KR102518758B1 - Needleless injector - Google Patents

Abstract

A needle-free syringe capable of injecting an optimal drug to a person subject to treatment without a needle is provided with a simple configuration. The needle-free syringe allows the drug to be injected with strong pressure according to the movement of the piston using the elastic force caused by the compression and release of the spring so that the drug can be injected to the person being treated.

Description

Needle-free syringe {NEEDLELESS INJECTOR}

The present invention relates to a syringe, and more particularly, to a needle-free syringe capable of optimally injecting a drug to a subject without a needle with a simple configuration.

In general, injection of the drug is performed using an oil immersion syringe. The injection method using such an oil immersion syringe has various problems such as cross-contamination of the subject to be injected, pain associated with the injection, and the possibility of the needle breaking or falling out in the subject to be injected.

Accordingly, in order to solve the problems associated with the oil immersion syringe, an injection method using a needleless syringe without a needle has recently been developed. A needle-free syringe typically refers to a device capable of injecting a high-pressure injection solution into the skin of a human or animal for injection.

Conventional needle-free syringes are powered by an external power source, such as an external gas source, to provide sufficient energy to move the drug solution through the skin.

For this reason, since the conventional needle-free syringe must be provided with a separate gas supply equipment, the overall size is increased, which causes inconvenience in operation. In addition, the conventional needle-free syringe has a complicated design and increases manufacturing cost, and it is difficult to control the injection amount of the drug solution because the injection amount of the drug solution is set when the syringe is manufactured.

KR Patent Publication No. 10-2012-0103859 (2012.09.20)

The present invention is to provide a needle-free syringe capable of optimally injecting a drug to a subject without a needle with a simple configuration in order to solve these problems.

A needle-free syringe according to an embodiment of the present invention is accommodated in a housing composed of a body portion and a handle portion, a drug container coupled to the upper side of the body portion, and the inside of the body portion, and the drug supplied from the drug container is applied to the skin of a person receiving treatment. It includes a scanning module that fires with

Here, the injection module is exposed to the front side of the body and the supply unit to which the drug is supplied from the drug container, and forwardly moves the piston to the discharge unit for receiving and charging the drug from the supply unit and the internal cavity of the discharge unit. and a launching unit that allows the charged drug to be launched onto the skin of a subject.

The needle-free syringe of the present invention allows the drug to be injected with strong pressure according to the movement of the piston using the elastic force caused by the compression and release of the spring, so that the drug can be injected to the person being treated.

Accordingly, the needle-free syringe of the present invention can be implemented with a simple configuration compared to the prior art, thereby reducing manufacturing costs, and injecting drugs to the subject without a needle, preventing problems such as broken needles. there is.

In addition, the needle-free syringe of the present invention can control the amount and pressure of the drug launched by the piston by adjusting the elastic force of the spring. Accordingly, the injection amount and the firing pressure of the drug may be adjusted according to the condition of the person to be treated so that the injection is optimally tailored to the person to be treated.

1 is a view showing a needle-free syringe according to an embodiment of the present invention.
2 is a diagram showing the configuration of the scanning module of FIG. 1;
FIG. 3 is a view showing the first rotating body of FIG. 2 .
FIG. 4 is a view specifically illustrating part A of FIG. 2 .
5A to 5C are diagrams illustrating the operation of a needleless syringe according to an embodiment of the present invention.

The terms or words used in this specification and claims are not limited to the usual or dictionary meanings, and the inventor can properly define the concept of the term in order to explain his or her invention in the best way. Based on this, it should be interpreted as a meaning and concept consistent with the technical spirit of the present invention.

Throughout the specification, when a certain component is said to "include", it means that it may further include other components without excluding other components unless otherwise stated. In addition, terms such as “… unit”, “… unit”, “module”, and “device” described in the specification mean a unit that processes at least one function or operation, which is implemented as a combination of hardware and/or software. It can be.

Throughout the specification, the term "and/or" should be understood to include all possible combinations from one or more related items. For example, the meaning of “a first item, a second item and/or a third item” may be presented from two or more of the first, second or third item as well as the first, second or third item. A combination of all possible items.

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

1 is a view showing a needle-free syringe according to an embodiment of the present invention, and FIG. 2 is a view showing the configuration of the injection module of FIG.

Referring to the drawings, the needle-free syringe 100 of the present invention may include a needle-free injection module 120 without a needle. Accordingly, the needle-free syringe 100 allows the drug to be injected with strong pressure from the injection module 120 in a state where one side of the injection module 120 is in contact with the skin of a person to be treated, for example, a human or animal, so that the drug is injected into the skin of the person to be treated. can be injected.

Accordingly, the needle-free syringe 100 of the present embodiment is coupled to the housing 110 forming the appearance of the syringe, the injection module 120 accommodated inside the housing 110, and the housing 110, and the injection module ( 120) may include a drug container 200 for supplying drugs.

The housing 110 may include a body portion 111 and a handle portion 115 extending from one side of the body portion 111 and gripped by a user's hand, that is, an operator.

An inner space is formed in the body portion 111, and the scan module 120 may be accommodated in the space. One end of the body portion 111, for example, the front side, may be formed with a first opening 111a exposing a part of the scan module 120, for example, the discharge unit 130 of the scan module 120 to the outside. A second opening 111b to which the drug container 200 is coupled may be formed on the upper side of the body portion 111.

An inner space is formed in the handle part 115, and a battery part 180 supplying operating power to the scan module 120 may be disposed in the space. The battery unit 180 may be a general battery or a rechargeable battery capable of being charged.

The scan module 120 may include a discharge unit 130 , a supply unit 140 and a firing unit 150 . The remaining units of the scan module 120 except for the discharge unit 130 may be accommodated inside the body portion 111 of the housing 110 . The injection module 120 discharges the drug supplied from the supply unit 140 to the discharge unit 130 according to a predetermined pressure applied from the discharge unit 150 to the discharge unit 130, for example, the elastic force of the elastic member. (130), that is, it can be fired into the skin of the pisisulja.

The discharge unit 130 of the scan module 120 is disposed to be exposed to the outside of the housing 110 and may come into contact with the skin of a person to be treated. The discharge unit 130 may eject the drug supplied through the supply unit 140 to the outside according to the operation of the firing unit 150 . The discharge unit 130 may include a drug discharge unit 131 and a protective cap 135.

The drug dispensing unit 131 includes a first flow path 132 through which the drug is supplied from the supply unit 140, a first cavity 133 where the drug supplied through the first flow path 132 is temporarily stored, and the first It may include a nozzle 134 formed on one side of the cavity 133 to launch the drug.

Here, the piston 161 of the firing unit 150 to be described later may be inserted into the first cavity 133 and moved in a horizontal direction, for example, forward and backward. Accordingly, the inner diameter of the first cavity 133 may be formed to be the same as the outer diameter of the piston 161 .

In addition, the nozzle 134 may be formed to have an inner diameter significantly smaller than that of the first cavity 133 in order to increase the firing pressure of the drug.

The drug ejection unit 131 may further include one or more backflow preventing units 137 . Referring to FIGS. 2 and 5A , the backflow prevention unit 137 may be disposed within the first flow path 132 of the drug dispensing unit 131 . However, the present invention is not limited thereto, and one or more backflow prevention units 137 may be disposed inside the passage of the supply unit 140 to be described later.

The backflow prevention unit 137 may prevent the drug supplied to the first cavity 133 through the first flow path 132 from flowing backward toward the supply unit 140 through the first flow path 132 . The backflow prevention unit 137 may include an elastic member such as a spring and a shielding member connected thereto.

In addition, the drug ejection unit 131 may further include one or more air inflow prevention units 138 . Referring to FIGS. 2 and 5A , the air inflow prevention unit 138 is disposed within the nozzle 134 to prevent external air from flowing into the first cavity 133 through the nozzle 134 . The air inflow prevention unit 138 may include an elastic member such as a spring and a shielding member connected thereto.

The above-described backflow prevention unit 137 and air inflow prevention unit 138 may open or shield corresponding areas, for example, the inside of the first flow path 132 and the inside of the nozzle 134 according to the operation of the firing unit 150. .

For example, when the piston 161 moves backward in the first cavity 133 by the firing unit 150, the backflow prevention unit 137 opens the first flow path 132, and the air inflow prevention unit 138 The nozzle 134 may be shielded. Accordingly, the drug may flow into the first cavity 133 through the first flow path 132 and be temporarily stored.

In addition, when the piston 161 moves forward in the first cavity 133 by the firing unit 150, the backflow prevention unit 137 shields the first flow path 132, and the air inflow prevention unit 138 The nozzle 134 can be opened. Thus, the drug temporarily stored in the first cavity 133 may be ejected to the outside through the nozzle 134 .

Meanwhile, according to another embodiment of the present invention, the backflow prevention unit 137 may open or block the first flow path 132 according to the operation of the supply unit 140 . For example, when a drug is supplied from the supply unit 140 to the first flow path 132, the backflow prevention unit 137 may open the inside of the first flow path 132 by the pressure of the supplied drug.

The protective cap 135 may be coupled and disposed to surround the outside of the drug dispensing unit 131 . The protective cap 135 may prevent the nozzle 134 of the drug dispensing unit 131 from directly contacting the skin of a person being treated. To this end, one end of the protective cap 135 may be formed extending beyond one end of the corresponding drug ejection unit 131 to come into contact with the skin of the person being treated. In addition, the other end of the protective cap 135 may be arranged to maintain a predetermined distance from the drug ejection unit 131 by a trigger unit 136 to be described later. The protective cap 135 may be formed of a material such as soft plastic in order to reduce the user's contact resistance.

Meanwhile, the discharge unit 130 may further include a trigger unit 136 capable of controlling the operation of the firing unit 150. The trigger unit 136 may include one or more space maintaining members 136a and a sensor 136b disposed between the drug dispensing unit 131 and the protective cap 135.

The gap maintaining member 136a may be disposed between the other end of the protective cap 135 and one side of the drug ejection unit 131 corresponding thereto. The gap maintaining member 136a may be composed of an elastic member such as a spring.

The distance maintaining member 136a maintains a constant distance between the other end of the protective cap 135 and one side of the drug dispensing unit 131 in normal times, and when one end of the protective cap 135 is in contact with the skin of the person being treated The other end of the protective cap 135 may contact one side of the drug ejection unit 131 .

The sensor 136b may be disposed on one side of the drug ejection unit 131. The sensor 136b may detect a gap between the protective cap 135 and the drug ejection unit 131 and output a trigger signal.

For example, when a predetermined distance is maintained between the other end of the protective cap 135 and one side of the drug ejection unit 131 by the above-described gap maintaining member 136a, the sensor 136b does not output a trigger signal. On the other hand, when the protective cap 135 is in contact with the skin of a person to be treated and the other end of the protective cap 135 is in contact with one side of the drug ejection unit 131, the sensor 136b may output a trigger signal.

Here, the trigger signal output from the sensor 136b may be provided to the driving unit 170 of the firing unit 150. The driving unit 170 may control the rotation direction of the first rotating body 171 based on the trigger signal. The operation of the trigger unit 136 will be described in detail later with reference to the drawings.

The supply unit 140 of the scan module 120 may be disposed between the discharge unit 130 and the firing unit 150 inside the housing 110 . The supply unit 140 may receive a drug from the drug container 200 coupled to the housing 110 and deliver the drug to the discharge unit 130 .

The supply unit 140 may include a drug injection unit 141, a second flow path 142, and a second cavity 143.

The drug injection unit 141 is connected to the inlet of the drug container 200 to receive the drug from the drug container.

The second flow path 142 may be formed between the drug injection unit 141 and the first flow path 132 of the discharge unit 130 . The second flow path 142 may supply the drug supplied to the drug injection unit 141 to the first flow path 132 .

As described above, one or more backflow prevention units may be disposed inside the second flow path 142, and the backflow prevention unit prevents the drug supplied to the second flow path 142 from flowing back toward the drug injection unit 141. can

The second cavity 143 may be formed to be disposed on the same line as the first cavity 133 of the discharge unit 130 . Like the first cavity 133, the piston 161 of the firing unit 150 is inserted into the second cavity 143 and can move forward and backward. Accordingly, the inner diameter of the second cavity 143 may be formed to be the same as the outer diameter of the piston 161 .

In addition, the supply unit 140 may further include a heater 145 so that the drug flowing through the second flow path 142 has a uniform viscosity. The heater 145 may receive operation power from the above-described battery unit 180 and heat the drug flowing through the second flow path 142 to a set temperature. At this time, the heater 145 may be selectively operated when the drug is supplied to the supply unit 140 to heat the inside of the second flow path 142 .

The firing unit 150 of the scan module 120 may be connected to the supply unit 140 inside the housing 110 . The firing unit 150 applies a predetermined pressure to the inside of the first cavity 133 of the discharge unit 130 and the second cavity 143 of the supply unit 140, thereby spraying the drug through the discharge unit 130. can be made The firing unit 150 may include a firing unit 160 and a driving unit 170.

The firing unit 160 may include a piston 161 and a cylinder 162 into which one side of the piston 161 is inserted.

One side of the piston 161 may be inserted into the cylinder 162 and coupled to the spring 165 . The other side of the piston 161 may be exposed to the outside of the cylinder 162 . The piston 161 may move forward and backward in the cavity of the discharge unit 130 and the supply unit 140 according to the operation of the spring 165 by the drive unit 170, for example, compression and release. .

The cylinder 162 may include a spring 165 , a spring compression unit 166 and a stopper 164 .

One side of the spring 165 may be coupled while surrounding an outer circumferential surface of one side of the piston 161 inserted into the cylinder 162 . The other side of the spring 165 may be connected to the spring compression unit 166 .

The spring 165 may be compressed inside the cylinder 162 by the spring compression unit 166 . At this time, the piston 161 may move backward in the inner direction of the cylinder 162 by compression of the spring 165 . Also, while the spring 165 is compressed, the compression may be released by the operation of the driving unit 170 . Accordingly, the piston 161 may move forward in the direction outside the cylinder 162, that is, in the common direction of the discharge unit 130 and the supply unit 140, due to the elastic force generated by the compression release of the spring 165.

The spring compression unit 166 may compress the spring 165 to a predetermined length according to the operation of the driving unit 170 . The spring compression unit 166 may compress the spring 165 while being moved in a horizontal direction, for example, backward by the driving unit 170 .

One or more stoppers 164 are disposed inside the cylinder 162 and may come into contact with one side of the spring 165 . The stopper 164 may control the length of the spring 165 inside the cylinder 162 when the compression of the spring 165 is released, that is, the length in which the spring 165 is extended.

As described above, the launching unit 160 of the present embodiment advances the piston 161 toward the discharge unit 130 using the elastic force of the spring 165, so that the drug inside the discharge unit 130 is launched to the recipient. can do.

Here, the firing pressure of the drug may vary according to the elastic force of the spring 165. The elastic force of the spring 165 may vary depending on the degree of compression of the spring 165 by the spring compression unit 166 and the degree of release of compression of the spring 165 by the stopper 164 .

For example, when the backward movement distance of the spring compression unit 166 is increased by the driving unit 170, the compression force of the spring 165 is increased, so that the elastic force according to the release of the compression of the spring 165 may be increased. In addition, when the distance between one side of the spring 165 compressed inside the cylinder 162 and the stopper 164 increases, the decompression force of the spring 165 increases, so that the elastic force according to the decompression of the spring 165 increases It can be. That is, the elastic force of the spring 165 may vary according to the moving distance of the spring compression unit 166 and the separation distance from the stopper 164 .

In this way, the launching unit 160 of the present embodiment may launch the drug to the subject through the forward movement of the piston 161 using the elastic force of the spring 165. Accordingly, the needle-free syringe 100 of the present invention can be implemented with a simple configuration compared to the prior art, so there is an effect of reducing manufacturing costs, and it is possible to inject drugs to a person without a needle, thereby preventing problems such as broken needles. It can be prevented.

The driving unit 170 may compress or decompress the spring 165 so that the piston 161 of the firing unit 160 moves forward and backward. The driving unit 170 may include a first rotating body 171 , a second rotating body 172 , a fixing unit 173 and a motor 174 .

FIG. 3 is a view showing the first rotating body of FIG. 2, and FIG. 4 is a view showing part A of FIG. 2 in detail.

Referring to FIGS. 2 to 4 , the first rotating body 171 of the driving unit 170 may include a coupling hole 171a, a rotation control unit 171b, and a fixed control unit 171c. This first rotating body 171 may be a cam.

A rotation shaft (not shown) of the motor 174 may be inserted into and coupled to the coupling hole 171a of the first rotating body 171 . Accordingly, the first rotating body 171 may be rotated in one direction and the other direction depending on the direction of rotation of the rotation shaft by the rotation of the motor 174 .

The rotation controller 171b of the first rotating body 171 may be formed as a step with a predetermined height. The rotation control unit 171b is in contact with one surface of the first rotating body 171 to control the rotational distance of the second rotating body 172 rotated according to the rotation of the first rotating body 171 . In other words, the second rotating body 172 can be rotated by the distance from the initial position in contact with one surface of the first rotating body 171 to the step of the rotation control unit 171b.

The fixing controller 171c of the first rotating body 171 may contact the fixing part 173 to be described later to control fixation and release of the spring 165 of the fixing part 173. The fixed control unit 171c may include a protruding portion protruding to a predetermined height and a non-protruding portion relatively lower than the protruding portion.

Accordingly, when one end of the fixing part 173 contacts the protruding part of the fixing control part 171c due to one-way rotation of the first rotating body 171, the spring 165 may be fixed by the fixing part 173. In addition, when one end of the fixing part 173 comes into contact with the non-protruding part of the fixing control part 171c due to the rotation of the first rotating body 171 in the other direction, the fixation of the spring 165 is released by the fixing part 173. It can be.

The second rotating body 172 may come into contact with one surface of the first rotating body 171 and rotate depending on the first rotating body 171 . The second rotating body 172 may be a cam follower.

The second rotating body 172 is connected to the spring compression unit 166 of the firing unit 160, and the spring compression unit 166 can be moved backward by a predetermined distance according to rotation. At this time, the moving distance of the spring compression unit 166 may correspond to the rotational distance of the second rotating body 172 . The rotational distance of the second rotational body 172 may be controlled by the rotation controller 171b of the first rotational body 171 .

The fixing part 173 temporarily fixes the spring 165 compressed inside the cylinder 162 according to the direction of rotation of the first rotating body 171 to maintain the compressed state, or releases the fixed state to hold the compressed spring 165 ) can be decompressed.

For example, when the first rotating body 171 is rotated in one direction, the fixing part 173 contacts the protruding part of the fixing control unit 171c of the first rotating body 171 to temporarily fix the spring 165. . At this time, the spring 165 may be in a compressed state by the backward movement of the spring compression unit 166 . In addition, when the first rotating body 171 is rotated in the other direction, the fixing part 173 comes into contact with the non-protruding part of the fixing control unit 171c of the first rotating body 171 to control the fixed state of the spring 165. can be unlocked

The motor 174 may rotate the first rotating body 171 in one direction and the other direction. The motor 174 may be operated by receiving operating power from the battery unit 180 described above. The motor 174 may be a brushless DC motor (BLDC motor) for high-speed rotation, but is not limited thereto.

Referring back to FIG. 2 , the needle-free syringe 100 may further include a display unit 190 for displaying that the injection is completed to the person receiving the treatment after the injection of the drug by the injection module 120 .

The display unit 190 is disposed below the scan module 120 inside the body portion 111 of the housing 110, and may be disposed parallel to the discharge unit 130 of the scan module 120. The display unit 190 may inject paint or paint of a predetermined color onto the skin of a subject at the same time as the drug is ejected from the discharge unit 130 . Thus, it can be recognized from the outside that the injection for the subject is completed. When the spring 165 of the firing unit 160 is compressed and one side of the display unit 190 comes into contact with the stopper 164, a predetermined amount of paint or paint may be sprayed.

5A to 5C are diagrams illustrating the operation of a needleless syringe according to an embodiment of the present invention.

Hereinafter, the operation of the needleless syringe 100 of the present embodiment will be described in detail with reference to FIGS. 1 to 4 together with FIGS. 5A to 5C.

First, referring to FIG. 4A , in the initial state, that is, in the state before the needleless syringe 100 is driven, the piston 161 of the launch unit 160 moves forward into the first cavity 133 of the discharge unit 130. and may be in an inserted state. At this time, the backflow prevention unit 137 and the air inflow prevention unit 138 may be in a state of shielding the first flow path 132 and the nozzle 134 of the discharge unit 130, respectively.

Subsequently, referring to FIG. 5B , the needleless syringe 100 may be driven and the discharge unit 130 may be in a charged state in which the drug is charged.

Specifically, as the motor 174 of the driving unit 170 rotates in one direction, the first rotating body 171 and the second rotating body 172 may be rotated. Subsequently, the spring compression unit 166 of the firing unit 160 connected to the second rotation body 172 may be moved backward by a predetermined distance corresponding to the rotation distance of the second rotation body 172 .

The spring 165 inside the cylinder 162 is compressed by the backward movement of the spring compression unit 166, and the piston inserted into the first cavity 133 of the discharge unit 130 is compressed by the compression of the spring 165. (161) can be moved backward in the direction of cylinder (162).

At this time, the compressed spring 165 may be temporarily fixed by the fixing part 173 of the driving part 170 . The fixing part 173 may temporarily fix the spring 165 by contacting the protruding part of the fixing control unit 171c of the first rotating body 171 as the first rotating body 171 rotates in one direction.

As the piston 161 moves backward, the backflow prevention unit 137 of the discharge unit 130 opens the first flow path 132, and the drug flows through the supply unit 140 to the first flow path 132. The inside of the first cavity 133 may be filled.

Here, the filling amount of the drug depends on the backward movement distance of the piston 161, and the backward movement distance of the piston 161 may vary depending on the degree of compression of the spring 165, that is, the backward movement distance of the spring compression unit 166. there is. In addition, the backward movement distance of the spring compression unit 166 may vary according to the rotational distance of the second rotation body 172 by the rotation control unit 171b of the first rotation body 171 .

Meanwhile, the heater 145 is driven in the supply unit 140, and the drug flowing from the supply unit 140 to the first flow path 132 of the discharge unit 130 by the heater 145 can maintain a constant temperature. . Also, the air inflow prevention unit 138 may maintain a state in which the nozzle 134 of the discharge unit 130 is shielded.

Next, referring to FIG. 5C , one end of the protective cap 135 of the discharge unit 130 may be in an injection state in contact with the skin of a person to be treated.

Specifically, the protective cap 135 may come into contact with the skin of a person to be treated so that the other end of the protective cap 135 may come into contact with the sensor 136b of the trigger unit 136 of the drug dispensing unit 131 . Accordingly, the sensor 136b may output a predetermined trigger signal to the driver 170 .

The motor 174 of the driving unit 170 may reversely rotate the motor 174 based on the trigger signal, that is, rotate the motor 174 in another direction opposite to the one direction in which it was previously rotated. Accordingly, the first rotation body 171 connected to the rotation shaft of the motor 174 may be reversely rotated.

By the reverse rotation of the first rotating body 171, the fixing part 173 of the drive unit 170 comes into contact with the non-protruding part of the fixing control unit 171c of the first rotating body 171, thereby fixing the spring 165. status can be released.

When the fixing part 173 is released, the compressed spring 165 is released from compression inside the cylinder 162 and can be extended to a predetermined length. Accordingly, the piston 161 may move forward into the first cavity 133 of the discharge unit 130 by the spring 165 that is compressed. The drug filled in the first cavity 133 of the discharge unit 130 by the forward movement of the piston 161 is ejected to the skin of the person to be treated through the nozzle 134, and the drug is injected into the skin by the pressure. injection can be completed.

In addition, when one side of the spring 165 is in contact with the stopper 164 according to the release of the compression of the spring 165, a predetermined amount of paint or paint is sprayed from the display unit 190 to the skin of the person to be treated, so that the injection for the person to be treated can indicate completion.

As described above, the needle-free syringe 100 of the present embodiment moves the piston 161 using the elastic force caused by compression and release of the spring 165, so that the drug is injected with strong pressure according to the movement of the piston 161. It can be fired and the drug can be injected into the subject. Accordingly, the needle-free syringe 100 of the present invention can be implemented with a simple configuration compared to the prior art, so there is an effect of reducing manufacturing costs, and it is possible to inject drugs to a person without a needle, thereby preventing problems such as broken needles. It can be prevented.

In addition, the needleless syringe 100 of the present invention controls the rotation direction and rotation distance of the first rotation body 171 and the second rotation body 172 of the drive unit 170 to adjust the elastic force of the spring 165, The amount of the drug launched by the piston 161 and its pressure can be adjusted. Accordingly, the needle-free syringe 100 of the present invention can adjust the amount and firing pressure of the drug according to the condition of the person to be treated so that the optimally customized injection can be performed for the person to be treated.

Although the present invention has been described in detail with respect to the specific embodiments described above, it is obvious to those skilled in the art that various changes and modifications are possible within the scope of the technical idea of the present invention, and it is natural that these changes and modifications fall within the scope of the appended claims.

100: needle-free syringe 110; housing
120; Scan module 130: discharge unit
131: drug dispensing unit 135: protective cap
136: trigger unit 140: supply unit
150: launch unit 160: launch unit
161: piston 162: cylinder
165: spring 166: spring compression part
170: driving unit 171: first rotating body
172: second rotating body 173: fixed part
174: motor 200: drug container

Claims (15)

A housing composed of a body portion and a handle portion;
a drug container coupled to an upper side of the body; and
It is accommodated inside the body and includes an injection module for launching the drug supplied from the drug container to the skin of the person to be treated,
The injection module,
a supply unit through which the drug is supplied from the drug container;
a discharge unit exposed to the front side of the body and receiving and charging the drug from the supply unit; and
A firing unit that moves the piston forward in the inner cavity of the ejection unit so that the filled drug is launched into the skin of the person to be treated;
The discharge unit,
a drug ejection unit provided with a first flow path through which the drug is supplied from the supply unit, a first cavity filled with the drug supplied to the first flow path, and a nozzle for discharging the drug from the first cavity; and
A protective cap coupled to surround the outside of the drug ejection unit and having one end in contact with the skin of the person being treated;
The discharge unit further includes a trigger unit for controlling an operation of the firing unit,
The trigger part,
a gap maintaining member disposed between the other end of the protective cap and the drug dispensing unit; and
A sensor for detecting a gap between the protective cap and the drug dispensing unit and outputting a trigger signal to the firing unit;
The sensor is a needleless syringe, characterized in that for outputting the trigger signal when the other end of the protective cap is in contact with the drug ejection portion.
delete According to claim 1,
The discharge unit,
one or more backflow preventing units disposed inside the first flow path to prevent the backflow of drugs; and
One or more air inflow prevention units disposed in the nozzle to prevent air inflow from the outside;
Needle-free syringe, characterized in that it further comprises.
delete According to claim 1,
The supply unit is disposed between the discharge unit and the firing unit,
a second flow path supplying the drug supplied from the drug container to the discharge unit; and
A needleless syringe comprising a second cavity formed to be disposed on the same line as the inner cavity of the discharge unit.
According to claim 5,
The supply unit,
Needle-free syringe, characterized in that it further comprises a heater for heating the drug flowing through the second flow path to a set temperature.
According to claim 1,
The firing unit,
a cylinder into which one side of the piston is inserted;
a spring disposed inside the cylinder and coupled with one side surrounding an outer circumferential surface of one side of the piston;
a spring compression unit connected to the other side of the spring to compress the spring;
a drive unit operating the spring compression unit to compress the spring and to release the compressed spring;
including,
The other side of the piston,
The needleless syringe, characterized in that when the spring is compressed, it moves backward in the direction of the cylinder, and when the spring is released, it moves forward in the direction of the inner cavity of the discharge unit.
According to claim 7,
A needleless syringe, characterized in that when the piston is moved backward, the drug is filled in the inner cavity of the discharge unit, and when the piston is moved forward, the filled drug is ejected to the outside of the discharge unit.
According to claim 7,
The needleless syringe further comprising one or more stoppers disposed in the cylinder and controlling a length when the spring is released.
According to claim 7,
the driving unit,
A first rotating body that rotates in one direction and the other direction by a motor;
a second rotating body that moves the spring compression unit backward when the first rotating body rotates in one direction; and
a fixing unit temporarily fixing the spring compressed by the spring compression unit moving backward and releasing the fixation of the spring when the first rotating body is rotated in another direction;
A needle-free syringe comprising a.
According to claim 10,
The motor is a needleless syringe, characterized in that for rotating the first rotating body in another direction by a trigger signal provided when the discharge unit is in contact with the skin of the person to be treated.
According to claim 10,
The first rotating body,
a coupling hole to which the rotating shaft of the motor is coupled;
a rotation controller controlling a rotation distance of the second rotation body; and
a fixing control unit controlling fixation and release of the fixing part;
A needle-free syringe comprising a.
According to claim 10,
The motor is a needleless syringe, characterized in that the brushless DC motor.
According to claim 1,
The needle-free syringe further comprises a battery unit accommodated in the handle unit to supply operating power to the injection module.
According to claim 1,
A needle-free syringe characterized in that it further comprises a display unit housed in the body so as to be disposed parallel to the discharge unit, and spraying at least one of paint and paint to the skin of a person to be treated when the drug is ejected from the discharge unit.

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