substances contained in the injection solution are filtered out by an ampoule, etc., so that only the necessary fluid can be injected.

Description

Filter for Medical Infusion Line and Manufacturing Method Thereof}

The present invention is applied to an infusion line used for a patient who cannot eat food or needs additional treatment while injecting an infusion solution into a patient or needs an emergency without consciousness. Or, in the case of additional injection of antibiotics, foreign substances contained in the injection solution are filtered out by an ampoule, etc., so that only the necessary fluid can be injected.

In the case of receiving infusion at the current hospital, the infusion bottle is placed at a certain height and the injection is made into the blood vessel using the potential energy of the infusion solution.In this case, the manufacturer's carelessness or additionally injected antibiotics are collected from the ampoule. In the case of injection, glass powder or foreign matter generated while the ampoule is cut is injected through an injection needle, causing a fatal risk to the patient and causing a medical accident.

Therefore, a method to remove foreign substances by attaching a filter to such an infusion line has been proposed, but it is difficult to filter by only the potential energy of the infusion bottle and to develop a filter to obtain the desired filtration amount, or such a filter can be removed up to 5μ. While there was considerable difficulty in obtaining the desired injection amount of the infusion solution, there were practically many difficulties in using the filter.

To this end, in the present invention, it is possible to remove up to 5μ and to smooth the flow of the injection solution, as well as to provide ease of manufacture and convenience of use.

To this end, the filter can be removed up to 5μ while increasing the filtration area, and in order to provide ease of flow, the filter has the shape of a cap and the structure of the filter is made to form a coating layer that allows beads of a certain diameter to adhere to the surface. Then, by bonding them to each other by pressurization, it is possible to remove foreign substances of a certain size by the space between the beads and the beads, and by installing such a filter in a packing with excellent airtightness, and then pressing the packing to the chamber. The sap was allowed to drain only through the filter.

Therefore, with a simple assembly structure, the size of foreign substances can be removed up to 5 μ, and filtering can be performed only with potential energy, and the desired amount of fluid can be injected.

1 is a schematic diagram showing a state of use of the present invention.
2 is a cross-sectional view showing the structure of a filter chamber equipped with a filter of the present invention.
Figure 3 is a cross-sectional view of the separated state of Figure 2;
4 is an enlarged view showing a detailed structure of the filter of the present invention.
5 is a process block diagram for manufacturing the filter of the present invention

Hereinafter, the present invention will be described in detail based on the accompanying drawings.

As shown in Figs. 1 to 3, the structure of the present invention is provided with an inlet 11 and a discharge port 12 through which sap is injected by potential energy in an infusion bottle 100 positioned at a certain height. It consists of a chamber 10 having a space 13, and a filter 30 is mounted in the inner space 13 of the chamber 10.

The filter 30 prevents the flowability of the filter 30 and facilitates assembly of the filter in the chamber, while the filter 30 is not floated by the sap and is easy to flow with a smooth sap volume without resistance. In the inner space 13 of the, a support frame 14 of a certain area is formed on the outside where the sap discharge port 12 is formed, and the support frame 14 is in close contact with the inner wall 15 of the chamber 10 A packing (20) having a through hole (21) is mounted in the center of the packing (20), and a filter (30) that closely adheres to the through hole (21) penetrated into the center of the packing (20) is mounted. Configuration.

At this time, the filter 30 is formed by forming a cap that protrudes upward from the inner space 13 in which the filter of the chamber 10 is mounted in a state of being combined with the filter, so that the fluid falling through the inlet 11 comes into contact. By increasing the area, the desired amount of fluid can be injected without resistance.

When the filter 30 is mounted on the packing 20, in order to prevent the sap from leaking without passing through the filter, a stepped frame 22 is formed outside the through hole 21 of the packing 20, and the While the cut surface 31 of the filter 30 is in close contact with the stepped frame 22, the outer wall 32 of the filter 30 is in close contact with the inner wall 23 formed on the upper side of the stepped frame of the opening hole 21. It was so.

The packing 20 in the present invention is made of a material that is harmless to the human body, and a silicone having excellent chemical resistance as well as tensile resistance and elasticity is used, and this material does not limit the object of the present invention.

In addition, the chamber 10 is divided into equal parts for assembly of the packing 20 and the filter 30 as shown in FIG. 3, and the adhesive frame 16 is first pinched by the adhesive border 16. It is to remove the harm to the human body by not using a separate adhesive when bonding by using ultrasonic waves to the outside.

In addition, in the present invention, the inlet 11 of the chamber 10 is formed so that the inner diameter into which the sap enters is smaller than the outer diameter of the filter 30 formed in a cap shape, so that when the sap falls, the cap portion 33 of the filter 30 ) To increase the amount of filtration by allowing it to fall directly on, and the discharge port 12 of the chamber 10 is made to be the same as the inner diameter of the filter 30 to facilitate the discharge flow.

In addition, in order to prevent a gap between the packing 20 coupled to the inner wall 15 of the chamber 10 due to a change in temperature or by a shape change of the chamber 10 due to various conditions, the chamber 10 ) To prevent deformation by forming a reinforcing rib 17 at the portion where the discharge port 12 and the injection port 11 are formed.

In addition, even when the fluid lines 110 and 120 are connected to the injection port 11 and the discharge port 12 by the reinforcing rib 17, deformation of the shape does not occur, and assembly is also facilitated.

In addition, the degree to which the filter 30 is mounted on the packing 20 is made so that at least 1/3 of the length of the filter 30 formed in the shape of a cap is combined with the inner wall 23 of the packing 20, thereby improving the bonding force. If such a combination is less than 1/4, a problem of being separated by shaking of the infusion line 110.120, etc., which occurs when using the infusion line 110, 120, etc., occurs, which causes the use of it.

In addition, since the structure of the filter 30 is formed in a cap shape, in order to solve the problem of not being able to maintain a uniform state in the size of the mesh when a mesh is used, a stainless powder having a large number of pores is used as a basic material. For the abrasion of the mold while preventing oxidation and moisture absorption in the pores, the mixture containing paraffin and zinc stearate (Zn-St) and kneaded are pressed with a press using a mold and formed into a cap-shaped filter 30 It is done.

At this time, the stainless powder is pressed against each other by the pores by the pressing force to form a cap shape, while maintaining a constant pore by controlling the degree of pressure.

After that, the filter 30 formed in the shape of a molded cap is put into a vacuum furnace and heated while continuously maintaining the vacuum with a vacuum pump to remove when the paraffin containing stearic acid is vaporized.

In the present invention, it was confirmed that oxidation by oxygen was prevented by adopting a heating method by a heater rather than a combustion method requiring oxygen, and this heating temperature was confirmed to be complete vaporization by heating in the range of 350 to 550°C. The generated gas is removed by continuously operating the vacuum pump.

After that, the cap-shaped filter, which has been evaporated, was sintered under the melting point of the stainless steel.

When heated to the melting point, the pores disappear and the filter loses its function.

In the present invention, it was confirmed that it is possible to provide a filter having desired pores by heating to a range of 1100 to 1300°C.

This heating time is also necessary to maintain the shape of the pores, but in the present invention, it was confirmed that the pores were maintained when heated within the range of 15 to 60 minutes.

After that, natural cooling is performed for cooling, and forced cooling is possible by injecting cooling gas for forced cooling. Although argon gas with good purity was used in the present invention, the same effect can be obtained when nitrogen gas is used. There is.

Therefore, pores are formed in the filter 30 in the molded state, and the sap flows through these pores.

The pores of the stainless powder used in the present invention are manufactured by a separate order or purchased and used.

10: chamber 11: injection port
12: discharge port 13: inner space
14: support frame 15: inner wall of the chamber
16: adhesive frame 17: reinforcing rib
20: packing 21: opening hole
22: stepped frame 23: inner wall of the opening hole
30: filter 31: cut surface
32: outer wall of the filter 33: cap portion

Claims (11)

In the infusion bottle 100, consisting of a chamber 10 having an inner space 13 provided with an injection port 11 and a discharge port 12 through which the solution is injected by potential energy,
In the inner space 13 of the chamber 10, a support frame 14 formed with a predetermined area outside the discharge port 12, and
The packing 20 is provided with a through opening hole 21 having the same inner diameter as the discharge port of the chamber 10 while being supported by the support frame 14, and in close contact with the inner wall 15 of the chamber,
In the center of the packing 20, a stepped frame 22 is formed to the outside with an opening hole 21 penetrating therethrough, and a cut surface 31 of the filter 30 of the cap portion 33 is formed on the stepped frame 22. At least 1/3 of the bottom of the outer wall 32 of the filter 30 is in close contact with the inner wall 23 of the opening hole 21 of the packing while making it close,
The inlet 11 of the chamber 10 is formed so that the inner diameter through which the sap enters is smaller than the outer diameter of the cap portion 33 of the filter 30 having a cap shape, and the outlet 12 of the chamber 10 is a filter ( By making it the same as the inner diameter of 30)
A filter for an infusion line used for medical purposes, characterized in that it facilitates the discharge flow while filtering foreign substances and prevents the filter from being separated by the shaking of the infusion line 110.120 generated during use. delete delete delete delete delete In the infusion bottle 100, a support frame 14 formed outside the chamber 10 having an inner space 13 provided with an injection port 11 and a discharge port 12 through which the solution is injected by potential energy, and the The packing 20 is provided with a through opening hole 21 having the same inner diameter as the discharge port of the chamber 10 while being supported by the support frame 14, and in close contact with the inner wall 15 of the chamber, and the packing 20 A stepped frame 22 is formed in the center of the through hole 21, and the cut surface 31 of the filter 30 of the cap 33 is in close contact with the stepped frame 22. At the lower end of the outer wall 32 of 30, at least 1/3 is in close contact with the inner wall 23 of the opening hole 21 of the packing, and the inlet 11 of the chamber 10 has an inner diameter into which the sap enters. It is formed to be smaller than the outer diameter of the cap portion 33 of the filter 30 having a shape, and the discharge port 12 of the chamber 10 is the same as the inner diameter of the filter 30 to facilitate the discharge flow while filtering foreign substances. Of course, in that the filter is not separated by the shaking of the infusion line (110.120),
The filter is made of stainless powder having a number of pores as a basic material, and is kneaded with paraffin and zinc stearate (Zn-St) for wear of the mold while preventing oxidation and moisture absorption in the pores. The first step of forming into a cap-shaped filter by pressing with a press using a mold and
When a filter in the shape of a cap molded by the first step is inserted into a vacuum furnace and heated while continuously maintaining the vacuum with a vacuum pump, a heating method by a heater is adopted instead of a combustion method requiring oxygen. In order to prevent oxidation by the second process and heating the heating temperature in the range of 350 ~ 550 ℃ and
A third step of removing the paraffin containing stearic acid heated by the second step by vacuum when vaporized,
The fourth step of heating the second step by raising the temperature in a state where the vacuum is maintained while the vaporized one is removed in the third step
In the fourth process, the secondary heating is heated to a range of 1100 to 1300°C and heated within a range of 15 to 60 minutes, so that natural cooling is based on a sintered state with a filter having the desired pores. Manufacturing method of filter for infusion line used for medical purposes, manufactured by the fifth process of cooling using good argon gas or nitrogen gas
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