JP3430540B2 - Ozone deodorization system - Google Patents

Description

Description: BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an ozone deodorizing system utilizing the deodorizing action of ozone, and in particular, has excellent deodorizing ability, is safe for the human body, and is easy to maintain. Ozone deodorizing system. 2. Description of the Related Art Foods and the like that easily generate odors are stored and stored.
During transportation, the odor adheres to the container or remains in the atmosphere. If this odor is transferred to another object, its commercial value will be impaired. For this reason, containers with odors cannot be used. In particular, the containers of warehouses, containers, and luggage vehicles that store and transport fresh fish and the like in a frozen or iced state tend to have odor because they are in a low-temperature and closed state. Conventionally, various methods have been considered for deodorizing. For example, a method of liquefying and dissolving odorous substances and collecting them as a liquid, a method of adsorbing odorous substances with an adsorbent,
There are a method of burning odorous substances and a method of neutralizing odorous substances with chemicals. There is also a method of deodorizing by oxidizing an odorous substance with ozone. A specific known example is described in JP-A-2-4.
No. 6853 is a method in which an odorous substance is adsorbed by an adsorption sheet and then burned.
In this method, odorous substances are dissolved and absorbed in a water-absorbing sheet and neutralized with a chemical. Japanese Patent Application Laid-Open No. 62-234666 discloses an apparatus which is not a deodorizing method but mixes an ozone-containing gas and fog water and discharges the mixed gas into a room. [0005] Each of the above-mentioned conventional methods has problems. The method cannot remove odorous substances adsorbed on the wall surface of the container. If the catalyst is continued to be used, the catalyst may deteriorate, and it is necessary to replace the catalyst. Since the suction sheet is only exposed to the indoor atmosphere, there is little chance that the odorous substance comes into contact with the suction sheet, and it takes time to deodorize. The method cannot remove odorous substances adsorbed on the wall of the container. Maintenance is troublesome because it is necessary to replace the water absorbing sheet. Odorous substances that are not water-soluble cannot be captured. [0008] In contrast to these methods, deodorization with ozone can remove odorous substances adsorbed on the wall surface of the container because ozone is a gas. In addition, ozone has a bactericidal effect. However, ozone is harmful to the human body, so it cannot be used in open spaces, and even in a closed container, ozone removal must be considered in order for people to enter and leave. . [0009] In the apparatus described above, since the ozone is dissolved in the fog water, the room becomes wet or the humidity increases. Also, since ozone chemically reacts with the target (fungi and odorous substances) in the fog water, only the water-soluble target is effective. In addition, there is a problem in efficiency because ozone is poorly water-soluble. [0010] The ozone released into the container disappears by encountering bacteria and odorous substances and undergoing a chemical reaction. However, excess ozone that has not been reacted remains. As a device for removing this surplus ozone, the adsorption sheet of the above deodorization method can be applied to ozone adsorption. There is also an ozone decomposition catalyst layer. However, in the case of the adsorption sheet, there is little opportunity for ozone to come into contact with the adsorption sheet, and it takes time to remove ozone. In addition, both the adsorption sheet and the ozone decomposition catalyst layer deteriorate in high-concentration ozone, and therefore need to be replaced periodically. An object of the present invention is to solve the above-mentioned problems and to provide an ozone deodorizing system which is excellent in deodorizing ability, is safe for a human body, and is easy to maintain. According to the present invention, there is provided an ozone generator for generating ozone in a container such as a warehouse, a container, or a luggage vehicle for storing and transporting food and the like. And a fan for diffusing the generated ozone into the container, an ozone detector for detecting the ozone concentration in the container, and an ozone absorbing device provided with an ozone adsorption surface made of activated carbon fiber so as to be freely opened and stored, The above ozone detection concentration is
If it is lower than the specified lower limit, operate the above ozone generator.
If the ozone detection concentration exceeds the lower limit,
When the ozone generator is stopped, the ozone detection
If the degree is lower than the upper limit set higher than the lower limit
When the ozone absorption device is
If the detected concentration exceeds the upper limit, the ozone absorption
It is provided with a control device for expanding the suction surface of the device. The principle of ozone decomposition and adsorption of activated carbon can be divided into the following three stages, and it has been clarified that the dominant factors differ depending on the ozone concentration. First stage Catalytic reaction C + 2O ₃ → C + 3O ₂ Reaction rate is slow. [0015] Only low concentrations can be handled. Second Stage Adsorption Phenomenon Third Stage Oxidation Reaction C + 2O ₃ → CO ₂ + 2O ₂ C + O ₃ → CO ₂ + 1 / 2O _{2 At a} high concentration, this reaction is dominant. As described above, when the concentration of ozone is high, the activated carbon is oxidized. The ozone concentration at the boundary where this oxidation becomes remarkable is about 10 ppm. Therefore, if the activated carbon is not exposed to an ozone atmosphere having a concentration higher than this boundary or the exposure time is short, deterioration of the activated carbon can be prevented. With the above configuration, the ozone generated by the ozone generator is diffused into the container by the fan, and the inner wall and atmosphere of the container are evenly deodorized. At this time, since the ozone adsorption surface is housed in the ozone absorbing device, it does not wastefully adsorb ozone for deodorizing.
Not deteriorated without exposure to high concentration ozone. Even if the ozone generator supplies ozone,
As long as the odorous substance remains in the container, ozone is consumed, and the ozone detection concentration does not increase so much. When the detected ozone concentration starts to increase, it is considered that the ozone is in a surplus state or close to it. The control device stops the ozone generator when the detected ozone concentration exceeds a certain value. afterwards,
If the diffusion by the fan proceeds and the detected ozone concentration decreases, the ozone generator may be operated again. When the detected ozone concentration exceeds a certain value higher than the above-mentioned value, it is considered that there is an excess state of ozone, and almost no odorous substance remains in the entire container. Therefore, subsequent ozone supply is unnecessary. The control device not only stops the ozone generator but also deploys the adsorption surface of the ozone absorbing device. The adsorption surface adsorbs the remaining surplus ozone. At this time, the fan is continuously operated, and the suction is rapidly advanced. Since the ozone generator is already shut down, ozone is rapidly reduced. Therefore,
The time for which the adsorption surface is exposed to relatively high concentrations of ozone is short. Embodiments of the present invention will be described below in detail with reference to the accompanying drawings. FIG. 1 is a block diagram of an ozone deodorizing system. Meter relay 1 having two contact circuits 2 (L side, H side) switched at different input voltages, 100 V AC power supply 3 connected to a common terminal of each contact circuit, and L side of contact circuit 2 An ozonizer (ozone generator) 4 that receives power and generates ozone, a conversion adapter 5 that receives power from the H side of the contact circuit 2 and outputs a DC power voltage, an activated carbon screen (electric screen) 6, An operation panel (electric screen remote control) that deploys the activated carbon screen 6 when the conversion adapter 5 operates.
7, an ozone concentration meter 8 which operates by receiving power directly from the AC 100V power supply 3 and outputs an ozone concentration signal to the meter side of the meter relay 1, and a fan 9 which operates by receiving power supply directly from the AC 100V power supply 3. It is shown. The meter relay 1 includes a meter-side display unit 1
Pointer 11 swinging according to input voltage to 0 and two setting hands 1
2 (L, H), and the H setting hand 12 is red, L
The setting hand 12 is green. Further, it has a green lamp and a red lamp (not shown) that are turned on corresponding to the setting hand 12. The meter relay 1 switches each contact circuit 2 when the pointer 11 exceeds the setting hand 12. Here, the connection of each terminal of the contact circuit 2 turns on the ozonizer 4 when the ozone concentration signal of the ozone concentration meter 8 is lower than the L-side set voltage, and turns off the ozonizer 4 when the ozone concentration signal is higher than the L-side set voltage. ing. The active carbon screen 6 is not turned on when the ozone concentration signal is lower than the H-side set voltage, and is turned on when the ozone concentration signal is higher than the H-side set voltage. FIG. 2 shows the relationship between the set voltages on the L side and the H side and the switching operation. The ozone concentration meter 8 outputs a high-voltage ozone concentration signal when the ozone concentration is high. The larger the scale shown in FIG. 2 where the full range is 1 volt, the higher the ozone concentration. The numerical correspondence between the scale and the ozone concentration will be described later. The activated carbon screen 6 is shown in FIG. An upper end of a curtain 51 containing activated carbon fibers is wound around a winding shaft 52, and a rod-shaped weight 53 is attached to a lower end. Although not shown, a drive mechanism and a holding mechanism are accommodated in the winding shaft 52, and the curtain 51 can be wound up around the outer periphery of the winding shaft 52, or the curtain 51 can be unwound. The weight 53 applies tension to the curtain 51. A state in which the curtain 51 is fully wound is referred to as a fully closed state, and a state in which the curtain 51 is completely unwound is referred to as a fully opened state. The activated carbon screen 6
The up and down (open / close) of the curtain 51 is controlled by the operation panel 7.
The operation panel 7 has a plurality of operation buttons, and each button (S
The functions and names of W) are ascending to fully closed (UP), stopping (STOP), descending to fully open (DOWN), ascending while pushing, and descending while pushing. The operation panel 7 has an automatic mode (AUTO) and a manual mode (MA).
NUAL). In this embodiment, in the automatic mode, the DOWN operation is started immediately after power is supplied. That is, when the conversion adapter 5 operates in FIG. 1, the activated carbon screen 6 is developed. The above-mentioned ozone deodorizing system is provided in a warehouse, a container, a luggage vehicle and the like for storing and transporting foods and the like. That is, as shown by a dashed line in FIG. 1, an ozone generator (ozonizer) 4 for generating ozone, a fan 9 for diffusing the generated ozone into the container, The ozone concentration meter 8 is provided as an ozone detector 21 for detecting the ozone concentration in the container, and the activated carbon screen 6 is provided as an ozone absorbing device 22 provided with an ozone adsorption surface made of activated carbon fiber so as to be freely opened and stored. Further, the meter relay 1 is provided as a control device 23 for stopping the ozonizer when the ozone detection concentration exceeds a predetermined value, and developing the adsorption surface of the ozone absorption device 22 when the ozone detection concentration exceeds a higher upper limit. Things. The ozone deodorizing system according to this embodiment is
It operates by combining manual operation and automatic operation. The operation procedure is shown in the flowchart of FIG. Of course, this operation procedure can be completely automatically operated by a computer or the like. Next, the operation of the embodiment will be described. Referring to FIG. 3, the operation of the ozone deodorizing system will be described. The power of the ozone concentration meter 8 is turned on and the measurement mode is selected. In the high concentration measurement mode (Hi), the ozone concentration corresponds to 10 ppm with respect to the full range of the scale of the meter relay 1, and in the low concentration measurement mode (Low), it corresponds to 1 ppm. Next, meter relay 1
L and H sides are set. This setting can be easily performed by the setting hands 12 which are color-coded. Here, the reason for setting is that the required ozone concentration differs depending on the odorous substance to be removed. That is, when the sensory strength of the odor is expressed numerically and represented by the odor strength shown in Table 1, the relationship between the concentration of the odor substance and the odor strength varies depending on the odor substance as shown in Table 2. Since the principle of deodorization with ozone is a chemical reaction between ozone and odorous substances, a corresponding ozone concentration is required to reduce a certain concentration of odorous substances to odorless. Therefore, the voltage setting of L and H is performed in consideration of the data of Table 2. [Table 1] [Table 2] Tables 1 and 2 are based on the Japan Environmental Health Center "Study on the Development of Odor Control Standards 1972" and "Study on the Measurement of Odor Substances 1975". After setting the voltage, the operation panel 7 is switched to AUTO. When the ozone concentration meter 8 is stabilized and the measurement mode is ready, the power of the meter relay 1 is turned on. As a result, the meter relay 1 is automatically controlled. When the ozone concentration A is lower than the set value L, the ozonizer 4 is turned on. At this time, the green lamp of the meter relay 1 is turned on, and the red lamp is turned off. An ozonizer (ozone generator) 4 emits ozone into the container, and a fan 9 diffuses the generated ozone into the container. Ozone deodorizes the inner wall and atmosphere of the container. At this time, since the activated carbon screen 6 is in the fully closed state, ozone for deodorizing is not wastefully adsorbed, and is not exposed to high-concentration ozone and does not deteriorate. When the ozone concentration A increases and exceeds the set value L, the ozonizer 4 is turned off. Ozone concentration A is set value H
If lower, this state is maintained. If the ozone concentration A becomes lower than the set value L again, the ozonizer 4 is turned on again. Conversely, if the ozone concentration A is higher than the set value H, the activated carbon screen 6 is lowered until it is fully opened (DO
WN). At this point, the automatic control of the meter relay 1 ends. Thereafter, since the activated carbon screen 6 is exposed to the atmosphere in the container in the fully opened state, the ozone concentration A decreases. Since the ozonizer 4 is already stopped, the ozone decreases rapidly. Accordingly, the time during which the activated carbon screen 6 is exposed to a high concentration of ozone is short. Thereafter, when it is confirmed that the ozone concentration A is lower than the set value H, the operation panel 7
Is switched to MANUAL, and the activated carbon screen 6 is raised (UP) to the fully closed state by operating the SW. In this embodiment, the ozone detector 8 is used as the ozone detector 21, but any device that outputs a signal proportional to the ozone concentration may be used.
Although the activated carbon screen 6 on which the curtain 51 containing activated carbon fibers is wound is used, any material capable of developing and storing the ozone adsorption surface may be used. Further, the meter relay 1 is used as the control device 23, and the power of each device connected to the contact circuit 2 is turned on and off. However, the control device 23 including a computer or the like and including the function of the operation panel 7 is provided. Each device may be controlled by a signal. Next, application examples of the present invention will be described. FIG. 4 shows a refrigerator in which the ozone deodorizing system of the present invention is applied to a frozen container for transporting fresh fish in a frozen state. As shown, the refrigerated container vehicle 41
The ozone generator 4, the ozone absorbing device 22, and the ozone detector 21 are provided in the refrigerating container 42 of. The control device 23 is housed in the cockpit 43. These components use a DC power supply for vehicle-mounted specifications, but are connected almost as shown in the block diagram of FIG. In addition, fan 9
The fan 9 of the refrigeration unit 44 installed in the refrigeration container 42 is used for the refrigeration container 42. Since the refrigeration unit 44 is installed above the refrigeration container 42 on the cockpit 43 side, the ozone generator 4 is mounted on the refrigeration unit 44 to use the fan 9. The ozone absorbing device 22 is constituted by the activated carbon screen 6 described above,
It is attached to the rear side of the freezing container 42. The ozone absorbing device 22 will be located downstream of the diffusion flow by the fan 9. The ozone detector 21 is mounted upstream of the ozone absorbing device 22. The main component of fish odor is trimethylamine.
The reference value of the ozone detection concentration for stopping the ozone generator 4 and deploying the ozone absorbing device 22 is derived from Table 2. The ozone generated by the ozone generator 4 is forcibly circulated in the refrigeration container 42 by the fan 9 of the refrigeration unit 44. Trimethylamine in the inner wall and atmosphere of the freezing container 42 is oxidatively decomposed by ozone. FIG. 6 is a graph showing the changes over time in the concentration of trimethylamine (TMA) and the ozone concentration in the container when ozone is continuously supplied to the container in a constant amount. Although the rate of change of the TMA concentration varies depending on the temperature, humidity, and the like in the container, the ozone concentration tends to start increasing when the TMA concentration decreases and reaches a certain value. This change point is below the TMA concentration at which the odor intensity in Table 2 indicates no odor. Also in the refrigeration container 42, the ozone concentration changes according to FIG. If the reference value of the controller 23 is set to the ozone detection concentration corresponding to the TMA concentration, the ozone generator 4 is stopped and the ozone absorbing device 22 is deployed before the ozone concentration rises significantly as shown in FIG. It is possible to do. As described above, when the ozone generator 4 is stopped and the ozone adsorbing surface of the ozone absorbing device 22 is developed, the ozone adsorbing surface is exposed to forced convection by the fan 9 and surplus ozone is discharged on the ozone adsorbing surface. Adsorbed and decomposed. Finally, the ozone concentration is 0.1 ppm, which is considered safe for the human body
Less than. Next, an embodiment of the ozone deodorizing system of the present invention in which the ozone generator 4 is turned on and off intermittently so that the ozone concentration does not exceed 0.1 ppm will be described. The TM
In the ozone deodorizing system for A, the controller 23 sets the reference value for stopping the ozone generator 4 to 0.1 ppm.
And The control device 23 operates according to the procedure of FIG.
The stop and restart of the ozone generator 4 are repeated. Therefore, the ozone concentration in the container is always 0.1 which is a measure of human safety.
Do not exceed ppm. This operating method was set as method C, and other operating methods (methods A and B) for a comparative experiment were tested under the same conditions (FIG. 7). Here, in the method A, the TMA is volatilized in advance, and the ozone generator 4 is continuously operated at the maximum. In the method B, volatilization of TMA and intermittent operation of the ozone generator 4 are performed in parallel, and after 15 minutes, TMA volatilization is stopped and the ozone generator 4 is continuously operated at the maximum. In the C method, volatilization of TMA and intermittent operation of the ozone generator 4 are performed in parallel, and after 50 minutes, TMA is performed.
The volatilization is stopped, and the ozone generator 4 is kept in the intermittent operation. A circle indicates that a sensory test is performed. TMA concentration was measured with an analyzer. The results of the test are shown in FIG. Method B, C
In the method, the TMA analysis value dropped to 10 ppb after 60 minutes. In Method A, it did not reach 10 ppb even after 3 hours. This indicates that the on-off intermittent operation of the ozone generator 4 is shorter in time until the odor is eliminated. The present invention exhibits the following excellent effects. (1) When odorous substances are decomposed by generating ozone, activated carbon fibers are stored.
Ozone is used exclusively for decomposition and is efficient. (2) Since the activated carbon fiber is exposed to a high concentration ozone atmosphere for a short time, the life is prolonged.
Maintenance such as replacement becomes unnecessary. (3) Since the ozone concentration can be controlled so as not to increase, and the recovery of surplus ozone is quick and reliable,
There is no effect on the human body and it is safe.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a block diagram of an ozone deodorizing system showing one embodiment of the present invention. FIG. 2 is a detailed view of a display section of a meter relay. FIG. 3 is a flowchart of an operation procedure of the ozone deodorizing system of the present invention. FIG. 4 shows a refrigerated container vehicle 41 showing an applied embodiment of the present invention.
FIG. FIG. 5 is a perspective view of an activated carbon screen. FIG. 6 is a graph of a temporal change in a TMA concentration and an ozone concentration. FIG. 7 is a time chart showing an operation method of an ozone generator for a comparative test. FIG. 8 is a graph showing a time change of a TMA analysis value in a comparative test. [Description of Signs] 4 Ozone generator 9 Fan 21 Ozone detector 22 Ozone absorption device 23 Control device

──────────────────────────────────────────────────続 き Continuing on the front page (72) Keiko Shibata, Inventor No. 8 Fujisawa-shi, Kanagawa Prefecture Isuzu Central Research Institute Co., Ltd. (72) Koichi Tatsuno 8-Tunisawa Fujisawa City, Kanagawa Prefecture Isuzu Central Research Inc. In-house (56) References JP-A-2-46853 (JP, A) JP-A-6-9641 (JP, A) JP-A-3-68416 (JP, A) JP-A-3-47261 (JP, A) JP-A-6-117663 (JP, A) JP-A-2-164704 (JP, A) JP-A-5-37245 (JP, A) JP-A-4-357956 (JP, A) JP-A-2-164703 (JP, A) JP-A-4-33923 (JP, U) JP-A-2-116450 (JP, U) (58) Fields investigated (Int. Cl. ⁷ , DB name) A61L 9/00-9 / twenty two

Claims (1)

(57) [Claims] [Claim 1] An ozone generator that generates ozone in a container such as a warehouse, a container, or a luggage vehicle for storing and transporting food and the like, and the ozone generated in the container. A fan for diffusion, an ozone detector for detecting the ozone concentration in the container,
And ozone absorption device provided with freely expand, accommodating ozone adsorbing surface made of activated carbon fiber provided, the above ozone detecting concentration
If it is lower than the specified lower limit, operate the above ozone generator.
If the ozone detection concentration exceeds the lower limit,
When the ozone generator is stopped, the ozone detection
If the degree is lower than the upper limit set higher than the lower limit
When the ozone absorption device is
If the detected concentration exceeds the upper limit, the ozone absorption
An ozone deodorizing system comprising a control device for developing an adsorption surface of the device.