JP2014005179A5 - - Google Patents

Description

The method of sterilizing and sterilizing microorganisms using chlorine dioxide gas is less toxic and safer than other methods using chlorine, sodium hypochlorite, hydrogen peroxide, etc. There is an advantage that there is no discomfort because there is no strong smell like chlorine. In addition, chlorine dioxide gas has a high sterilizing power per unit weight, has an excellent sterilizing and sterilizing effect against spores, fungi, bacteria, viruses and the like, and has an advantage of not producing carcinogenic substances. When chlorine dioxide gas comes into contact with proteins of microbial cells, O ₂ is separated and oxidized, and at the same time, it reacts with sodium contained in microorganisms to become NaCl. Chlorine dioxide gas reacts quickly when it comes into contact with proteins.
ClO ₂ + microbial Na → oxidized microbial protein + NaCl

On the other hand, chlorine dioxide gas is unstable and difficult to store at a constant concentration over a long period of time. Therefore, conventionally, a method has been adopted in which sodium chlorite and an acidic liquid are supplied into a container and chlorine dioxide gas is generated by a chemical reaction between the two. For example, when sodium chlorite solution and malic acid solution are mixed, chlorine dioxide gas is generated according to the following reaction formula.
_{4NaClO 2 + 2 HOOC-CH (} OH) -CH 2 -COOH + O 2 → 2 NaOOC-CH (OH) -CH 2 -COO Na + 4ClO 2 + 2H 2 O

However, when the bubble of chlorine dioxide gas (ClO ₂ ) generated in the liquid in the container rises up to the liquid level, the fine mist scatters and the mist thus scattered floats in the room and becomes contaminated. is there. In addition, when the fine mist that scatters floats and dries, it becomes solid particles of the reaction product NaOOC—CH (OH) —CH ₂ —COO Na . NaOOC-CH-CH (OH) -CH2-COO Na is a soluble residue that remains after the reaction of sodium chlorite with an acidic liquid to release chlorine dioxide gas, and is not a gaseous substance. NaOOC—CH—CH (OH) —CH 2 —COO Na remains dissolved in the solution after generation of chlorine dioxide gas, but remains as white powdered salt when the water has completely evaporated. When the mist and solid particles floating in the room adhere to products and devices arranged in a clean room or the like, quality causes.

According to the present invention, a chlorine dioxide gas generator that supplies pellet-like sodium chlorite and an acidic liquid to a container and generates chlorine dioxide gas by a chemical reaction between the two, and in a space surrounded by a shield with the container, the container is partitioned into a plurality of container portion, and each container portion, characterized in that in communication with each other at the opening of a size pellets JoA sodium chlorate can not pass A chlorine dioxide gas generator is provided.

In this chlorine dioxide gas generator, a fan for blowing the chlorine dioxide gas generated in the gas generation chamber and a filter for filtering may be provided above the space. Further, in the interior of the space, above the container, fan adding swirl component to the flow of chlorine dioxide gas rises inside the space by the operation of the fan may be provided. Moreover, the partition member which divides the inside of the said container into a some container part may be provided, and the said partition member may be detachable from the said container. Moreover, you may provide the heater which heats the acidic liquid supplied to the said container.

In addition, a fan is provided above the space surrounded by the shield, and the operation of the fan causes indoor air to be sucked into the space from below the shield, and toward the fan in the space. A flowing updraft is formed. For this reason, the chlorine dioxide gas generated by the reaction between the pelletized sodium chlorite and the acidic liquid in the container disposed in the space passes through the fan and the filter and is then supplied into the room. In this case, in the space, fine mist may be scattered when the bubbles of chlorine dioxide gas generated in the liquid in the container rise to the liquid level and burst, but this mist and solid particles generated by the mist are Captured with a filter , indoor contamination is avoided.

In addition, inside the space, a swirling component is added to the updraft by air blown from another fan, so that chlorine dioxide gas can be put on the swirling updraft and lifted up to the fan and the filter to be supplied indoors. It becomes possible. The molecular weight of chlorine dioxide gas is 67.5, which is 2.3 times the weight of air molecular weight 28.8. By placing such heavy chlorine dioxide gas on a swirling updraft and lifting it to the fan and the filter, the chlorine dioxide gas can be evenly diffused into the room that is the decontamination target room.

The chlorine dioxide gas generator 1 is installed in a room such as a clean room. And the pellet-shaped sodium chlorite a is thrown into the container 13 of the chlorine dioxide gas generator 1. In this case, the pelletized sodium chlorite a is introduced into each of the plurality of container portions 20 partitioned by the partition member 21 inside the container 13. The amount of pelletized sodium chlorite a charged into one container part 20 may be an amount that is 0.5 g / cm 2 or less with respect to the bottom area of the container part 20 charged. In addition, the pinch nozzle 27 is opened, and the acidic liquid b in the tank 26 is introduced into the container 13 through the nozzle 25. At this time, as one container part 20, in this embodiment, the acidic liquid b is introduced into the central container part 20. Since each container part 20 in the container 13 communicates with each other through an opening 22 provided in the partition member 21, the acidic liquid b introduced into one container part 20 of the container 13 in this way is supplied to all each container. The portion 20 is supplied evenly. Note that the openings 22 are not necessarily provided in all the partition members, and may be communicated so that the acidic liquid b is distributed to all the container parts 20 when the acidic liquid b is introduced into one container part 20. However, it is possible to spread the acidic liquid b over the whole more quickly by providing the openings 22 in many partition members 21. Moreover, the container part 20 which introduce | transduces the acidic liquid b is not restricted to the center container part 20, and any container part 20 may be sufficient. Thus, in each container portion 20 in the container 13, the pelletized sodium chlorite a and the acidic liquid b chemically react to generate chlorine dioxide gas (ClO ₂ ) c. The reaction formula is as follows.
_{4NaClO 2 + 2 HOOC-CH (} OH) -CH 2 -COOH + O 2 → 2 NaOOC-CH (OH) -CH 2 -COO Na + 4ClO 2 + 2H 2 O

Claims (5)

A chlorine dioxide gas generator for supplying a pellet sodium chlorite and an acidic liquid to a container and generating chlorine dioxide gas by a chemical reaction between the two,
The container is provided in a space surrounded by a shield,
Said container is partitioned into a plurality of container portion, and each container portion, characterized in that the pellets JoA sodium chlorate are in communication with each other at the opening of a size not pass, chlorine dioxide gas Generator.   The chlorine dioxide gas generator according to claim 1, further comprising a fan for blowing chlorine dioxide gas generated in the gas generation chamber and a filter for filtering above the space.   In the interior of the space, a fan that adds a swirling component to the flow of chlorine dioxide gas that rises in the space by operation of the fan is provided above the container. Item 3. The chlorine dioxide gas generator according to Item 2.   The chlorine dioxide gas generation according to any one of claims 1 to 3, further comprising a partition member that divides the interior of the container into a plurality of container parts, wherein the partition member is detachable from the container. apparatus.   The chlorine dioxide gas generator according to any one of claims 1 to 4, further comprising a heater for heating the acidic liquid supplied to the container.