KR20180047761A - Apparatus for injecting liquid medicine which can regulate inside pressure - Google Patents

Abstract

In the present invention, provided is a liquid medicine injection device capable of adjusting internal pressure which comprises: a cylinder which is extended in one direction and has one end portion connected to a liquid medicine flow tube for receiving and discharging liquid medicine, and the other end portion joined to a gas generation unit having a gas generation space for generating gas; an injection piston which can move in the cylinder in an airtight condition and divides an inner space of the cylinder into a liquid medicine storage space for receiving the liquid medicine through the liquid medicine flow tube and being filled with the liquid medicine and a gas supply space for receiving a supply of the gas generated by the gas generation unit; and a switch member which is arranged between the gas supply space and gas generation space, connects the atmosphere to the gas supply space during charging of the liquid medicine, and connects the gas supply space to the gas generation space during injection of the liquid medicine.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a chemical-

The present invention relates to a chemical liquid injecting apparatus capable of adjusting an internal pressure, and more particularly, to a liquid chemical injecting apparatus capable of adjusting an internal pressure, And more particularly, to a chemical liquid injecting apparatus capable of stably and continuously injecting a charged chemical liquid into a patient at a constant flow rate while being easily influenced by a change in environment such as a height of a chemical liquid injector or an external temperature.

Specifically, in the present invention, the switch member is not operated during the filling of the chemical liquid, so that the inside of the apparatus is communicated with the outside atmosphere, thereby reducing the chemical liquid inflow resistance caused by the injection piston which may occur upon filling the chemical liquid storage space in the apparatus. When the chemical liquid is injected into the patient, the switch member is actuated by the driving force of the gas generated in the gas generating unit in the apparatus, so that the communication between the inside of the apparatus and the outside air is blocked, The present invention relates to a chemical liquid injecting apparatus capable of stably and continuously injecting a charged chemical liquid into a patient at a constant flow rate while being less affected by changes in environment such as a height of the chemical liquid injector or an external temperature by allowing a high pressure to act on the injection piston will be.

Further, according to the present invention, when the internal pressure of the apparatus exceeds a predetermined pressure by the gas generated in the gas generating unit, the switch member operates as a pressure regulating valve, thereby maintaining the internal pressure of the apparatus constant at a predetermined pressure To a chemical liquid injecting apparatus capable of adjusting an internal pressure.

When injecting drugs for special injectable drugs such as anticancer drugs and antibiotics into patients, it is necessary to constantly apply a certain amount of drug for a considerably long time depending on the condition of the patient. If the special injection medicines are not continuously and constantly applied to the patient's required amount, there is a risk of causing a shock and causing an accident. In view of such a problem, a mechanical device for injecting a predetermined amount of drug solution per unit time into the patient has been devised and used.

However, such a conventional mechanical device is a pushing device of a syringe by a driving force of a motor, which requires an additional device such as a motor, and thus is large in size and unsuitable for a patient to carry.

In view of such a problem, Korean Patent Registration No. 10-0262930 discloses a drug solution injecting device which can be carried by a patient. This conventional portable liquid injecting apparatus is a structure in which a resilient bag (called balloon or balloon) of a rubber material is provided in the chamber. The elastic balloon has an inlet and an outlet. Pouring fluid into the injection port causes pockets to swell. So that the chemical solution gradually escapes through the discharge port equipped with the elongated tube. The drug solution is discharged in small quantities and injected into the patient's vein.

However, in the chemical liquid injecting apparatus equipped with such an elastic balloon, the thickness of the elastic balloon may not be uniform during production of the balloon, or a defective product such as a minute hole may be produced. These defects change the elasticity and the pockets do not have the desired elasticity. Then, it is difficult to keep the injection amount per unit time constant. In addition, the elastic balloon may have different elasticity depending on the amount of the remaining chemical liquid, and thus the external force (elastic restoring force) that influences the flow of the chemical liquid may be different at the initial stage and at the end of the injection.

Further, the chemical liquid injecting apparatus having the elastic balloon has a weak physical force to push the chemical liquid. A chemical liquid injecting apparatus having an elastic balloon having a low chemical injecting pressure is very sensitive to the external environment such as the height or temperature of the apparatus and thus the change in the flow rate of the chemical liquid injected into the patient is very severe. Particularly, when the flow rate of the chemical liquid to be injected to the patient is large, when the chemical liquid injection pressure is low, the chemical liquid may not be constantly pushed. For this reason, it is necessary to increase the chemical liquid injection pressure in the chemical liquid injecting apparatus. In addition, higher pressures are required to change the flow rate from time to time while injecting the drug into the patient.

In order to overcome such a problem, a gas-generating chemical liquid injecting apparatus disclosed in Korean Patent Registration No. 10-0507593 is known. In this apparatus, the injection piston in the cylinder is steadily and slowly advanced by the generated high gas pressure, and the chemical solution filled in the chemical solution storage space in the cylinder is steadily and continuously injected into the patient at a constant flow rate by the forward movement of the injection piston do.

However, in the gas-generating-type chemical-liquid injector, when the chemical-liquid injection pressure is increased, a chemical-liquid injection resistance is generated at the step of filling the chemical-liquid into the chemical-liquid storage space. For this reason, the conventional gas generating liquid injecting apparatus has a limitation in increasing the chemical injecting pressure to facilitate the chemical liquid filling.

That is, although the above-described conventional gas-generative chemical-liquid injecting apparatus is an excellent technique, constant improvement can be achieved as with other superior technologies. For example, there is a demand to increase the injection pressure of the chemical liquid to inject the chemical liquid steadily and continuously to the patient while being less influenced by changes in the environment such as the height of the chemical liquid injector or the external temperature, It is necessary to provide a new gas generating type chemical liquid injecting apparatus which solves this difficult problem at the same time.

Therefore, the liquid medicament injecting apparatus of the present invention is capable of precisely and detailedly implementing two functions for facilitating the filling of the liquid medicines while the liquid chemical injection pressure is high, And an improvement of a technique for efficiently controlling the pressure inside the apparatus according to a chemical solution injection mode.

Korean Patent Registration No. 10-0262930 (Aug. 2000) Korean Registered Patent No. 10-0507593 (Aug. 10, 2005)

The present invention relates to a chemical liquid injector capable of adjusting the internal pressure in accordance with a chemical liquid filling and injection mode, wherein the internal pressure of the chemical liquid equilibrates with the external atmospheric pressure when the chemical liquid is filled, and when the chemical liquid is injected into the patient, The present invention provides a chemical liquid injecting apparatus capable of stably and continuously injecting a charged chemical liquid at a constant flow rate while being easily influenced by a change in environment such as a height of a liquid chemical injector or an external temperature while easily filling a chemical liquid. .

Specifically, in the present invention, the switch member is not operated during the filling of the chemical liquid, so that the inside of the apparatus is communicated with the outside atmosphere, thereby reducing the chemical liquid inflow resistance caused by the injection piston which may occur upon filling the chemical liquid storage space in the apparatus. When the chemical liquid is injected into the patient, the switch member is actuated by the driving force of the gas generated in the gas generating unit in the apparatus, so that the communication between the inside of the apparatus and the outside air is blocked, A chemical liquid injecting device capable of stably and continuously injecting the charged chemical liquid at a constant flow rate while being less affected by changes in the environment such as the height of the chemical liquid injector or the external temperature by allowing the high pressure to act on the injection piston It has its purpose.

Further, according to the present invention, when the internal pressure of the apparatus exceeds a predetermined pressure by the gas generated in the gas generating unit, the switch member operates as a pressure regulating valve, thereby maintaining the internal pressure of the apparatus constant at a predetermined pressure And it is an object of the present invention to provide a chemical liquid injecting apparatus capable of adjusting the internal pressure.

According to one aspect of the present invention, there is provided a gas generating device comprising a gas generating part having a gas generating space extending at one end and extending at a first end thereof and a chemical solution flow tube through which a chemical solution flows in and out, A chemical solution storage space in which the chemical solution flows into the cylinder internal space through the chemical solution flow tube and is filled in the chemical solution storage space, And a gas supply space provided between the gas supply space and the gas generation space for connecting the atmospheric gas and the gas supply space at the time of filling the chemical solution, There is provided an internal-pressure-adjustable chemical-liquid injecting apparatus including a switch member connecting a space.

The switch member includes a switch cylinder connected to the atmosphere, the gas supply space and the gas generating space, and a switch cylinder movably installed in the switch cylinder and connecting the atmosphere and the gas supply space according to a position in the switch cylinder And a switch piston connecting the gas supply space and the gas generating space.

The switch cylinder includes a first hole for connecting the atmosphere and the inside of the switch cylinder, a second hole for connecting the gas generating space and the inside of the switch cylinder, and a second hole for connecting the gas supply space and the inside of the switch cylinder And a third hole positioned between the first hole and the second hole.

For example, when the chemical liquid is filled, the switch piston is positioned between the third hole and the second hole in the switch cylinder to connect the atmosphere to the gas supply space. When the chemical liquid is injected, And is disposed between the third hole and the first hole in the switch cylinder to connect the gas supply space and the gas generating space.

The switch cylinder further includes a fourth hole exposed to the outside, and the switch member may further include a cap for blocking the fourth hole.

Preferably, the stopper is made of a light-transmitting material so as to visually recognize the movement of the switch piston so that the switch member can be normally operated. For example, the stopper may be made of a transparent material or a translucent material.

Wherein the switch member forms a bypass flow path connecting the gas supply space and the atmosphere when the internal pressure of the gas supply space exceeds a predetermined pressure value during chemical solution injection, Gas can be discharged to the outside.

Wherein the switch member includes a switch cylinder connected to the atmosphere, the gas supply space, and the gas generating space, the switch cylinder including a bypass flow path connecting the gas supply space and the atmosphere, A switch piston which connects the atmosphere and the gas supply space according to a position in the switch cylinder or connects the gas supply space and the gas generating space, and a switch piston which is installed in the switch cylinder and is located between the atmosphere and the switch piston, And a switch elastic member capable of providing an elastic force to the switch piston to close the bypass passage until the internal pressure of the gas supply space during injection exceeds a predetermined pressure value.

The switch cylinder includes a first hole for connecting the atmosphere and the inside of the switch cylinder, a second hole for connecting the gas generating space and the inside of the switch cylinder, and a second hole for connecting the inside of the gas supply space and the switch cylinder And a stepped portion formed between the first hole and the third hole and forming a bypass flow path connected to the first hole, the third hole being located between the first hole and the second hole, can do.

For example, when the chemical liquid is filled, the switch piston is positioned between the third hole and the second hole in the switch cylinder to connect the atmosphere to the gas supply space. When the chemical liquid is injected, Wherein the gas supply space is located between the third hole and the step portion in the switch cylinder to connect the gas supply space with the gas generating space, and when the internal pressure of the gas supply space during the chemical solution injection exceeds a predetermined pressure value, The switch piston is positioned between the first hole and the step portion in the switch cylinder to form a bypass flow path connecting the gas supply space and the atmosphere.

The length from the first hole to the step portion may be shorter than the length of the switch elastic member or shorter than the sum of the length of the switch elastic member and the length of the switch piston.

The switch cylinder may be integrated with the body of the gas generating part.

The chemical liquid injector according to the embodiment of the present invention has an advantage that the internal pressure can be adjusted according to the chemical liquid filling and injection mode. When the chemical liquid is charged, the internal pressure of the apparatus equilibrates with the external atmospheric pressure. By applying a high pressure to the inside, it is possible to easily inject the drug solution into the patient stably and continuously at a constant flow rate while being easily influenced by changes in the environment such as the height of the drug solution injector or the external temperature while facilitating the filling of the drug solution.

Specifically, in the chemical liquid injector according to the embodiment of the present invention, when the chemical liquid is charged, the switch member is not operated, so that the inside of the apparatus communicates with the outside atmosphere, When the chemical liquid is injected into the patient, the switch member is actuated by the driving force of the gas generated in the gas generating unit in the apparatus, so that the communication between the inside of the apparatus and the outside air is interrupted The high pressure generated by the generated gas acts on the injection piston, thereby making it possible to inject the charged chemical liquid into the patient steadily and constantly at a constant flow rate while being less influenced by changes in the environment such as the height of the chemical liquid injector or the external temperature. It provides an advantage that can be done.

Further, in the chemical liquid injector according to the embodiment of the present invention, when the internal pressure of the apparatus exceeds a preset pressure by the gas generated in the gas generating unit, the switch member operates as a pressure regulating valve, There is an additional advantage of being able to remain constant at the set pressure.

1 is a perspective view schematically showing a chemical liquid injecting apparatus 1000 capable of adjusting an internal pressure according to an embodiment of the present invention.
FIG. 2 is a perspective view schematically showing a chemical liquid injecting apparatus 1000 capable of adjusting an internal pressure in another direction according to an embodiment of the present invention.
3 is an exploded perspective view schematically illustrating a state in which a chemical liquid injector 1000 capable of adjusting an internal pressure according to an embodiment of the present invention is disassembled.
4 and 5 are an exploded perspective view and an exploded perspective sectional view schematically showing a part of the structure of a chemical liquid injecting apparatus 1000 capable of adjusting an internal pressure according to an embodiment of the present invention.
FIG. 6 is a cross-sectional view and a partial enlarged view of a chemical liquid injecting apparatus 1000 capable of adjusting an internal pressure according to an embodiment of the present invention.
7A to 7E are diagrams showing operation procedures of a chemical liquid injector 1000 capable of adjusting an internal pressure according to an embodiment of the present invention, .
8A to 8E are diagrams showing an operation procedure of the chemical liquid injecting apparatus 1000 capable of adjusting an internal pressure according to an embodiment of the present invention. to be.
Fig. 9 is an enlarged view of Fig. 8 (e), illustrating that the switch member operates as a preliminary (auxiliary) pressure regulating valve.
Figs. 10A and 10B are views for explaining before and after the operation of the pressure regulating valve. Fig.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings. It should be understood that the following embodiments of the present invention are only for embodying the present invention and do not limit or limit the scope of the present invention. It will be understood by those of ordinary skill in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. The references cited in the present invention are incorporated herein by reference.

FIG. 1 is a perspective view schematically showing a chemical liquid injecting apparatus 1000 according to an embodiment of the present invention, and FIG. 2 is a perspective view of a chemical liquid injecting apparatus 1000 according to an embodiment of the present invention. 3 is an exploded perspective view of a chemical liquid injector 1000 according to an embodiment of the present invention.

The chemical liquid injector 1000 capable of adjusting the internal pressure according to an embodiment of the present invention includes a substantially cylindrical cylinder 110, an injection piston 140, and a switch member 136 as main components.

As shown in FIG. 1, a chemical liquid flow tube 150 through which a chemical liquid flows in and out is connected to one end of a substantially cylindrical cylinder 110, and a gas generating part 130 is coupled to the other end.

The injection piston 140 is airtightly moveable inside the cylinder 110 and moves the inner space of the cylinder 110 into the chemical solution storage space 114 through which the chemical solution flows into the chemical solution flow tube 150, And a gas supply space 116 through which gas generated in the gas generating unit 130 is supplied. An end cap (not shown) may be provided at the end of the drug solution flow tube 150, and an injection needle or catheter (not shown) may be connected to the end cap.

3, seal ring insertion grooves 146a and 146b are formed between the ring-shaped protrusions on the circumference of the body of the injection piston 140. The seal ring insertion grooves 146a and 146b are respectively sealed Rings 144a and 144b are fitted and engaged. The injection piston 140 can be airtightly moved inside the cylinder 110 by these seal rings 144a and 144b.

As shown in FIGS. 1 to 3, the gas generating unit 130 is largely composed of a body 131 and a cap 132. At this time, the trunk portion 131 includes a gas generating space 139 therein (see FIG. 6).

The gas generating part 130 accommodates the liquid material L and the solid material 134. The liquid material L is accommodated in the body part 131 and the solid material is accommodated in the cap part 132. [ The solid material 134 is isolated from the liquid material L by the partition 133 and is accommodated in the cap portion 132. [ The solid material 134 may be in the form of a pellet based on sodium carbonate (Na ₂ CO ₃ ) and the liquid material L may be an acidic liquid material such as citric acid that generates carbon dioxide upon reaction with the solid material 134 Lt; / RTI >

The liquid material L is received by a gas-permeable and liquid-impermeable filter (not shown) provided on the circumference and the bottom of the body portion 131, And does not flow out into the gas supply space 116 of the cylinder 110.

When an external force is applied to the cap portion 132 and the partition wall 133 is disengaged and the solid material 134 falls into the gas generating space 139 in the body portion 131, a gas, that is, carbon dioxide do.

The generated gas passes through the gas-permeable and liquid-impermeable filters in the body 131 and is discharged into the gas supply space 116 of the cylinder 110, thereby pushing the rear of the injection piston 140.

The boss 137 protruding from the body 131 of the gas generating part 130 may be provided with a pressure control valve 138 for preventing the pressure of the gas from exceeding a predetermined pressure or more.

The pressure regulating valve 138 connects the gas supply space 116 to the outside (for example, the atmosphere) when the pressure of the gas supply space 116 becomes higher than a predetermined pressure, in order to prevent the chemical solution from being injected to the patient faster than a predetermined flow rate So that the gas in the gas supply space 116 flows out to the outside. As a result, the pressure in the gas supply space 116 is kept constant.

The pressure regulating valve 138 includes a substantially cylindrical body 220, an opening and closing member 230, an elastic member 240, Cap part 250 and the like.

The body portion 220 of the pressure regulating valve has a substantially cylindrical shape and can be fitted in a fitting manner to the inner surface of the boss 137 as shown in the figures. However, the present invention is not limited thereto. For example, the body 220 of the pressure regulating valve may be installed in the boss 137 by various methods such as ultrasonic welding.

The body portion 220 of the pressure regulating valve is installed in the boss 137 so as to protrude into the gas supply space 116. An inner passage is formed in the protruding portion of the body portion 220 to allow gas to flow therethrough. The opening and closing member 230 of the pressure regulating valve is installed to be exposed to the gas supply space 116 through the internal passage of the protrusion so as to move according to the pressure of the gas supply space 116.

The cap portion 250 of the pressure regulating valve is installed in the body 220 of the pressure regulating valve and is provided on the opposite side of the opening and closing member 230. The cap portion 250 is formed with an opening at the center so as to allow the gas to escape. At this time, the opening of the cap portion 250 communicates with the outside of the chemical liquid injecting apparatus. More specifically, the opening of the cap portion 250 communicates with the external air inlet 135 formed in the body portion 131 of the gas generating portion 130.

The elastic member 240 of the pressure regulating valve is installed between the opening and closing member 230 and the cap portion 250 by a coil spring. When the pressure of the gas supply space 116 becomes higher than a predetermined pressure, the elastic member 240 is compressed while the opening and closing member 230 is retracted.

When the pressure of the gas supply space 116 exceeds the internal pressure reference value (preset pressure value), the gas in the gas supply space 116 pushes the opening and closing member 230 while overcoming the elastic restoring force of the elastic member 240 . At this time, the front surface of the opening and closing member 230, which has been in contact with the inner surface of the body 220 (or the sealing ring provided on the inner surface of the body) to block gas inflow, is spaced from the inner surface of the body 220. The gas introduced along the inner passage formed in the protruding portion of the body portion 220 is separated from the space between the front surface of the opening and closing member 230 and the inner surface of the body portion 220, And ultimately through the inner space of the elastic member 240 (i.e., the inner space of the coil spring) and the opening of the cap portion 250, (See Fig. 10B). Therefore, the internal pressure of the gas supply space 116 is kept constant.

The cylinder 110, the injection piston 140, the gas generating portion 130, the boss 137, and the pressure control valve 138 are the same as those described in the prior art including Korean Patent Registration No. 10-0507593 Those skilled in the art can readily apply the present invention to the present invention, and thus a detailed description thereof will be omitted.

Hereinafter, the switch member 136, which is a main component of the chemical liquid injecting apparatus 1000 capable of adjusting the internal pressure of the present invention, will be described with reference to FIGS. 1 to 9. FIG.

The switch member 136 is provided between the gas supply space 116 and the gas generating space 139 to connect the atmospheric gas and the gas supply space 116 when the chemical solution is filled and the gas supply space 116 And the gas generating space 139 are connected to each other. To this end, a switch member 136 is provided between the atmosphere, the gas supply space 116 and the gas generating space 139. Here, the meaning of the connection means that two or more spaces are connected so that gas (air or carbon dioxide) flows.

Here, the atmospheric air refers to the outside of the chemical liquid injecting apparatus 1000 and is at atmospheric pressure. The atmosphere may be a place or a device that maintains atmospheric pressure or similar pressure, or maintains a pressure lower than the pressure of the chemical solution storage space 114 when injecting the chemical solution.

1, 2, 6, and 9, the switch member 136 will be described in detail.

The switch member 136 includes a switch cylinder 310 and a switch piston 320.

The switch cylinder 310 is connected to the atmosphere, the gas supply space 116, and the gas generating space 139. The switch cylinder 310 may be a cylindrical cylinder extending in one direction. Here, the switch cylinder 310 may extend in the radial direction of the cylinder 110. Of course, the shape and / or the extending direction of the cylinder is not limited thereto.

6, the switch cylinder 310 includes a first hole 311 for connecting the atmosphere to the inside of the switch cylinder 310, and a second hole 311 for connecting the inside of the gas generating space 139 and the switch cylinder 310 And a third hole 313 connecting the gas supply space 116 and the inside of the switch cylinder 310. The first hole 311, the second hole 312, and the third hole 313 serve as a flow path through which the gas flows.

At this time, the third hole 313 is located between the first hole 311 and the second hole 312. The third hole 313 is formed adjacent to the first hole 311 with respect to the vertical direction (the longitudinal direction of the cylinder).

For example, the second hole 312 and the third hole 313 are formed in the side wall of the switch cylinder 310 as shown in FIG. The first hole 311 may be formed at one end of the switch cylinder 310 as shown in FIG. The third hole 313 is located between the second hole 312 and the first hole 311. The distance between the first hole 311 and the third hole 313 is shorter than the distance between the first hole 311 and the second hole 312 with respect to the vertical direction (the longitudinal direction of the cylinder).

At this time, the other end of the switch cylinder 310 may be clogged. Alternatively, the switch cylinder 310 may further include a fourth hole 314. The fourth hole 314 is formed on the opposite side of the first hole 311, that is, the other end of the switch cylinder 310. The fourth hole 314 is blocked by a cap 340 described later. A detailed description of the cap 340 will be given later.

The switch cylinder 310 described above may be formed integrally with the body 131 of the gas generating part 130. Alternatively, the switch cylinder 310 may be separately configured and coupled to the body 131 of the gas generating unit 130. Hereinafter, the switch cylinder 310 is integrally formed on the body 131 to simplify the description, but the present invention is not limited thereto.

As shown in FIG. 6, the body portion 131 of the gas generating portion 130 has partition walls formed therein, and the outer wall has a generally cylindrical shape. The first hole 311, the second hole 312, the third hole 313 and the fourth hole 314 are formed in the inner partitions or the outer wall of the body 131.

The body portion 131 of the gas generating portion 130 may include an external air inlet 135 connected to the switch cylinder 310. The external air inlet 135 is formed on the side of the body 131 of the gas generating part 130 and is connected to the first hole 311 of the switch cylinder 310.

The external air inlet 135 may be provided with a gas-permeable and liquid-impermeable hydrophobic filter (not shown). The hydrophobic filter allows external air to be introduced into the apparatus through the external air inlet 135, but prevents water, chemical liquid, and pollutants such as liquid from entering the apparatus from the outside.

The body portion 131 of the gas generating portion 130 further includes an external air passage 401 connecting the external air inlet 135 and the first hole 311. The pressure regulating valve 138 is connected to the external air passage 401 and is installed between the external air inlet 135 and the switch member 136.

The switch piston (320) is hermetically movably installed in the switch cylinder (310). To this end, the switch piston 320 includes ring-shaped protrusions around the trunk and seal ring insertion grooves 321 between these protrusions. The seal ring insertion groove 321 is fitted with a seal ring 323. The switch piston 320 can be hermetically moved within the switch cylinder 310 by this seal ring 323 (see FIGS. 4 and 5).

The switch piston 320 connects the atmosphere and the gas supply space 116 or connects the gas supply space 116 and the gas generating space 139 according to the position thereof. That is, the switch piston 320 connects the first hole 311 and the third hole 313 or connects the second hole 312 and the third hole 313.

For example, when the chemical liquid is charged, the switch piston 320 connects the atmosphere with the gas supply space 116 and cuts off the connection between the gas supply space 116 and the gas generating space 139 (FIGS. 6, 7 (A) and Fig. 8 (a)). That is, the switch piston 320 is positioned between the second hole 312 and the third hole 313 and connects the third hole 313 and the first hole 311. Therefore, when the chemical liquid is filled, the gas supply space 116 is connected to the atmosphere, so that the internal pressure thereof equilibrates with the atmospheric pressure or maintains a somewhat high level.

Therefore, when performing the operation of filling the chemical solution storage space 114 in the cylinder 110 with the chemical solution as a preparation work for injecting the chemical solution into the patient, the chemical solution storage space 114 and the gas supply space 116 are divided It is possible to facilitate the filling of the chemical liquid by minimizing the pushing action of the injection piston 140 that interferes with the flow of the chemical liquid flowing into the chemical liquid storing space 114, that is, the chemical liquid inflow resistance by the injection piston 140.

When the chemical liquid is injected, the switch piston 320 connects the gas supply space 116 and the gas generating space 139. That is, the switch piston 320 is located between the first hole 311 and the third hole 313, connects the second hole 312 and the third hole 313, and the atmosphere and the gas supply space 116 ). Accordingly, when the chemical liquid is injected, the switch member 136 can guide the gas generated in the gas generating unit 130 to the gas supply space 116.

In addition, in the gas supply space 116, the high pressure of the gas generated by the gas generating part 130 acts on the injection piston 140, thereby effectively advancing the injection piston 140, It is possible to stably and continuously infuse the drug solution filled in the reservoir 114 to the patient at a constant flow rate.

Referring to FIGS. 1, 3 to 6, the switch member 136 may further include a stopper 340.

The cap 340 closes the fourth hole 314 of the switch cylinder 310 exposed to the outside as described above. For example, the switch cylinder 310 is located inside the body 131 of the gas generating part 130 and includes a first hole 311 formed at one end and a fourth hole 313 formed at the other end, (314). At this time, the stopper 340 blocks the fourth hole 314 and blocks the switch cylinder 310 from being connected to the outside through the fourth hole 314.

The cap 340 may receive a portion of the rod 322 of the switch piston 320 until a predetermined pressure is applied to the switch piston 320. Specifically, in order for the chemical liquid to be stably charged, the switch piston 320 needs to maintain a state connecting the gas supply space 116 to the atmosphere at the time of filling the chemical liquid. At this time, since the cap 340 stably holds and holds a part of the rod 322 of the switch piston 320, the gas supply space 116 and the atmosphere can be stably connected when the chemical liquid is filled.

4 and 5, the stopper 340 may have a generally hemispherical shape as shown to fit into the fourth hole 314.

In addition, the stopper 340 may include an inwardly facing engagement portion 341 of the switch cylinder 310 (see FIGS. 5 and 6). For example, the engaging portion 341 comprises a concave groove facing the inside of the switch cylinder 310, and the switch piston 320 includes a rod 322 guided and received by the engaging portion 341. At this time, the rod 322 may include a hollow portion formed along the longitudinal direction thereof.

The stopper 340 is preferably made of a light-transmitting material so that the user visually recognizes the movement of the switch piston 320 so that the switch member 136 is normally operated. For example, the stopper 340 may be made of a transparent material or a translucent material.

If a portion of the rod 322 of the switch piston 320 is still positioned on the plug 340 side even if gas is generated in the gas generating portion 130 during the injection of the chemical solution, (136) is not operating properly.

Further, the switch piston 320 and / or the switch elastic member 330 to be described later are housed in the switch cylinder 310 through the fourth hole 314. Then, the stoppers 340 seal the fourth holes 314 to prevent them from being detached from the switch cylinder 310.

On the other hand, the switch member 136 can connect the atmosphere to the gas supply space 116 when the internal pressure of the gas supply space 116 is higher than the allowable value.

For example, when the pressure control valve 138 described above fails or fails to perform its function, the pressure in the gas supply space 116 may exceed the allowable value. In this case, the drug may be injected faster than the tolerance and the patient may be in danger.

As another example, there may be a case where the pressure regulating valve 138 is not present and excessive gas is generated in the gas generating part 130, so that the pressure of the gas supplying space 116 is increased. Even in this case, the drug may be injected faster than the tolerance and the patient may become dangerous.

In order to prevent this, the switch member 136 may include a bypass flow path 315 and a switch elastic member 330. Specifically, the switch cylinder 310 may include a bypass flow path 315 therein.

The bypass flow path 315 is connected to the first hole 311 and is formed along the inner wall of the switch cylinder 310. For example, the bypass passage 315 may be connected to the first hole 311 and may have a groove shape formed along the longitudinal direction of the switch cylinder 310. At this time, the bypass flow path 315 extends from the first hole 311 and is spaced apart from the third hole 313 by a predetermined distance.

Referring to Figs. 6 and 9, the bypass flow path 315 is formed by the step portion 316. Fig. The step 316 is formed between the first hole 311 and the third hole 313.

The inner diameter of the switch cylinder 310 is referred to as "D1" from the first hole 311 to the step portion 316, and the inner diameter of the switch cylinder 310 is defined as " The inner diameter of the switch cylinder 310 up to the third hole 313 is referred to as D2. In order for the stepped portion 316 to form the bypass flow path 315, D1 is larger than D2. A bypass flow path 315 is formed as shown in FIG.

In addition, the length from the first hole 311 to the step portion 316 may be shorter than the length of the switch elastic member 330. Alternatively, the length from the first hole 311 to the step portion 316 may be shorter than the sum of the length of the switch elastic member 330 and the length of the switch piston 320. Here, the direction of the length may be parallel or substantially parallel to the axial direction of the switch cylinder 310.

The switch elastic member 330 is disposed in the switch cylinder 310 and is located between the atmosphere and the switch piston 320. The switch elastic member 330 is biased until the internal pressure of the gas supply space 116 becomes higher than the allowable value, (I.e., pushing resilient restoring force) to the switch piston 320 in order to close the path passage 315.

For example, the switch resilient member 330 is located within the switch cylinder 310 and is located between the first hole 311 and the switch piston 320. More specifically, the switch elastic member 330 may be disposed adjacent to the first hole 311 as shown in FIGS. 6 and 9. At this time, the switch elastic member 330 does not block the first hole 311. Alternatively, the switch resilient member 330 may be located on the switch piston 320 side to be accommodated in a recessed groove (see Fig. 5) formed in the switch piston 320. [

The switch elastic member 330 is a coil spring, and may be a conical coil spring as shown. However, the present invention is not limited thereto, and the switch elastic member 330 can be modified in various ways such as a cylindrical coil spring.

FIG. 7 is a diagram showing an operation state of a chemical liquid injector according to an embodiment of the present invention (a state of use when the pressure regulating valve normally operates) according to an operation sequence. FIG.

Referring to FIG. 7A, the injection piston 140 is in the state of being adjacent to the tip end of the cylinder 110, as a pre-filling step or an initial step of filling the chemical solution.

At this time, the switch member 136 is connected to the air supply space 116 and the atmosphere. That is, the switch piston 320 is positioned between the second hole 312 and the third hole 313. The gas supply space 116 is connected to the atmosphere via the third hole 313, the interior of the switch cylinder 310, the first hole 311, the external air passage 401 and the external air inlet 135 .

As the chemical solution is charged, the injection piston 140 is retracted rearward and the pressure state in the gas supply space 116 is maintained in the third hole 313, the interior of the switch cylinder 310, the first hole 311, And is kept substantially in equilibrium with the atmosphere via the external air passage 401 and the external air inlet 135. At this time, a part of the rod 322 of the switch piston 320 is retained in the stopper 340. 7 (b), the switch member 136 remains in the state shown in FIG. 7 (a) until the chemical liquid filling is completed.

Accordingly, the pressure inside the gas supply space 116 stably equilibrates with the atmospheric pressure. In this state, when the operation of filling the chemical solution storage space 114 with the chemical solution is performed, the pushing action of the injection piston 140 to interfere with the flow of the chemical solution flowing into the chemical solution storage space 114, So that the filling of the chemical liquid can be facilitated.

7 (c) and 7 (d), after the chemical liquid filling is completed, an external force is applied to the cap portion 132, so that the partition wall 133 is disengaged and the solid material 134 flows into the gas generating space (139), it reacts with the liquid material (L) to generate gas, that is, carbon dioxide.

The gas generated in the gas generating space 139 flows into the switch cylinder 310 through the second hole 312 and pushes the switch piston 320 so that the switch piston 320 is separated from the stopper 340 .

Thereafter, the introduced gas continues to move the switch piston 320 along the switch cylinder 310. The second hole 312 and the third hole 313 are connected by the movement of the switch piston 320 by a predetermined distance. In this state, the switch piston 320 is supported by the switch elastic member 330, so that the switch piston 320 is kept in a state of no further movement unless the pressure is significantly increased (see Fig. 7 (d)).

As described above, as the second hole 312 and the third hole 313 are connected, the gas flows into the gas supply space 116 and advances the injection piston 140 to inject the drug solution into the patient. During the chemical liquid injecting step, the switch piston 320 isolates the first hole 311 from the gas generating space 139 and the gas supplying space 116.

Referring to FIG. 7 (e), gas is excessively generated during chemical solution injection, and the pressure of the gas supply space 116 can be considerably increased. As a result, the drug solution can be injected at a rate faster than a predetermined flow rate to the patient.

In order to prevent this, when the pressure of the gas supply space 116 becomes considerably high, the pressure regulating valve 138 is opened and the gas supply space 116 and the atmosphere can be connected to discharge the gas into the atmosphere. Therefore, as the pressure regulating valve 138 is opened, the pressure of the gas supply space 116 can be maintained to an extent necessary for injecting the chemical liquid.

Also, the pressure regulating valve 138 is closed when the gas supply space 116 reaches a proper pressure as the gas flows out, so that the gas supply space 116 can be maintained at an appropriate pressure.

8 is a view showing, in an operation order, another state of use (a state of use when the pressure regulating valve does not normally operate) of the chemical liquid injecting apparatus according to an embodiment of the present invention. The operation from (a) to (d) of FIG. 8 is the same as the operation from (a) to (d) of FIG. 7 as described above, and a description thereof will be omitted. 8 (e) shows that the switch member 136 serves as a preliminary (auxiliary) pressure regulating valve.

Referring to FIG. 8E, during the chemical liquid injection, the gas is excessively generated, so that the pressure of the gas supply space 116 can be considerably increased. As a result, the drug solution can be injected at a rate faster than a predetermined flow rate to the patient.

At this time, the pressure regulating valve 138 may not exist, or may malfunction or malfunction. In this case, the switch member 136 connects the gas supply space 116 to the atmosphere when the internal pressure of the gas supply space 116 exceeds the allowable value during the chemical solution injection.

Specifically, when the internal pressure of the gas supply space 116 exceeds the allowable value, the pressure in the switch cylinder 310 as well as the gas supply space 116 becomes high, and the gas pressurizes the switch piston 320 to a higher pressure . Accordingly, the switch elastic member 330 is compressed by the pressure of the raised gas, and the switch piston 320 is moved to a position where the bypass passage 315 is opened (see FIG. 9).

Accordingly, the gas exceeding the predetermined pressure is discharged to the atmosphere through the bypass flow path 315, the first hole 311, the external air flow path 401, and the external air flow port 135. Therefore, the pressure of the gas supply space 116 can be maintained to an extent necessary for injecting the chemical liquid.

When the gas supply space 116 reaches an appropriate pressure as the gas flows out, the switch elastic member 330 moves the switch piston 320 in the opposite direction by the elastic restoring force to close the bypass flow path 315 8 (d)). As such, the switch member 136 can maintain the gas supply space 116 at an appropriate pressure.

With the above-described operation, the chemical liquid injector of the present invention can provide a high chemical liquid injection pressure for injecting the chemical liquid stably and continuously into the patient, while being less influenced by changes in the environment such as elevation or external temperature, In order to solve the problem of difficulty in filling the chemical liquid at the injection pressure, when the chemical liquid is filled, the inside of the apparatus is communicated with the outside air so that the pressure inside the apparatus equilibrates with the atmospheric pressure, thereby facilitating the filling of the chemical liquid. Further, when the internal pressure of the apparatus exceeds the predetermined pressure by the gas generated in the gas generating unit, the switch member operates as the pressure regulating valve, so that the internal pressure of the apparatus can be kept constant at a predetermined pressure.

Although the present invention has been described with reference to the above embodiments, the present invention is not limited thereto. It will be understood by those skilled in the art that modifications and variations may be made without departing from the spirit and scope of the invention, and that such modifications and variations are also contemplated by the present invention.

1000: chemical liquid injecting apparatus 110: cylinder
114: chemical solution storage space 116: gas supply space
130: gas generating part 131: body part
132: Cap portion 135: Outside air inlet
136: Switch member 138: Pressure regulating valve
139: gas generating space 140: injection piston
310: switch cylinder 311: first hole
312: first hole 313: third hole
314: Fourth hole 315: Bypass passage
316: step portion 320: switch piston
330: switch elastic member 340: stopper

Claims (12)

A cylinder to which a chemical liquid flow tube to which a chemical liquid flows and flows is connected at one end and a gas generating unit having a gas generating space for generating a gas is connected at the other end,
And a gas supply unit for supplying the gas generated from the gas generating unit to the gas supply space, the gas supply unit comprising: An injection piston,
And a switch member which is provided between the gas supply space and the gas generating space and connects the atmospheric gas and the gas supply space at the time of filling the chemical solution and connects the gas supply space and the gas generating space at the time of injecting the chemical solution, , A chemical liquid injector capable of adjusting the internal pressure. The method according to claim 1,
Wherein the switch member comprises:
A switch cylinder connected to the atmosphere, the gas supply space, and the gas generating space; And
And a switch piston movably installed in the switch cylinder and connecting the atmosphere to the gas supply space according to the position in the switch cylinder or connecting the gas supply space to the gas generating space, Liquid injection device. 3. The method of claim 2,
The switch cylinder includes a first hole for connecting the atmosphere and the inside of the switch cylinder, a second hole for connecting the gas generating space and the inside of the switch cylinder, and a second hole for connecting the gas supply space and the inside of the switch cylinder And a third hole positioned between the first hole and the second hole. The method of claim 3,
The switch piston is positioned between the third hole and the second hole in the switch cylinder to connect the atmosphere and the gas supply space when the chemical liquid is filled, and when the chemical liquid is injected, the switch piston is positioned in the switch cylinder Wherein the gas supply space is located between the third hole and the first hole and connects the gas supply space and the gas generating space. The method according to claim 3 or 4,
Wherein the switch cylinder further includes a fourth hole exposed to the outside, and the switch member further includes a cap for blocking the fourth hole. 6. The method of claim 5,
Wherein the stopper is made of a light-transmitting material so as to visually recognize the movement of the switch piston and to know whether the switch member is normally operated. The method according to claim 6,
Wherein the stopper is made of a transparent material or a semitransparent material. 5. The method according to any one of claims 1 to 4,
When the internal pressure of the gas supply space exceeds a predetermined pressure value during the chemical solution injection, the switch member discharges gas as much as the pressure value exceeded through the bypass channel connecting the gas supply space and the atmosphere to the outside Wherein the inner pressure adjusting means is configured to adjust the inner pressure of the chemical liquid injecting device. The method according to claim 1,
Wherein the switch member comprises:
A switch cylinder connected to the atmosphere, the gas supply space, and the gas generating space, the switch cylinder including a bypass flow path connecting the gas supply space and the atmosphere;
A switch piston movably installed in the switch cylinder and connecting the atmosphere and the gas supply space according to a position in the switch cylinder or connecting the gas supply space and the gas generating space; And
And a switch piston disposed in the switch cylinder and positioned between the atmosphere and the switch piston, wherein the switch piston is closed to close the bypass flow passage until the internal pressure of the gas supply space exceeds a predetermined pressure value during chemical solution injection A switchable elastic member capable of providing an elastic force. 10. The method of claim 9,
The switch cylinder includes:
A first hole connecting the atmosphere and the inside of the switch cylinder;
A second hole connecting the gas generating space and the inside of the switch cylinder;
A third hole which connects the gas supply space and the interior of the switch cylinder and is located between the first hole and the second hole; And
And a step portion formed between the first hole and the third hole, the step portion forming the bypass flow path connected to the first hole. 11. The method of claim 10,
The switch piston is positioned between the third hole and the second hole in the switch cylinder to connect the atmosphere and the gas supply space when the chemical liquid is filled, and when the chemical liquid is injected, the switch piston is positioned in the switch cylinder Wherein the switch piston is located between the third hole and the step portion to connect the gas supply space with the gas generating space, and when the internal pressure of the gas supply space during the chemical solution injection exceeds a predetermined pressure value, And a bypass flow path which is located between the first hole and the step portion and connects the gas supply space and the atmosphere in the switch cylinder. The method according to claim 10 or 11,
Wherein a length from the first hole to the stepped portion is shorter than a length of the switch elastic member or shorter than a sum of a length of the switch elastic member and a length of the switch piston.

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