KR102565598B1 - Micro-jet injection device capable of adjusting the amount of medicine liquid - Google Patents

Abstract

The present invention relates to a microjet injection device capable of adjusting a capacity of a chemical solution, and more particularly, to a microjet injection device capable of adjusting a capacity of a chemical solution by adjusting a space accommodating the chemical solution, comprising: a shear case formed in a cylindrical shape; a cylindrical cylinder that is coaxially and closely coupled within the front case and has a working fluid inlet formed at a rear end through which the working fluid is delivered; A piston coaxially installed in the cylinder and transmitting the pressing force by the working fluid to the front end; a syringe that is exposed to the outside of the front end of the front end of the front end of the front end of the front end of the piston and is inserted and connected to the inside of the front end of the front end of the front end of the front end of the front end of the front end of the front end of the front end of the front end of the front end of the front end of the front end of the piston; a cylindrical electrode mount formed inside the front end case at the rear end of the piston and having a working fluid transfer path to the inside; a pair of electrodes fastened to the electrode mount with a gap between the top and bottom, the ends of which are disposed to be submerged in the working fluid; a rear case having a front end coupled to the front case in communication, a rear end sealed by a cover, and a wire connection socket formed in the center of the cover; a working fluid chamber coaxially coupled to the inside of the rear end case and receiving a working fluid therein; a wire connected through a space between the rear end case and the working liquid chamber, led in from the wire connection socket and connected to the electrode mount; a working fluid pressurized base in which the front end portion is coaxially and airtightly inserted at the rear end of the working fluid chamber, and the rear end portion has a screw thread formed on the central axis; The front end portion is formed of an adjusting screw fastened to the central axis of the rear end portion of the operating fluid presser, and the rear end portion is formed of an operating fluid adjusting screw formed of an adjusting dial exposed to the outside of the rear end case.

Description

Microjet injection device capable of adjusting the capacity of the drug solution {MICRO-JET INJECTION DEVICE CAPABLE OF ADJUSTING THE AMOUNT OF MEDICINE LIQUID}

The present invention relates to a microjet injection device capable of adjusting a capacity of a chemical solution, and more particularly, to a microjet injection device capable of adjusting a capacity of a chemical solution by adjusting a space accommodating a chemical solution.

A syringe is generally used to inject a chemical solution into the body of an organism. Since these syringes directly inject the drug solution by pushing the needle provided at the end into the body, the subject feels fear and rejection compared to other drug administration methods, and there is a risk of infection because it directly wounds the skin. In addition, since the disposable syringe is directly inserted into the body of a patient holding pathogens, special care is required in handling medical waste, and there is also a risk that the needle may be exposed as it is during the disposal process.

In order to solve this problem, a drug delivery device such as a needle-free injector has recently been developed, and as part of this research, a system that injects a drug solution at high speed in a microjet method and penetrates through the epidermis of the skin is proposed. there is.

In order to generate high-speed injection like the microjet method, a precise and powerful injection system is required to penetrate the drug into the skin precisely and powerfully. Representative examples include a spraying method using a piezoelectric ceramic element, a spraying method using a shock wave caused by applying a laser beam to an aluminum foil, a spraying method using a Lorentz force, and a spraying method using a laser-bubble etc.

Microjet-type needle-free syringes using the above method require a large size and high cost depending on the type of injection system, and it is difficult to control the amount of liquid injected, so it is difficult to separately measure and control the components. There are problems that need to be provided, and the development of related technologies is urgently needed.

[0001] Korean Patent Registration No. 10-2209394 (Microjet drug delivery system) [0002] Korean Registered Patent Publication No. 10-2287079 (optical fiber-based needle-free injection with connector for supplying chemical solution) [0003] Korean Patent Laid-open Publication No. 10-2021-0127632 (Chemical solution injection device using pulse shock wave)

One object of the microjet injection device capable of adjusting the capacity of the chemical solution according to the present invention is to use a simple dial structure to adjust the space for accommodating the chemical solution, thereby controlling the total amount of the injected chemical liquid. Microjet injection capable of adjusting the capacity of the chemical solution to provide the device.

And, another object of the present invention is to provide a microjet injection device capable of adjusting the capacity of a chemical solution capable of microjet jetting a chemical solution contained therein by pushing a piston by generating an expansion pressure by a discharge spark in the working fluid. .

Shear case formed in a cylindrical shape; a cylindrical cylinder that is coaxially and closely coupled within the front case and has a working fluid inlet formed at a rear end through which the working fluid is delivered; A piston coaxially installed in the cylinder and transmitting the pressing force by the working fluid to the front end; a syringe that is exposed to the outside of the front end of the front end of the front end of the front end of the front end of the piston and is inserted and connected to the inside of the front end of the front end of the front end of the front end of the front end of the front end of the front end of the front end of the front end of the front end of the front end of the front end of the piston; a cylindrical electrode mount formed inside the front end case at the rear end of the piston and having a working fluid transfer path to the inside; a pair of electrodes fastened to the electrode mount with a gap between the top and bottom, the ends of which are disposed to be submerged in the working fluid; a rear case having a front end coupled to the front case in communication, a rear end sealed by a cover, and a wire connection socket formed in the center of the cover; a working fluid chamber coaxially coupled to the inside of the rear end case and receiving a working fluid therein; a wire connected through a space between the rear end case and the working liquid chamber, led in from the wire connection socket and connected to the electrode mount; a working fluid pressurized base in which the front end portion is coaxially and airtightly inserted at the rear end of the working fluid chamber, and the rear end portion has a screw thread formed on the central axis; The front end is formed by an adjustment screw fastened to the central axis of the rear end of the operating fluid pressurizer, and the rear end is an operating fluid adjustment screw composed of an adjustment dial exposed to the outside of the rear end case. A microjet injection device is the subject of the present invention.

Preferably, the cylinder is a microjet injection device capable of adjusting the capacity of the chemical liquid, characterized in that it includes a stopper for limiting the forward movement of the piston on the inside.

The operating fluid presser includes a pressure plate guide disposed on an outer circumferential surface of the operating fluid presser and formed from the rear end of the operating fluid chamber to the front end of the control dial to guide the forward and backward movement of the operating fluid presser. It is preferable to be a microjet injection device capable of adjusting the capacity of the chemical solution characterized in that.

The operating fluid control screw is fixedly coupled to the rear surface of the control dial, fixed to the inner upper end of the rear end case, and a dial fixing panel for guiding the wire drawn from the socket to the inner circumferential direction of the rear end case. It is preferable to be a microjet injection device capable of adjusting the capacity of the chemical solution characterized in that.

A discharge body is provided between the electrodes, and when electricity is applied to the electrodes, an expansion pressure is generated in the working liquid by a discharge spark to press the piston to spray the chemical liquid in micro units. It is desirable to have a microjet injection device capable of this.

According to the present invention, there is an effect of providing a microjet injection device capable of adjusting the capacity of the chemical solution capable of adjusting the total amount of the injected chemical solution.

In addition, there is an effect of providing a microjet injection device capable of adjusting the capacity of the chemical solution capable of microjet ejecting the chemical solution contained therein by pushing the piston by generating expansion pressure by submerged discharge.

1 is an internal cross-sectional view of a microjet injection device capable of adjusting a capacity of a chemical solution according to the present invention before adjusting a space for accommodating a chemical solution.
FIG. 2 is an internal cross-sectional view after adjusting the space for accommodating the chemical solution of the microjet injection device capable of adjusting the capacity of the chemical solution according to the present invention.
3 is an external perspective view of the microjet injection device capable of adjusting the capacity of the chemical solution according to the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. However, in describing the present invention, descriptions of already known functions or configurations will be omitted to clarify the gist of the present invention.

In addition, the terms used in the present invention have been selected from general terms that are currently widely used as much as possible while considering the functions in the present invention, but they may vary depending on the intention or precedent of a person skilled in the art, the emergence of new technologies, etc. Therefore, the term used in the present invention should be defined based on the meaning of the term and the overall content of the present invention, not simply the name of the term.

And, when a part in the entire specification "includes" a certain component, it means that it may further include other components, not excluding other components unless otherwise stated.

Hereinafter, with reference to the accompanying drawings, embodiments of the present invention will be described in detail so that those skilled in the art can easily carry out the present invention. However, the present invention may be embodied in many different forms and is not limited to the embodiments described herein. And in order to clearly explain the present invention in the drawings, parts irrelevant to the description are omitted, and similar reference numerals are attached to similar parts throughout the specification.

Referring to the embodiments of the present invention with reference to the accompanying drawings, as shown in FIGS. Piston (30), syringe (40), electrode mount (50), electrode (60), rear end case (70), working fluid chamber (80), wire (90), working fluid pressurizer (100), working fluid control It consists of a screw 110.

The shear case 10 is formed in a cylindrical shape, a space is provided therein, and the front surface is opened in a hole shape to communicate with the inside.

The cylinder 20 is coaxially and closely coupled in the shear case 10, and an operating fluid inlet 21 through which the operating fluid L is passed to the inside is formed.

The piston 30 is coaxially installed in the cylinder 20 and transfers the pressing force by the working fluid L to the front end.

At this time, a space portion in which the piston 30 is installed and driven is provided inside the cylinder 20, and is formed to communicate with the working fluid inlet 21 so that the working fluid L flowing from the working fluid inlet 21 is supplied to the piston ( 30) is formed to move by pressing the rear end.

And, the piston 30 may be composed of a head part and an insertion part.

The head part is formed on the upper side and is closely coupled to the inner space of the cylinder 20 so that when the working fluid L is introduced into the working fluid inlet 21, the working fluid L is directly received and moved downward by receiving the pressing force. L) is preferably formed so that it does not flow in the front end direction from the rear end of the head part.

The insertion unit is formed at the center of the front surface of the head unit and has a diameter smaller than that of the head unit and is inserted into the syringe 40 .

The syringe 40 is installed so as to be exposed to the outside of the front end case 10, and the front end of the piston 30 is inserted into and connected to the inside.

At this time, the rear end of the syringe 40 is open and the piston 30 is inserted into the inside, and the volume of the space in which the liquid medicine L is accommodated is determined according to the degree of insertion of the piston 30.

That is, it is preferable that the insertion part of the piston 30 is tightly coupled to the inner space of the syringe 40 and driven by the piston.

Therefore, when the head of the piston 30 is pressurized by the movement of the working fluid (L) and moves forward, the insertion portion moves forward in the inner space of the syringe 40 so that the chemical fluid (M) is accommodated in the space. volume will decrease.

The electrode mount 50 has a cylindrical shape, is disposed at the rear end of the piston 30 in the front case 10, and has a working fluid delivery path to the inside.

A pair of electrodes 60 are provided and fastened to the electrode mount 50 with a gap between the top and bottom, and the ends are disposed so as to be submerged in the working fluid L.

At this time, the electrode mount 50 fixes the electrode 60 and dissipates heat generated from the electrode 60 .

In addition, it is preferable that the electrode mount 50 is formed of a conductive material and transfers current transmitted from the outside to the electrode 60 .

The front end of the rear case 70 is communicatively coupled to the front case 10, and the rear end is sealed by a cover 71.

In addition, a wire connection socket 72 is coupled to the center of the cover 71, and the wire connection socket 72 may include a power input unit and a wire withdrawal unit.

At this time, a member for fixing the rear end case 70 and the cover 71 may be provided.

The working fluid chamber 80 is coaxially coupled to the inside of the rear end case 70, and a space for receiving the working fluid L is provided therein.

At this time, the front end of the working fluid (L) accommodating space inside the working fluid chamber 80 is formed in communication with the working fluid delivery path so that the working fluid (L) is delivered in the direction of the electrode mount (50).

The wire 90 is introduced from the wire connection socket 72 and connected to the electrode mount 50, and transfers electrical energy input from the outside to the electrode mount 50.

At this time, the wire 90 is connected through a space between the rear case 70 and the working liquid chamber 80, and is preferably disposed in close contact with the inner wall surface of the rear case 70.

The front end of the working fluid pressure table 100 is coaxially and airtightly inserted at the rear end of the working fluid chamber 80, and the rear end is formed with a hole including a screw thread on the central axis.

In addition, the operating fluid adjusting screw 110 disposed at the rear end of the operating fluid pressure base 100 is composed of an adjusting screw 111 and an adjusting dial 112.

The adjustment screw 111 is fastened to the central axis of the rear end of the operating fluid pressurized table 100, and a screw thread is formed on the outer circumferential surface.

The adjustment dial 112 is formed at the rear end of the adjustment screw 111 and exposed to the outside of the rear end case 70 .

At this time, the adjusting dial 112 has a screw head shape of the adjusting screw 111, and the adjusting screw 111 can be rotated by rotating the outer circumferential surface of the adjusting dial 112.

Accordingly, when the adjusting dial 112 is rotated, the adjusting screw 111 is rotated, and the operating fluid pressure base 100 and the screw threads of the adjusting screw 111 are interlocked to move, thereby controlling the forward and backward driving.

In addition, the cylinder 20 of the microjet injection device capable of adjusting the capacity of the chemical liquid according to the present invention may include a stopper 22.

The stopper 22 is formed inside the cylinder 20 to limit the forward movement of the piston 30 .

That is, by using the step difference between the head part and the insertion part of the piston 30, the insertion part passes through and is formed to be caught on the lower surface of the head part so that the movement can be restricted.

In addition, the operating fluid pressure table 100 of the microjet injection device capable of adjusting the capacity of the drug solution according to the present invention may include a pressure plate guide 101.

The press plate guide 101 is disposed on the outer circumferential surface of the working fluid press table 100, and is formed from the rear end of the working fluid chamber 80 to the front end of the control dial 112, so that the working fluid press table 100 Guides forward and backward movement.

That is, it is preferable that the pressure base guide 101 is disposed to surround the outer circumferential surface of the operating fluid pressure base 100 .

In addition, the operating fluid adjusting screw 110 of the microjet injection device capable of adjusting the capacity of the chemical solution according to the present invention may include a dial fixing panel 113.

The dial fixing panel 113 is fixedly coupled to the rear surface of the control dial 112 and is fixed to the inner upper end of the rear end case 70 .

That is, it is preferable that the control dial 112 is fixed to the front side of the fixed panel 113 and the rear side is fixed to the inner upper surface of the rear case 70 .

At this time, the dial fixing panel 113 may guide the wire 90 introduced from the wire connection socket 72 toward the inner peripheral surface of the rear case 70.

Therefore, the wire 90 is connected to the electrode mount 50 in a fixed state along the inner upper surface and the inner circumferential surface of the rear end case 70 from the center of the wire connection socket 70 .

In addition, the microjet injection device capable of adjusting the capacity of the chemical solution according to the present invention may be configured to microjet inject the chemical solution by submerged discharge.

As an example, a discharge body 61 is formed between the pair of electrodes 60 . Electric energy is applied to the wire connection socket 72, and current is transmitted to the electrode mount 50 and the electrode 60 along the wire 90, and a discharge spark is generated in the working fluid L. As a result, an expansion pressure is generated so that the piston 30 is pressurized and moves forward, and the liquid medicine contained in the syringe 40 is sprayed outward.

As described above, the basic technical idea of the present invention relates to a microjet injection device capable of adjusting a capacity of a chemical solution, and more particularly, to a microjet injection device capable of adjusting a capacity of a chemical solution by adjusting a space accommodating a chemical solution.

Of course, various modifications are possible by those skilled in the art within the scope of the basic technical idea of the present invention, and therefore, the scope of the present invention should be interpreted within the scope of the patent claims prepared to include various modifications. will be.

10: Shear case
20: cylinder
21: working fluid inlet
22 : stopper
30: piston
40: syringe
50: electrode mount
60: electrode
61: discharge body
70: rear end case
71: cover
72: wire connection socket
80: working fluid chamber
90: wire
100: working fluid pressure stand
101: pressurizer guide
110: working fluid adjustment screw
111: adjustment screw
112: control dial
113: dial fixing panel
L: working fluid
M: chemical solution

Claims (5)

Shear case formed in a cylindrical shape;
a cylindrical cylinder that is coaxially and closely coupled within the front case and has a working fluid inlet formed at a rear end through which the working fluid is delivered;
A piston coaxially installed in the cylinder and transmitting the pressing force by the working fluid to the front end;
a syringe that is exposed to the outside of the front end of the front end of the front end of the front end of the front end of the piston and is inserted and connected to the inside of the front end of the front end of the front end of the front end of the front end of the front end of the front end of the front end of the front end of the front end of the front end of the front end of the piston;
a cylindrical electrode mount formed inside the front end case at the rear end of the piston and having a working fluid transfer path to the inside;
a pair of electrodes fastened to the electrode mount with a gap between the top and bottom, the ends of which are disposed to be submerged in the working fluid;
a rear case having a front end coupled to the front case in communication, a rear end sealed by a cover, and a wire connection socket formed in the center of the cover;
a working fluid chamber coaxially coupled to the inside of the rear end case and receiving a working fluid therein;
a wire connected through a space between the rear end case and the working liquid chamber, led in from the wire connection socket and connected to the electrode mount;
a working fluid pressurized base in which the front end portion is coaxially and airtightly inserted at the rear end of the working fluid chamber, and the rear end portion has a screw thread formed on the central axis;
The front end is formed by an adjustment screw fastened to the central axis of the rear end of the operating fluid pressurizer, and the rear end is an operating fluid adjustment screw composed of an adjustment dial exposed to the outside of the rear end case. Microjet injection device. According to claim 1,
the cylinder,
A microjet injection device capable of adjusting the capacity of the chemical liquid, comprising a stopper inside to limit the forward movement of the piston. According to claim 1,
The working fluid pressure stand,
A pressure plate guide disposed on the outer circumferential surface of the pressure plate and formed from the rear end of the pressure chamber to the front end of the control dial to guide the forward and backward movement of the pressure pressure plate; Adjustable microjet injection device. According to claim 1,
The working fluid adjusting screw,
The drug liquid characterized in that it comprises a; dial fixing panel fixedly coupled to the rear surface of the control dial, fixed to the inner upper end of the rear end case, and guiding the wire drawn from the wire connection socket to the inner circumferential direction of the rear end case. Microjet injection device with adjustable capacity. According to claim 1,
A discharge body is provided between the electrodes,
When electricity is applied to the electrode, an expansion pressure by a discharge spark is generated in the working fluid to pressurize the piston to inject the chemical solution in micro units.