KR20190106136A - Disinfection chamber and sterile management chamber using the same - Google Patents

Abstract

The present invention relates to a disinfection chamber for disinfecting both inside and outside of a target object. The disinfection chamber comprises: at least one gas injection unit installed on at least one sidewall and a ceiling of the disinfection chamber to inject gas into the disinfection chamber; a first diffusion unit for evenly diffusing the gas into the disinfection chamber; a second diffusion unit for evenly diffusing the gas into the target object; a first gas sensor sensing a residual amount of gas in the air in the disinfection chamber; at least one suction unit for discharging the gas after disinfection of the target object; a monitoring unit showing a disinfection situation of the target object; a door unit opened and closed when the target object enters and exits; and a control unit configured to detect an entry and exit of the target object and to control a disinfection process for the target object.

Description

Disinfection chamber and sterilization general management chamber using the same {DISINFECTION CHAMBER AND STERILE MANAGEMENT CHAMBER USING THE SAME}

The present invention relates to a chamber for disinfecting a vehicle and a chamber capable of managing the same. A disinfection chamber capable of disinfecting not only the exterior of the vehicle but also items in the inner space and the inner space by using a specific gas and a sterilization comprehensive management using the same Relates to a chamber.

Ambulance sterilization is required at least once a week in the ambulance operation management guidelines. In addition to ambulances, buses and vans are commonly used by many people, so it is necessary to disinfect the inside of the vehicle regularly for public hygiene.In recent years, the prevention of respiratory diseases such as SARS and swine flu To this end, the need for regular sterilization or disinfection inside the vehicle is increasing. In addition, even in the case of personal passenger cars, it is necessary to sterilize molds and bacteria in the air conditioners and air inlets, and to remove odors and keep the interior clean. Since there is a high tendency to keep clean, a simple and efficient sterilization means for the interior of the vehicle is required to maintain the interior as well as cleaning for maintaining the exterior of the vehicle.

In the case of an ambulance, the sanitary environment was secured by passing the vehicle through a tunnel-type device for external disinfection or by spraying a very small amount of disinfectant disinfectant directly or by using a portable spraying device regularly or frequently inside the vehicle. In this case, the sprayed disinfectant is not only distributed uniformly, but there is a problem that the disinfectant is not applied to the part that is not exposed to the outside.

In addition, in the case of emergency equipment or medical equipment has been used to separate the sterilization device using the ultraviolet equipment or disinfectant to remove from the ambulance (10).

Therefore, the internal disinfection device for the vehicle and the external disinfection device are separately provided, so expensive equipment should be administered, and since the disinfection area is local, the administrator must disinfect manually.

The biggest problem of the disinfection method by spraying is to spray the liquid directly, so if the spray is not made of fine particles or even if the spray is made directly, even if the spray is made by direct contact with the particles and the poisonous substances, damage or corrosion inside the vehicle may occur. Not only can it cause the condensation of the chemicals sprayed into the chamber, it can be present in the liquid phase on the bottom of the chamber even after disinfection is completed.

The present invention is to solve the above-mentioned problems and to efficiently disinfect things in and out of the vehicle and the inside of the vehicle, and does not leave a residue of the disinfectant disinfection chamber suitable for disease prevention and hygiene management and sterilization comprehensive management chamber using the same The purpose is to provide.

It is also another object to provide a simpler, more feasible but more durable disinfection chamber.

Disinfection chamber according to an embodiment of the present invention for achieving the above object is a disinfection chamber for disinfecting both the inside and the outside of the target object is installed on at least one side wall and ceiling in the disinfection chamber at least to inject gas into the disinfection chamber A gas injector, a first diffuser to evenly diffuse the gas into the disinfection chamber, a second diffuser to evenly diffuse the gas into the target object, and a first gas to sense a residual amount of gas in the air in the disinfecting chamber A sensor, at least one suction unit for discharging the gas after completion of disinfection of the target object, a monitoring unit showing a disinfection state of the target object, a door unit opened and closed when the target object is in and out, and detecting an entry and exit of the target object And a control unit controlling a disinfection process for the target object.

The gas is wet chlorine dioxide gas generated from stabilized chlorine dioxide.

The disinfection chamber further comprises a loading means for loading the target object so as to be spaced apart from the bottom surface of the disinfection chamber, wherein the bottom surface of the lower end of the loading means is formed to be inclined at a predetermined angle with respect to the suction part. do.

The suction part includes a pipe for sucking and discharging the gas in the disinfection chamber and a second gas sensor for sensing a residual amount of gas around the suction part.

The disinfection chamber is located in the suction unit located on the bottom surface of the disinfection chamber, and the first rotation to smoothly collect and discharge the gas in the disinfection chamber in the pipe and to diffuse the gas on the bottom of the disinfection chamber And a third diffusion that makes a second rotation.

The sterilization comprehensive management chamber according to another embodiment of the present invention further includes a computing chamber for controlling and monitoring a disinfection operation of the control unit observed through the disinfection chamber and the monitoring unit.

The computer chamber includes a computer unit and the computer unit includes a gas management unit, a disinfection management unit, a computer control unit, and an operation unit.

The sterilization integrated management chamber according to another embodiment of the present invention includes a disinfection chamber and a storage chamber for storing the gas injected in connection with the gas injection unit.

The storage chamber may include a first fuel storage unit for storing fuel, a vaporization unit for vaporizing the fuel with the gas, a sensing unit for measuring the concentration, humidity, or pressure of the fuel and the gas, and the airtightness of the storage chamber. It includes a security unit for.

The storage chamber further includes liquefaction means for liquefying the gas used for disinfection of the target object and discharged through the suction unit and a second fuel storage unit for storing the liquefied gas.

The disinfection chamber may be implemented by combining a plurality of plate-shaped pieces of carbon and glass fiber sheet material.

The sterilization comprehensive management chamber controls the disinfection operation of the control unit observed through the monitoring unit, manages disinfection history and disinfection schedule of the target object, checks internal and external disinfection history before and after the entry and exit of the target object, and manages the disinfection chamber. It further includes a computer chamber for monitoring and storing information, such as to provide to an external server.

The present invention can prevent the damage of the vehicle due to the residual disinfectant even after disinfection by using a gas method rather than a spray method of the disinfectant, and since the injected gas is diffused by the diffusion unit can effectively disinfect the inside and outside of the vehicle. .

The present invention has the advantage of not irritating the bronchus of the operator, the vehicle occupant because the residual disinfection gas is discharged through the suction unit.

The present invention uses a plate-like piece made of carbon and fiberglass sheets, so that it is possible to provide a disinfecting chamber that can be easily assembled and yet has strong durability and corrosion resistance.

1 is a front view of a disinfection chamber according to an embodiment of the present invention.
2 is a plan view of a disinfection chamber according to an embodiment of the present invention.
3 is a view for explaining the gas diffusion of the disinfection chamber according to an embodiment of the present invention.
Figure 4 is a plan view of a sterile comprehensive management chamber according to another embodiment of the present invention.
5 is a diagram showing the configuration of a computer unit according to another embodiment of the present invention.
6 is a view showing the configuration of a storage chamber according to another embodiment of the present invention.

In describing each drawing, like reference numerals are used for like elements. Terms such as first and second may be used to describe various components, but the components should not be limited by the terms. The terms are used only for the purpose of distinguishing one component from another.

For example, without departing from the scope of the present invention, the first component may be referred to as the second component, and similarly, the second component may also be referred to as the first component. The term “and / or” includes any combination of a plurality of related items or any item of a plurality of related items.

Unless defined otherwise, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art.

Terms such as those defined in the commonly used dictionaries should be construed as having meanings consistent with the meanings in the context of the related art and shall not be construed in ideal or excessively formal meanings unless expressly defined in this application. Should not.

Hereinafter, a sterilization chamber and a sterilization comprehensive management chamber using the same according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 is a front view of a disinfection chamber according to an embodiment of the present invention.

Referring to FIG. 1, the disinfection chamber 100 includes a gas injection unit 110, a first diffusion unit 120, a second diffusion unit 130, a third diffusion unit 140, and a first gas sensor 150. , A suction unit 160, a monitoring unit 170, a door unit 180, and a controller 190.

The gas injection unit 110 may be installed on the side wall or the ceiling of the disinfection chamber 100. For efficient disinfection, the gas injection unit 110 may be provided in plural and may be installed at a position other than the side wall or the ceiling.

The gas injection unit 110 injects disinfection gas to the vehicle 10. The disinfection gas is supplied from a storage unit connected to the outside of the disinfection chamber 100. The disinfection gas may be a wet chlorine dioxide gas generated from stabilized chlorine dioxide. Sterilized disinfection using chlorine dioxide gas, which has been sterilized in a wide range of areas such as viruses, bacteria, and fungi as commercialized gasified chlorine dioxide gas is recognized as a sterile gas, is a continuous means to cope with influenza virus, fruits, vegetables, and livestock infectious diseases. The findings are published and applied directly to the industry.

In order to supply the disinfecting gas to the gas spraying unit 110, a gas pipe 161 is provided in the side wall and the ceiling of the disinfection chamber 100, and the gas pipe 161 is connected to the storage unit. The gas injection unit 110 may inject the disinfecting gas by opening and closing the injection nozzle.

According to another embodiment of the present invention, the gas injection unit 110 may further include a blowing means (not shown) for injecting the gas. A representative example of the blowing means includes a fan, but is not limited thereto, and includes all means for inducing or injecting the gas supplied from the storage unit into the vehicle 10 in the disinfection chamber 100.

The first diffusion part 120 induces air circulation so that the gas injected by the gas injection part 110 diffuses in the disinfection chamber 100. The first diffusion part 120 may be installed on the ceiling of the disinfection chamber 100. However, for the efficient diffusion of the injected gas, the first diffusion part 120 may exist in plural and may be installed at various positions in the disinfection chamber 100.

The first diffusion part 120 is provided with a blowing means to induce circulation of air. The blowing means may be a general fan or air circulator. However, the present invention is not limited thereto, and includes all means for generating a straight air and causing air circulation.

The second diffusion unit 130 induces air circulation so that the gas injected by the gas injection unit 110 diffuses into the vehicle 10.

The second diffusion part 130 may be installed on the sidewall of the disinfection chamber 100. However, a plurality of second diffusion parts 130 may exist and may be installed at various positions in the disinfection chamber 100 so that the injected gas is efficiently diffused in the vehicle 10.

The second diffusion unit 130 is provided with a blowing means to induce circulation of air. The blowing means may be a general fan or air circulator. However, the present invention is not limited thereto, and includes all means for generating a straight air and causing air circulation.

The second diffusion part 130 has a smaller size than the first diffusion part 120 in that the second diffusion part 130 is not mainly designed to circulate inside the disinfection chamber 100, and has a larger number than the first diffusion part 120. It may be present and installed to face an open portion of the vehicle 10 (ie, a window, in the case of the SUV vehicle 10, the rear of the vehicle 10, the trunk portion, etc.).

The inside and outside of the vehicle 10 may be efficiently disinfected through the first and second diffusion parts 130, 120 and 130.

The first gas sensor 150 is disposed on the side wall of the disinfection chamber 100 and senses a residual amount of gas in the air in the disinfection chamber 100. Specifically, the first gas sensor 150 is used to detect the presence or absence of residual disinfection gas before and after the disinfection process of the vehicle 10. For efficient gas sensing, a plurality of first gas sensors 150 may exist and may be installed at a position other than the side wall of the disinfection chamber 100.

In the gas sensing method, electrochemical, semiconducting, optical, and catalytic combustion can be divided into four types. The semiconductor gas sensor and the contact combustion gas sensor are used in many ways, but the present invention is not limited thereto. The first gas sensor 150 may include any method capable of sensing the disinfecting gas used in the disinfection chamber 100.

The suction unit 160 includes a pipe 161 and a second gas sensor 162. The suction unit 160 is installed on the bottom surface of the disinfection chamber 100 to discharge the disinfection gas present in the disinfection chamber 100 through the pipe 161 after the disinfection process is completed. The suction unit 160 may be installed in a plurality of disinfection chamber 100 to efficiently discharge the disinfecting gas injected. The bottom surface of the disinfection chamber 100 may be inclined toward the suction unit 160 from the side of the disinfection chamber 100 so that the disinfection gas may be discharged well.

The third diffusion part 140 may be installed in the pipe 161.

The third diffusion unit 140 circulates air for diffusion and discharge of the injected disinfection gas. The third diffusion part 140 is provided with a blowing means to induce circulation of air. The blowing means may be a general fan or air circulator. However, the present invention is not limited thereto, and includes all means for generating a straight air and causing air circulation.

Unlike the first and second diffusers 130, 120 and 130, the third diffuser 140 operates in two ways. While the gas diffusion unit injects gas for disinfection of the vehicle 10 in the disinfection chamber 100, the air is circulated in the disinfection chamber 100. When the disinfection process is completed, the air is circulated toward the outer direction of the disinfection chamber 100, that is, the direction in which the suction unit 160 is installed so that disinfection gas is better discharged through the suction unit 160.

The second sensor is installed in the pipe 161 to sense the residual amount of gas in the air in the pipe 161. In detail, the second gas sensor 162 is used together with the first gas sensor 150 to detect the presence of residual disinfectant gas before and after the disinfection process of the vehicle 10. The gas sensing method of the second sensor may include all methods capable of sensing the disinfecting gas used in the disinfection chamber 100, like the first sensor.

Since the residual disinfection gas is efficiently discharged through the suction unit 160, there is an advantage of not irritating the bronchus of the operator and the occupant of the vehicle 10.

The monitoring unit 170 shows a disinfection situation of the vehicle 10. The monitoring unit 170 is disposed on one side of the disinfection chamber 100. However, in order to facilitate monitoring by the user, the disinfection chamber 100 may be disposed on a plurality of side surfaces.

Specifically, the monitoring unit 170 continuously monitors whether disinfection process starts, disinfection process start time, disinfection process end time, and the presence of disinfection gas in the disinfection chamber 100 detected by the first detection sensor. In addition, the monitoring unit 170 has a display unit (not shown) disposed toward the outside of the disinfection chamber 100 to display the monitored information.

The controller 190 controls the disinfection process of the disinfection chamber 100 by sensing the entry and exit of the vehicle 10. The controller 190 may be disposed on the side wall of the disinfection chamber 100. The controller 190 may be disposed on any portion of the disinfection chamber 100 as well as the bottom, ceiling, etc. for ease of design.

The controller 190 detects the presence or absence of the vehicle 10 in the disinfection chamber 100, and starts and ends the disinfection process of the disinfection chamber 100, and controls all operations of each component of the disinfection chamber 100. Therefore, the components of the disinfection chamber 100 except for the control unit 190 are connected to each other through the space between the inside and the outside of the disinfection chamber 100 through electrical wiring.

Specifically, the control unit 190 includes an operation unit 214 (not shown). The operation unit 214 may be a touch panel or a physical button, and may be formed as a lever. The form of the operation unit 214 is not limited thereto, and includes a form capable of inputting an operation related to the operation of the disinfection chamber 100 to the controller 190 from the outside of the disinfection chamber 100.

The controller 190 detects the presence of the vehicle 10 in the disinfection chamber 100 and starts the disinfection process upon receiving an input for starting the disinfection process. Even if the input of the disinfection process is received, if the presence of the vehicle 10 is not detected, the disinfection process is not started, and the monitoring unit 170 is controlled to indicate that the vehicle 10 is not present in the disinfection chamber 100.

When the disinfection process is started, the controller 190 controls the gas injection unit 110 so that disinfection gas is injected into the disinfection chamber 100. Thereafter, the controller 190 controls the first, second, and third gas diffusion units 120, 130, and 140 to diffuse the injected disinfecting gas into the disinfection chamber 100 and the vehicle 10.

The controller 190 controls the gas injection unit 110, the first diffusion unit 120, and the second diffusion unit 130 to stop the operation when a predetermined time elapses after the disinfection process starts, and the third diffusion unit ( 140 controls to stop the operation of disinfecting gas diffusion in the disinfection chamber 100.

The predetermined time is set in consideration of the time taken for the various bacteria to be dissipated by the disinfecting gas and the time taken for the inside and outside of the vehicle 10 to be sterilized efficiently.

Each configuration of the disinfection chamber 100 may be manufactured using plate-shaped pieces of carbon and fiberglass sheets. Accordingly, the disinfection chamber 100 can be easily assembled and has advantages in terms of durability and corrosion resistance.

2 is a plan view of a disinfection chamber 100 according to an embodiment of the present invention.

Referring to FIG. 2, the disinfection chamber 100 includes a door part 180.

The door unit 180 is opened and closed when the vehicle 10 enters and exits the disinfection chamber 100. In the opening and closing method, there are various methods such as a sliding method, a sliding method, and a shutter method. The door unit 180 is not limited to the above examples, and includes all methods capable of sealing the disinfection chamber 100 with the external atmosphere.

The door part 180 is disposed at one side of the disinfection chamber 100. However, in order to facilitate the entry and exit of the vehicle 10 into the disinfection chamber 100 may be disposed in a direction facing each other.

The control operation of the controller 190 in relation to the opening and closing of the door unit 180 will be described in detail below.

The controller 190 continuously receives information on the presence or absence of gas in the disinfection chamber 100 from the monitoring unit 170 while the power is turned on. The information is used for opening and closing the door unit 180 before the vehicle 10 enters the disinfection chamber 100 or moves the vehicle 10 out of the disinfection chamber 100 after disinfection. Even if the disinfection process is not in progress or the disinfection process is terminated, when the disinfection gas is present in the disinfection chamber 100, the controller 190 controls the door unit 180 to not be opened.

Disinfection chamber 100 may include a loading means for loading the vehicle 10 to be spaced apart from the floor. The structure of the loading means may be a mesh structure, but the present invention is not limited thereto and includes all forms in which disinfection gas can be smoothly discharged to the suction unit 160 while maintaining durability for loading the vehicle 10.

3 is a view for explaining the gas diffusion of the disinfection chamber 100 according to an embodiment of the present invention.

Referring to FIG. 3, the second diffusion unit 130 circulates air toward the vehicle 10 having the rear door opened. The circulation of air rising from the bottom of the vehicle 10 to the top is caused by the third diffusion unit 140. Since the disinfection gas is diffused into every corner of the vehicle 10 inside and outside as the air circulates, the inside of the vehicle 10 may be efficiently disinfected.

4 is a plan view of a sterile comprehensive management chamber 400 in accordance with another embodiment of the present invention.

Referring to FIG. 4, the sterilization comprehensive management chamber 400 includes a disinfection chamber 100, a computational chamber 200, and a storage chamber 300. According to another embodiment of the present invention, the sterilization comprehensive management chamber 400 may be composed of the disinfection chamber 100 and the computational chamber 200, and may be composed of the disinfection chamber 100 and the storage chamber 300. It may be.

Disinfection chamber 100 is the same as described in Figures 1 to 3 above.

The computer chamber 200 is located at one side of the disinfection chamber 100 in which the monitoring unit 170 is disposed so that the user can check in and out the progress of the disinfection process through the monitoring unit 170. The computational chamber 200 includes a computational unit 210 that allows a user to control the disinfection of the disinfection chamber 100. The computer chamber 200 is connected to the control unit 190 of the disinfection chamber 100 to allow more precise control of the disinfection process through the control unit 190.

The storage chamber 300 is connected to the gas injection unit 110 to store the disinfecting gas injected into the disinfection chamber 100. The storage chamber 300 replaces a storage unit for supplying gas to the gas injection unit 110 to prevent explosion or damage due to a gas tank exposed to the outside while safely storing the gas.

5 is a diagram showing the configuration of the computer unit 210 according to another embodiment of the present invention.

Referring to FIG. 5, the computer unit 210 includes a gas management unit 211, a disinfection management unit 212, a computer control unit 213, and an operation unit 214.

The gas management unit 211 is connected to the control unit 190 of the disinfection chamber 100 to check the remaining amount of gas present in the gas tank or storage chamber 300 connected to the gas injection unit 110. If the remaining gas cannot perform the disinfection process more than a predetermined number of times, a notification is provided through the monitoring unit 170. The predetermined number of times may be set in consideration of a disinfection schedule as a number of times of 1 to 2 or more, or may be arbitrarily set by a user.

Disinfection management unit 212 is connected to the control unit 190 of the disinfection chamber 100, and manages the disinfection schedule. Specifically, the disinfection management unit 212 stores disinfection details for each vehicle 10 and manages a disinfection schedule of each vehicle 10. The disinfection management unit 212 notifies the number of the specific vehicle 10 through the monitoring unit 170 when the disinfection schedule for the specific vehicle 10 approaches in the near future, and the vehicle 10 that has passed the scheduled disinfection date. About it periodically. The near term may be set in consideration of a vehicle type and a purpose of the specific vehicle 10 as a period of days to months.

The computer control unit 213 controls the gas management unit 211 and disinfection management. In addition, the computer control unit 213 is connected to the control unit 190 of the disinfection chamber 100 to control the overall disinfection process. The computer control unit 213 checks the disinfection history stored in the disinfection management unit 212 before and after the disinfection process and controls the disinfection management unit 212 to store the modified disinfection history.

The computer control unit 213 may be connected to an external server to transmit data related to the monitored disinfection process, data stored in the gas management unit 211 and data stored in the disinfection management unit 212 to the external server. Through the computer control unit 213, it is possible to remotely manage each chamber and manage the disinfection schedule of each vehicle 10.

6 is a view showing the configuration of a storage chamber according to another embodiment of the present invention.

Referring to FIG. 6, the storage chamber 300 includes a first fuel storage unit 310, a vaporization unit 320, a sensing unit 330, and a security unit 340.

The first fuel storage unit 310 stores the fuel of the disinfection gas for supplying to the gas injection unit 110. Stabilized chlorine dioxide is mentioned as an example of the said fuel.

The vaporization unit 320 vaporizes the fuel stored in the first fuel storage unit 310 and supplies disinfection gas to the gas injection unit 110.

The vaporization unit 320 does not require a vacuum operation, wet chlorine dioxide gas containing a certain amount of moisture in chlorine dioxide gas at normal pressure, room temperature in real time without a separate pre-treatment process for maintaining the relative humidity in the disinfection chamber 100 It allows the sterilization of even the spores present in the sterilization target.

The sensing unit 330 measures the amount of fuel stored in the first fuel storage unit 310, the pressure of the first fuel storage unit 310, the concentration of the sterilizing gas, and the humidity. The values measured by the sensing unit 330 are transferred to the monitoring unit 170 of the disinfection chamber 100 so that the user can check the current fuel state, the need to check the storage chamber, and the like.

The security unit 340 ensures the confidentiality of the storage chamber. Specifically, the leakage of the fuel or disinfection gas to the outside of the storage chamber is continuously monitored for leakage. When the fuel stored in the first fuel storage unit 310 or the disinfection gas of the vaporization unit 320 is leaked into or out of the storage chamber, or when the pressure of the first fuel storage unit 310 exceeds or falls below the reference value. The security unit 340 gives an alarm to the control unit 190 of the disinfection chamber 100. The alarm contains specific information about where the problem occurred. The controller 190 receiving the alarm controls the monitoring unit 170 to display a corresponding situation after stopping the disinfection process.

Through the security unit 340, the disinfection process can be carried out more safely, and can prevent safety accidents in advance.

According to another embodiment of the present invention, the storage chamber 300 may further include a liquefaction unit 350 and a second fuel storage unit 360.

The liquefaction unit 350 is connected to the pipe 161. The liquefaction unit 321 liquefies the disinfecting gas discharged through the pipe 161 of the suction unit 160 after being used in the disinfection process.

The second fuel storage unit 360 stores the liquefied disinfecting gas. When the fuel is stored to the second fuel storage unit 360 to perform the disinfection process one or more times, the computer control unit 213 of the control unit 190 or the computational chamber 200 in the next disinfection process is performed. The fuel stored in the second fuel storage unit 360 is used instead of the fuel stored in the first fuel storage unit 310.

By liquefying and reusing the used disinfection gas, the amount of fuel consumed in the disinfection process can be minimized.

On the other hand, each of the components of the present invention are separately shown in the drawings to show that they can be functionally and logically separated, and does not necessarily mean that they are physically separate components or implemented in separate code.

In this specification, each functional unit (or module) may mean a functional and structural combination of hardware for performing the technical idea of the present invention and software for driving the hardware. For example, each functional unit may mean a logical unit of a predetermined code and a hardware resource for performing the predetermined code, and does not necessarily mean a physically connected code or a kind of hardware. It can be easily inferred by the average expert in the art. In addition, in the present specification, "~ unit" may mean a functional structural combination of software and hardware that respectively store corresponding information.

The present invention has been described above with the aim of method steps indicative of the performance of certain functions and their relationships. The boundaries and order of these functional components and method steps have been arbitrarily defined herein for convenience of description.

Alternative boundaries and orders may be defined so long as the specific functions and relationships are properly performed. Any such alternative boundaries and orders are therefore within the scope and spirit of the claimed invention.

In addition, the boundaries of these functional components have been arbitrarily defined for ease of explanation. Alternative boundaries may be defined so long as any important functions are performed properly. Likewise, flowchart blocks may also be arbitrarily defined herein to represent any important functionality.

For extended use, the flowchart block boundaries and order may have been defined and still perform some important function. Alternative definitions of both functional components and flowchart blocks and sequences are therefore within the scope and spirit of the claimed invention.

The invention may also be described, at least in part, in terms of one or more embodiments. Embodiments of the invention are used herein to illustrate the invention, aspects thereof, features thereof, concepts thereof, and / or examples thereof. Physical embodiments of apparatus, articles of manufacture, machines, and / or processes embodying the present invention may be described in terms of one or more aspects, features, concepts, examples, etc. described with reference to one or more embodiments described herein. It may include.

Moreover, in the entire drawing, embodiments may incorporate the same or similarly named functions, steps, modules, etc. that may use the same or different reference numbers, and as such, the functions, The steps, modules, etc. may be the same or similar functions, steps, modules, etc. or others.

In the present invention as described above has been described by the specific embodiments, such as specific components and limited embodiments and drawings, but this is only provided to help a more general understanding of the present invention, the present invention is not limited to the above embodiments. For those skilled in the art, various modifications and variations are possible from these descriptions.

Therefore, the spirit of the present invention should not be limited to the described embodiments, and all of the equivalents and equivalents of the claims as well as the claims to be described later belong to the scope of the present invention. .

10: vehicle
100: disinfection chamber
110: gas injection unit
120: first diffusion portion
130: second diffusion part
140: third diffusion part
150: first gas sensor
160: suction unit
161: piping
162: second gas sensor
170: monitoring unit
180: door part
190: control unit
200: computer chamber
210: computer
211: gas management
212: disinfection management
213: computer control unit
214: control panel
300: storage chamber
310: first fuel storage unit
320: vaporizer
330: sensing unit
340: security
350: liquefaction
360: second fuel storage unit
400: sterile comprehensive management chamber

Claims (10)

Disinfection chamber to disinfect both inside and outside of the target object,
At least one gas injection unit installed on at least one side wall and a ceiling of the disinfection chamber to inject gas into the disinfection chamber;
A first diffusion part to evenly diffuse the gas into the disinfection chamber;
A second diffuser configured to spread the gas evenly into the target object;
A first gas sensor which senses a residual amount of gas in the air in the disinfection chamber;
At least one suction unit for discharging the gas after disinfection of the target object;
A monitoring unit showing a disinfection situation of the target object;
A door unit which opens and closes when the target object enters and exits; And
And a controller configured to detect an entry and exit of the target object and to control a disinfection process for the target object. The method of claim 1, wherein the gas
Disinfection chamber, which is a wet chlorine dioxide gas generated from stabilized chlorine dioxide. The method of claim 1, wherein the disinfection chamber
Further comprising a loading means for loading the target object to be spaced apart from the bottom surface of the disinfection chamber,
The bottom surface of the bottom of the loading means
Disinfection chamber, characterized in that formed to be inclined at a predetermined angle with respect to the suction unit. The method of claim 1, wherein the suction unit
A pipe for sucking and discharging the gas in the disinfection chamber; And
Disinfecting chamber comprising a second gas sensor for sensing the remaining amount of gas around the suction unit. The method of claim 1, wherein the disinfection chamber
Located in the suction unit located on the bottom surface of the disinfection chamber, the first rotation to smoothly collect and discharge the gas in the disinfection chamber in the pipe and the second rotation to diffuse the gas on the bottom of the disinfection chamber Disinfecting chamber comprising a third diffusion. Disinfection chamber of claim 1; And
Further comprising a computer chamber for controlling and monitoring the disinfection operation of the control unit observed through the monitoring unit, the computer chamber includes a computer unit,
The computerized sterilization comprehensive management chamber, characterized in that the computer comprises a gas management unit, disinfection management unit, computerized control unit and operation unit. Disinfection chamber of claim 1; And
A storage chamber connected to the gas injection unit and storing the gas injected therein;
The storage chamber is
A first fuel storage unit storing fuel;
A vaporization unit for vaporizing the fuel with the gas;
Sensing unit for measuring the concentration, humidity or pressure of the fuel and the gas; And
To include a security unit for ensuring the confidentiality of the storage chamber,
Sterile Comprehensive Care Chamber. The storage chamber of claim 7
Liquefaction means used for disinfection of the target object and for liquefying the gas discharged through the suction unit; And
And a second fuel reservoir for storing the liquefied gas. The disinfection chamber of claim 1
Disinfection chamber, which is implemented by combining a plurality of plate-shaped pieces of carbon and fiberglass sheet material. Sterilization general management chamber of claim 8
By controlling the disinfection operation of the control unit observed through the monitoring unit, by monitoring information such as disinfection history and disinfection schedule management of the target object, check the internal and external disinfection history before and after the entry and exit of the target object and the management state of the disinfection chamber A storage chamber, and further comprising a computing chamber for providing to an external server, sterile comprehensive management chamber.

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