KR102385578B1 - Medication injection device - Google Patents

Abstract

The present invention relates to a drug injection device, and more particularly, when high energy is discharged into an incompressible fluid and the incompressible fluid is rapidly expanded, the drug is injected with a microjet so that the drug stored therein can be injected into the subcutaneous tissue with that force. It's about the device.
The drug injection device according to the present invention includes a housing, an elastic membrane, a pair of electrodes, a dielectric breakdown unit, and a charging means. The housing is formed with a receiving part for accommodating the drug therein, and has a nozzle for spraying the drug. The elastic membrane separates the receiving portion so that the incompressible fluid can be accommodated in the receiving portion to be separated from the drug. The pair of electrodes are mounted to the receiving portion in which the incompressible fluid is accommodated to be insulated from each other by a predetermined interval. The insulation breaking unit applies a high voltage to the electrodes so that the insulation of the pair of electrodes is broken and energized. The charging means provides the high energy to the electrode to inflate the incompressible fluid so as to pressurize the drug to be injected into the subcutaneous fat by injecting the drug into the nozzle when the electrode is energized by charging high energy. and a charging member, and a transfer switch for controlling the transfer of the high energy to the electrode.
According to the present invention, the pair of electrodes are spaced apart so as to conduct only at a voltage greater than or equal to the voltage supplied from the dielectric breakdown part. In this case, if the insulation breaking part is provided, it is possible to conduct electricity by breaking the insulation of the electrode even if a separate connection member is not provided in order to conduct electricity. Therefore, it is easy to reuse, so it is possible to reduce the replacement cost, and regardless of temperature and humidity, the operator can break the insulation of the electrode and energize it at the desired point in time to inject the drug to the operator.

Description

Drug injection device {Medication injection device}

The present invention relates to a drug injection device, and more particularly, when high energy is discharged into an incompressible fluid and the incompressible fluid is rapidly expanded, the drug is injected with a microjet so that the drug stored therein can be injected into the subcutaneous tissue with that force. It's about the device.

As a drug delivery system for injecting a drug into the body, a syringe having a needle has traditionally been used. However, these traditional syringes have been feared by patients due to pain during injection, and have unavoidable problems such as concerns about infection due to wounds.

In order to solve this problem, drug delivery systems such as needle-free injectors are being developed, and as part of this research, drugs are injected at high speed in a microjet method to directly penetrate the body through the epidermis of the skin. A drug delivery system is proposed.

In order to generate such a high-speed injection of the microjet method, it is necessary to precisely and strongly spray the drug to the outside (ie, the skin). This spraying method has been developed in various ways since the 1930s. Recently, a spraying method using a piezoelectric ceramic element, a spraying method using a shock wave induced by applying a laser beam to aluminum foil, a spraying method using Lorentz force, Various injection methods have been developed, such as an injection method using a laser-bubble. Also, recently, a submerged discharge type microjet injection method that can be made at a low cost by simplifying the structure and can easily control the pressure and speed of the microjet as desired has been developed.

In the submerged discharge method shown in FIG. 5, when the ground terminal 23 of the chemical liquid delivery body 20 is in contact with the ground terminal 13 of the discharge body 10, electrical energy is transferred from the power supply unit 11 to the electrode 23 side. is supplied Then, a high-temperature spark by electric energy is generated in the discharge body 24 connecting the electrodes 23 , and the plasma pressure generated through this is diffused in the pressure generating space 21 to expand the pressure generating liquid 21a. Then, as the pressure generating liquid 21a expands, the elastic separation membrane 23 is pressurized to spray the chemical solution 22a in the chemical solution accommodating space 22 to the nozzle 26 . At this time, since the discharge body 24 is vaporized by explosion by electric energy, there is a problem in that the entire chemical liquid delivery body 20 needs to be replaced in order to be reused. In addition, when electric energy is supplied to the discharge body 24 and energized, it is affected by temperature and humidity. Due to this, the minimum voltage required during energization is changed, so that energization may not be achieved at a desired time.

Patent Publication No. 10-2019-0117919 (published on October 17, 2019) Registered Patent No. 10-1207977 (Registration Date 2012.11.28) Patent Publication No. 10-2014-0021383 (published on February 20, 2014) Registered Patent No. 10-1549966 (Registration Date 2015.08.28) Registered Patent No. 10-1834773 (Registration Date 2018.02.27)

The present invention is to solve the above problems. The present invention has a simple structure, easy to reuse, and discharges high energy into an incompressible fluid so that when the incompressible fluid rapidly expands, the drug can be injected with a microjet so that the drug stored therein can be injected into the subcutaneous tissue with that force. The purpose is to provide a device.

The drug injection device according to the present invention includes a housing, an elastic membrane, a pair of electrodes, a dielectric breakdown unit, and a charging means. The housing is formed with a receiving part for accommodating the drug therein, and has a nozzle for spraying the drug. The elastic membrane separates the accommodating part so that the incompressible fluid can be accommodated in the accommodating part to be separated from the drug. The pair of electrodes are mounted to the receiving part in which the incompressible fluid is accommodated to be insulated from each other by a predetermined interval. The insulation-breaking unit applies a high voltage to the electrodes so that insulation of the pair of electrodes is broken to conduct electricity. The charging means provides the high energy to the electrode to inflate the incompressible fluid to pressurize the drug to be injected into the subcutaneous fat by injecting the drug to the nozzle when the electrode is energized by charging high energy and a charging member, and a transfer switch for controlling the transfer of the high energy to the electrode.

In addition, in the drug injection device, it is preferable that the insulation breakdown unit is provided with an insulation switch for controlling the transfer of the high voltage to the electrode.

In addition, in the drug injection device, the pair of electrodes is energized at a voltage greater than or equal to the voltage supplied from the dielectric breakdown unit, and is preferably spaced apart so as to be insulated at a voltage less than or equal to the voltage supplied from the charging means.

In addition, in the drug injection device, the charging means is preferably provided with a diode so that the current does not flow from the dielectric breakdown portion to the charging means.

Alternatively, in the drug injection device, the charging means is preferably a capacitor.

According to the present invention, the pair of electrodes are spaced apart so as to conduct only at a voltage greater than or equal to the voltage supplied from the dielectric breakdown part. In this case, if the insulation breaking part is provided, it is possible to conduct electricity by breaking the insulation of the electrode even if a separate connection member is not provided in order to conduct electricity. Therefore, it is easy to reuse, reducing replacement cost, and regardless of temperature and humidity, the operator can break the insulation of the electrode at the desired point in time to energize and inject the drug to the operator.

In addition, according to the present invention, the pair of electrodes are spaced apart so as to be insulated at a voltage equal to or less than the voltage supplied from the charging means. Therefore, even if sufficient energy is charged in the charging means, the insulating state can be maintained.

1 is a conceptual diagram of an embodiment of a drug injection device according to the present invention;
Figure 2 is a state diagram of the charging state of the embodiment shown in Figure 1,
3 is a diagram of the dielectric breakdown state of the embodiment shown in FIG. 1,
Figure 4 is a drug injection diagram of the embodiment shown in Figure 1,
5 is a conceptual diagram of a conventional drug shearing device.

An embodiment of the drug injection device according to the present invention will be described with reference to FIGS. 1 to 4 .

The drug injection device according to the present invention includes a housing 10 , an elastic membrane 20 , a pair of electrodes 30 , an insulation breaking unit 40 , and a charging means 50 .

The housing 10 has a receiving portion 11 for accommodating the drug 1 therein, and includes a nozzle 13 . Here, the nozzle 13 serves to inject the drug 1, and is located at one end of the housing 10 for this purpose. At this time, the drug 1 flowing out through the nozzle 13 is sprayed in the form of a microjet.

The elastic membrane 20 serves to separate the receiving unit 11 so that the incompressible fluid 3 can be accommodated in the receiving unit 11 by separating the drug 1 from it. Therefore, the receiving portion 11 is accommodated in the upper side by the elastic membrane 20, the incompressible fluid (3), the drug (1) is accommodated in the lower side.

The pair of electrodes 30 are mounted in the receiving portion 11 in which the incompressible fluid 3 is accommodated to be insulated from each other by a predetermined interval. Here, the pair of electrodes 30 is energized at a voltage greater than or equal to the voltage supplied from the insulation breakdown unit 40 , and is preferably spaced apart so as to be insulated at a voltage less than or equal to the voltage supplied from the charging means 50 . In the present embodiment, the pair of electrodes 30 are mounted in the receiving portion 11 to be spaced apart from each other by 10 mm to 20 mm.

The insulation breaking unit 40 serves to apply a high voltage to the electrode 30 so that the insulation of the pair of electrodes 30 is broken and energized. To this end, the insulation breakdown unit 40 includes a high voltage module 43 and an insulation switch 41 . The high voltage module 43 is connected to apply a high voltage to the pair of electrodes 30 so as to break the insulation of the pair of electrodes 30 , and the insulation switch 41 is connected to the electrode from the high voltage module 43 . Controls the transmission of high voltage to (30).

In the present embodiment, the dielectric breakdown unit 40 provides electrical energy of 10,000 V or more to the electrode 30 . In this case, as the energy provided, a higher voltage should be provided when the spaced apart distance of the electrode 30 is increased, and a voltage may be lowered when the spaced apart distance of the electrode 30 is reduced.

The charging means 50 injects the drug 1 into the nozzle 13 when the electrode 30 is energized to expand the incompressible fluid 3 so as to press the drug 1 to be injected into the subcutaneous fat. It serves to provide high energy to (30). To this end, the charging means 50 includes a charging member 53 , a transfer switch 55 , and a diode 51 . The charging member 53 can charge high energy through the power supply means 60, and provides high energy to the electrode 30 in order to expand the incompressible fluid so that the electrode 30 can inject a drug when energized. connected so that After connecting the charging member 53 to the power supply means 60 , when the power switch 61 is turned on, the charging member 53 is charged with energy supplied from the power supply means 60 . The transfer switch 55 controls the charging member 53 to transmit high energy to the electrode 30 . The diode 51 prevents current from flowing from the dielectric breakdown part 40 to the charging means 50 . In this embodiment, the charging member 53 of the charging means 50 is implemented as a capacitor, and provides electrical energy of 5,000V to 8,000V to the electrode 30 . In the case of this embodiment, since the insulation is broken when it is more than 10,000V, the power supplied from the charging means 50 must be less than 10,000V so that the insulation is not broken.

In the case of this embodiment, first, before using the drug delivery device, the power switch 61 is turned on by connecting the charging means 50 to the power supply means 60 as shown in FIG. 2 . Then, the charging means 50 is charged with sufficient energy. When the charging of the charging means 50 is completed, the preparation for use of the drug delivery device is completed. In order to use the drug delivery device, the insulation switch 41 of the insulation breakdown unit 40 is turned on as shown in FIG. 3 . When the isolation switch 41 is turned on, electrical energy of a high voltage of 10,000 V or more is supplied from the high voltage module 43 to the pair of electrodes 30 . Then, the insulation of the electrode 30 is broken to conduct electricity. When the pair of electrodes 30 is energized by the insulation breaking unit 40, the delivery switch 55 is turned on as shown in FIG. 4 to inject the drug. When the transfer switch 55 is turned on, electric energy of 5,000V to 8,000V is supplied from the charging means 50 to the electrode 30 . When the electrode 30 is energized and electric energy is supplied from the charging means 50 to the electrode 30 , a spark 5 due to electric energy is generated between the electrodes 30 , thereby causing the pressure in the receiving part 11 . This momentarily rises to expand the incompressible fluid (3). Then, as shown in FIG. 4 , the elastic membrane 20 presses the drug 1 by the expansion of the incompressible fluid 3 . Then, the drug 1 is rapidly injected through the nozzle 13 . At this time, since the nozzle 13 is in contact with the skin, it is possible for the injected drug 1 to be injected into the subcutaneous fat through the skin. The charging means 50 in which the supply of high voltage electric energy is completed can be used again by charging it through the power supply means 60 .

In the conventional case, as shown in FIG. 5 , when the ground terminal 23 of the chemical liquid delivery body 20 is in contact with the ground terminal 13 of the discharge body 10, electricity is supplied from the power supply unit 11 to the electrode 23 side. energy was supplied. Then, a high-temperature spark by electric energy is generated in the discharge body 24 connecting the electrodes 23, and the plasma pressure generated through this is diffused in the pressure generating space 21 to expand the pressure generating liquid 21a. Then, as the pressure generating liquid 21a is expanded, the elastic separation membrane 23 is pressurized to spray the chemical solution 22a in the chemical solution accommodating space 22 to the nozzle 26 . At this time, since the discharge body 24 is vaporized by explosion by electric energy, there is a problem in that the entire chemical liquid delivery body 20 needs to be replaced in order to be reused. In addition, when electric energy is supplied to the discharge body 24 and energized, it is affected by temperature and humidity. Due to this, the minimum voltage required during energization is changed, so that energization may not be achieved at a desired time. On the other hand, according to the present invention, the pair of electrodes 30 are spaced apart to conduct only at a voltage greater than or equal to the voltage supplied from the dielectric breakdown unit 40 . In this case, if the insulation breaking part 40 is provided, it is possible to conduct electricity by breaking the insulation of the electrode 30 even if a separate connection member is not provided in order to conduct electricity through the electrode 30 . Therefore, it is possible to easily reuse and reduce replacement cost, and regardless of temperature and humidity, the operator can break the insulation of the electrode 30 and energize it at the desired time, thereby injecting the drug to the operator. In addition, according to the present invention, the pair of electrodes 30 are spaced apart so as to be insulated at a voltage equal to or less than the voltage supplied from the charging means 50 . Therefore, even if sufficient energy is charged in the charging means 50, the insulating state can be maintained.

1: Drug 3: Incompressible fluid
5: spark 10: housing
11: accommodating part 13: nozzle
20: elastic film 30: electrode
40: insulation breakdown part 41: insulation switch
43: high voltage module 50: charging means
51: diode 53: charging member
55: transfer switch 60: power supply means
61: power switch

Claims (5)

A housing having a receiving part for accommodating the drug therein, and a nozzle for spraying the drug;
An elastic membrane for separating the accommodating part so that the incompressible fluid can be accommodated in the accommodating part to be separated from the drug;
A pair of electrodes mounted on the receiving part in which the incompressible fluid is accommodated and spaced apart so as to be insulated;
Insulation breaking part for applying a high voltage to the electrode so that the insulation of the pair of electrodes is broken and energized;
A filling member that provides the high energy to the electrode in order to fill the high energy and expand the incompressible fluid to pressurize the drug to inject the drug into the subcutaneous fat by injecting the drug into the nozzle when the electrode is energized; , a charging means having a transfer switch for controlling the transfer of the high energy to the electrode,
The pair of electrodes is energized at a voltage greater than or equal to the voltage supplied from the insulation breakdown unit, and is spaced apart so as to be insulated from the voltage below the voltage supplied from the charging means. According to claim 1,
The drug injection device, characterized in that the insulation breakdown unit is provided with an insulation switch for controlling the transfer of the high voltage to the electrode. 3. The method of claim 2,
The charging means is a drug injection device, characterized in that provided with a diode so that the current does not flow from the dielectric breakdown part to the charging means. 4. The method according to any one of claims 1 to 3,
The charging means is a drug injection device, characterized in that the capacitor. delete

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