KR102283889B1 - Needless injector - Google Patents

Abstract

The present invention is to solve the problems of the prior art as described above, using a spring to generate a driving force for drug injection. In order to provide a needle-free syringe that can improve the reliability of operation with less wear or damage of parts.

Description

Needle-free syringe {NEEDLESS INJECTOR}

The present invention relates to a needle-free syringe capable of injecting an injection solution into the skin in a non-invasive manner.

In general, a syringe is a medical device that injects by pushing the injection solution inside the syringe with a piston by invading the skin with a hollow needle while the syringe is filled with an injection solution. Techniques related to syringes of various configurations, such as manual injection syringes as well as automatic injection syringes capable of automatic injection, have been disclosed.

However, the invasive type syringe as described above causes damage to the skin tissue or side effects such as allergic reactions because the needle must be inserted into the skin. There was a problem in that it caused fear and pain due to invasion.

In order to solve this problem, a non-invasive type needle-free syringe has appeared. The needle-free syringe generates a driving force for drug injection using a motor in a state in which a nozzle for drug injection is in close contact with the skin, and the driving force is used to inject the drug. By injecting high pressure through the nozzle, the drug is instantly injected into the body through the skin.

As prior art documents related to such needle-free syringes, Patent Application No. 10-2018-0059072, Patent Application No. 10-2010-0006592, Patent Application No. 10-2010-0039393, etc. have been disclosed.

The needle-free syringe according to the prior art generates a driving force for drug injection using the elasticity of the spring, and various methods are used in the method of operating the spring.

In the case of the Patent Application No. 10-2018-0059072, the thrust of the spring is generated by compressing the spring while the rod moves along the track by inserting the rod into the crankshaft forming the track with a groove and rotating the crankshaft. In the process of moving the rod along the groove, friction is seriously generated, which often results in malfunctions, and there is a problem in that the rods are easily damaged.

In addition, in the case of Patent Application No. 10-2010-0006592, a method of operating a spring by rotating a drum wound with a wire is disclosed. Since it is very difficult to implement and the wire is easily broken, there is a problem in which operation failure is easy to occur.

In addition, in the case of Patent Application No. 10-2010-0039393, a method of injecting a drug using air pressure is disclosed. Since the size of the device must be large because compressed air is used, a device having a compact size or a portable needleless needle It is very difficult to implement in the form of a syringe or the like, and there is a problem in that it is difficult to keep the injection amount of the drug constant because it uses air pressure.

[Prior art literature]

Patent Application No. 10-2018-0059072

Patent Application No. 10-2010-0006592

Patent Application No. 10-2010-0039393

The present invention is to solve the problems of the prior art as described above, using a spring to generate a driving force for drug injection. In order to provide a needle-free syringe that can improve the reliability of operation with less wear or damage of parts.

Needle-free syringe according to an embodiment of the present invention, a driving unit for providing a driving force by rotating the driving shaft; an injection propulsion unit operating by driving the driving unit to provide a driving force for drug injection; and a drug injection unit for injecting the drug injected through the drug injection unit by the driving force of the injection propulsion unit, wherein the injection propulsion unit includes a casing in which the driving unit is coupled to one side and the drug injection unit is coupled to the other side, and the casing unit An actuating cam provided inside and rotating according to the driving of the driving unit to form a spiral curved surface at the tip, a propulsion spring provided between the driving unit and the operating cam, and a spiral curved surface of the operating cam provided inside the casing A cam operation support part is provided to be positioned on the part to support the operation of the operation cam, and as the operation cam rotates while the spiral curved surface part of the operation cam is supported by the cam operation support part by the driving of the driving part The drug is injected by using the elastic force of the propulsion spring as the propulsion force when the propulsion spring is compressed and then restored.

Also preferably, the injection propulsion unit further includes a drive adapter coupled to the drive shaft rotated by the drive unit and rotated by the rotation of the drive shaft, the drive adapter passing through the propulsion spring to the rear end of the actuating cam It is coupled to a support coupling part provided in the drive shaft and rotates the operation cam while the drive adapter is coupled to the support coupling part by the rotation of the drive shaft while the operation cam is linearly moved to the rear end by the cam operation support part. It is characterized in that it is configured to compress the propulsion spring.

Also preferably, the actuating cam includes a support coupling part coupled to the driving part side, and an actuating guide part provided at the tip of the support coupling part to form the spiral curved part moving with respect to the cam operation support part, It is characterized in that it is configured to compress the propulsion spring while the helical curved portion moves with respect to the cam operation support fixed to the casing portion while the operation guide portion rotates by rotating the support coupling portion as the drive shaft rotates by the drive portion. .

Also preferably, the operation guide part of the actuating cam forms a helical curved surface or an inclined surface from the lowest point position to the highest point position, and forms a cliff part falling from the highest point position to the lowest point position, so that the operation of the operating cam is formed. As the guide part rotates, the cam motion support part is positioned from the lowest point position on the spiral curved part to the highest point position to compress the propulsion spring, and the cam motion support part follows the cliff part at the highest point position of the spiral curved part. As the compression state of the propulsion spring is restored as it falls to the lowest point position, it is characterized in that the propulsion force is generated by the restoring force.

Also preferably, the cam operation support portion includes a support protrusion formed to protrude inward from the casing portion, or is fixed to protrude inwardly from the casing portion and slides along the spiral curved portion according to the rotation of the operation cam. It is characterized in that it comprises a sliding support member configured to, or is fixed to protrude inwardly to the casing portion and comprises a support roller configured to roll along the spiral curved portion according to the rotation of the operation cam.

Also preferably, the cam operation support portion includes a fixing portion fixed to protrude inward to the casing portion, a sliding portion configured to slide along the spiral curved portion according to the rotation of the actuating cam, the fixing portion and the It is provided between the sliding parts and characterized in that it comprises a sliding elastic support member having an elastic support for elastically supporting the sliding part.

Also preferably, the cam operation support portion includes a fixing portion fixed to protrude inwardly from the casing portion, a rolling portion configured to roll along the spiral curved portion according to the rotation of the actuating cam, the fixing portion and the It is provided between the rolling parts and characterized in that it comprises an elastic support roller having an elastic support part for elastically supporting the rolling part.

The needle-free syringe according to the present invention uses a spring to generate a driving force for drug injection. It has a simple configuration and is easy to implement in a compact size. Thus, in operating the propulsion spring, there is less wear or damage to parts and the reliability of operation can be improved.

1 is a view showing the overall configuration of a needle-free syringe according to an embodiment of the present invention.
Figure 2 is an exploded perspective view showing an exploded configuration of the needle-free syringe shown in Figure 1;
Figure 3 is a view showing the main internal configuration of the needle-free syringe shown in Figure 1 to be seen.
FIG. 4 is a view showing the configuration of the casing part and the drug injection part in the needle-free syringe according to the embodiment shown in FIG. 3 in more detail (except for the piston), and the configuration of the operation cam and the cam operation support part.
Figure 5 (a) shows the configuration of the operation cam and the cam operation support portion shown in Figure 4 from different angles, and Figures 5 (b) and (c) are related to the cam operation support portion of the needle-free syringe according to the present invention. It is a diagram for explaining two different embodiments.
6 (a) and (b) is a view for explaining another embodiment of the cam operation support of the needle-free syringe according to the present invention.
7 and 8 are views for explaining the operation of the needle-free syringe according to an embodiment of the present invention.

The specific details of the needle-free syringe according to the present invention will be described with reference to the drawings.

First, a configuration of a needle-free syringe according to an embodiment of the present invention will be described with reference to FIGS. 1 to 3 .

1 is a view showing the overall configuration of a needle-free syringe according to an embodiment of the present invention, FIG. 2 is an exploded perspective view showing the configuration of the needle-free syringe shown in FIG. 1 by disassembling it, and FIG. It is a view showing the main internal configuration of the syringe.

1 to 3, the needle-free syringe according to an embodiment of the present invention includes a driving unit 100, an injection propulsion unit 200, a drug injection unit 300, and a drug injection unit 400. is configured to include

As shown, the needle-free syringe according to an embodiment of the present invention can be configured in a compact manner by serially combining the driving unit 100, the injection propulsion unit 200, and the drug injection unit 300.

The driving unit 100 is a component that provides a driving force by the driving motor 110 rotating the driving shaft 120 .

The injection propulsion unit 200 is a component that is provided inside the casing unit 201 and operates by driving the driving unit 100 to provide a driving force for drug injection.

The drug injection unit 300 is connected to the drug injection unit 400 and is a component that injects the drug injected through the drug injection unit 400 by the driving force of the injection propulsion unit 200 .

As shown in FIG. 2 , a casing coupling part 130 is fixed to the driving part 100 , and one end of the casing part 201 is coupled to the casing coupling part 130 , and the other of the casing part 201 . A support cap 260 is coupled to the end.

The drug injection unit 300 is configured to include an injection syringe 310, a piston 320, and an injection nozzle 330, and the drug injection unit 400 is connected to one side of the injection syringe 310. can be configured.

A coupling hole 262 is formed in the support cap 260 coupled to the other end of the casing unit 201, the end of the injection syringe 310 of the drug injection unit 300 is coupled, and the injection syringe 310 The piston 320, which is inserted inside and pushes the drug inside the injection syringe 310 while moving in a straight line by the driving force of the injection propulsion unit 200, is at the tip of the operating cam 230 provided in the injection propulsion unit 200. It may be coupled to the formed piston coupling portion 236 .

On the other hand, as shown in Figures 2 and 3, the injection propulsion unit 200 of the needle-free syringe according to an embodiment of the present invention includes a casing portion 201 and a drive adapter 210 provided therein and , a propulsion spring 220 , an operation cam 230 , and a cam operation support part 250 fixedly provided on one side of the casing part 201 .

The drive adapter 210 is coupled to the drive shaft 120 rotating by the drive motor 110 and rotates together as the drive shaft 120 rotates.

The drive adapter 210 is a component that is coupled to the actuating cam 230 and rotates the actuating cam 230 as the drive shaft 120 rotates.

As shown in FIG. 2 , the driving adapter 210 includes a driving surface portion 212 on a body, and the operation cam 230 has an operation guide portion 232 at the front end and a support coupling portion 231 at the rear end. ), and a groove portion 231a corresponding to the shape of the drive surface portion 212 of the drive adapter 210 is formed in the support coupling portion 231 of the actuating cam 230, the drive adapter 210 of the driving surface portion 212 may be configured to be coupled to the groove portion 231a of the support coupling portion 231 of the operation cam 230 .

Accordingly, the driving adapter 210 rotates as the driving motor 110 rotates the driving shaft 120 , and the driving adapter 210 operates by rotating the support coupling portion 231 of the operating cam 230 . It is possible to rotate the guide part 232 .

On the other hand, as the driving adapter 210 and the support coupling part 231 are coupled, the propulsion spring 220 is fitted thereto as shown in FIGS. 2 and 3 to be seated on the casing coupling part 130. .

That is, the propulsion spring 220 may be provided between the driving unit 100 and the actuating cam 230 , and specifically, the center of the coil spring-shaped propulsion spring 220 is positioned between the driving adapter 210 and the actuating cam. The support coupling portion 231 of the 230 may be provided in a state coupled to each other while passing through.

As shown in FIGS. 2 and 3 , a spiral curved surface portion 234 is formed in the operation guide portion 232 provided at the tip of the support coupling portion 231 of the operation cam 230 , and the casing portion 201 . ), the cam operation support part 250 fixed to one side is positioned on the spiral curved surface part 234 of the operation cam 230 .

The spiral curved surface portion 234 of the actuating cam 230 is configured to form a curved floor that is helically connected from the lowest point position 234a to the highest point position 234b on the operation guide unit 232, and must be at the foremost position ( 234a) may include a case of forming a 'curved floor' from the highest point position 234b, as well as a case of forming a 'slope floor' from the lowest point position 234a to the highest point position 234b.

In addition, a cliff portion 235 forming a cliff falling from the highest point position 234b of the spiral curved portion 234 to the lowest point position 234a may be formed.

As shown in Figure 2, the operation guide portion 232 of the operation cam 230, the spiral curved portion 234 having the above-described cliff portion 235 is provided on both sides can be configured to be connected to each other, the cap The operation support unit 250 may be provided on each of the spiral curved portions 234 , respectively.

By combining the components shown in FIG. 2, it is possible to implement the configuration of the needle-free syringe as shown in FIG. 3), the cam operation support part 250 fixed to protrude inwardly from the casing part 201 as shown in FIG. 3 is located on the spiral curved surface part 234 of the operation cam 230, As the driving adapter 210 and the supporting coupling part 231 rotate by the driving of the driving unit 100, the operating cam 230 can rotate. At this time, the cam operation supporting unit 250 is supported in a fixed state. As the spiral curved surface portion 234 moves by rotation while the position of the cam operation support portion 250 changes on the spiral curved portion 234, the operation cam 230 gradually compresses the propulsion spring 220. As the cam operation support part 250 moves from the highest point position to the lowest point position in the cliff part 235, the compression of the propulsion spring 220 is released and the propulsion force is generated by the elastic restoring force of the propulsion spring 220. will do

This will be described in more detail with reference to FIGS. 4 and 5 .

4 and 5 (a) omit the configuration of the casing unit 201 and the drug injection unit 300 in the needle-free syringe according to the embodiment shown in Fig. 3 (except the piston 230), the operation cam The configuration of 230 and the cam operation support part 250 is shown in more detail, and FIGS. 5 (b) and (c) are for explaining two different embodiments of the cam operation support part 250. It is a drawing.

4 and 5 (a), the needle-free syringe according to an embodiment of the present invention forms a curved floor from the lowest point position (234a) to the highest point position (234b) and at the highest point position (234b). and an actuating cam 230 forming a spiral curved portion 234 forming a cliff portion 235 forming a cliff to the next lowest point position 234a, and a cam operation support portion 250 on the spiral curved portion 234 . ) is characterized in that it is configured to be located, respectively. A piston 320 may be coupled to the distal end of the actuating cam 230 .

Accordingly, while the actuating cam 230 is rotated while the driving adapter is coupled to the support coupling part by the rotation of the driving shaft, the actuating cam 230 is linearly moved to the rear end (in the direction of the driving part) by the cam motion support part 250 . The propulsion spring 220 can be compressed, and as the cam operation support part 250 falls from the highest point position to the lowest point position in the cliff part 235 of the actuating cam 230, the actuating cam 230 has a tip (drug injection part). direction), the compression state of the propulsion spring 220 can be released, and accordingly, the elastic restoring force of the propulsion spring 220 becomes a propulsive force to move the piston 230 in a straight line.

The cam operation support part 250 as described above may be implemented as a support protrusion (formed integrally with the casing part) formed to protrude inward from the casing part (not shown).

In addition, as shown in (b) of FIG. 5, it is fixed to protrude inward to the casing part (not shown) and slides (sliding or sliding) along the spiral curved surface part 234 according to the rotation of the actuating cam 230. It may be implemented as a sliding support member 251 configured to do so.

In addition, as shown in (c) of FIG. 5, the support roller is fixed to protrude inwardly to the casing part (not shown) and configured to roll along the spiral curved part 234 according to the rotation of the actuating cam 230. 252 .

However, as described above, as the operation cam 230 rotates, the cam operation support part 250 whose position changes on the spiral curved portion 234 is the operation cam in the process of falling from the highest point position to the lowest point position in the cliff part 235 . 230 may transmit an impact to the cam operation support unit 250 by the elastic restoring force of the propulsion spring 220 .

Needle-free syringe according to another embodiment of the present invention, as shown in (a) and (b) of Figure 6, the actuating cam 230 as described above is a cam by the elastic restoring force of the propulsion spring 220 In order to buffer the impact transmitted to the operation support unit 250 , the cam operation support unit 250 may be implemented as a sliding elastic support member 254 or may be implemented as an elastic support roller 256 .

In (a) of FIG. 6, as an example of the cam operation support part 250, a sliding elastic support member 254 is shown, and as shown, the sliding elastic support member 254 is a casing portion (not shown). A fixed part (254a) fixed to the inside of the), a sliding part (254b) configured to slide along the spiral curved surface part (234) according to the rotation of the operation cam (230), and the fixing part (254a) and the It is provided between the sliding parts 254b and may be configured to include an elastic support part 254c for elastically supporting the sliding parts 254b.

Therefore, even if the sliding portion 254b of the sliding elastic support member 254 slides along the spiral curved portion 234 and falls off the cliff portion, it can be buffered by the elastic force of the elastic support portion 254c.

On the other hand, in (b) of FIG. 6, as another example of the cam operation support part 250, it is shown with respect to the case where the elastic support roller 256 is implemented. As shown, the elastic support roller 256 is a casing part ( (not shown) a fixed part 256a fixed to the inside, a rolling part 256b configured to roll along the spiral curved part 234 according to the rotation of the actuating cam 230, and the fixing part 256a and It may be configured to include an elastic support portion 256c provided between the rolling portions 256b to elastically support the rolling portions 256b.

Accordingly, even if the rolling portion 256b of the elastic support roller 256 is rolled along the spiral curved portion 234 and falls from the cliff portion, it can be buffered by the elastic force of the elastic support portion 256c.

Meanwhile, the operation of the needleless syringe according to an embodiment of the present invention having the configuration as described above will be described with reference to FIGS. 7 and 8 .

The needle-free syringe according to an embodiment of the present invention operates in the order of (a) of FIG. 7 --> (b) of FIG. 7 --> (a) of FIG. 8 --> (b) of FIG. .

In the needle-free syringe according to an embodiment of the present invention, the operator can start the operation by using means such as an operation switch provided separately.

When the operation of the needle-free syringe according to an embodiment of the present invention is started, the driving motor 110 of the driving unit starts to operate as shown in FIG. A quantity of the drug is introduced into the injection syringe 310 .

A drug storage container (not shown) provided separately may be coupled to the drug injection unit 400, or a tube (not shown) may be connected from a separate drug storage container, and the drug injection unit 400 may include a drug injection syringe ( 310) A valve (eg, a solenoid valve, etc.) is provided to control the inflow into the interior, and as the operator operates a means such as an operation switch as described above, the valve of the drug injection unit 400 is opened and the drug is injected It may be introduced into the syringe 310 .

At this time, when the drug flows into the injection syringe 310 through the drug injecting unit 400, the valve of the drug injecting unit 400 is immediately blocked.

On the other hand, as described above, when the driving motor 110 starts to operate by the manipulation of the operating switch, the driving adapter 210 passing through the propulsion spring 220 and the supporting coupling portion 231 of the operating cam 230 are mutually In the coupled state, the actuating cam 230 is rotated by a drive shaft (not shown) of the drive motor 110 .

As shown in (b) of FIG. 7 , when the actuating cam 230 rotates by the rotation of the drive shaft, the drive adapter 210 and the support coupling part 231 of the drive motor 110, the cam operation support part ( The spiral curved portion 234 of the actuating cam 230 with respect to 250 moves.

That is, according to the rotation of the operation cam 230, the position of the cam operation support part 250 gradually changes from the lowest point position 234a of the spiral curved portion 234 to the highest point position 234b, and accordingly, in Fig. 7 (b) As shown, the actuating cam 230 moves linearly in the direction of the arrow in the drawing (the rear end direction of the actuating cam), thereby gradually compressing the propulsion spring 220 .

And as the actuating cam 230 linearly moves in the rear end direction, the piston 320 coupled to the front end also linearly moves to the rear end together with the actuating cam 230 .

As shown in (a) of FIG. 8 , the driving motor 110 continuously rotates the driving shaft, and accordingly, the operating cam 230 continues to rotate while being supported by the cam operation support part 250 , and the cam operation The support part 250 is changed in position on the spiral curved part 234 and reaches the highest point position 234b. reaches a maximum

At this time, the piston 320 coupled to the tip of the actuating cam 230 is also in a state in which it has moved to the maximum from the injection syringe 310 .

After the state as described above, the driving motor 110 continues to rotate the driving shaft, and as shown in FIG. ), the maximally compressed propulsion spring 220 as it is positioned on the cliff part 235 momentarily strongly pushes the actuating cam 230 in the direction of the arrow in the drawing (the tip direction of the actuating cam) with an elastic restoring force, and accordingly The piston 320 coupled to the tip of the actuating cam 230 strongly pushes the drug inside the injection syringe 310 so that the drug can be strongly injected to the outside through the injection nozzles 330 .

At this time, while the elastic restoring force of the propulsion spring 220 pushes the actuating cam 230 in the direction of the arrow in the drawing, the cam operation support part 250 passes the cliff part 235 and the lowest point position 234a of the spiral curved part 234. will be located

With one operation of the operation switch, a series of operations as described above are performed, so that the injection of the drug can be made.

As described above, the needle-free syringe according to the present invention is a method of generating a driving force for drug injection using a spring, and has a simple configuration and is easy to implement in a compact size. In operating the propulsion spring using the cam operation support, there is a feature that there is less wear or damage to parts and the reliability of operation can be improved.

100: drive unit, 110: drive motor
120: drive shaft, 130: casing coupling portion
200: injection propulsion unit, 201: casing unit
210: drive adapter, 220: propulsion spring
230: operation cam, 250: cam operation support
260: support cap, 300: drug injection unit
310: injection syringe, 320: piston
330: injection nozzle, 400: drug injection unit

Claims (7)

a driving unit providing a driving force by rotating the driving shaft;
an injection propulsion unit operating by driving the driving unit to provide a driving force for drug injection;
It includes a drug injection unit for injecting the drug injected through the drug injection unit by the driving force of the injection propulsion unit,
The injection propulsion unit,
A casing part to which the driving part is coupled to one side and the drug injection part to the other side; A propulsion spring provided between the cams, and a cam operation support portion provided inside the casing portion to be positioned on the spiral curved surface of the operation cam to support the operation of the operation cam,
As the actuating cam rotates while the spiral curved surface of the actuating cam is supported by the cam motion support part by the driving of the driving unit, the propulsion spring is compressed and restored. Needle-free syringes that allow for spraying. According to claim 1, wherein the injection propulsion unit,
Further comprising a drive adapter coupled to the drive shaft rotated by the drive unit to rotate by the rotation of the drive shaft,
The drive adapter passes through the propulsion spring and is coupled to a support coupling portion provided at the rear end of the action cam, and rotates the action cam while the drive adapter is coupled to the support coupling portion by rotation of the drive shaft. Needle-free syringe, characterized in that the actuating cam is configured to compress the propulsion spring while moving linearly to the rear end by the cam operation support. According to claim 1, wherein the operation cam,
A support coupling part coupled to a driving adapter rotated by the drive shaft of the driving part, and an operation guide part provided at the tip of the support coupling part to form the helical curved part moving with respect to the cam operation support part,
As the drive adapter rotates by the drive shaft, the support coupling portion is rotated to rotate the operation guide portion and the spiral curved portion moves with respect to the cam operation support portion fixed to the casing portion to compress the propulsion spring. Needle-free syringe characterized. The method of claim 3, wherein the operation guide portion of the operation cam,
The spiral curved surface part forms a spiral curved surface or inclined surface from the lowest point position to the highest point position, and forms a cliff part falling from the highest point position to the lowest point position,
As the operation guide portion of the operation cam rotates, the cam operation support portion is positioned from the lowest point position on the spiral curved portion to the highest point position, thereby compressing the propulsion spring, and the cam operation support portion is the highest point position of the spiral curved portion. Needle-free syringe, characterized in that as the compression state of the propulsion spring is restored as it falls to the lowest point along the cliff portion, the propulsion force is generated by the restoring force. According to claim 1, wherein the cam operation support portion,
a support protrusion formed to protrude inward from the casing portion, or a sliding support member fixed to protrude inwardly from the casing portion and configured to slide along the spiral curved portion according to the rotation of the actuating cam; Needle-free syringe, characterized in that it is fixed to protrude inwardly to the casing portion comprises a support roller configured to roll along the spiral curved portion in accordance with the rotation of the operation cam. According to claim 1, wherein the cam operation support portion,
A fixing part fixed to protrude inward to the casing part, a sliding part configured to slide along the spiral curved part according to the rotation of the actuating cam, and a sliding part provided between the fixing part and the sliding part to make the sliding part elastic Needle-free syringe comprising a sliding elastic support member having an elastic support for supporting. According to claim 1, wherein the cam operation support portion,
A fixing part fixed to protrude inward from the casing part, a rolling part configured to roll along the spiral curved part according to the rotation of the actuating cam, and a rolling part provided between the fixing part and the rolling part to elastically support the rolling part Needle-free syringe, characterized in that it comprises an elastic support roller having an elastic support.

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