KR20110119954A - Needleless continuous injection device - Google Patents

Abstract

The present invention relates to a needleless continuous injection device which allows continuous injection while continuously and automatically adjusting the required amount of injection liquid.
To this end, the present invention in the needle-less injection device for administering the injection solution in the subcutaneous tissue of the patient, the main cylinder 20 to which the front and rear air inlet (22, 23) is connected inside the housing (1) is formed The coupler 30 is connected to the main cylinder 20, the spacer 40 is coupled to the coupler 30, and the elastic spring of the expansion spring 90 is formed inside the spacer 40. The rod 50 is formed to be elastically supported so as to protrude outward and backward, but at one end surface of the rod 50, a piston 100 is formed, and the rod 50 is formed on an outer surface of the rod 50. The rod guide 60 to guide the front and rear is formed, and the chamber 70 is cap 74 so that the injection liquid 200 is injected through the injection liquid inlet 71 at the end surface of the rod guide 60. Is connected to, the connecting bracket 120 on the outer surface of the rod guide 60 The injection liquid backflow and leakage preventing means 8 is formed to advance the rod 50 to prevent the backflow and leakage of the injection liquid 200 injected into the chamber 70 in the connection bracket 120. It is characterized by.

Description

Needleless continuation injection apparatus

The present invention relates to a needleless continuous injection device, and more particularly, to a needleless continuous injection device that allows continuous injection while automatically and automatically adjusting a necessary amount of injection liquid.

In general, needle injectors have been widely used in the medical field for the local supply of reagents or solutions or for the treatment of specific areas.

However, the needle injection device has a disadvantage in that a needle injecting into the injected skin tissue region forms a hole in the injection site, causing damage to tissue cells and skin trauma.

To this end, the medical field has introduced a needleless injection device to compensate for the above disadvantages, and the needleless injection device is commercialized in the medical field, and its use is gradually expanding.

The needle-free injection device injects fluid medicine into the skin tissue at the same time as the preloaded spring expands and penetrates the skin through the subcutaneous injection nozzle when a specific button is pressed on the patient's skin to administer the fluid medication into the patient's subcutaneous tissue. Done.

When the injection of the fluid chemical is completed, the operation housing or the piston rebounds from the injection position to rebound from the injection position and returns to the original position.

The conventional needleless injection device described above simply consists of a structure in which the fluid drug contained in the chamber is injected at high pressure into the human body through a ram or a rod through an elastic body or an external energy source, and the user refills the fluid medicine, In the case of use to the patient, it is often accompanied by a plurality of operation process, causing inconvenience in use.

In addition, in the high-speed injection of the fluid drug in the human body, it takes a considerable time for the drug entered into the body to be absorbed into the skin cell tissue by administering the fluid drug to the relatively gentle skin tissue.

In addition, even when operating the needle-free injection device, there is a problem that the structure is complicated, causing operation problems in use.

In addition, in the conventional needleless injection device, the volume of the chamber in which the fluid drug is accommodated is always constantly standardized for each needleless injection device, and thus, the fluid drug to be injected has a limited problem.

Accordingly, the present invention has been made to solve the above problems, the object of which is to maximize the convenience of use by allowing the first injection to be continuously and automatically continuously irrespective of the dose.

Second, it is possible to prevent the backflow of the injection liquid injected into the chamber to improve the performance of the product.

Third, it is to provide a needle-free continuous injection to improve the operability by the injection of the injection liquid and the injection of the human body by a single switch operation.

The present invention for achieving the above object is formed in the housing is a main cylinder to which the front and rear air inlet is connected, the coupler is connected to the main cylinder, the coupler is fastened to the spacer, the spacer The rod is formed to be forward and backward to protrude to the outside while being elastically supported by the elastic force of the expansion spring in the interior of the end of the rod is formed with a piston, to guide the rod forward and backward on the rod outer surface The rod guide is formed, characterized in that the chamber is connected to the cap so that the injection liquid is injected through the injection liquid injection hole on the end surface of the rod guide.

In addition, in the housing, needleless backflow and leakage preventing means for advancing the rod to move the piston forward to prevent the backflow and leakage of the injection liquid injected into the chamber from the injection liquid inlet is formed To provide continuous scanning.

As described above, the present invention is connected to the rod while the injection liquid backflow and leakage prevention means pushes the rod so that the injection liquid injected into the chamber through the injection liquid injection port can be used to prevent the injection liquid backflow and leakage by using the injection liquid backflow and leakage prevention means inside the housing. When the injection preparation is completed by moving the piston forward, the main cylinder operates to inject the injection liquid through the nozzle to continuously inject the injection liquid, thereby maximizing convenience for the user.

In addition, the present invention has the effect of eliminating the inconvenience of filling the injection liquid by allowing the injection in the chamber to be continuously supplied through the injection hole without limiting the injection as in the prior art.

1 is a cross-sectional view showing the internal configuration of the needle-free injection device according to the present invention.
Figure 2 is a cross-sectional view showing the injection liquid preparation ready state of the needle-free injection device according to the present invention.
3 is an enlarged view of a portion “A” of FIG. 2.
Figure 4 is an operation cross-sectional view showing a state in which the injection liquid injection of the needle-free injection device according to the present invention.
5 is an enlarged view of a portion “C” of FIG. 4.
6 is an illustration of the use of the needle-free injection device according to the invention.

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

1 is a cross-sectional view showing the internal configuration of the needle-free injection device according to the present invention, Figure 2 is a cross-sectional view showing the preparation state of the injection liquid injection of the needle-free injection device according to the invention, Figure 3 is "A" of FIG. 4 is an enlarged cross-sectional view showing an injection state of the injection liquid of the needleless injection device according to the present invention, and FIG. 5 is an enlarged view "C" of FIG.

The present invention provides a needleless injection device for administering an injection in a patient's subcutaneous tissue, wherein a housing 1 is formed therein and a bushing 11 is coupled to a rear surface thereof. The main cylinder 20 is provided with a working rod 21 to operate forward and backward according to the injection of air pressure in the housing 1, and prevents the back flow of the injection liquid 200 to the main cylinder 20 and leaks. Injection liquid advance means (3) is formed to advance the injection liquid 200 while preventing the injection, injection liquid injection means (7) to inject the injection liquid 200 is advanced to the injection liquid advance means (3) It is formed and connected to the injection liquid advance means (3) in the housing (1) to prevent the back flow and leakage of the injection liquid 200 injected into the injection liquid injection means 7 to prevent the back flow and leakage prevention means ( 8) is configured to include.

The injection liquid forwarding means 3 is formed in the receiving portion 12 of the housing 1, the main cylinder 20 is formed with the operation rod 21 is formed so as to operate forward and backward in accordance with the air pressure, the main cylinder The coupler 30 is fastened while being supported by the nut N on the operation rod 21 of the 20, the spacer 40 is fastened to the coupler 30, and charged into the spacer 40. The rod 50 is formed so as to protrude to the outside while the rod guide 60 is formed on the outer surface of the rod 50 so that the rod 50 can be smoothly operated before and after.

The injection liquid injection means 7 is a chamber 70 is fixed to the cap 74 so that the injection liquid 200 is injected and discharged to the end of the rod guide 60, the work of the chamber 70 The injection liquid injection port 71 is formed to be connected to the side so that the injection liquid 200 can be injected from the external injection liquid supply means 300.

A connection bracket 120 is formed on an outer surface of the rod guide 60 to prevent backflow and leakage of the injection liquid 200 injected into the chamber 70 into the connection bracket 120 to prevent leakage of the rod 50. Injection liquid backflow and leakage preventing means 8 for advancing is formed.

The front air inlet 22 and the reverse air inlet 23 are formed at the front and rear sides of the main cylinder 20 so as to move the operating rod 21 forward and backward.

At one end of the rod 50, a piston 100 for pushing the injection liquid 200 in the chamber 70 is mounted.

In addition, the O-ring 110 is formed at the outer circumference of the piston 100 so that the injection liquid 200 in the chamber 70 does not leak.

An expansion spring 90 is formed in the spacer 40 to elastically support the rod 50.

The rod 50 has a separation preventing jaw 51 formed on one inner surface of the expansion spring 90 so as not to be separated, and a locking piece for allowing the injection liquid backflow and leakage preventing means 8 to contact an external intermediate portion. 52) is formed.

The chamber 70 has an air discharge hole 72 formed on the other side so that the injection liquid 200 can be smoothly supplied into the chamber 70 through the injection liquid inlet 71.

In addition, a nozzle 73 is formed at the end of the chamber 70 so that the injection liquid 200 injected through the injection liquid injection port 71 can be injected as the piston 100 advances.

The connection bracket 120 is electrically connected to a controller (not shown) that controls the operation of the injection liquid 200 injected into the main cylinder 20, the injection liquid backflow and leakage preventing means 8, and the injection liquid injection port 71. A button B and a switch S are formed to be grounded to operate the needleless injection device according to the present invention.

Meanwhile, as shown in FIG. 6, the injection liquid injection means 7 is supplied to the injection liquid injection means 7 so that the injection liquid 200 can be continuously and supplied to the injection chamber 200 from the outside so that the injection liquid 200 can be continuously inserted into the chamber 74. The means 300 are connected.

Looking at the operating state according to the present invention made of a configuration as described above are as follows.

First, when the button (B) and the switch (S) is pressed, the injection liquid 200 is supplied into the injection liquid inlet 71 and is injected into the chamber 70, and the injection liquid backflow and leakage preventing means ( 8) is activated and the catch piece 52 is caught by the injection liquid backflow and leakage prevention means 8 as the injection liquid backflow and leakage prevention means 8 advances, and the rod 50 causes the injection liquid backflow and leakage prevention means. Advance along (8).

On the other hand, the injection liquid 200 which is injected into the chamber 70 by the injection liquid backflow and leakage preventing means 8 which advances the rod 50 as described above can prevent the back flow or leakage.

As such, the piston 100 mounted on the rod 50 blocks the injection liquid inlet 71 while the rod 50 is advanced by the injection liquid backflow and leakage preventing means 8. As in 3, the injection preparation state is made in the state in which the injection liquid 200 is injected into the chamber 70.

At this time, when the rod 50 is advanced by the operation of the injection liquid backflow and leakage preventing means 8, the rod 50 is not flowed by the rod guide 60 formed outside the rod 50. It works smoothly.

In addition, when the rod 50 is advanced, the expansion spring 90 provided in the spacer 40 to elastically support the rod 50 is contracted. In this state, the injection liquid backflow and leakage prevention are prevented. The means 8 will keep the rod 50 in the pushed state.

Thereafter, air pressure is injected into the main cylinder 20 through the forward air inlet 22, and the working rod 21 is advanced by air pressure, and the coupler 30 connected to the working rod 21. The rod 50 is pushed forward as it moves forward.

Accordingly, the injection liquid injected into the chamber 70 while advancing the rod 50 maintaining the injection preparation state according to the operation of the injection liquid backflow and leakage preventing means 8 as shown in FIGS. 2 and 3. As shown in FIGS. 4 and 5, the injection liquid 200 is injected through the nozzle 73 of the chamber 70 as shown in FIGS. 4 and 5, and the piston 100 is nozzle 73 in the chamber 70. The injection of the injection liquid 200 is completed by advancing to the) site.

When the injection of the injection liquid 200 in the chamber 70 is completed, as shown in FIG. 4, air pressure is injected into the main cylinder 20 through the backward air inlet 23, and thus the operation is performed. The rod 21 is pushed backward, and the rod 50 is pushed backward by the expansion force of the expansion spring 90 that has been contracted inside the spacer 40 as the working rod 21 moves backward. .

In addition, the injection liquid backflow and leakage preventing means 8 is operated backward, and the injection liquid backflow and leakage preventing means 8 is caught from the locking piece 52 according to the backflow of the injection liquid backflow and leakage preventing means 8. The rod 50 is completely pushed backward by the expansion force of the expansion spring 90 to maintain the initial state of the needleless injection device according to the present invention as shown in FIG. 1.

Thereafter, the injection liquid 200 is injected into the chamber 70 through the injection liquid injection port 71, and the injection liquid backflow and leakage preventing means 8 moves forward to push the rod 50. As shown in FIG. 4, the injection preparation state of the injection liquid 200 is made, and as the rod 50 moves forward according to the operation of the main cylinder 20, the injection liquid 200 passes through the nozzle 73 as shown in FIG. 4. It is sprayed to the outside.

Thus, in the needleless injection device according to the present invention, a predetermined amount of the injection liquid 200 is automatically injected through the injection liquid injection port 71, and primarily according to the signal of the button B and the switch S. In order to prevent leakage along with the backflow of the injection liquid 200 injected into the chamber 70, the injection liquid backflow and leakage preventing means 8 is operated to advance the rod 50, and then the main cylinder 20 secondly. When the piston (100) injects the injection liquid 200 through the nozzle 73 while the rod 50 is operated while the main cylinder 20 and the injection liquid backflow and leakage preventing means (8) retreat to the original state. The operation of returning to the standby state is continuously performed with one operation signal.

The present invention is not limited to the above-described specific preferred embodiments, and various modifications can be made by any person having ordinary skill in the art without departing from the gist of the present invention claimed in the claims. Of course, such changes will fall within the scope of the claims.

1 housing 3 injection liquid advancement means
7: injection liquid injection means 8: injection liquid backflow and leakage preventing means
11 bushing 12 receiving part
20: main cylinder 21: working rod
22: forward air inlet 23: reverse air inlet
30: coupler 40: spacer
50: rod 51: release prevention jaw
52: jam piece 60: road guide
70: chamber 71: injection liquid inlet
72: air discharge hole 73: nozzle
74: cap 90: expansion spring
100: piston 110: o-ring
120: connection bracket 200: injection liquid
300: injection liquid supply means N: nut
B: Button S: Switch

Claims (9)

In the needle-free injection device for administering the injection in the subcutaneous tissue of the patient,
A housing 1 in which a receiving portion 12 is formed therein;
An injection liquid advancing means (3) for advancing the injection liquid (200) while operating forward and backward in accordance with the air pressure in the receiving portion (12) of the housing (1);
An injection liquid injection means (7) connected to the injection liquid advance means (3) and for injecting the injection liquid (200) advanced according to the operation of the injection liquid advance means (3);
Injection liquid backflow and leakage preventing means (8) connected to the injection liquid advance means (3) in the housing (1) to prevent backflow and leakage of the injection liquid (200) injected into the injection liquid injection means (7); Needle-free continuous scanning device, characterized in that configured to include. The method of claim 1,
The injection liquid advance means 3,
A main cylinder (20) having an actuating rod (21) formed in the receiving portion (12) of the housing (1) to operate forward and backward according to air pressure;
A coupler 30 fastened to the operation rod 21 of the main cylinder 20;
A spacer 40 fastened to the coupler 30;
It is inserted into the spacer 40 and protrudes to the outside, and pushes the injection liquid 200 to the injection liquid injection means 7 in accordance with the operation of the main cylinder 20 and the injection liquid backflow and leakage preventing means (8) A rod 50 to be given;
An expansion spring (90) formed in the spacer (40) to elastically support the rod (50);
A rod guide 60 formed on an outer surface of the rod 50 so that the rod 50 can be smoothly operated before and after;
Needleless continuous scanning device, characterized in that it comprises a; comprising a connecting bracket (120) formed on the outer surface of the rod guide (60). The method of claim 2,
Needleless continuous injection device, characterized in that the front air inlet 22 and the reverse air inlet (23) is formed so that the front and rear sides of the main cylinder 20, the operation rod (21) forward and backward. The method of claim 2,
Needleless continuous scanning device, characterized in that the piston (100) for pushing the injection liquid 200 in the injection liquid injection means (7) is mounted at one end of the rod (50). The method of claim 4, wherein
Needleless continuous injection device, characterized in that the outer circumference of the piston 100 is formed with an O-ring 110 so that the injection liquid 200 in the injection liquid injection means (7) does not leak. The method of claim 2,
The rod 50 has a separation preventing jaw 51 formed on one inner surface of the expansion spring 90 so as not to be separated, and a locking piece for allowing the injection liquid backflow and leakage preventing means 8 to contact an external intermediate portion. 52) needleless continuous scanning device, characterized in that formed. The method of claim 1,
The injection liquid injection means 7,
Injection liquid injection port 71 is formed to be supplied to the injection liquid 200 from the outside on one side,
The chamber 70 is connected to the injection liquid inlet 71 and the cap 70 is connected to the injection liquid advance means 3 so that the injection liquid 200 can be injected and discharged through the injection liquid inlet 71. Needle free continuous injection device. The method of claim 7, wherein
The chamber 70 is provided with an air discharge hole 72 so that the injection liquid 200 can be smoothly supplied into the chamber 70 through the injection liquid inlet 71 on the other side, and the injection liquid inlet at an end thereof. A needleless continuous injection device, characterized in that the nozzle (73) is formed so that the injection liquid 200 injected through the (71) can be injected in accordance with the advancing of the injection liquid forwarding means (3). The method of claim 1,
The injection liquid injection means 7 is characterized in that the injection liquid supply means 300 is connected to the injection liquid injection port 71 and detachable from the outside so as to continuously supply the injection liquid 200 into the chamber 70 Needle continuous injection device.

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