KR101597138B1 - Sterilization truck - Google Patents

Abstract

A sterilizing truck according to an embodiment of the present invention includes a first storage unit on which a chlorine dioxide producing apparatus for generating chlorine dioxide is disposed on the body frame; An opening / closing unit provided in the first storage unit for opening / closing the first storage unit so that the control panel of the chlorine dioxide manufacturing apparatus is exposed to the outside of the first storage unit; A preliminary chamber disposed on the body frame for temporarily storing the chlorine dioxide generated from the chlorine dioxide producing apparatus; And a second storage portion provided on the vehicle body frame, the second storage portion introducing the chlorine dioxide from the spare chamber to provide a sterilization space for the object.

Description

STERILIZATION TRUCK

The present invention relates to a sterilization truck.

In the course of delivering to the consumers through storage and distribution, agricultural and fishery products are decomposed by microorganisms, physiological actions or temperature conditions, and the value as a commodity is damaged. The loss ratio reaches 20% to 30% of the total agricultural output, which is several trillion won in terms of the economic loss scale.

In order to reduce losses during storage and distribution of agricultural and livestock products, the cold chain method is mainly used. By changing the composition of the air in the closed storage space, oxygen is reduced, and carbon dioxide is increased by CA (Controlled Atmosphere), MA ) Storage method is also utilized. There is also an emerging method of controlling ethylene, which acts as an aging hormone in plants. In the case of livestock products, techniques for maintaining freshness by applying various methods such as temperature control and vacuum packaging exist.

However, it is difficult to control accelerated degradation of agricultural products by microorganisms without lowering the density of microorganisms attached to the surface of agricultural products. In order to remove microorganisms, agricultural products are washed with sterilization solution to remove microorganisms according to the crops. However, most of the fruit crops and herbs, including strawberries, grapes and peaches, are not in contact with aqueous solutions and there is no alternative for livestock products. to be.

Experimental results have been reported that even if contact of the solution is allowed, the bactericidal effect of microorganisms in the cracked or wounded interstices of agricultural products is much higher than that of washing with solution.

Compared with solution washing sterilization, applying gas fumigation can result in the contact of gas and crops through very fine air holes after product packaging, which can lead to a sterilization effect.

There are many kinds of substances used in such a gas fumigation method. In the case of sulfur fumigation, the possibility of harm to the human body is questioned. In the case of MB (methyl bromide) fumigation, the use of ozone-depleting substances is prohibited while chlorine dioxide is a registered food additive in the KFDA. It is eco-friendly as an organic handling material registered for cleaning and disinfection purposes.

Chlorine dioxide has a wide range of effects as an antimicrobial agent from fungi to bacteria and viruses. Microbiological sterilization mechanism penetrates the protective membrane of microorganisms and kills microorganisms by interfering with the enzymatic action of the cells by oxidative power.

These sterilizing powers are effective in a wide PH range, and are more than 2.5 times more sterilizing power than chlorine and do not generate carcinogens such as THM (trihalomethane), and thus they are being regarded as environmentally friendly green fungicides in Europe and USA. The UN World Health Organization (WHO) and Food and Agriculture Organization (FAO) recommend chlorine dioxide as a disinfectant.

In addition to research on various devices capable of generating chlorine dioxide, studies on the convenience of the sterilization process are underway.

Korean Patent Application No. 10-2000-0039341

The sterilizing truck according to the embodiment of the present invention is intended to improve the mobility and facilitate the sterilization work on the object.

The task of the present application is not limited to the above-mentioned problems, and another task which is not mentioned can be clearly understood by a person skilled in the art from the following description.

According to an aspect of the present invention, there is provided a sterilizing truck including a body frame, wherein the sterilizing truck comprises: a first storage unit on which a chlorine dioxide producing apparatus is disposed; An opening / closing unit provided in the first storage unit for opening / closing the first storage unit so that the control panel of the chlorine dioxide manufacturing apparatus is exposed to the outside of the first storage unit; A preliminary chamber disposed on the body frame for temporarily storing the chlorine dioxide generated from the chlorine dioxide producing apparatus; And a second storage portion provided on the vehicle body frame, the second storage portion introducing the chlorine dioxide from the spare chamber to provide a sterilization space for the object.

Wherein the sterilizing truck includes a first damper and a second damper, wherein the first damper forms a first flow path for discharging the chlorine dioxide inside the second storage section to the outside of the second storage section, The damper may form a second flow path for introducing outside air into the second storage portion while the first damper forms the first flow path.

The sterilization truck according to one aspect of the present invention may further include a flexible tube through which the chlorine dioxide discharged through the first damper is transferred as part of the first flow path.

The chlorine dioxide producing apparatus includes a chlorine dioxide generating unit for generating the chlorine dioxide through electrolysis, and a cleaning unit for spraying the cleaning material toward the cathode of the chlorine dioxide generating unit.

After the anode cleaning, the cleaning material contains NaOH.

The chlorine dioxide producing device may further comprise a raw material storage part for storing the raw material for chlorine dioxide production in the chlorine dioxide generating device and a cleaning material storage part for storing the cleaning material recovered from the chlorine dioxide generating part after the cleaning of the negative electrode .

Wherein the chlorine dioxide producing device further comprises a gas pump for causing the chlorine dioxide of the preliminary chamber to flow to the first storage portion and an air supply portion for supplying air, wherein a first portion of the air flows out from the preliminary chamber The chlorine dioxide may be diluted and a second portion of the air may be introduced into the pre-chamber.

The disinfection truck may further include a jetting unit installed at an upper portion of the second storage unit to jet the chlorine dioxide into the second storage unit and a chlorine dioxide supply unit installed at a lower portion of the second storage unit, As shown in Fig.

A roller may be installed on the bottom of the second storage unit.

The chlorine dioxide producing device may be supplied with power through a power outlet provided in the sterilization truck during engine operation of the sterilization truck.

The disinfection truck according to the embodiment of the present invention can improve the mobility and facilitate the disinfection by installing a manufacturing apparatus for producing chlorine dioxide using electrolysis in a truck.

The effects of the present application are not limited to the effects mentioned above, and other effects not mentioned can be clearly understood by those skilled in the art from the following description.

Figure 1 shows a sterilization truck according to an embodiment of the present invention.
2 shows an apparatus for generating chlorine dioxide in a sterilization truck according to an embodiment of the present invention.
FIG. 3 shows the chlorine dioxide generating part and the cleaning part of FIG. 2 in detail.
Figure 4 shows the chlorine dioxide generator of Figure 3 in detail.
5 shows the inside of the second storage portion.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. It is to be understood, however, that the appended drawings illustrate the present invention in order to more easily explain the present invention, and the scope of the present invention is not limited thereto. You will know.

Also, the terms used in the present application are used only to describe certain embodiments and are not intended to limit the present invention. The singular expressions include plural expressions unless the context clearly dictates otherwise.

In the present application, the terms "comprises" or "having" and the like are used to specify that there is a feature, a number, a step, an operation, an element, a component or a combination thereof described in the specification, But do not preclude the presence or addition of one or more other features, integers, steps, operations, elements, components, or combinations thereof.

Figure 1 shows a sterilization truck according to an embodiment of the present invention. 1, a sterilizing truck according to an embodiment of the present invention includes a body frame 110, a first storage unit 130, an opening and closing unit 150, a spare chamber 170, and a second storage unit 190 ).

The first storage part 130 is disposed on the vehicle body frame 110 to house the chlorine dioxide producing device 200 for generating chlorine dioxide. The chlorine dioxide manufacturing apparatus 200 can electrolyze the raw material to generate chlorine dioxide, and a detailed description of the chlorine dioxide manufacturing apparatus 200 will be described later with reference to the drawings.

The opening portion is provided in the first storage portion 130 to open and close the first storage portion 130 so that the control panel 210 of the chlorine dioxide manufacturing apparatus 200 is exposed to the outside of the first storage portion 130. 1, the opening / closing part 150 may be hinged to the side of the first storage part 130 and may be rotated, and a shock absorber 151 may be installed between the first storage part 130 and the opening / Lt; RTI ID = 0.0 > 150 < / RTI > The shock absorber 151 can cause the opening and closing part 150 to be opened or closed gradually.

The structure of the opening and closing part 150 is not limited to the opening and closing structure shown in FIG. 1, and the opening and closing part 150 having various structures can be applied to the sterilizing truck according to the embodiment of the present invention.

The control panel 210 may include a switch for setting various information necessary for operating the chlorine dioxide manufacturing apparatus 200, a knob or a button, The concentration of chlorine dioxide in the unit 190, and the like.

The reserve chamber 170 is installed on the vehicle body frame 110 to temporarily store chlorine dioxide generated from the chlorine dioxide producing apparatus 200. The reserve chamber 170 will be described later together with the chlorine dioxide producing apparatus 200 with reference to the drawings.

The second storage unit 190 is installed on the vehicle body frame 110 and chlorine dioxide flows from the spare chamber 170 to provide a sterilization space for the object.

In this case, the first storage part 130 and the second storage part 190 may be provided on two separate containers adjacent to each other on the vehicle body frame 110. One container may be divided by the partition wall, The first storage unit 130 and the second storage unit 190 may be formed. The structures of the first storage unit 130 and the second storage unit 190 are merely one example, but the present invention is not limited thereto.

The vehicle body frame 110 may include a case where one container including the first storage unit 130 and the second storage unit 190 is provided on the vehicle body frame 110, And a case where the first storage part 130 and the second storage part 190 are provided on the plate and are formed of separate containers. The structure in which the first storage part 130 and the second storage part 190 are provided on the body frame 110 is not limited to this.

Since the sterilizing truck according to the embodiment of the present invention can move, it is possible to access a consumer or a consumer who desires to sterilize an object through chlorine dioxide. Accordingly, the consumer or the customer can sterilize the object with chlorine dioxide even without a warehouse equipped with the chlorine dioxide manufacturing apparatus 200. [

Next, an apparatus 200 for manufacturing chlorine dioxide in a sterilization truck according to an embodiment of the present invention will be described with reference to the drawings.

2 shows an apparatus 200 for producing chlorine dioxide in a sterilization truck according to an embodiment of the present invention. 2, the chlorine dioxide manufacturing apparatus 200 may include a chlorine dioxide generating unit 230 and a cleaning unit 250. [ 3 shows the chlorine dioxide generating unit 230 and the cleaning unit 250 of FIG. 2 in detail.

As shown in FIGS. 2 and 3, the chlorine dioxide generating unit 230 generates chlorine dioxide through electrolysis. The cleaning unit 250 also injects the cleaning material toward the cathode 233 of the chlorine dioxide generating unit 230.

The body 231 of the chlorine dioxide generating unit 230 includes a first space S1 into which a raw material for producing chlorine dioxide is injected and a second space S2 partitioned from the first space S1. Respectively. The chlorine dioxide manufacturing apparatus 200 may include a raw material storage unit 270 for storing a raw material for chlorine dioxide production. At this time, it can be injected into the first space S1 of the body 231 through the pump 271 for the raw material and the valve 273 for the raw material. The pump 271 for the raw material and the valve 273 for the raw material may be provided in the flow path portion 275 for the raw material through which the raw material for chlorine dioxide is transferred.

The anode 232 of the chlorine dioxide generating unit 230 is in contact with the raw material for producing chlorine dioxide in the first space S1 and the cathode 233 is exposed in the second space S2.

The cleaning unit 250 injects the cleaning material toward the by-product adhered to the surface of the cathode 233 in the process of electrolyzing the raw material for producing chlorine dioxide as voltage is applied to the anode 232 and the cathode 233.

FIG. 4 shows the chlorine dioxide generator 230 of FIG. 3 in detail.

An electrolyte injection port 234 for injecting raw material for producing chlorine dioxide containing sodium chlorite (NaClO ₂ ) and a first discharge port 235 for discharging chlorine dioxide (ClO ₂ ) gas are provided at one side of the body 231 . In addition, a second outlet 236 may be formed on the other side of the body 231. And the by-product generated in the process of generating chlorine dioxide gas through the second outlet 236 may be discharged. The by-products will be described later in detail.

The conductive film 237 may be provided inside the body 231. The first space S1 and the second space S2 of the body 231 may be partitioned by the electroconductive film 237. [ The conductive film 237 may be provided as a proton conductive material in hydrocarbon and fluorocarbon type, wherein the fluorocarbon-type resin may have excellent oxidation resistance to halogens, strong acids, and bases.

The anode 232 can be connected to a power source (not shown) and can contact one side of the conductive film 237. The cathode 233 can also be connected to the power source and can contact the other side of the conductive film 237 opposite to the one side. The anode 232 causes an oxidation reaction with sodium chlorite, which is an electrolyte, and the cathode 233 causes a reduction reaction. The connection between the power source and the anode 232 and the cathode 233 is common to those of ordinary skill in the art, and a detailed description thereof will be omitted.

The anode 232 and the cathode 233 may further include an electrochemical catalyst to maximize the efficiency of the redox reaction. The electrochemical catalyst may be a mixture, oxide, alloy or a combination thereof comprising at least one of platinum, palladium, rhodium, iridium, ruthenium, osmium, carbon, gold, tantalum, tin, indium, nickel, tungsten, .

Sodium chlorite (NaClO2) injected through the electrolyte inlet 234 may be composed of sodium chlorite (NaClO2) salt and water (H2O). The sodium chlorite (NaClO2) salt is converted into chlorine dioxide (ClO2) gas, sodium ion (Na +) and electron (e-) by the oxidation reaction of the anode 232, Oxygen (O 2) gas, hydrogen ion (H +) and electron (e-).

The chlorine dioxide (ClO2) gas and the oxygen (O2) gas formed by the oxidation reaction of the anode 232 are discharged to the outside through the first outlet 235 and the sodium ions (Na +) and the hydrogen ions Through the electroconductive film 237 and to the cathode 233.

At this time, water (H2O) can move together with sodium ions (Na +) and hydrogen ions (H +). The hydrogen ion (H +) which has migrated to the cathode 233 becomes hydrogen by a reduction reaction with the cathode 233 and the sodium ion (Na +) is converted to sodium hydroxide (NaOH) by binding with OH ^- of water . That is, by-products are produced in the electrolysis process, and the by-products may include hydrogen and sodium hydroxide.

Sodium hydroxide may act as a by-product, which is generated in the process of generating chlorine dioxide gas through electrolysis, as a resistance that interferes with the flow of current when attached to the cathode 233. If the amount of sodium hydroxide adhered to the cathode 233 increases, the amount of electric current required to generate the chlorine dioxide gas increases, and the efficiency of electrolysis may decrease.

The cleaning unit 250 may spray the cleaning material toward the cathode 233 in order to remove the sodium hydroxide attached to the cathode 233. Since the electrochemical catalyst of the anode 232 and the cathode 233 promotes the oxidation reaction of the anode 232 and the reduction reaction of the cathode 233, the electrochemical catalyst of the conductive film 237 and the anode 232 The electroconductive film 237 can be in contact with the anode 232 and the cathode 233 without a gap and a gap between the electroconductive film 237 and the cathode 233. [

When the both sides of the electroconductive film 237 are in contact with the anode 232 and the cathode 233 as in the embodiment of the present invention, The efficiency of production of chlorine dioxide gas through decomposition can be increased.

As described above, the chlorine dioxide generating unit 230 generates chlorine dioxide through electrolysis, so that it is safer than the method of chemically producing chlorine dioxide through chlorine.

That is, since chlorine may harm the human body, a device for producing chlorine dioxide through chlorine adds a separate device for treating chlorine, which increases the manufacturing cost and the volume of the device.

In addition, even if a safety device for chlorine is added, chlorine may be leaked due to vibration or impact during truck operation, so that chlorine dioxide manufacturing equipment may be difficult to mount on a truck

On the other hand, the apparatus for producing chlorine dioxide of the sterilization truck according to the embodiment of the present invention not only uses electrolysis without using chlorine but also has low electrical resistance, thereby improving the stability of the chlorine dioxide producing apparatus and reducing the volume, .

Meanwhile, the cleaning material injected by the cleaning unit 250 may include H ₂ O or a material having an acidic group. Since sodium hydroxide is well soluble in water, water can be used as a washing agent. In addition, since the acid group smoothly bonds with OH- of sodium hydroxide, a substance having an acidic group can also be used as a cleaning material.

For example, the material having an acidic group may be a citric acid solution or a nitric acid solution. Citric acid solution or acetic acid solution is diluted with citric acid or acetic acid in water. It is cheap and easy to obtain as well as less harmful to human body.

3 and 4, the cleaning unit 250 may include a nozzle unit 251, a flow path for the cleaning material 252, and a pump 253 for the cleaning material. The nozzle unit 251 may be provided in the second space S2 of the body 231 so that the cleaning material may be sprayed toward the cathode 233. As shown in FIG. 4, a nozzle channel portion 254 communicating with the cleaning material channel portion 252 may be formed in the nozzle portion 251.

The flow path portion 252 for the cleaning material communicates with the nozzle portion 251 to transfer the cleaning material to the nozzle portion 251. The pump 253 for the cleaning material may be installed in the flow path for the cleaning material to transfer the cleaning material to the cleaning material flow path 142. At this time, the cleaning material may be stored in the storage tank 260 of FIG. 3, and a valve 261 for the cleaning material for controlling the flow of the cleaning material may be provided in the cleaning material flow path 142.

2 and 3, the apparatus 200 for producing chlorine dioxide may further include a discharge unit 280. [ The discharge unit 280 includes an exhaust flow path 281 communicating with the second space S2, a discharge pump 282 provided in the discharge flow path for transferring the cleaning material in the second space S2, (233), and a cleaning material storage unit (283) for storing the cleaning material recovered from the chlorine dioxide generating unit (230) after the cleaning.

At this time, a discharge valve for controlling the flow of the cleaning material may be provided in the discharge flow path. Since the sodium hydroxide adhered to the cathode 233 is washed by the cleaning material, NaOH may be contained in the cleaning material after the cathode 233 is cleaned. The raw material pump 271, the cleaning material pump 253, the discharge pump 282, the raw material material valve 273, the cleaning material valve 261, Controller 290, and the controller 290 can output a valve control signal and a pump control signal.

The raw material material valve 273, the cleaning material valve 261 and the discharge valve are connected to the raw material for chlorine dioxide production, the cleaning material flowing into the second space S2, It is possible to control the amount of flow of the cleaning material discharged from the cleaning material passage 252 and the discharge passage portion 281 and to open and close the flow passage portion 275, the cleaning material passage portion 252 and the discharge passage portion 281.

The operation of the raw material pump 271, the cleaning material pump 253 and the discharge pump 282, the operation stop, and the amount of the raw material for chlorine dioxide production and the amount of the cleaning material pumped, etc., Lt; / RTI >

Meanwhile, as shown in FIG. 4, the cleaning material may also flow into the first space S1 of the body 231. FIG. The cleaning material flowing into the first space S1 is for cleaning the inner surface of the body 231 forming the first space S1 after the generation of chlorine dioxide is stopped or for preventing the conductive film 237 from drying.

3, the cleaning part 250 may include a channel part 255 for the auxiliary cleaning material and a valve 256 for the auxiliary cleaning material, and the valve 256 for the auxiliary cleaning material may include auxiliary And may be provided in the flow path portion 255 for the cleaning material. The valve 256 for the auxiliary cleaning material may also operate in response to the valve control signal of the controller 290.

4, the cleaning material may be introduced into the first space S1 through the cleaning material inlet 238 of the body 231 and the waste material of the first space S1 may be introduced into the body 231, The waste material can be discharged through the waste material outlet 239 of the first space S1.

The waste material in the first space S1 can be discharged to the outside of the body 231. [ For this purpose, the discharge portion 280 may include a valve 284 for a waste material, a pump 285 for a waste material, and a flow passage portion 286 for a waste material. The waste material valve 284 and the waste material pump 285 may be installed in the waste material flow path portion 286 and may operate according to the valve control signal and the pump control signal of the controller 290. [ Such a waste material may be transferred to the cleaning material storage portion 283 through the channel portion 255 for the auxiliary cleaning material.

The waste material in the first space S1 may be a raw material remaining in the first space S1 after completion of the generation of the chlorine dioxide gas or a cleaning material remaining in the first space S1 after the cleaning, The cleaning material remaining in the first space S1 for preventing drying of the first space S1, or a mixture thereof.

Meanwhile, as shown in FIG. 2, the concentration sensor 300 may be installed in the second storage unit 190. The controller 290 receives the sensing signal of the concentration sensor 300 and outputs at least one of the valve control signal or the pump control signal related to the concentration control to control the concentration of the chlorine dioxide gas in the second storage unit 190 .

2 and 3, the chlorine dioxide manufacturing apparatus 200 may further include a gas pump 400 and an air supply unit 500. [ The gas pump 400 allows the chlorine dioxide of the preliminary chamber 170 to flow into the first storage unit 130, and the air supply unit 500 supplies air. The air supply unit 500 may be a ring blower, but is not limited thereto.

The gas pump 400 may be provided in the gas passage unit 410 communicating with the spare chamber 170 and the gas valve unit 420 may be provided in the gas passage unit 410. The gas pump 400 and the gas valve 420 may operate according to the pump control signal and the valve control signal of the controller 290, respectively. 2, the first portion of the air dilutes the chlorine dioxide leaving the preliminary chamber 170 and the second portion of the air may enter the preliminary chamber 170. [ The diluted chlorine dioxide may be introduced into the second storage unit 190.

If the second portion of the air does not flow into the preliminary chamber 170, the chlorine dioxide flows out from the preliminary chamber 170 according to the operation of the gas pump 400 and negative pressure is applied to the preliminary chamber 170 . When negative pressure is applied to the preliminary chamber 170, the outflow of chlorine dioxide from the preliminary chamber 170 may become difficult.

Therefore, when the second portion of the air is introduced into the preliminary chamber 170, negative pressure is prevented from being applied to the preliminary chamber 170, so that the chlorine dioxide can easily flow out from the preliminary chamber 170.

On the other hand, the reserve chamber 170 can temporarily store the high concentration of chlorine dioxide generated from the chlorine dioxide generator 230. The chlorine dioxide generating unit 230 may not generate a constant amount of chlorine dioxide over time. Accordingly, when the chlorine dioxide flows directly from the chlorine generating unit 230 to the second storing unit 190, it becomes difficult to control the concentration of chlorine dioxide in the second storing unit 190.

The chlorine dioxide concentration of the second storage portion 190 can be relatively easily controlled since the amount of chlorine dioxide flowing out of the spare chamber 170 can be constant over time when the chlorine dioxide is temporarily stored in the spare chamber 170 have.

On the other hand, as shown in FIG. 2, the sterilizing truck may include a jetting section 600 and a suction section 650. The sprayer 600 is installed on the upper portion of the second storage unit 190 to spray chlorine dioxide into the second storage unit 190 and the suction unit 650 is installed below the second storage unit 190 So that the chlorine dioxide can be discharged to the outside of the storage unit 2. Since the chlorine dioxide is heavier than air, the jetting unit 600 may be positioned above the suction unit 650.

2, the sterilization truck may include a first damper 700 and a second damper 750. The first damper 700 may form a first flow path for discharging the chlorine dioxide in the second storage portion 190 to the outside of the second storage portion 190. The second damper 750 may form a second flow path for allowing the outside air to flow into the second storage part 190 while the first damper 700 forms the first flow path.

After the sterilization of the object stored in the second storage unit 190 is completed, chlorine dioxide remaining in the second storage unit 190 should be released into the atmosphere. The air outside the second storage unit 190 flows into the second storage unit 190 through the second damper 750 while the chlorine dioxide is released from the second storage unit 190 through the first damper 700, Of chlorine dioxide can be released easily. At this time, an exhaust fan (not shown) may be provided adjacent to the first damper 700.

1 and 2, the sterilizing truck according to the embodiment of the present invention includes a flexible tube FT through which chlorine dioxide discharged through the first damper 700 is transferred as a part of the first flow path, As shown in FIG.

The disinfection truck is excellent in mobility, so sterilization of the object can be performed in a room such as a warehouse. That is, after the sterilization truck has moved to the inside of the warehouse, objects such as agricultural products and foods are disposed in the second storage unit 190 so that the object can be sterilized.

When the sterilization process is completed, the chlorine dioxide remaining in the second storage unit 190 is discharged to the outside through the first damper 700. Since the sterilization truck is inside the warehouse, the chlorine dioxide discharged through the first damper 700 It can be discharged into the warehouse.

Since the flexible tube FT has a predetermined length, chlorine dioxide in the second storage unit 190 can be discharged to the outside of the warehouse because the flexible tube FT can extend to a window or an entrance of the warehouse.

5 shows the interior of the second storage unit 190. Fig. As shown in FIG. 5, a roller 800 may be installed on the bottom of the second storage unit 190. The roller 800 is used to easily draw or draw a box or the like containing an object into the second storage unit 190.

2, the chlorine dioxide manufacturing apparatus 200 may include a power source unit 900. [ The power supply unit 900 can supply power to the chlorine dioxide generating unit 230 such that the power is supplied to the anode 232 and the cathode 233 of the chlorine dioxide generating unit 230, have.

The power source unit 900 can also convert at least one of the voltage magnitude, current magnitude, and frequency suitable for the chlorine dioxide manufacturing apparatus 200 by supplying electricity from a power outlet 910 installed in the sterilizing truck.

The electricity of the power outlet 910 is supplied through the generator 930 provided in the sterilizing truck, and the generator 930 can also generate electricity as the sterilizing truck operates the engine.

That is, the chlorine dioxide manufacturing apparatus 200 can be supplied with electric power through the power outlet 910 equipped with the sterilizing truck during engine operation of the sterilizing truck. At this time, the power supply unit 900 may include a power conversion unit.

Accordingly, the sterilizing truck according to the embodiment of the present invention can sterilize the object even without a separate electricity supply device. There is also no need for the disinfection truck to be placed adjacent to the outlet provided in the building or the like to obtain electricity. Accordingly, the mobility of the sterilizing truck can be improved.

The various valves described above may be solenoid valves, but are not limited thereto.

It will be apparent to those skilled in the art that the present invention may be embodied in other specific forms without departing from the spirit or scope of the invention as defined in the appended claims. . Therefore, the above-described embodiments are to be considered as illustrative rather than restrictive, and the present invention is not limited to the above description, but may be modified within the scope of the appended claims and equivalents thereof.

The first storage unit 130 of the vehicle body frame 110,
The opening and closing part 150, the shock absorber 151,
The reserve chamber 170, the second storage unit 190,
The flexible tube (FT) chlorine dioxide manufacturing apparatus 200
Control panel 210 The chlorine dioxide generator 230,
The body 231, the anode 232,
The cathode 233, the electrolyte inlet 234,
The first outlet 235, the second outlet 236,
Conductive film (237) Cleaning material inlet (238)
The waste material discharge port 239, the cleaning unit 250,
The nozzle portion 251, the flow path portion 252 for the cleaning material,
The pump for the cleaning material 253, the flow path for the nozzle 254,
Valves for cleaning auxiliary substances (256)
Storage tanks (260) Valves for cleaning materials (261)
Raw material storage (270) Pumps for raw material (271)
Valves for raw materials (273) Channel bars for raw materials (275)
The discharge passage 280 discharging passage portion 281,
The discharge pump 282, the cleaning material storage unit 283,
Valves for waste products (284) Pumps for waste products (285)
Flowmeters for dischargers (286) Controllers (290)
The concentration sensor 300, the gas pump 400,
The gas flow path 410, the gas valve 420,
The air supply unit 500, the jetting unit 600,
The suction unit 650 includes a first damper 700,
The second damper 750, the roller 800,
The power unit 900 includes a power outlet 910,
Generators (930)

Claims (10)

In a sterilizing truck comprising a body frame,
A first storage unit in which a chlorine dioxide producing apparatus is disposed on the body frame to generate chlorine dioxide;
An opening / closing unit provided in the first storage unit for opening / closing the first storage unit so that the control panel of the chlorine dioxide manufacturing apparatus is exposed to the outside of the first storage unit;
A preliminary chamber disposed on the body frame for temporarily storing the chlorine dioxide generated from the chlorine dioxide producing apparatus; And
And a second storage unit installed on the vehicle body frame for introducing the chlorine dioxide from the preliminary chamber to provide a sterilizing space for the object,
Wherein the sterilizing truck includes a first damper and a second damper,
Wherein the first damper forms a first flow path for discharging the chlorine dioxide inside the second storage section to the outside of the second storage section,
Wherein the second damper forms a second flow path for introducing outside air into the second storage section while the first damper forms the first flow path.
delete The method according to claim 1,
Further comprising a flexible tube through which the chlorine dioxide discharged through the first damper is conveyed as part of the first flow path.
The method according to claim 1,
Wherein the chlorine dioxide producing device comprises:
A chlorine dioxide generating unit for generating the chlorine dioxide through electrolysis, and
And a washing section for spraying the washing substance toward the cathode of the chlorine dioxide generating section.
5. The method of claim 4,
And the NaOH is contained in the cleaning material after the anode cleaning.
5. The method of claim 4,
Wherein the chlorine dioxide producing device comprises:
A raw material storage for storing the raw material for chlorine dioxide production in the chlorine dioxide generator,
And a cleaning material storage portion for storing the cleaning material recovered from the chlorine dioxide generating portion after the cathode cleaning.
The method according to claim 1,
The chlorine dioxide producing apparatus
A gas pump for causing the chlorine dioxide of the preliminary chamber to flow to the first storage portion, and an air supply portion for supplying air,
Wherein the first portion of the air dilutes the chlorine dioxide flowing out of the preliminary chamber,
Wherein the second portion of the air is introduced into the preliminary chamber.
The method according to claim 1,
The sterilization truck,
A spraying unit installed on the second storage unit for spraying the chlorine dioxide into the second storage unit;
And a suction unit installed at a lower portion of the second storage unit for discharging the chlorine dioxide to the outside of the aseptic storage unit.
The method according to claim 1,
And a roller is installed on the bottom of the second storage portion.
10. A method according to any one of claims 1 to 9,
Wherein the chlorine dioxide producing device is supplied with power through a power outlet provided in the sterilization truck during engine operation of the sterilization truck.

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