KR101273764B1 - Device for injecting sterilant and sterillization apparatus including the same - Google Patents

Abstract

The present invention relates to a sterilant injector for injecting a sterilant into a chamber having a space in which the sterilant is located, the holder for holding a container containing the sterilant; A bucket containing the sterilant; And a perforation unit for perforating the container to supply the sterilant in the container to the bucket.

Description

Sterilizer injector and sterilization apparatus including the same {DEVICE FOR INJECTING STERILANT AND STERILLIZATION APPARATUS INCLUDING THE SAME}

The present invention relates to a sterilant injector and a sterilization apparatus including the same, and more particularly, to a sterilant injector capable of supplying a sterilant in a quantitative manner and a sterilization apparatus including the same.

Various types of medical devices are used by sterilizing microorganisms on the surface and lumen with a sterilization device. As a sterilization apparatus, a high pressure steam sterilizer (steam sterilizer), an ethylene oxide (EO) gas sterilizer, a plasma sterilizer, etc. can be used.

The high pressure steam sterilizer is sterilized using steam at high pressure, so there is a problem in that it is not suitable for sterilization of a medical device having a vulnerability to high temperature, humidity and / or high pressure. And since the ethylene oxide gas sterilizer uses ethylene oxide gas, which is a toxic gas, toxic residues may remain in the sterilized product. Accordingly, since a separate residual gas removal process must be performed to remove the toxic gas, the process becomes complicated and the process cost increases.

On the other hand, the plasma sterilizer can be sterilized at a relatively low temperature by using a plasma, and has the advantage that the plasma can be easily decomposed into a material that is harmless to the environment. In such a plasma sterilizer, the operator can supply the sterilizing agent by pouring the sterilizing agent after removing the stopper and the like of the container containing the sterilizing agent. According to this method, the work efficiency may be lowered, and problems such as undesired flow of the sterilant may occur in the process of mounting the container to the holder.

The present invention is to provide a sterilant supply device and a sterilization apparatus including the same that can simplify the sterilant injection process and improve productivity.

The sterilant injector according to the present embodiment is a sterilant injector for injecting a sterilant into a chamber having a space where a sterilized material is placed, the holder for holding a container containing the sterilant; A bucket containing the sterilant; And a perforation unit for perforating the container to supply the sterilant in the container to the bucket.

An upper portion of the container may be supported by the holder.

The sterilant injector, the pressing portion for pressing the lower portion of the container to be punctured by the upper portion of the container; And a driving part for driving the pressing part up and down.

The container may include a container part containing the sterilant and an upper part of the container part and a stopper part blocking an upper part of the container part, and the perforation part may puncture the stopper part.

The drive unit may include a pneumatic cylinder.

The planar area of the pressing portion may be wider than the planar area of the container.

Holes through which the sterilant may flow may be formed in the perforation.

The end of the perforation may be pointed.

A first portion in which the perforation is fixed to the holder; A second portion protruding from the first portion and having a smaller cross-sectional area than the first portion; And a third portion protruding from the second portion and gradually decreasing in cross-sectional area.

The perforation unit may include a first hole formed at a side surface of the third portion; A second hole formed on a side of the second portion; And a third hole opening toward the first portion in the perforation part and communicating with the first and second holes.

The sterilant injector may further include a vaporizer for vaporizing the sterilant.

The sterilant injector includes a sterilant supply pump connected to the bucket and driven to inject the sterilant into the vaporizer; And a sterilant control valve positioned between the pump and the vaporizer to control the flow of the sterilant.

The sterilant injector, the air filter for filtering the outside air; And it may further include an air control valve for controlling the flow of the filtered outside air. The sterilant may be injected into the chamber after being vaporized by the vaporizer and the filtered outside air may be injected into the chamber by the air control valve.

On the other hand, sterilization apparatus according to an embodiment of the present invention, the sterilant injector described above; And a chamber in which the sterilized material placed therein is sterilized using the sterilant injected by the sterilant injector.

The sterilant may include a hydrogen peroxide solution, and sterilize the sterilized product using plasma.

According to this embodiment, the sterilant leaked in the process of removing the closure of the container can prevent the risk of contact with the skin of the operator, causing damage to the skin, the time to remove the closure of the container, time to follow the sterilant It can reduce the back and can be supplied to the bucket without spilling the sterilant. In addition, the operator can easily know when to replace the container using a specially designed sensor to measure the amount of sterilant. Therefore, the sterilant injection process can be simplified and productivity can be improved by minimizing the loss of the sterilant and the operator's convenience can be achieved.

In addition, the sterilant and filtered outside air may be injected into the chamber to accelerate the penetration of the sterilant into the sterilant. Thereby, the sterilization effect can be improved.

1 is a schematic configuration diagram of a sterilization apparatus according to an embodiment of the present invention.
Figure 2 is a side view showing the sterilant injector of Figure 1;
3 is a cross-sectional view showing in detail the container, holder, bucket and perforation of FIG.
4 is an enlarged perspective view of the perforated part of FIG. 2.
5 is a cross-sectional view of FIG. 4.
FIG. 6 is a cross-sectional view taken along the line VI-VI of FIG. 2.

Hereinafter, with reference to the accompanying drawings, a sterilant injector and a sterilization apparatus including the same according to an embodiment of the present invention will be described in detail.

1 is a schematic configuration diagram of a sterilization apparatus according to an embodiment of the present invention.

Referring to FIG. 1, the sterilization apparatus 100 according to the present embodiment may include a chamber 10, a vacuum unit 20, a sterilant injector 30, a plasma generator 40, an external air supply unit 50, and the like. It may include.

The chamber 10 provides a space in which the sterilized substance 80 can be placed, and can be heated, sealed, and exhausted so that the inside of the chamber 10 can maintain a desired temperature and pressure.

The vacuum unit 20 is for vacuuming the inside of the chamber 10 to a desired pressure. For example, the vacuum unit 20 may include a vacuum pump 21 for exhausting air in the chamber 10, and may include an exhaust control valve 23 for controlling the flow of air. And it may further include a filter 25 for filtering the air exhausted from the interior of the chamber (10). As the vacuum pump 21 and the exhaust control valve 23, various types of pumps and valves may be used. For example, a solenoid valve may be used as the exhaust control valve 23. As the filter 25, a filter using various catalysts may be used in consideration of a sterilizing agent. As an example, when the sterilant includes hydrogen peroxide (H ₂ O ₂ ), it is possible to use the filter 25 using a manganese dioxide catalyst.

The sterilant injector 30 serves to supply sterilant and external air into the chamber 10. In one example, the sterilant injector 30 includes a sterilant inlet 31, a sterilant supply pump 32, a sterilant control valve 34, an air filter 36, an air control valve 37 and a vaporizer 39. ) May be included. The sterilant injector 30 will be described in more detail later with reference to FIGS. 2 to 6.

The plasma generator 40 may include a power supply 41 for supplying power for generating plasma, and an electrode 43 for receiving a power from the power supply 41 to form a plasma. The power supply 41 and the electrode 43 may include a power supply source and an electrode in various ways. For example, a power supply for providing a high frequency voltage to the power supply 41 may be used. When the chamber 10 has a cylindrical shape with one surface open, the electrode 43 corresponds to the internal shape of the chamber 10. It may have a cylindrical shape.

The external air supply unit 50 is for supplying external air to boost the inside of the chamber 10. As an example, the external air supply unit 50 may include a filter 51 for filtering the external air and an air control valve 53 for controlling the flow of the filtered external air.

In addition, the pressure sensor 60 for detecting the pressure in the chamber 10, and a temperature sensor (not shown) for detecting the temperature in the chamber 10 may be further included. In addition, various sensors capable of detecting various process conditions and a circuit breaker (not shown) which automatically cuts off the power when an electrical short or overheat occurs, may be further included. In addition, the chamber 10 may further include a heater (not shown) that can adjust the temperature inside.

The sterilant injector 30 will be described in more detail with reference to FIGS. 2 and 3. FIG. 2 is a side view of the sterilant injector 30 of FIG. 1, and FIG. 3 is a detailed cross-sectional view of the container 310, the holder 312, the bucket 314 and the perforation 316 of FIG. 2. to be. In FIG. 3, the sterilant amount sensor 324 is omitted in FIG. 3 for clarity and simplicity.

Referring to FIG. 2, the sterilant injector 30 supplies a sterilant injector 31, a sterilant supply pump 32, and a sterilant control valve 34 to supply a sterilant, and to supply filtered external air. It may include an air filter 36 and an air control valve 37 and a vaporizer 39 to vaporize the sterilant.

Here, the sterilant injecting unit 31 is a holder (312) for holding the container 310 containing the sterilizing agent, a bucket 314 and a container 310 containing the sterilizing agent provided from the container 310 to puncture the container ( 310 may include a perforated portion 316 for supplying a sterilant in the bucket 314. Then, the pressing portion 318 for pressing the lower portion of the container 310 so that the upper portion of the container 310 is drilled by the punching portion 316, and the driving portion 319 for driving the pressing portion 318 up and down. It may further include. This will be explained in more detail.

The container 310 may use various shapes of the container 310 as a container containing a sterilizing agent. The container 310 may include a container part 310a having an open top while containing a sterilizing agent, and a stopper part 310b covering an upper part of the container part 310a. The container portion 310a is formed of a material capable of safely containing the sterilizing agent to safely receive the sterilizing agent. The sterilant may be supplied to the bucket 314 by puncturing the stopper 310b.

For example, the sterilant may be a sterile solution, preferably a hydrogen peroxide solution. At this time, the hydrogen peroxide solution may have a concentration of 60% or less as determined by law. However, the present invention is not limited thereto, and various materials may be used as sterilizing agents.

In an embodiment, the holder 312 may include a cover portion 312a covering the top of the bucket 314 and a protrusion 312b protruding from the cover portion 312a and having a space into which the container 310 is fitted. . The cover part 312a may be fixed to the bucket 314 by a screw 312c or the like. An inner surface of the protrusion 312b may have a shape corresponding to a portion of the side surface of the container 310, and a portion of the side surface of the container 310 may be wrapped and supported by the protrusion 312b. For example, when the container 310 is formed in a substantially cylindrical shape, the inner space of the protrusion 312b may also be formed in a cylindrical shape. When the container 310 is placed upside down in the holder 312 to be positioned in the holder 312, the upper portion of the container 310 may be supported by the holder 312.

The perforations 316 perforate the top of the vessel 310, in particular the closure 310b, to supply sterilant inside the vessel 310 to the bucket 314. The perforations 316 may be fixed to the cover 312a of the holder 312 by a screw 316c or the like.

4 and 5 together with FIGS. 2 and 3, the perforations 316 of this embodiment will be described in more detail. 4 is an enlarged perspective view of the perforation part 316 of FIG. 2, and FIG. 5 is a cross-sectional view of FIG. 4.

As shown in the figure, the drilling portion 316 has a first portion 316a having a relatively large area and a first portion 316a so that a screw 316d for fixing to the lid portion 312a can be mounted. A second portion 316b protruding upward from the upper portion having a substantially same cross-sectional area, and a third portion 316c having a sharp end portion having a gradually reduced cross-sectional area. The stopper 310b of the container 310 is perforated by the pointed end of the third portion 316c.

The cover portion 312a of the holder 312 is formed with a fixing hole 312d into which a portion of the first portion 316a and the second portion 316b of the drilling portion 316 is fitted. When the screw 316d is tightened to the first portion 316a and the cover portion 312a after inserting the punching portion 316 into the fixing hole 312d, the punching portion 316 is stably fixed to the lid portion 312a. can do.

A hole 360 through which a sterilant (for example, a sterile solution) may flow is formed in the perforation part 316. The hole 360 may include a first hole 361 formed on the side of the third part 316c, a second hole 363 formed on the side of the second part 316b, and a hole 316. It may include a third hole 365 opening toward the first portion 316a and communicating with the first and second holes 361.

Here, the first hole 361 is a hole for allowing air to flow into the container 310, the second hole 363 is a hole for allowing the sterilant inside the container 310 to flow into the bucket 314, The third hole 365 is a hole for allowing air and a sterilant to circulate alternately. The second hole 363 may have a shape that is elongated along the length direction of the second portion 316b to sufficiently use the length of the second portion 316b.

As a result, when the stopper 310b of the container 310 is drilled by the puncturing part 316, air is introduced into the container 310 along the first hole 361, and the sterilant in the container 310 is discharged. It flows along the second hole 363 to the third hole 365 of the perforation portion 316, and moves downward along the third hole 365 to supply the sterilant to the bucket 314.

As described above, since the sterilant is supplied using the first to third holes 361, 363, and 365 formed in the perforation part 316, the sterilant may be prevented from flowing in an undesired direction or standing in an undesired place. have.

Referring to FIGS. 2 and 3 again, the pressing part 318 presses the lower part of the container 310 by the driving part 319 driven up and down while the container 310 is positioned in the holder 312. Then, the stopper 310b of the container 310 is perforated by the perforations 316.

Various methods may be applied to the driver 319. For example, a pneumatic cylinder that can easily obtain compressed air as a power source and can freely transmit pressure can be used as the driving unit 319.

The pressing portion 318 applies pressure to the vessel 310 such that the stopper 310b of the vessel 310 is perforated by the perforations 316. The pressing portion 318 may have a planar area that is wider than the planar area of the vessel 310 so that pressure can be evenly transmitted to the vessel 310. The pressing part 318 may be made of various materials that do not damage the container 310, but the pressing part 318 is not limited to the above, and may be formed of various shapes and materials.

As the bucket 314, a bucket 314 of various manners and shapes capable of receiving a sterilant therein may be used. The bucket 314 is connected to the sterilant supply pipe 322 to move the sterilization solution.

In addition, the bucket 314 may be provided with a sterilant amount sensor 324 capable of measuring the amount of the sterilant of the sterilant (eg, sterile solution). At this time, by placing a plurality of sterilant amount sensor 324 in the vertical direction to accurately detect the amount of the sterilant in the bucket 314. As such sterilant amount sensor 324, various known sterilant amount sensors may be used.

The sterilant supply pump 32 is connected to the bucket 314 by a sterilant supply pipe 322 and to supply the sterilant of the bucket 314 to the vaporizer 39 under the control of the sterilant control valve 34. Driven. As the sterilant supply pump 32 and the sterilant control valve 34, various pumps and valves may be used.

On the other hand, the air filter 36 filters the outside air, and the filtered outside air is controlled by the air control valve 37 and supplied to the chamber (reference numeral 10 of FIG. 1, hereinafter same). Various filters and valves may be used as the air filter 36 and the air control valve 37. In one example, a solenoid valve may be used as the air control valve 37.

The vaporizer 39 vaporizes the injected sterilant and supplies it to the chamber 10. As the vaporizer 39, various types of vaporizers can be used. An example of such a vaporizer 39 is demonstrated with reference to FIG. FIG. 6 is a cross-sectional view taken along the line VI-VI of FIG. 2.

Referring to FIG. 6, the vaporizer 39 includes a wall portion 39a that provides an internal space in which vaporization occurs, a heater 39b mounted on an outer surface of the wall portion 39a, and a heat insulating material surrounding the heater 38b ( 39c). The heat insulating material 39c may be made of a heat insulating material capable of keeping the temperature inside the vaporizer and maintaining the temperature. In addition, various heaters may be used as the heater 39b. For example, a silicon heater having excellent thermal conductivity, uniformly applying heat, and attachable to a three-dimensional surface may be used as the heater 39b. As the wall portion 39a, various materials capable of effectively transferring heat while being heat resistant may be used. However, the present invention is not limited thereto, and the vaporizer 39 may be used in other manners and shapes.

Referring back to FIG. 2, the vaporizer 39 is provided with a thermostat 392, and when the temperature inside the vaporizer 39 exceeds a control set point, the temperature of the vaporizer 39 is automatically shut off to reduce the temperature. As the thermostat 392, various types of thermostats may be used.

1 to 3, the operation of the sterilant injector 30 and the sterilization apparatus 100 including the same will be described below.

After the container 310 is mounted on the holder 312, when the driving unit 319 is driven, the pressing unit 318 presses the container 310. Then, the stopper 310b of the container 310 is perforated by the perforations 316. The sterilant in the vessel 310 flows into the bucket 314 through the first and second holes 361 and 363 of the perforation portion 316 and the third hole 365 and is received in the bucket 314.

The sterilant contained in the bucket 314 is supplied to the vaporizer 39 by an amount by the sterilant supply pump 32 and the sterilant control valve 34. Then, the sterilizing agent vaporized by the vaporizer 39 is supplied to the chamber 10, and the outside air filtered by the air filter 36 is also passed through the vaporizer 39 by the air control valve 37 to the chamber 10. Is supplied.

As described above, the sterilant and the outside air are supplied to the vacuum chamber 10 to undergo a diffusion process and a vacuum process, thereby generating plasma, thereby accelerating sterilization of the sterilant material 80 inside the chamber 10. After the set plasma time has elapsed, the vacuum pump 21 is operated to remove residual gas in the chamber 10, and then the air is blown up to atmospheric pressure, and then the sterilant 80 is taken out to complete the sterilization process. do.

If the amount of sterilant measured by the sterilant amount sensor 324 is below a certain value, the controller (not shown) sounds an alarm so that the operator can recognize it. Then, the worker removes the empty container 310 and mounts the new container 310 to the holder 312, and then drives the drive unit 319 to puncture the container 310 mounted on the holder 312 to bucket 314 Sterilizers can be supplied to

In this embodiment, since the air is injected into the chamber 10 after the sterilant is injected, the pressure inside the chamber 10 may be increased to accelerate the penetration of the sterilant into the sterilant 80. In particular, the sterilant in the sterilant 80 having a narrow and long form of lumen, such as lumen can penetrate deep into the lumen. Thereby, the sterilization effect can be improved. On the other hand, in the case of heating after injecting the sterilant into the chamber 10 or when not using the filtered outside air there is a limit to increase the pressure inside the chamber 10, the sterilization effect may not be excellent have.

In the past, after the operator removed the stopper 310b of the container 310, the sterilant was supplied by pouring the sterilant in the container 310 to the bucket 314. Therefore, the risk that the sterilant leaked in the process of removing the closure of the container is in contact with the operator's skin and cause damage to the skin and the time to remove the closure 310b of the container 310, the time according to the bucket 314 The process time is long due to the like, and there is a problem such as flowing a sterilizing agent along the bucket 314. In addition, the operator has to check the amount of sterilizing agent in the bucket 314 from time to time to supply the sterilizing agent was inconvenient.

On the other hand, in the present embodiment, the sterilant injector 31 is supplied by the sterilant in the container 310 to simplify the process, minimize the loss of the sterilant, and secure the safety of the operator. In addition, by using the sterilant amount sensor 324, etc., the operator can easily know when to replace the container 310, or can automatically supply the sterilant.

Although the above-described drawings and descriptions illustrate that the sterilant injector 30 described above is used in the sterilization apparatus (reference numeral 100 of FIG. 1) using plasma, the present invention is not limited thereto. Therefore, the sterilant injector 30 described above may be used if a sterilant is used without using plasma. Other variations are possible.

Features, structures, effects and the like according to the above-described embodiments are included in at least one embodiment of the present invention, and the present invention is not limited to only one embodiment. Further, the features, structures, effects, and the like illustrated in the embodiments may be combined or modified in other embodiments by those skilled in the art to which the embodiments belong. Therefore, it should be understood that the present invention is not limited to these combinations and modifications.

Claims (15)

A holder for holding a container containing a sterilant; And
A perforated part having at least one first hole through which the sterilant is supplied to the bucket and air is introduced into the container.
Sterilant injector comprising a. The method of claim 1,
A sterilant injector having an upper portion of the container supported by the holder. The method of claim 2,
A pressing portion for pressing the vessel so that the vessel is perforated by the perforation portion; And
Sterilizer injector further comprises a driving unit for driving the pressing portion up and down. The method of claim 3,
The container includes a container portion containing the sterilant and an upper portion of the container portion, and a closure portion blocking an upper portion of the container portion,
A sterilant injector in which the perforations puncture the stopper. The method of claim 3,
Sterilizer injector, wherein the drive unit comprises a pneumatic cylinder. The method of claim 3,
A sterilant injector in which the planar area of the press is larger than the planar area of the container. The method of claim 1,
The perforation part
A second hole allowing the sterilant to flow into the bucket; And
A sterilant injector comprising a third hole through which the sterilant passing through the second hole and the air intersect. The method of claim 1,
Sterilant injector with a sharp end of the perforation. The method of claim 1,
The perforations,
A first portion fixed to the holder;
A second portion protruding from the first portion and having a smaller cross-sectional area than the first portion; And
A third portion protruding from the second portion and gradually decreasing in cross-sectional area
Sterilant injector comprising a. 10. The method of claim 9,
Wherein the perforations
A first hole formed on a side of the third portion;
A second hole formed on a side of the second portion; And
A third hole opening toward the first portion in the perforation portion and communicating with the first and second holes
Sterilant injector comprising a. The method of claim 1,
A sterilant injector further comprising a vaporizer for vaporizing the sterilant. The method of claim 11,
A sterilant feed pump connected to the bucket and driven to inject the sterilant into the vaporizer; And
Sterilant control valve located between the pump and the carburetor to control the flow of the sterilant
Sterilizer injector further comprising. The method of claim 11,
An air filter for filtering outside air; And
An air regulating valve controlling the flow of the filtered outside air
Further comprising:
The sterilant is vaporized by the vaporizer and then injected into the chamber,
And the filtered external air is injected into the chamber by the air control valve. A sterilant injector according to any one of claims 1 to 13;
A chamber in which the sterilized material placed therein is sterilized using a sterilant injected by the sterilant injector
Sterilization apparatus comprising a. 15. The method of claim 14,
The sterilant comprises a hydrogen peroxide solution,
Sterilization apparatus for sterilizing the sterilized material using a plasma.

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