KR20200049360A - A syringe for mixing and dispensing a different drugs - Google Patents

Abstract

The present invention relates to a syringe for mixing and dispensing different types of drugs, which comprises a first receptor having one end and the other end open, having an empty inside, and having a piston formed at the other end; a second receptor formed at the one end of the first receptor to accommodate powdery drug therein, and having a top and a bottom open; and a mixing unit formed in the first receptor and the second receptor, and mixing distilled water with the powdery drug when the distilled water is sucked into the first receptor through the second receptor by a piston.

Description

A syringe for mixing and dispensing dissimilar drugs {A syringe for mixing and dispensing a different drugs}

The present invention relates to a syringe for mixing and discharging heterogeneous drugs, and more specifically, when discharging or suctioning distilled water under pressure, the lyophilized powder drug is discharged while being restored to a liquid state, and can be used without a separate mixing waiting time. It relates to a syringe that is discharged by mixing.

In general, injections are stored sealed in ampoules or vials, and when injected, the ampoule is cut or the rubber cap of the vial is pierced with a needle to inject the stored injection into the syringe and injected into the patient.

Since these injections are stored in a liquid state, they have a short shelf life, so they can be freeze-dried and sterilized to be stored in a powder state, which allows storage at room temperature and significantly increases the shelf life.

However, in order to restore the powder drug to a liquid state, there is a problem in which distilled water or another drug in the liquid phase must be added and mixed, and the powder drug takes a long time to be liquefied and there is a risk of contamination of the drug or infection from bacteria during this process. Did.

Korean Patent Publication No. 10-2006-7018980 for solving such a problem relates to a pre-filled syringe, a nozzle member 20, and a barrel in which a bypass 13 for expanding outward in a radial direction is formed ( 10), the tip gasket 60 for sealing the tip of the barrel 10, and the intermediate section for partitioning the inside of the barrel 10 into the front chamber 11 and the rear chamber 12 accommodating the liquid agent L A gasket 70 and a plunger gasket 80 located at a proximal end of the intermediate gasket 70 and sealing the inside of the barrel 10 are provided, and the intermediate gasket 70 is an inner wall of the barrel 10 It characterized in that it comprises at least one seal portion (71) in contact with, and a bypass communication path (72) communicating with the front chamber (11) and the rear chamber (12) in cooperation with the bypass (13). have.

The prior art as described above uses the seal formed inside the barrel to store and keep different drugs from each other, and when the piston is pressed during injection, the two drugs are mixed and discharged, thereby reducing the risk of infection and simplifying the mixing process. have.

However, in the case of the prior art as described above, when mixing the powder and the liquid material, the barrel is sealed and the two medicines are moved to one side of the barrel, and then the barrel must be shaken so that the two medicines are completely mixed. there was.

In addition, in the case of the prior art as described above, since the two medicines must be separated and injected into the barrel, productivity decreases, and when a medicine is injected into the barrel, there is a risk of infection, and the two medicines are mixed with each other through the gaps inside the barrel. There was a problem of deterioration.

Korean Patent Publication No. 10-2006-7018980

The object of the present invention for solving the above problems is to be automatically mixed while contacting the powdered drug when distilled water is discharged or sucked, so that the powdered drug can be liquefied and injected without an action to promote mixing time or mixing. It is to provide a syringe for mixing and dispensing dissimilar drugs.

In addition, another object of the present invention is to separate the lyophilized powder drug and distilled water into different containers, and if necessary, combine the containers containing the two drugs with each other to use a syringe to mix heterogeneous drugs that reduce the risk of infection and degeneration. It is to provide a syringe to discharge.

Syringe discharging by mixing the different drugs of the present invention for solving the above problems is formed so that one end and the other end are opened and accommodate distilled water therein, and a piston is formed at the other end to the one end direction to discharge the distilled water A first receptor for pressurized discharge, and a second receptor formed at one end of the first receptor so that the powder drug can be accommodated therein, and the upper and lower ends are opened to discharge the distilled water in one direction, It is formed in the second receptor, characterized in that it comprises a mixing unit for discharging the distilled water by mixing with the powder agent when the distilled water is introduced into the second receptor.

In addition, the mixing portion of the syringe for mixing and discharging the heterogeneous agent of the present invention is in contact with the powder medicine so that the distilled water is mixed with the powder medicine when the distilled water is discharged from the second receptor without a separate mixing waiting time. It is characterized in that to be moved.

In addition, the mixing portion of the syringe for discharging by mixing the dispensing agent of the present invention is formed inside the second receptor to prevent the powdered drug from moving in the upper direction of the second receptor, so that the distilled water can pass A spray plate formed with a plurality of spray holes and a ship formed under the spray plate to prevent the powdery agent from moving in the lower direction of the second receptor, and a ship having a plurality of discharge holes formed so that the distilled water can pass through It is characterized by being made by publishing.

In addition, a plurality of steps are formed on the inner surface of the second receptor of the syringe for discharging by mixing the dispensing agent of the present invention so that the injection plate and the discharge plate are mounted, and the outer peripheral surface of the injection plate and the discharge plate It is characterized in that the elastic ring is formed in close contact with the inner surface of the second receptor so that the distilled water does not leak into the gap.

In addition, the injection hole of the syringe to mix and discharge the different drugs of the present invention is made of a nozzle shape that gradually decreases in diameter from the top to the bottom so that the distilled water can be discharged at a high speed, the distilled water is the powdered drug It is characterized by increasing the contact area by spraying from the top.

In addition, the injection plate of the syringe for mixing and discharging the different drugs of the present invention sprays the pressurized distilled water horizontally toward the lower surface of the injection plate, so that the powdered medicine is the distilled water by the pressure change by the flow of the distilled water. It is characterized in that to be mixed with the distilled water while moving along the flow direction of.

In addition, the injection plate of the syringe for discharging by mixing the dispensing agent of the present invention includes a plurality of injection holes formed to discharge the distilled water in the horizontal direction, and formed on both sides of the lower portion of the injection plate and injected through the injection hole Characterized in that the distilled water comprises a ramp leading to move along the lower surface of the spray plate, and a vacuum hole formed in the lower center of the spray plate and formed to allow the powder agent to flow into the injection hole by pressure change. Is done.

In addition, it further comprises a connector formed on the inner upper end of the second receptor of the syringe for discharging by mixing the dispensing agent of the present invention and detachable from the first receptor, the connector protrudes upward and one end of the first receptor A support end supporting an outer surface, a connection end formed to be spaced inwardly from the support end and inserted into one inner surface of the first receptor, and a connection end connected to the first receptor, and formed in the center of the connection end, the distilled water It is characterized in that it consists of a connection port having a hole so that it can be introduced into the second receptor.

In addition, the second receptor of the syringe to be discharged by mixing the dispensing agent of the present invention is made of a tapered shape that narrows in diameter as it goes from the top to the bottom. As the distilled water moves to the bottom, the pressure decreases and the speed increases, resulting in turbulent flow. It is characterized in that the mixing performance of the powdered drug and the distilled water is increased.

In addition, the syringe for discharging by mixing the dispensing agent of the present invention, the first end and the other end is opened, the inside is empty, the other end of the first receptor is formed with a piston, the powder can be accommodated therein at one end of the first receptor It is formed so as to be formed inside the first and second receptors, the first and second receptors having an open top and bottom, and distilled water is sucked into the first receptor through the second receptor by the piston. It characterized in that it comprises a mixing portion for mixing with the powder drug.

In addition, the piston of the syringe to be discharged by mixing the dispensing agent of the present invention while moving in the other direction of the first receptor to reduce the pressure inside the first receptor and the second receptor to suck the distilled water, the distilled water is It is characterized in that it is introduced into the first receptor while passing and mixing the powder drug contained in the 2 receptor.

In addition, the mixing portion of the syringe for discharging by mixing the dispensing agent of the present invention comprises a first mixing filter formed inside the second receptor, and a second mixing filter formed inside the first receptor, the first mixing The filter and the second mixed filter are characterized in that a plurality of pores penetrating the front and rear surfaces are formed to prevent the distilled water from boiling in a vacuum.

In addition, the first mixing filter and the second mixing filter of the syringe discharging by mixing the dispensing agent of the present invention reduces the scattering of the distilled water through the pores and occurs when the distilled water boils or is mixed with the powder drug It is characterized by reducing the foam.

In addition, the mixing portion of the syringe for discharging by mixing the dispensing agent of the present invention is formed inside the first receptor, and when the distilled water and the powdered medicine are introduced, a plurality of mixing balls to generate turbulence in the flow of the distilled water to promote mixing Characterized in that it further comprises.

In addition, the mixing ball of the syringe to be discharged by mixing the different drugs of the present invention is characterized in that a catalyst for promoting mixing is coated on the outer surface or a raw material of the mixing ball is used as a catalyst.

As described above, according to the syringe that mixes and discharges the different drugs according to the present invention, when the distilled water is discharged or sucked, it is automatically mixed while being in contact with the powdered drug, thereby allowing the powdered drug to be mixed without waiting for mixing time or action to promote mixing. It has the effect of being liquefied and injectable.

In addition, according to the syringe for dispensing by mixing and dispensing heterogeneous drugs according to the present invention, the freeze-dried powder and distilled water are stored separately in different containers, and if necessary, the containers containing the two drugs are combined with each other and used as syringes to prevent infection and deterioration. It has the effect of reducing risk.

1 is a cross-sectional view showing a prior art pre-filled syringe.
Figure 2 is a perspective view showing the appearance of a syringe for discharging by mixing different drugs according to the present invention.
Figure 3 is a perspective view showing the internal structure of the second receptor and the mixing portion of the syringe to discharge by mixing the different drugs according to the present invention.
Figure 4 is a cross-sectional view showing a state in which the syringe is discharged by mixing and dispensing different drugs according to the present invention.
Figure 5 is a cross-sectional view showing the inner appearance of the second receptor of the syringe to discharge by mixing the different drugs according to the present invention.
Figure 6 is a cross-sectional view showing a mixing portion of a syringe for discharging by mixing different drugs according to the first embodiment of the present invention.
Figure 7 is a cross-sectional view showing the flow path of the fluid generated by the mixing portion of the syringe to discharge by mixing the different drugs according to the first embodiment of the present invention.
Figure 8 is a cross-sectional view showing the initial state of a syringe for discharging by mixing different drugs according to a second embodiment of the present invention.
9 is a cross-sectional view showing a state in which distilled water is sucked into a syringe to be discharged by mixing different drugs according to a second embodiment of the present invention.
Figure 10 is a cross-sectional view showing a state for injecting a mixture mixed by a syringe for discharging by mixing the different drugs according to the second embodiment of the present invention.

Specific features and advantages of the present invention will be described in detail below with reference to the accompanying drawings. Prior to this, when it is determined that the detailed description of the functions and configurations related to the present invention may unnecessarily obscure the subject matter of the present invention, the detailed description will be omitted.

The present invention relates to a syringe for mixing and discharging heterogeneous drugs, and more specifically, when discharging or suctioning distilled water under pressure, the freeze-dried powder drug is discharged while being restored to a liquid state and can be used without a separate mixing waiting time. It relates to a syringe that is discharged by mixing.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

Figure 2 is a perspective view showing the appearance of a syringe for discharging by mixing different drugs according to the present invention.

As shown in Figure 2, the syringe discharging by mixing the different drugs according to the present invention is formed so that one end and the other end is opened and accommodate distilled water therein, and the other end is formed with a piston 110 to distilled water The first receptor 100 is pressurized and discharged in the direction of discharging, and is formed so that the powder drug can be accommodated therein at one end of the first receptor 100, and the upper and lower ends are opened to discharge distilled water in one direction. The second receptor 200 is formed to be formed, and includes a mixing unit 300 formed inside the second receptor 200 and distilled water is mixed with the powdered drug and discharged when distilled water flows into the second receptor 200 It is characterized by.

The first receptor 100 is formed in a cylindrical shape, and has one end and the other end open, and the inside is empty, so that the distilled water is accommodated therein and stored, and at one end, a stopper (not shown) is formed to form the first distilled water. It can be prevented from being discharged to the outside of the receptor 100.

At this time, the piston 110 is formed at the other end of the opened first receptor 100 to suck the distilled water into the first receptor 100 or press the distilled water contained in the first receptor 100 in one direction. It can be discharged.

The diameter of one end of the first receptor 100 is formed smaller than the diameter of the other end so that the speed at which distilled water is discharged from the first receptor 100 is increased by the pressure generated by the piston 110 when the distilled water is discharged. desirable.

In addition, a scale is formed on the outer surface of the first receptor 100 to check the capacity of the distilled water, so that the amount to be input can be checked.

Since the second receptor 200 is empty inside, it is formed to accommodate the mixing unit 300 and the lyophilized powder drug therein, and is opened to allow distilled water to move to the top and bottom.

At this time, the opened upper and lower ends of the second receptor 200 are preferably sealed by a stopper (not shown) to prevent foreign matter from entering when storing the powdered drug, and when injected, the second receptor 200 The upper end is detachably attached to one end of the first receptor 100, and the lower end of the needle holder 410 is formed with a needle 410 is coupled.

The mixing unit 300 is formed inside the second receptor 200 and fixes the position of the powder agent and induces distilled water and the powder agent to be mixed when distilled water is introduced into the second receptor 200. The description will be described later.

Figure 3 is a perspective view showing the internal structure of the second receptor 200 and the mixing unit 300 of the syringe for discharging by mixing the different drugs according to the present invention.

As shown in Figure 3, the mixing portion 300 of the syringe to discharge by mixing the dispensing agent according to the present invention is formed in the interior of the second receptor 200, the powder drug is directed toward the top of the second receptor 200 To prevent movement, and a plurality of injection holes 311 are formed to allow distilled water to pass through, and the powder agent is formed on the lower portion of the injection plate 310 and the powder agent is at the bottom of the second receptor 200. It is prevented from moving in the direction, and is characterized by being made of a discharge plate 320 in which a plurality of discharge holes 321 are formed to allow distilled water to pass therethrough.

The injection plate 310 and the discharge plate 320 are positioned inside the second receptor 200 in a state of being spaced apart from each other, and between the injection plate 310 and the discharge plate 320 are spaced apart, a powder agent is positioned. .

At this time, when the distilled water pressurized by the piston 110 of FIG. 2 is introduced into the second receptor 200, it flows between the injection plate 310 and the discharge plate 320 through the injection hole 311 of the injection plate 310. And distilled water can be mixed with the powder agent.

In addition, since a plurality of injection holes are formed, distilled water is dispersed through each injection hole 311 to contact the powder chemical agent, so that the contact area is widened to increase the mixing performance of the distilled water and powder chemical agent.

The discharge plate 320 prevents the powdered drug from being discharged, and a plurality of discharge holes 321 are formed, so that when the distilled water and the powdered drug are mixed, the discharged material may be discharged toward the bottom of the second receptor 200.

At this time, the discharge hole 321 is formed so that the upper diameter is small and the lower diameter is gradually increased, so that the time for distilled water to stay between the injection plate 310 and the discharge plate 320 is increased so that the powdery medicine and distilled water are mixed with each other. It can be induced.

At the bottom of the second receptor 200, a discharge port 210 is formed so that a mixture of liquids in which mixing is completed can be injected, and the needle holder 400 and the needle of FIG. 2 coupled to the discharge port 210 By 410) it is possible to inject the mixture into the human body.

The upper end of the second receptor 200 is formed with a connector 220 that is detachably attached to the first receptor 100 of FIG. 2, and the connector 220 seals the opened upper end of the second receptor 200 to preserve storage power. In order to improve the distilled water input from the first receptor 100, a connection port 221 is formed.

Through the connector 220, the second receptor 200 and the first receptor 100 of FIG. 2 can be detached from each other.

Figure 4 is a cross-sectional view showing a state in which the syringe to discharge by mixing and dispensing heterogeneous drugs according to the present invention, Figure 5 is a view showing the interior of the second receptor 200 of the syringe to discharge by mixing the different drugs according to the present invention It is a cross section.

As shown in Figures 4 to 5, is formed on the inner top of the second receptor 200 of the syringe to discharge by mixing the different drugs according to the present invention, the first receptor 100 and the connector 220 detachably attached Further included, the connector 220 is formed to be spaced inwardly from the support end 222 and the support end 222 to protrude in the upper direction to support the outer surface of one end of the first receptor 100, the first receptor 100 ) Is formed to be inserted into the inner surface of the first end 100 is connected to the connection terminal 223, and is formed in the center of the connection end 223, so that distilled water can be introduced into the second receptor 200 It characterized in that it consists of a connection port 221 is formed.

The connector 220 is formed in a disc shape to seal the upper end of the second receptor 200, and connect the first receptor 100 and the second receptor 200 to distill water only into the second receptor 200. It is to make it possible.

The support end 222 and the connection end 223 are formed at the center of the connector 220, and the support end 222 and the connection end 223 are spaced apart from each other, so that the space of the first receptor 100 is spaced apart. One end can be inserted and fixed.

At this time, the connection end 223 is inserted into one end of the first receptor 100, and the support end 222 becomes a form surrounding one end of the first receptor 100, and the outer surface of the connection end 223 A thread is formed on the inner surface of the 1 receptor 100, so that the connection end 223 and the first receptor 100 are coupled to each other to be fixed.

The connection port 221 is formed so that the center of the connection end 223 penetrates from the top to the bottom. Through the connection port 221 formed so that the distilled water accommodated in the first receptor 100 penetrates the connection end 223 The second receptor 200 may be introduced into the interior.

The connector 220 is preferably screwed and fixed to the second receptor 200, and the portion where the connector 220 and the second receptor 200 are contacted is distilled water using a rubber ring to improve the sealing force. It is possible to prevent the second receptor 200 from leaking in the upper direction.

In addition, the second receptor 200 is made of a tapered shape in which the diameter becomes narrower as it goes from the top to the bottom, and as the distilled water moves to the bottom, the pressure decreases and the speed increases, resulting in turbulence, resulting in an increase in the mixing performance of the powdered drug and distilled water. It is characterized by being.

In addition, the mixing unit 300 is characterized in that the distilled water is moved in contact with the powder medicine so as to be mixed with the powder medicine when the distilled water is discharged from the second receptor 200 without a separate mixing waiting time.

The second receptor 200 is formed so that the lower diameter is smaller than the upper diameter, so that the movement speed of distilled water gradually increases as the distilled water discharged from the first receptor 100 moves toward the lower direction of the second receptor 200. It is.

Since the jet plate 310 and the connector 220 are spaced apart from each other, the distilled water injected from the first receptor 100 is located on the upper portion of the jet plate 310, and the second between the jet plate 310 and the connector 220 Distilled water is filled according to the inner cross-sectional area of the receptor 200.

Thereafter, when the distilled water accommodated in the first receptor 100 is pressurized by the piston 110 to be introduced into the second receptor 200, the distilled water located between the spray plate 310 and the connector 220 is injected into the injection hole ( 311) is moved between the injection plate 310 and the discharge plate 320 to be in contact with the powder agent.

As the distilled water accommodated in the first receptor 100 is continuously introduced into the second receptor 200, the distilled water gradually moves toward the lower direction of the second receptor 200, and while distilled water is in contact with the powder agent during the movement. The powdered drug is mixed.

At this time, since the cross-sectional area of the second receptor 200 decreases from the top to the bottom, as the distilled water moves to the bottom, the pressure of distilled water decreases and the speed increases due to Bernoulli's theorem. Occurs and the mixing performance is increased.

Thereafter, when the distilled water passes through the powdery medicine and becomes a mixture, it is moved to the bottom of the second receptor 200 through the discharge hole 321 of the discharge plate 320, and the discharge port 210 of the second receptor 200 is Through the needle holder 400 and the needle 410, it can be injected.

Through this process, distilled water is automatically mixed with the powder agent on the move, so that a mixture of distilled water and powder drug can be generated without a separate mixing waiting time.

In addition, a plurality of steps are formed on the inner surface of the second receptor 200 so that the injection plate 310 and the discharge plate 320 can be mounted, and the outer circumferential surfaces of the injection plate 310 and the discharge plate 320 are formed. 2 It is characterized in that the elastic ring is formed in close contact with the inner surface of the receptor 200 to prevent distilled water from leaking into the gap.

Since the second receptor 200 is formed in a tapered form, the second receptor 200 can support and fix the discharge plate 320, the spray plate 310, and the connector 220 formed inside the second receptor 200 A step is formed on the inner surface of the 200 at the position where the discharge plate 320, the injection plate 310, and the connector 220 are formed.

The step is formed at a right angle from the inner surface of the tapered second receptor 200, and when the discharge plate 320, the jet plate 310, and the connector 220 are seated on the step, the step moves in the lower direction of the second receptor 200. It prevents and prevents the discharge plate 320, the spray plate 310, the connector 220 to be positioned horizontally.

In addition, grooves are formed on the outer circumferential surfaces of the discharge plate 320, the injection plate 310, and the connector 220 so that an elastic ring can be fitted, and the discharge plate 320, the injection plate 310, and the connection hole are provided through the elastic ring. A gap between the outer circumferential surface of 220 and the second receptor 200 may be prevented from leaking distilled water or powder.

In addition, the discharge plate 320, the injection plate 310, the connector 220 may be fixed to the inner surface of the second receptor 200 through the elastic ring, and the grooves are also formed on the inner surface of the second receptor 200. It may be formed so that the discharge plate 320, the injection plate 310, the connector 220 can be fixed to the second receptor 200 by an elastic ring.

In addition, the injection hole 311 is made of a nozzle shape that gradually decreases in diameter from the top to the bottom so that the distilled water can be discharged at high speed, so that the distilled water is sprayed from the top of the powdered medicine to increase the contact area. .

Since the spray hole 311 formed in the spray plate 310 is formed in a nozzle form, when distilled water is sprayed to the top of the powder agent, distilled water can be spread in a spray form to increase the area in contact with the powder agent.

That is, when the distilled water passes through the injection hole 311, since it is sprayed onto the powdered medicine in a spray form, the surface area of the distilled water is widened and can be quickly brought into contact with and mixed with the powdered medicine, so that the powdered medicine located at a distance from the injection hole 311 It also increases the probability of contact with.

In this case, the injection hole 311 is preferably formed with a wide upper diameter and a narrow lower diameter to increase the speed of distilled water discharged from the discharge hole 321, and by applying a slope to each injection hole 311, distilled water is second It is preferable to discharge the entire interior of the receptor 200.

In addition, the discharge hole 321 of the discharge plate 320 is formed with a spiral groove or protrusion on the inner surface to generate a vortex when the mixture is discharged to the bottom of the second receptor 200 through the discharge hole 321 The powdered drug remaining in the mixture can be induced to be completely mixed with distilled water.

In addition, a filter is formed inside the discharge port 210 of the second receptor 200 so that a filter (not shown) capable of filtering the powdered medicine discharged in powder form without being mixed with distilled water is formed. It can be prevented from being introduced into the body.

At this time, the powdered medicine filtered by the filter (not shown) can be discharged together with the mixture while being melted again by the discharged mixture.

6 is a cross-sectional view showing a mixing unit 300 of a syringe for discharging a mixture of disparate medicaments according to a first embodiment of the present invention, and FIG. 7 is for discharging a mixture of disparate medicaments according to a first embodiment of the invention It is a cross-sectional view showing a flow path of the fluid generated by the mixing part 300 of the syringe.

6 to 7, the injection plate 310 formed in the mixing portion 300 of the syringe for mixing and discharging heterogeneous drugs according to the first embodiment of the present invention is used to pressurized distilled water to the injection plate 310 ) By spraying horizontally toward the lower surface of the distilled water by the pressure change by the flow of distilled water is characterized in that it is mixed with distilled water while moving along the flow direction of distilled water.

In addition, the injection plate 310 has a plurality of injection holes 311 formed to discharge the distilled water in the horizontal direction, and is formed on both sides of the lower portion of the injection plate 310, and the distilled water injected through the injection hole 311 ( 310) and a vacuum hole formed in the lower center of the injection plate 310 to be moved along the lower surface of the injection plate 310 and formed to allow the powder agent to flow into the injection hole 311 by pressure change. It is characterized by consisting of (312).

The injection plate 310 is formed in a cylindrical shape, and a connection pipe 314 that protrudes upward and has an empty interior is formed at the center, so that the connection pipe 314 is disposed inside the discharge port 210 of the second receptor 200. It is formed so that it can be inserted.

At this time, the outer circumferential surface of the connecting pipe 314 is formed with a circular fixed end 315 protruding to the outer surface, thereby preventing the connecting pipe 314 from being excessively inserted into the discharge port 210.

In addition, in order to allow distilled water to be introduced into the injection plate 310 through the connection pipe 314, the upper portion of the injection plate 310 is preferably formed with a circular opening 316, the opening 316 The inner diameter of is formed smaller than the inner diameter of the connecting pipe 314, it is preferable to increase the speed of distilled water when distilled water is added.

The injection hole 311 is formed at the bottom of the opening 316 and discharges the distilled water introduced into the injection plate 310 in the horizontal direction, and the distilled water discharged horizontally through the injection hole 311 is each injection hole. (311) is moved to the lower surface of the spray plate 310 along the ramp 313 formed at the end.

At this time, the ramps 313 are dug inward from both sides of the lower center of the injection plate 310, and may be formed in plural according to the number of injection holes 311.

In addition, since the size of the injection hole 311 is smaller than the diameter of the opening 316 of the injection plate 310, the speed of distilled water is increased by Bernoulli's theorem, and through the injection hole 311 to the ramp 313 The sprayed distilled water can be moved along the lower surface of the spray plate 310 by the Coanda effect.

At this time, since the distilled water moves at a high speed along the lower surface of the injection plate 310, the pressure in the region located at the lower portion of the injection plate 310 is relatively reduced by Bernoulli's theorem, and fluid flow phenomenon occurs. , As the powdered pharmaceuticals move together along the flow of distilled water, turbulent flow occurs to increase the mixing performance of distilled water and powdered pharmaceuticals.

In addition, a plurality of vacuum holes 312 are formed toward the injection hole 311 at the lower portion of the injection plate 310, and the powder agent is injected through the vacuum hole 312 by the pressure change generated when distilled water is moved. It may be introduced into the hole 311 to be mixed with distilled water.

At this time, the vacuum hole 312 is preferably inclined toward the direction in which the distilled water passes through the injection hole 311 so that the distilled water passing through the injection hole 311 is not discharged through the vacuum hole 312.

In order to increase the mixing performance, the discharge hole 321 formed in the discharge plate 320 is formed of a diffuser shape in which the upper diameter is formed narrower than the lower diameter, so that distilled water cannot be easily escaped to the outside.

In this case, after the distilled water is moved along the lower surface of the spray plate 310, it is moved in the direction of the discharge plate 320 along the inner surface of the second receptor 200, and the powder drug is introduced into the vacuum hole 312. Because it is circulated, distilled water is also moved to the center and circulated.

Due to this flow, the distilled water is mixed between the powder agent and the distilled water while staying between the jet plate 310 and the discharge plate 320, and the distilled water is completely filled between the jet plate 310 and the discharge plate 320. The mixture mixed by the pressure of the piston 110 of 2 can be discharged to the discharge hole 321.

8 is a cross-sectional view showing an initial state of a syringe for discharging a mixture of different drugs according to a second embodiment of the present invention.

As illustrated in FIG. 8, the syringe for discharging a mixture of dissimilar drugs according to the second embodiment of the present invention has one end and the other end opened, the inside empty, and the first receptor having a piston 110 formed at the other end ( 100), the second receptor 200 formed at one end of the first receptor 100 to accommodate the powder medicine 20 therein, and the upper and lower openings, and the first receptor 100 When the distilled water is formed inside the second receptor 200 and is sucked into the first receptor 100 through the second receptor 200 by the piston 110, the mixing unit 300 for mixing the distilled water with the powder agent 20 It characterized in that it comprises a.

The first receptor 100 is formed in a cylinder shape with one end and the other end open, and the piston 110 is formed at the other end, so that pressure can be applied to the inside of the first receptor 100 or pressure can be reduced.

In addition, on both sides of the other end of the first receptor 100 is formed with a protruding wing portion 120 to support the first receptor 100 with a finger when the user pulls or pushes the piston 110, the wings It is possible to apply a force to the piston 110 in a state where the part 120 is gripped with a finger.

At this time, the wing portion 120 is made of a curved shape at both ends toward one direction of the first receptor 100, so that the user can prevent the finger from slipping when the user puts a finger on the wing portion 120.

In addition, a curved portion (not shown) that is bent in a direction opposite to the wing portion 120 may be formed at an end of the piston 110 to increase an area in contact with a finger applying force to the piston 110 through the curved portion. As a result, it is possible to easily pressurize the piston 110.

The second receptor 200 is formed in a tapered shape in which the diameter decreases as it goes down to the bottom, and is formed to accommodate the powdery medicine 20 because the inside is empty.

In addition, the upper and lower ends of the second receptor 200 are opened so that distilled water can be sucked through the lower end, and the upper end is combined with one end of the first receptor 100 to move distilled water into the first receptor 100. I can do it.

At this time, the upper end of the second receptor 200 is formed to seal the upper surface of the second receptor 200 because the connection port 220 is formed on the opened upper end of the second receptor 200, and a hole is formed in the center of the connection port 220 to form the second receptor ( 200) Distilled water introduced into the inside may be introduced into the first receptor 100 through the hole of the connector 220.

In addition, a suction port 230 protruding to the bottom to form distilled water is formed at the opened lower end of the second receptor 200, and the needle holder 400 of FIG. 9 is coupled to the outer surface of the suction port 230. It is possible to suck the distilled water through the needle 410 into the second receptor 200.

The mixing unit 300 is formed inside the first receptor 100 and the second receptor 200, and is intended to allow the distilled water and the powder agent 20 to be mixed with each other when the distilled water passes.

The mixing unit 300 includes a first mixing filter 330 formed inside the second receptor 200, a second mixing filter 340 formed inside the first receptor 100, and a first receptor 100. It consists of a mixing ball 350 formed inside.

At this time, after the first mixing filter 330 is located inside the second receptor 200, the upper surface is fixed by the connector 220 and the lower surface is in contact with the inner surface of the second receptor 200 having a tapered shape. It can be fixed.

The powder agent 20 is located on the lower surface of the first mixing filter 330 so that the distilled water flowing through the suction port 230 passes through the powder agent 20 and moves into the first receptor 100 to be mixed. do.

In addition, the powder medicine 20 accommodated inside the second receptor 200 may contain an anti-hyperthermal agent or sodium so as not to deteriorate at an external temperature, and may also be stored in a liquid state of the powder medicine 20.

The detailed description of the mixing unit 300 will be described later with the accompanying drawings.

9 is a cross-sectional view showing an initial state of a syringe for discharging a mixture of different drugs according to a second embodiment of the present invention.

As shown in FIG. 9, the piston 110 of the syringe discharging by mixing and dispensing the different drugs according to the second embodiment of the present invention is moved to the other end of the first receptor 100 while the first receptor 100 and The pressure inside the second receptor 200 is reduced to aspirate distilled water, and the distilled water is introduced into the first receptor 100 while passing through and mixing the powder agent 20 accommodated in the second receptor 200. .

In addition, the mixing unit 300 includes a first mixing filter 330 formed inside the second receptor 200; It is made of a second mixing filter 340 formed inside the first receptor 100, and the first mixing filter 330 and the second mixing filter 340 are formed with a plurality of pores penetrating the front and rear surfaces. It is characterized by preventing boiling in the vacuum when distilled water is passed.

At the bottom of the second receptor 200, a needle holder 400 having a needle 410 is coupled to surround the outer surface of the suction port 230, and the piston 110 is inserted into the first receptor 100. To initiate suction.

At this time, the needle 410 is inserted into a vial or ampoule in which distilled water is accommodated, and when the piston 110 is pulled out of the first receptor 100, the inside of the first receptor 100 and the second receptor 200 The pressure decreases as the volume increases.

Due to the pressure reduction, distilled water is sucked through the needle 410 into the second receptor 200, and the distilled water sucked according to the movement of the piston 110 is reduced in vacuum to the second receptor 200. It boils inside.

At this time, since the distilled water is passed while boiling with the powder agent 20 accommodated in the second receptor 200, the area in contact with the powder agent 20 is widened, and the first mixed filter located on the upper part of the powder agent 20 It passes through the pores of 330 and moves into the first receptor 100.

The first mixed filter 330 is formed with fine pores, so that boiled distilled water passes through the pores of the small area of the first mixed filter 330 together with the powder agent 20 to prevent distilled water from boiling.

The distilled water and the powder agent 20 that have passed through the first mixing filter 330 are partially mixed and some are moved into the first receptor 100 in an unmixed state, and once the first receptor 100 While passing through the fine pores of the second mixing filter 340 formed on the inner surface once again, double distilled water is prevented from boiling.

In addition, the narrower the pores of the first mixing filter 330 and the second mixing filter 340, the more distilled water can pass through and reduce scattering. As the distilled water boils or mixes with the powder agent 20, By removing the generated bubbles, the size of the bubbles is reduced inside the first receptor 100 and the second receptor 200.

In addition, the first mixing filter 330 and the second mixing filter 340 are not completely fixed inside the second receptor 200 and the first receptor 100, and the second receptor 200 and the first according to the pressure change. It may be formed to move in the vertical direction inside the receptor (100).

In addition, the mixing unit 300 is formed inside the first receptor 100 and further includes a plurality of mixing balls 350 to promote mixing by generating turbulence in the flow of distilled water when distilled water and powder agent 20 are introduced. It is characterized by.

The mixing ball 350 is for more effectively mixing the distilled water and the powdery medicine 20 introduced into the first receptor 100, and a plurality of beads processed from a stainless steel material is between the second mixing filter 340 and the piston 110. Is formed on.

At this time, the mixing ball 350 forms the mixing ball 350 in an elliptical shape and rotates when distilled water hits the mixing ball 350 when distilled water flows into the first receptor 100 by the piston 110, thereby generating turbulent flow while rotating. And the powder drug 20 can be induced to be mixed with each other.

In this case, it is preferable that the specific gravity of the mixing ball 350 is formed to be about 1.2 to 1.3 to sink in water, and when the specific gravity is less than 1.2, the mixing ball 350 is pressurized by the flow of distilled water to get the other of the first receptor 100. Since it can be easily moved in one direction, it is difficult to generate turbulent flow, and if the specific gravity exceeds 1.3, the distilled water is blocked by the mixing ball 350 and the flow rate can be reduced.

Therefore, by forming the specific gravity of the mixing ball 350 between 1.2 and 1.3, when the distilled water is introduced, the mixing ball 350 is separated from the second mixing filter 340 according to the flow of distilled water and then falls, thereby forming turbulence at an irregular position. It is desirable.

In addition, it is also possible to promote mixing by shaking the first receptor 100 so that the mixing ball 350 moves between the distilled water filled in the first receptor 100 and the powder agent 20.

In addition, the mixing ball 350 is characterized in that a catalyst for promoting mixing is coated on the outer surface or a raw material of the mixing ball 350 is used as a catalyst.

A catalyst for promoting the mixing of distilled water and powder agent 20 is coated on the outer surface of the mixing ball 350, so that when the distilled water and powder agent 20 flows into the first receptor 100, the catalyst agent on the outer surface of the mixing ball 350 Is dissolved by distilled water, it is possible to chemically promote the mixing of distilled water and the powder agent (20).

In this case, the catalyst coated on the outer surface of the mixing ball 350 can be visually checked to confirm whether the distilled water and the powder agent 20 are completely mixed, and the color of the catalyst can be distinguished from the color of the mixing ball 350. desirable.

In addition, since the mixing ball 350 itself can be processed using a catalyst rather than a stainless steel material, the mixing ball 350 itself forms turbulence and simultaneously dissolves to promote mixing, thereby confirming the presence or absence of the mixing ball 350. By doing so, it is possible to check the presence or absence of mixing of distilled water and the powder agent 20.

In this case, it is preferable to form the specific gravity of the mixing ball 350 to be about 1.2 to 1.3 to sink in water. When the specific gravity is less than 1.2, the mixing ball 350 floats in distilled water due to the flow of distilled water, so dissolution and turbulence are difficult. , When the specific gravity exceeds 1.3, the distilled water is blocked by the mixing ball 350, the flow rate decreases, and the contact area decreases, making it difficult to dissolve.

Therefore, by forming the specific gravity of the mixing ball 350 between 1.2 and 1.3, when the distilled water is introduced, the mixing ball 350 is separated from the second mixing filter 340 according to the flow of distilled water, and then falls and forms turbulence at an irregular position and dissolves. It is desirable to dissolve rapidly as the contact area with distilled water increases.

10 is a cross-sectional view showing a state for injecting a mixture 30 mixed by a syringe for discharging a mixture of dissimilar drugs according to a second embodiment of the present invention.

As shown in Figure 10, the syringe for discharging by mixing the different drugs according to the second embodiment of the present invention, the first receptor 100, the distilled water and the powder agent 20 is completely mixed in Figure 9 2 The receptor 200 is separated and the needle holder 400 is coupled to one end of the first receptor 100.

Through the needle 410 formed on the needle holder 400, a mixture 30 in which distilled water and powdery medicine 20 are mixed can be introduced into the body, and when the piston 110 is pressed, some of the mixture is not mixed. The powder agent 20 may be re-mixed while passing through the fine pores of the mixing ball 350 and the second mixing filter 340.

As described above, according to the syringe that mixes and discharges the different drugs according to the present invention, when the distilled water is discharged or sucked, it is automatically mixed while being in contact with the powdered drug, so that the powdered drug without mixing waiting time or an action to promote mixing is performed. It can be liquefied and injected, and the lyophilized powder drug and distilled water are stored separately in different containers, and if necessary, the container containing the two drugs is combined with each other and used as a syringe to reduce the risk of infection and degeneration.

As described above, the present invention has been described with reference to preferred embodiments, but those skilled in the art to which the present invention pertains vary the present invention without departing from the technical spirit and scope described in the claims of the present invention. It can be modified or modified. Therefore, the scope of the invention should be construed by the claims set forth to cover many examples of such modifications.

10: distilled water 20: powder pharmaceutical
30: mixture 100: first receptor
110: piston 120: wing
200: second receptor 210: discharge port
220: connector 221: connection port
222: support 223: connecting end
230: suction port 300: mixing unit
310: spray plate 311: spray hole
312: vacuum hole 313: ramp
314: connector 315: fixed end
316: opening 320: discharge plate
321: discharge hole 330: first mixed filter
340: second mixing filter 350: mixing ball
400: needle holder 410: needle

Claims (6)

A first receptor having one end and the other end open, the inside empty, and a piston formed at the other end;
A second receptor formed at one end of the first receptor so as to accommodate a powder drug therein, and having a top and a bottom open;
And a mixing unit formed inside the first receptor and the second receptor and mixing the distilled water with the powder agent when distilled water is sucked into the first receptor through the second receptor by the piston. doing
A syringe that mixes and discharges different drugs.
According to claim 1,
The piston is sucked in the distilled water by reducing the pressure inside the first receptor and the second receptor while moving in the other direction of the first receptor,
The distilled water is passed through and mixed with the powder drug contained in the second receptor, characterized in that is introduced into the first receptor
A syringe that mixes and discharges different drugs.
According to claim 1,
The mixing part
A first mixed filter formed inside the second receptor;
It is made of; a second mixed filter formed in the first receptor;
The first mixing filter and the second mixing filter are characterized in that a plurality of pores penetrating the front and rear are formed to prevent the distilled water from boiling in a vacuum.
A syringe that mixes and discharges different drugs.
According to claim 3,
The first mixing filter and the second mixing filter
It characterized in that to reduce the scattering of the distilled water through the pores and to reduce the foam generated when the distilled water boils or is mixed with the powder agent
A syringe that mixes and discharges different drugs.
According to claim 1,
The mixing part
It characterized in that it further comprises a plurality of mixing balls that are formed inside the first receptor and generate turbulence in the flow of the distilled water to promote mixing when the distilled water and the powder drug are introduced.
A syringe that mixes and discharges different drugs.
The method of claim 5,
The mixing ball is characterized in that a catalyst for promoting mixing is coated on the outer surface or a raw material of the mixing ball is used as a catalyst.
A syringe that mixes and discharges different drugs.

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