KR102336021B1 - Nozzle assembly, injector body and needleless injector includind the nozzle assembly and the injector body - Google Patents

Abstract

The present invention relates to a needle-free syringe. A needle-free syringe according to an embodiment of the present invention comprises: a nozzle assembly in which a chemical solution is accommodated therein and the chemical solution is discharged; a syringe body for applying pressure to the nozzle assembly to discharge the chemical, wherein the nozzle assembly includes a nozzle container having a space for accommodating the chemical therein and having a discharge hole through which the chemical is discharged; and a plunger for applying pressure to the chemical solution in the nozzle container, wherein the syringe body includes: a piston connected to the plunger; a piston elastic member for applying an elastic force to the piston in a first direction in which the plunger applies pressure to the chemical; a loading unit for moving the piston to a locking position in a second direction opposite to the first direction; and a locking unit for locking the piston to stop at the locking position and releasing the locking.

Description

Nozzle assembly, syringe body, and needle-free syringe comprising same

The present invention relates to a nozzle assembly, a syringe body, and a needle-free syringe including the same, and more particularly, to a nozzle assembly capable of continuously injecting a drug solution without a needle, a syringe body, and an needle-free syringe including the same.

Conventionally, an oil-immersed syringe is used to inject a drug, that is, a drug solution to an animal or a human. However, such an oil-needle syringe has various problems such as cross-contamination of the injection target, pain associated with such injection, and the needle breaking and falling out in the injection target. In particular, when the needle is broken or dropped in the subject to be injected, it may be harmful to the health and safety of the subject, as well as cause significant economic problems.

In an attempt to avoid the problems associated with the currently used oil needle syringe, various companies are spurring the development of needle-free syringes.

The needle-free syringe does not have a needle penetrating the skin of an animal or human for injecting the drug solution, and injects the drug solution through instantaneous pressure.

However, some products of the existing needle-free syringe are unsanitary and may pose a risk of infection because the drug solution to be injected into the target and the instrument part are integrally provided. Alternatively, some products of the manual needle-free syringe were inconvenient to continuously inject because only one injection of the drug was possible with one loading.

Korean Patent Publication No. 10-1913544 (2018.11.01.)

An object of the present invention is to provide a nozzle assembly, a syringe body, and a needle-free syringe including the same, which are hygienic and can reduce the risk of infection.

Another object of the present invention is to provide a nozzle assembly capable of continuously injecting a chemical solution, a syringe body, and a needle-free syringe including the same.

Problems to be solved by the present invention are not limited thereto, and other problems not mentioned will be clearly understood by those skilled in the art from the following description.

The present invention provides a needle-free syringe. According to an embodiment, the needle-free syringe includes a nozzle assembly in which a chemical solution is accommodated and the chemical solution is discharged; a syringe body for applying pressure to the nozzle assembly to discharge the chemical, wherein the nozzle assembly includes a nozzle container having a space for accommodating the chemical therein and having a discharge hole through which the chemical is discharged; and a plunger for applying pressure to the chemical solution in the nozzle container, wherein the syringe body includes: a piston connected to the plunger; a piston elastic member for applying an elastic force to the piston in a first direction in which the plunger applies pressure to the chemical; a loading unit for moving the piston to a locking position in a second direction opposite to the first direction; and a locking unit for locking the piston to stop at the locking position and releasing the locking.

The nozzle assembly may be provided detachably from the syringe body.

The nozzle container may be formed with an injection hole through which a chemical may be injected from the outside.

The plunger may be inserted and removed from the nozzle container through the injection hole.

One end of the plunger is exposed to the outside of the nozzle container through the injection hole, and one end of the plunger and one end of the piston may be provided to be engaged with each other to be fixed in the first direction and the second direction. .

The space of the nozzle container includes a first space adjacent to the discharge hole and communicating with the discharge hole, and a second space provided further from the discharge hole than the first space, and viewed in the first direction When the diameter of the first space is provided to be smaller than the diameter of the second space, the other end of the plunger may be inserted into the first space from the second space.

The plunger is provided with a chemical liquid movement path penetrating between one area of the side surface and the other end, and a backflow prevention part for preventing the fluid from flowing back into the first space from the discharge hole is provided in the first space, the side surface The one region of may be located in the second space when the plunger is located at the locking position, and located in the first space when the plunger is located closer to the discharge hole than the locking position. .

In addition, the present invention provides a nozzle assembly in which a chemical solution is accommodated therein, is detachable from the syringe body, and discharges the chemical solution by the pressure applied by the syringe body. According to an embodiment, the nozzle assembly includes: a nozzle container having a space in which a chemical solution is accommodated therein, and a discharge hole through which the chemical solution is discharged; and a plunger for applying pressure to the chemical solution in the nozzle container, wherein the plunger is detached from the piston of the syringe body, and is moved by movement of the piston.

The nozzle container may be formed with an injection hole through which a chemical may be injected from the outside.

The plunger is inserted into and separated from the nozzle container through a surface opposite to the surface on which the discharge hole is formed, and one end of the plunger is exposed to the outside of the nozzle container while the plunger is inserted into the nozzle container and a grip portion capable of being gripped by a user is provided at one end of the plunger, and the grip portion may be removed from the plunger after the plunger is inserted into the nozzle container.

The space of the nozzle container includes a first space adjacent to the discharge hole and communicating with the discharge hole, and a second space provided further from the discharge hole than the first space, and viewed in the first direction When the diameter of the first space is provided to be smaller than the diameter of the second space, the other end of the plunger may be inserted into the first space from the second space.

The plunger is provided with a chemical liquid movement path penetrating between one area of the side surface and the other end, and a backflow prevention part for preventing the fluid from flowing back into the first space from the discharge hole is provided in the first space, the side surface The one region of may be located in the second space when the plunger is located in the locking position, and located in the first space when the plunger is located closer to the discharge hole than the locking position.

The first space may include an insertion space into which the plunger is inserted; a reverse flow communicating with the discharge hole and including a valve providing space adjacent to the discharge hole rather than the insertion space, wherein a backflow preventing hole opened and closed by the backflow preventing unit is formed between the insertion space and the valve providing space a valve member provided with a preventive wall, and wherein the backflow preventing unit is provided at a position corresponding to the backflow preventing hole of the valve providing space; A valve elastic member for applying an elastic force to the valve member in a direction from the discharge hole toward the backflow prevention hole may be included.

In addition, the present invention provides a syringe body that is detached from the nozzle assembly in which the chemical solution is accommodated, and applies pressure to the nozzle assembly so that the chemical solution is discharged. According to one embodiment, the syringe body, the piston to which the plunger of the nozzle assembly is detachable; a piston elastic member for applying an elastic force to the piston in a first direction in which the plunger applies pressure to the chemical; a loading unit for moving the piston to a locking position in a second direction opposite to the first direction; a locking unit locking the piston to stop at the locking position and releasing the locking; and a housing in which a space in which the piston is provided is formed.

The housing is opened from the surface facing the one end of the piston to a region corresponding to the one end of the piston so that a side facing one end of the piston is opened, and the nozzle assembly can be inserted into a side surface of the housing A nozzle assembly coupling hole may be formed, and an opening/closing member for opening and closing the nozzle assembly coupling hole may be provided in the nozzle assembly coupling hole.

The nozzle assembly, the syringe body, and the needle-free syringe including the same according to an embodiment of the present invention are hygienic and can reduce the risk of infection.

In addition, the nozzle assembly, the syringe body, and the needle-free syringe including the same according to an embodiment of the present invention can continuously inject a chemical solution.

1 is a perspective view showing a needle-free syringe according to an embodiment of the present invention.
FIG. 2 is a side cross-sectional view illustrating a ready-to-operate state after the nozzle assembly of the needle-free syringe of FIG. 1 is coupled to the syringe body.
3 is a side cross-sectional view showing an area adjacent to the discharge hole of the needle-free syringe of FIG.
Figure 4 is a side cross-sectional view showing a region adjacent to the other end of the piston of the needle-free syringe of Figure 2;
Figure 5 is a side cross-sectional view showing a state that the piston of the needle-free syringe of Figure 1 is moved to the locking position.
6 is a side cross-sectional view showing an area adjacent to the discharge hole of the needle-free syringe of FIG.
Figure 7 is a side cross-sectional view showing a state in which the piston of the needle-free syringe of Figure 1 is positioned in the locking position.
8 is a side cross-sectional view showing an area adjacent to the discharge hole of the needle-free syringe of FIG.
9 is a side cross-sectional view showing an area adjacent to the other end of the piston of the needle-free syringe of FIG.
10 is a side cross-sectional view showing a state in which the drug solution of the needleless syringe of FIG. 1 is discharged.
11 is a side cross-sectional view showing an area adjacent to the discharge hole of the needle-free syringe of FIG. 1 in a state in which the liquid is being discharged.
Figure 12 is a side cross-sectional view showing the core of the needle-free syringe of Figure 10.
13 is a side cross-sectional view illustrating a state in which the chemical liquid of the needleless syringe of FIG. 1 is discharged and the force applied to the handle is loosened.
14 to 16 are views sequentially illustrating an example of a method of injecting a chemical solution into the nozzle assembly of FIG. 1 .

Hereinafter, an embodiment of the present invention will be described in more detail with reference to the accompanying drawings. Embodiments of the present invention may be modified in various forms, and the scope of the present invention should not be construed as being limited to the following embodiments. This embodiment is provided to more completely explain the present invention to those of ordinary skill in the art. Accordingly, the shapes of elements in the drawings are exaggerated to emphasize a clearer description.

1 is a perspective view showing a needle-free syringe 10 according to an embodiment of the present invention. FIG. 2 is a side cross-sectional view showing the operation preparation state after the nozzle assembly 1000 of the needleless syringe 10 of FIG. 1 is coupled to the syringe body 2000 . 3 is a side cross-sectional view showing an area adjacent to the discharge hole 1120 of the needle-free syringe 10 of FIG. 4 is a side cross-sectional view showing an area adjacent to the other end of the piston 2100 of the needle-free syringe 10 of FIG. 1 to 4 , the needle-free syringe 10 includes a nozzle assembly 1000 and a syringe body 2000 .

The nozzle assembly 1000 contains a chemical liquid therein. The nozzle assembly 1000 is provided so that the chemical solution contained therein is discharged by the pressure applied by the syringe body 2000 . According to an embodiment, the nozzle assembly 1000 includes a nozzle container 1100 , a plunger 1200 , and a backflow prevention unit 1300 . The nozzle assembly 1000 is provided detachably from the syringe body 2000 .

The nozzle container 1100 is provided with a space 1110 in which the chemical is accommodated. A discharge hole 1120 through which the chemical liquid contained therein is discharged is formed in the nozzle container 1100 . The discharge hole 1120 is exposed to the outside of the syringe body 2000 of the nozzle container 1100, and is formed in a region facing the body to inject the chemical solution. For example, the discharge hole 1120 may be formed in the end face of the nozzle container 1100 in the direction opposite to the direction toward the syringe body 2000.

The nozzle container 1100 is formed with an injection hole 1130 into which a chemical solution can be injected from the outside. According to an embodiment, the injection hole 1130 may be formed on a surface facing the syringe body 2000 in a state coupled to the syringe body 2000 of the nozzle container 1100 . The injection hole 1130 may be formed on a surface opposite to the surface on which the discharge hole 1120 of the nozzle container 1100 is formed.

According to an embodiment, the space 1110 of the nozzle container 1100 includes a first space 1111 and a second space 1112 .

The first space 1111 is an area adjacent to the discharge hole 1120 of the space 1110 of the nozzle container 1100 and communicates with the discharge hole 1120 . According to an embodiment, the first space 1111 includes an insertion space 1111a and a valve providing space 1111b.

The plunger 1200 is inserted into the insertion space 1111a. The valve providing space 1111b is in direct communication with the discharge hole 1120 . The valve providing space 1111b is located closer to the discharge hole 1120 than the insertion space 1111a. A backflow prevention wall 1310 is provided between the insertion space 1111a and the valve providing space 1111b. A backflow prevention hole 1311 is formed in the backflow prevention wall 1310 . When the chemical solution is discharged, the chemical solution in the insertion space 1111a is introduced into the valve providing space 1111b through the backflow prevention hole 1311 .

The second space 1112 is an area provided farther from the discharge hole 1120 than the first space 1111 of the space 1110 of the nozzle container 1100 .

When viewed in the first direction, the diameter of the first space 1111 is provided to be smaller than the diameter of the second space 1112 . According to an embodiment, the first direction is a direction from the syringe body 2000 toward the nozzle assembly 1000 .

According to an embodiment, an O-ring 1140 may be provided in a region adjacent to the second space 1112 of the first space 1111 . The inner surface of the O-ring 1140 is provided to be in close contact with the side surface of the plunger 1200 . The O-ring 1140 is provided with a waterproof material having elasticity. By providing the O-ring 1140 , it is possible to prevent the chemical from moving between the side surface of the plunger 1200 and the inner surface of the first space 1111 .

The plunger 1200 applies pressure to the chemical solution in the nozzle container 1100 . The plunger 1200 may be inserted into and removed from the nozzle container 1100 through the opposite surface of the surface on which the discharge hole 1120 is formed. For example, the plunger 1200 may be inserted into and removed from the nozzle container 1100 through the injection hole 1130 .

The plunger 1200 may be provided to be detachably attached to the piston 2100 of the syringe body 2000 . The plunger 1200 may be moved by movement of the piston 2100 . One end of the plunger 1200 may be exposed to the outside of the nozzle container 1100 through the injection hole 1130 while the plunger 1200 is inserted into the nozzle container 1100 . One end of the plunger 1200 and one end of the piston 2100 are engaged with each other to be fixed with respect to the first direction and the second direction. The second direction is opposite to the first direction.

The other end 1220 of the plunger 1200 is inserted and separated from the second space 1112 to the first space 1111 in the first direction and the second direction.

According to an embodiment, a chemical liquid passage 1230 is formed in the plunger 1200 . The chemical liquid passage 1230 is formed to penetrate between one region of the side surface of the plunger 1200 and the other end 1220 of the plunger 1200 . The one area of the side of the plunger 1200 is located in the second space 1112 when the plunger 1200 is located in the locking position, and the plunger 1200 is located adjacent to the discharge hole 1120 rather than the locking position. If it is, it is located in the first space 1111 .

A backflow prevention unit 1300 is provided in the first space 1111 . The backflow prevention unit 1300 prevents a chemical liquid such as a chemical liquid or external air from flowing backward from the discharge hole 1120 into the first space 1111 . According to an embodiment, the backflow prevention unit 1300 may prevent the backflow by opening and closing the backflow prevention hole 1311 . For example, the backflow prevention unit 1300 includes a valve member 1320 and a valve elastic member 1330 .

The valve member 1320 is provided to correspond to the backflow prevention hole 1311 of the valve providing space 1111b. The valve member 1320 moves according to the flow of the chemical generated by the elastic force of the valve elastic member 1330 and the movement of the plunger 1200, and is in close contact with and spaced apart from the backflow preventing wall 1310, thereby forming the backflow preventing hole 1311. can be opened and closed.

The valve elastic member 1330 applies an elastic force to the valve member 1320 in a direction from the discharge hole 1120 toward the backflow prevention hole 1311 . The valve elastic member 1330 is a coil-type spring whose diameter decreases from the discharge hole 1120 to the valve member 1320 to form a gap through which the chemical can be discharged to the discharge hole 1120 in a compressed state. can be provided.

The syringe body 2000 applies pressure to the nozzle assembly 1000 so that the chemical solution in the nozzle assembly 1000 is discharged. According to an embodiment, the nozzle assembly 1000 in which the chemical solution is accommodated is detachably attached to the syringe body 2000 . The syringe body 2000 includes a piston 2100 , a piston elastic member 2200 , a loading unit 2300 , a locking unit 2400 , and a housing 2500 .

The piston 2100 is connected to the plunger 1200 . According to an embodiment, the plunger 1200 is detachably connected to the piston 2100 . An inner ball receiving groove 2130 is formed on a side surface of the piston 2100 . The inner ball accommodating groove 2130 is provided so that when the piston 2100 is positioned in the locking position, the locking ball 2420 moves inward to be accommodated in the inner ball accommodating groove 2130 .

The piston elastic member 2200 applies an elastic force to the piston in a first direction in which the plunger 1200 applies pressure to the chemical solution in the nozzle container 1100 . The piston elastic member 2200 may be provided as a coil-type spring.

The loading unit 2300 moves the piston 2100 in the second direction to a locking position. According to an embodiment, the loading unit 2300 includes a handle 2310 and a locking protrusion 2320 .

The handle 2310 is provided to be rotatable between a position where the other end contacts the housing 2500 and a position away from the housing 2500 about one end extending from the side surface of the housing 2500 and connected to the housing 2500 .

According to an embodiment, a locking protrusion 2320 extending toward the housing is provided on the side facing the housing 2500 of the handle 2310 . The locking protrusion 2320 is provided such that the other end is rotatable along a surface parallel to the rotation surface of the handle 2310 around one end connected to the side surface of the handle 2310 .

According to an embodiment, an area corresponding to the handle 2310 on the side of the housing 2500 is provided to be open. A locking member 2110 to which the other end of the locking protrusion 2320 is caught in the second direction is provided in an area corresponding to the area of the handle 2310 on the side of the piston 2100 .

Accordingly, when the other end of the handle 2310 is moved from a position far from the housing 2500 to an adjacent position, the other end of the locking protrusion 2320 is caught on the locking member 2110 and is attached to the locking member 2110 in the second direction. apply force

The loading part 2300 may be provided with a locking protrusion elastic member that applies an elastic force to the locking protrusion 2320 in a direction away from the handle 2310 at the other end. Accordingly, after the handle 2310 is moved in the direction of the housing 2500 to position the piston 2100 in the locking position by the user, the handle 2310 is moved away from the housing 2500 again by the elastic force of the locking protrusion elastic member. .

The locking unit 2400 locks the piston 2100 to stop at the locking position, and releases the locking. According to an embodiment, the locking unit 2400 includes a push button 2410 , a locking ball 2420 , a ball receiving member 2430 , and a ball receiving member elastic member 2440 .

The push button 2410 is provided on a surface opposite to the surface where one end connected to the plunger 1200 of the piston 2100 of the housing 2500 is facing.

The locking ball 2420 is rotatably provided at one position inside the housing 2500 . A plurality of locking balls 2420 may be provided to surround a side surface adjacent to the other end of the piston 2100 . The locking ball 2420 is provided to be fixed with respect to the first direction and the second direction. The locking ball 2420 is provided to be movable along a direction perpendicular to the first direction and the second direction.

The ball receiving member 2430 is moved in the first direction by the push button 2410 . An outer ball receiving groove 2431 is formed in the ball receiving member 2430 . The outer ball receiving groove 2431 provides a space in which the locking ball 2420 can move outward when the ball receiving member 2430 is positioned at a position corresponding to the locking ball 2420 .

The ball receiving member elastic member 2440 applies an elastic force to the ball receiving member 2430 in the second direction. The ball receiving member elastic member 2440 may be provided as a coiled spring.

The housing 2500 has a space in which the piston 2100 is provided. According to an embodiment, the housing 2500 has an open side facing one end of the piston 2100 . A nozzle assembly coupling hole is formed in a side surface of the housing 2500 so that the nozzle assembly 1000 can be inserted into the housing 2500 .

The nozzle assembly coupling hole is formed so that one end of the piston 2100 is opened to a region corresponding to the one end of the piston 2100 from the facing surface.

An opening/closing member 2520 for opening and closing the nozzle assembly coupling hole may be provided in the nozzle assembly coupling hole. According to an embodiment, the opening and closing member 2520 has one end facing the second direction connected to the housing 2500 by a hinge 2521, and the position and the housing with the other end facing the first direction around the one end. The nozzle assembly coupling hole can be opened and closed by rotating between positions away from the .

Hereinafter, a method of injecting a drug solution using the needle-free syringe 10 of FIG. 1 will be described.

2 to 4 , the nozzle assembly 1000 in a state in which the chemical liquid is supplied to the space of the nozzle container 1100 is coupled to the syringe body 2000 . According to an embodiment, in the state in which the opening and closing member 2520 is opened, the nozzle assembly 1000 has one end protruding from the nozzle assembly coupling hole to the injection hole 1130 of the plunger 1200 is one end of the piston 2100 . It is inserted into the housing 2500 so as to be coupled to the syringe body 2000 and is coupled. At this time, the piston 2100 is in the unlocked state. Accordingly, the plunger 1200 is in a state in which it is maximally inserted into the insertion space 1111a. In addition, the locking ball 2420 is inserted into the outer ball receiving groove 2431 , and the inner ball receiving groove 2130 is moved in the first direction rather than the position facing the locking ball 2420 .

5 is a side cross-sectional view showing a state in which the piston 2100 of the needle-free syringe 10 of FIG. 1 is moved to the locking position. 6 is a side cross-sectional view showing an area adjacent to the discharge hole 1120 of the needleless syringe 10 of FIG. 5 . 5 and 6, after the process of FIG. 2 is performed, when the user applies a force to the handle 2310 to move the handle 2310 in the direction in which the housing 2500 is located, the piston 2100 is moved to the locking position along the second direction. At this time, while the plunger 1200 also moves in the second direction together with the piston 2100, the hole formed on the side of the piston 2100 of the chemical liquid movement path 1230 is exposed to the second space 1112 until the insertion space ( A space between the backflow prevention wall 1310 of 1111a) and the other end of the piston 2100 becomes a vacuum state. A user may apply a force to the handle 2310 toward the housing 2500 by holding the handle 2310 and the periphery of the side surfaces of the housing 2500 together by hand. At this time, in a state in which the handle 2310 is completely moved toward the housing 2500, the end of the auxiliary protrusion protruding in the vertical direction from one end of the locking protrusion 2320 outward from the area corresponding to the auxiliary protrusion on the side of the housing. It protrudes and rotates along the inclined surface of the inclined protrusion having an inclined surface inclined in the first direction toward the outside, whereby the locking protrusion 2320 is rotated so that the other end of the locking protrusion 2320 is out of the locking member 2110. do.

7 is a side cross-sectional view showing a state in which the piston 2100 of the needle-free syringe 10 of FIG. 1 is positioned in the locking position. 8 is a side cross-sectional view showing an area adjacent to the discharge hole 1120 of the needle-free syringe 10 of FIG. 9 is a side cross-sectional view showing an area adjacent to the other end of the piston 2100 of the needle-free syringe 10 of FIG. 7 to 9 , when the process of FIGS. 5 and 6 is completed, the piston 2100 is positioned at a position where the inner ball receiving groove 2130 corresponds to the locking ball 2420 . Accordingly, the locking ball 2420 is accommodated in the inner ball receiving groove 2130 , and the locking ball 2420 blocking the ball receiving member 2430 is moved to the inner ball receiving groove 2130 , so that the ball receiving member 2430 ) is moved in the second direction by the elastic force of the ball receiving member elastic member 2440 . Therefore, the locking ball 2420 is prevented from moving outward by the area located on the first direction side than the outer ball receiving groove 2431 of the ball receiving member 2430, and the piston 2100 is the inner ball receiving groove ( It is stopped at the locking position by the locking ball 2420 accommodated in 2130). In this case, the hole formed on the outside of the plunger 1200 of the chemical liquid passage 1230 is exposed to the second space 1112 , so that the chemical liquid in the second space 1112 passes through the chemical liquid passage 1230 in a vacuum state. is introduced into the insertion space 1111a.

10 is a side cross-sectional view showing a state in which the chemical solution of the needleless syringe 10 of FIG. 1 is discharged. 11 is a side cross-sectional view showing an area adjacent to the discharge hole 1120 in a state in which the chemical of the needle-free syringe 10 of FIG. 1 is being discharged. 12 is a side cross-sectional view showing the core of the needle-free syringe 10 of FIG. 10 to 12, when the user presses the push button 2410 using a thumb or the like while holding the needle-free syringe 10 by hand as described above, the ball receiving member 2430 receives the outer ball The groove 2431 is moved in the first direction to a position corresponding to the locking ball 2420 . Accordingly, the locking ball 2420 accommodated in the inner ball receiving groove 2130 is moved to the outer ball receiving groove 2431 , and the locking ball 2420 is inserted into the inner ball receiving groove 2130 , thereby locking the piston. The 2100 is moved in the second direction by the elastic force of the piston elastic member 2200 . At this time, the plunger 1200 connected to the piston 2100 is moved in the second direction by the movement of the piston 2100, whereby the chemical solution accommodated in the insertion space 1111a is discharged through the discharge hole 1120. At this time, the valve member 1320 is moved in the discharge hole direction by the pressure of the chemical liquid applied by the piston 2100, and the chemical liquid is transferred to the discharge hole through between the valve member 1320 and the backflow prevention hole 1311. .

13 is a side cross-sectional view illustrating a state in which the chemical liquid of the needleless syringe 10 of FIG. 1 is discharged and the force applied to the handle 2310 is loosened. 13, when the user loosens the hand holding the needle-free syringe 10 after discharging the chemical, the locking protrusion 2320 rotates by the elastic force of the locking protrusion elastic member and the handle 2310 is attached to the housing ( 2500) by rotating in a direction away from, the needle-free syringe 10 is again in the same state as in FIG. In particular, in the needle-free syringe 10 according to the embodiment of the present invention, as described above, only the chemical liquid flowing into the insertion space 1111a among the chemical liquid accommodated in the nozzle container 1100 is discharged at one time, so that the chemical liquid is accommodated in the nozzle assembly Once 1000 is coupled to the injector body 2000, the drug may be continuously injected several times by a predetermined amount.

Hereinafter, a method of injecting a chemical into the nozzle assembly 1000 of the needle-free syringe 10 according to an embodiment of the present invention will be described.

14 to 16 are views sequentially illustrating an example of a method of injecting a chemical solution into the nozzle assembly 1000 of FIG. 1 . 14 to 16 , a chemical is injected into the empty nozzle assembly 1000 through the injection hole 1130 using a dropper 30 or the like.

Thereafter, the plunger 1200 is inserted from the other end 1220 through the injection hole 1130 into the nozzle assembly 1000 into which the chemical is injected.

According to an embodiment, a gripper 1240 may be provided at one end of the plunger 1200 . The user can easily move the plunger 1200 while holding the gripper 1240 . The gripper 1240 is removed from the plunger 1200 after the plunger 1200 is inserted into the nozzle container 1100 . A cut region provided to be indented in the circumferential direction of the side surface of the plunger 1200 may be formed in an area adjacent to the side surface of the plunger 1200 of the gripper 1240 . Accordingly, when removing from the plunger 1200 by applying force to the gripping part 1240 , the cut region is cut, and the gripping part 1240 can be easily removed.

As described above, the needle-free syringe 10 according to an embodiment of the present invention can continuously inject a predetermined amount of a chemical solution a plurality of times by replacing the nozzle assembly 1000 once. In addition, the needle-free syringe 10 according to an embodiment of the present invention is hygienic and can reduce the risk of infection because the nozzle assembly 1000 in which the chemical solution is accommodated is replaced and used.

The above detailed description is illustrative of the present invention. In addition, the above description shows and describes preferred embodiments of the present invention, and the present invention can be used in various other combinations, modifications, and environments. That is, changes or modifications are possible within the scope of the concept of the invention disclosed herein, the scope equivalent to the written disclosure, and/or within the scope of skill or knowledge in the art. The written embodiment describes the best state for implementing the technical idea of the present invention, and various changes required in specific application fields and uses of the present invention are possible. Accordingly, the detailed description of the present invention is not intended to limit the present invention to the disclosed embodiments. Also, the appended claims should be construed to include other embodiments.

Claims (15)

a nozzle assembly accommodating a chemical solution therein and discharging the chemical solution;
Comprising a syringe body that applies pressure to the nozzle assembly so that the chemical is discharged,
The nozzle assembly,
a nozzle container having a space in which the chemical is accommodated, and having a discharge hole through which the chemical is discharged;
A plunger for applying pressure to the chemical solution in the nozzle container,
The syringe body,
a piston connected to the plunger;
a piston elastic member for applying an elastic force to the piston in a first direction in which the plunger applies pressure to the chemical;
a loading part for moving the piston to a locking position in a second direction opposite to the first direction;
A locking part for locking the piston to stop at the locking position and releasing the locking,
The space of the nozzle container includes a first space adjacent to the discharge hole and communicating with the discharge hole, and a second space provided farther from the discharge hole than the first space,
When viewed in the first direction, the diameter of the first space is provided to be smaller than the diameter of the second space,
The other end of the plunger is a needle-free syringe inserted into the first space from the second space. The method of claim 1,
The nozzle assembly is a needle-free syringe provided detachably to the syringe body. The method of claim 1,
A needle-free syringe in which an injection hole into which a chemical solution can be injected from the outside is formed in the nozzle container. 4. The method of claim 3,
The plunger is a needle-free syringe that is inserted and separated into the nozzle container through the injection hole. 5. The method of claim 4,
One end of the plunger is exposed to the outside of the nozzle container through the injection hole,
One end of the plunger and one end of the piston are provided to be engaged with each other to be fixed with respect to the first direction and the second direction. delete 6. The method of claim 5,
The plunger is formed with a chemical liquid movement path passing between one area of the side and the other end,
A backflow prevention unit is provided in the first space to prevent a backflow of the fluid from the discharge hole to the first space,
The one area of the side is located in the second space when the plunger is located in the locking position, and is located in the first space when the plunger is located closer to the discharge hole than the locking position needle-free syringe. In the nozzle assembly, the chemical solution is accommodated therein, is detachable from the syringe body, and discharges the chemical solution by the pressure applied by the syringe body,
a nozzle container having a space in which the chemical is accommodated, and having a discharge hole through which the chemical is discharged;
A plunger for applying pressure to the chemical solution in the nozzle container,
The plunger is detached from the piston of the syringe body, and is moved by the movement of the piston,
The space of the nozzle container includes a first space adjacent to the discharge hole and communicating with the discharge hole, and a second space provided farther from the discharge hole than the first space,
When viewed in the first direction in which the plunger to the piston applies pressure to the chemical solution, the diameter of the first space is provided to be smaller than the diameter of the second space,
The other end of the plunger is inserted into the first space from the second space. 9. The method of claim 8,
A nozzle assembly in which an injection hole into which a chemical liquid can be injected from the outside is formed in the nozzle container. 9. The method of claim 8,
The plunger is inserted into and separated from the nozzle container through a surface opposite to the surface on which the discharge hole is formed of the nozzle container,
One end of the plunger is exposed to the outside of the nozzle container in a state in which the plunger is inserted into the nozzle container,
The one end of the plunger is provided with a grip portion that can be gripped by a user,
The nozzle assembly wherein the gripper is removed from the plunger after the plunger is inserted into the nozzle container. delete 10. The method of claim 9,
The plunger is formed with a chemical liquid movement path passing between one area of the side and the other end,
A backflow prevention unit is provided in the first space to prevent a backflow of the fluid from the discharge hole to the first space,
The one area of the side surface is located in the second space when the plunger is located in the locking position, and is located in the first space when the plunger is located closer to the discharge hole than the locking position. assembly. 13. The method of claim 12,
The first space is
an insertion space into which the plunger is inserted;
and a valve providing space communicating with the discharge hole and adjacent to the discharge hole than the insertion space,
Between the insertion space and the valve providing space, there is provided a backflow preventing wall having a backflow preventing hole that is opened and closed by the backflow preventing unit,
The backflow prevention unit,
a valve member provided at a position corresponding to the backflow prevention hole of the valve providing space;
and a valve elastic member for applying an elastic force to the valve member in a direction from the discharge hole toward the backflow prevention hole. delete delete

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