JP4545481B2 - Ozone supply device - Google Patents

Description

This invention, produced storing ozone using power, it relates to Luo Zon supply device can be supplied at a constant rate in and continuously ozone consumption objects as necessary stored ozone.

  FIG. 28 is a block diagram showing an intermittent ozone supply device which is a conventional ozone storage device. This ozone storage device is a device for temporarily storing ozone. In the figure, 1 is an ozone generator for generating ozonized oxygen by discharging in an oxygen-containing gas supplied from an oxygen supply source 2, and 3 is a circulation blower. An oxygen-containing gas supplied from the oxygen supply source 2 (hereinafter referred to as an oxygen-containing gas) , Oxygen).) Is circulated through the circulation path L1 between the ozone generator 1 and the adsorption / desorption tower 4 that temporarily stores the generated ozonated oxygen (see, for example, Patent Document 1).

  5 is a cold source that generates a refrigeration gas that is circulated through the circulation path L2 in the adsorption / desorption tower 4, 6 is a heating source that generates a heating agent that is circulated through the circulation path L3 in the adsorption / desorption tower 4, and 7 is a water stream ejector. The water flow ejector 7 sucks and removes (desorbs) ozone from ozonated oxygen temporarily stored in the adsorption / desorption tower 4, disperses and dissolves in water, and is not shown as ozone-containing water. Send to ozone consumption object.

  8-1, 8-2 are provided on the upstream side and the downstream side of the cold heat source 5 through the circulation pipe L2, and are switching valves for controlling supply of the refrigeration gas to the adsorption / desorption tower 4, and 8-3 is the adsorption / desorption tower. A switching valve 8-4 provided between the discharge side of 4 and the suction side of the circulation blower 3 via a circulation pipe L1 is connected to the discharge side of the ozone generator 1 and the suction side of the adsorption / desorption tower 4 via a circulation path L1. The switching valves 8-5 and 8-7 are provided on the upstream side and the downstream side of the heating source 5 through the circulation pipe L3, and control the supply of the heating agent to the adsorption / desorption tower 4. .

  The adsorption / desorption tower 4 is a double cylinder, of which the inner cylinder is filled with an adsorbent and the outer cylinder is filled with a heat medium. Further, silica gel is generally used as the adsorbent, and ethylene glycol or alcohols are used as the heat medium. The circulation blower 3, the ozone generator 1, and the adsorption / desorption tower 4 are connected in this order by a ring L 1 to constitute one ozone circulation system.

Next, the operation of the conventional apparatus will be described. There are two operations: ozone adsorption operation and ozone desorption operation.
First, the adsorption operation will be described. Oxygen is supplied from the oxygen supply source 2 so that the inside of the ozone circulation system is always at a constant pressure. The pressure at this time is normally maintained at 1.5 kg / cm 2. When oxygen is supplied into the ozone circulation system by the circulation blower 3 with the switching valves 8-3 and 8-4 being opened, oxygen is generated by silent discharge while oxygen passes through the discharge gap of the ozone generator 1. Part of this is converted into ozone to become ozonated oxygen, which is transported to the adsorption / desorption tower 4.

  At this time, refrigeration gas is supplied into the adsorption / desorption tower 4 from the cold heat source 5 through the open switching valves 8-1 and 8-2. Therefore, the temperature of the adsorbent is cooled to −30 ° C. or lower by the refrigeration gas. The adsorbent in the adsorption / desorption tower 4 selectively adsorbs ozone from ozonated oxygen, and the remaining oxygen is returned to the circulation blower 3 via the switching valve 8-3. The oxygen consumed as ozone is replenished from the oxygen supply source 2.

  The amount of ozone adsorbed by the adsorbent varies greatly depending on the temperature of the adsorbent. That is, the ozone adsorption amount increases when the temperature of the adsorbent is lowered, and conversely when the temperature rises, the ozone adsorption amount decreases. Therefore, the adsorbent is cooled when ozone is adsorbed, and the temperature of the adsorbent is increased when ozone is desorbed.

  When ozone is adsorbed to the adsorbent to near the ozone saturated adsorption amount, the operation proceeds to the desorption operation. In the desorption operation, the operation of the ozone generator 1, the circulation blower 3, and the cold heat source 5 is stopped, and the switching valves 8-1, 8-2, 8-3, and 8-4 are closed. Thereafter, the heating source 6 and the water flow ejector 7 start operation, and the switching valves 8-5 and 8-7 are opened. When the switching valves 8-5 and 8-7 are opened, the heating agent is sent from the heating source 6 to the adsorption / desorption tower 4. As a result, the temperature in the adsorption / desorption tower 4 rises so that ozone adsorbed by the adsorbent can be easily desorbed.

  When the switching valve 8-6 is opened, the ozone adsorbed on the adsorbent is sucked into the water ejector 7 under reduced pressure at once, dispersed and dissolved in the water, and sent to the ozone consuming object as ozone-containing water. . When ozone is sucked under reduced pressure, the ultimate pressure in the adsorption / desorption tower 4 is about 0.13 atm (1.3 × 10 −6 Pa). When the desorption period ends in this way, the operation moves to the initial adsorption operation again and the operation is continuously repeated.

JP-A-52-3595

  Since the conventional intermittent ozone supply device is configured as described above, when ozone is dispersed and dissolved in water at the time of desorption and supplied to an ozone consumer as ozone-containing water, the life of ozone in water is short. Ozone disappears during supply. Therefore, ozone cannot be continuously supplied to the ozone consuming object at a constant rate. In addition, since ozone that is dispersed and dissolved in water is taken out at the locations where ozone is used, considering the life of ozone in water, there are problems such as the scope of ozone being limited to water treatment methods. It was.

  In addition, during adsorption, if ozone is to be adsorbed by the adsorbent efficiently, it is necessary to increase the partial pressure of ozone in the ozonized oxygen. However, if this is done, the ozone generation efficiency in the ozone generator is reduced. Therefore, there has been a problem that ozone cannot be stored efficiently.

The present invention has been made to solve the above problems, and is an ozone supply device that can efficiently store ozone generated using electric power and stably supply the stored ozone to an ozone consuming object. The purpose is to obtain.

Another object of the present invention is to obtain an ozone supply device as follows.
(1) An object of the present invention is to obtain an ozone supply device that can effectively use the cold heat of liquid oxygen that is a raw material of ozone.

(2) An object of the present invention is to obtain an ozone supply device that can reduce the power required to cool the adsorption / desorption device when ozone is adsorbed and stored.

(3) An object of the present invention is to obtain an ozone supply device that can reduce the amount of electric power used when generating ozone and can reduce the adsorption / desorption device for storing ozone.

(4) An object of the present invention is to provide an ozone supply device that can stably supply a certain amount of ozone-containing gas containing ozone at a certain concentration to an ozone consuming object.

(5) An object of the present invention is to obtain an ozone supply device capable of efficiently cooling the adsorbent filled in the adsorption / desorption tower.

(6) An object of the present invention is to obtain an ozone supply device capable of processing ozone stored safely and promptly when trouble occurs during ozone storage.

According to the present invention, ozone generating means for generating ozonized oxygen from an oxygen-containing gas, ozone is selected from the ozonated oxygen generated by the ozone generating means and adsorbed on an adsorbent, and ozone is absorbed from the adsorbent. An ozone supply device comprising an adsorption / desorption means for desorption and a circulation path for returning the oxygen-containing gas after ozone adsorption from the adsorption / desorption means to the ozone generation means, wherein the ozone adsorbed and stored by the adsorption / desorption means is depressurized. Ozone suction means for suction, a first gas flow rate control device for controlling the flow rate of gas flowing to the ozone suction means, oxygen supply means for supplying oxygen to the adsorption / desorption means, and supply from the oxygen supply means A second gas flow rate control device for controlling the flow rate of oxygen gas, and a medium for controlling the flow rate of the medium gas added to ozonized oxygen taken out by the ozone suction means Generator, an ozone concentration meter for measuring the ozone concentration in the ozone-containing gas supplied to the ozone consuming object, a signal from the ozone concentration meter, the first gas flow control device, the second gas flow control device An ozone supply device comprising: a gas flow rate control device; and a control device that controls a flow rate of a flowing gas by changing an operation of the medium gas generation device .

According to the present invention, ozone generating means for generating ozonized oxygen from an oxygen-containing gas, ozone is selected from the ozonated oxygen generated by the ozone generating means and adsorbed on an adsorbent, and ozone is absorbed from the adsorbent. An ozone supply device comprising an adsorption / desorption means for desorption and a circulation path for returning the oxygen-containing gas after ozone adsorption from the adsorption / desorption means to the ozone generation means, wherein the ozone adsorbed and stored by the adsorption / desorption means is depressurized. Ozone suction means for suction, a first gas flow rate control device for controlling the flow rate of gas flowing to the ozone suction means, oxygen supply means for supplying oxygen to the adsorption / desorption means, and supply from the oxygen supply means A second gas flow rate control device for controlling the flow rate of oxygen gas, and a medium for controlling the flow rate of the medium gas added to ozonized oxygen taken out by the ozone suction means Generator, an ozone concentration meter for measuring the ozone concentration in the ozone-containing gas supplied to the ozone consuming object, a signal from the ozone concentration meter, the first gas flow control device, the second gas flow control device Since it is an ozone supply device comprising a gas flow rate control device and a control device for controlling the flow rate of the flowing gas by changing the operation of the medium gas generation device, ozone generated using electric power is While storing efficiently, the stored ozone can be stably supplied to an ozone consumption object.

Reference Example 1
Hereinafter, reference examples and embodiments of the present invention will be described with reference to the drawings. Figure 1 is a diagram showing an arrangement of an ozone storage device according to Example 1 of the present invention, It should be noted that the same reference numerals as in FIG. 28 in the figure indicate the same or corresponding parts. In the figure, reference numeral 11 denotes an ozone releasing means for taking out ozone from the adsorption / desorption tower 4 in a fixed amount. The ozone releasing means 11 controls an ozone gas flow rate control device 12 for controlling the ozone quantity released from the adsorption / desorption tower 4 and an ozone gas flow rate adjustment. The gas suction pump 13 is configured to suck ozone from the adsorption / desorption tower 4 through the device 12.

  Reference numeral 14 denotes ozone concentration control means for supplying a constant amount of ozone-containing gas containing ozone at a constant concentration to the ozone consuming object 15. The ozone concentration control means 14 is used to carry ozone to the ozone consuming object 15. A medium gas production machine 16 that produces a medium gas and a gas mixer 17 that mixes the medium gas and ozone extracted from the adsorption / desorption tower 4 to generate an ozone-containing gas are included.

  18 is an ozone concentration meter that detects the ozone concentration in the ozone-containing gas produced by the gas mixer 17, and 19 is a control signal that receives a control signal from the ozone concentration meter 18 and that controls the ozone gas flow rate adjusting device 12 and the gas suction pump 13. It is a control device that sends. Reference numeral 20 denotes a cryogenic separation device that produces oxygen as a raw material of ozone by performing cryogenic separation of the air and supplies it to the ozone generator 1.

Next, the operation of Reference Example 1 will be described. This operation includes two operations: an operation for adsorbing ozone and an operation for desorbing ozone.
First, the operation | movement which adsorb | sucks ozone is demonstrated. When air is supplied to the cryogenic separator 20, it is liquefied and liquid oxygen, liquid nitrogen, and the like are separated and generated. The generated liquid oxygen is again vaporized oxygen and is supplied so that the pressure in the circulation system is always constant. The pressure in the circulation system at this time is normally maintained at 1.5 to 2.0 kg / cm 2.

  When oxygen is circulated through the circulation system by the circulation blower 3 with the switching valves 8-3 and 8-4 being opened, oxygen is silently discharged while passing through the discharge gap of the ozone generator 1. The portion is converted to ozone to become ozonated oxygen, and this ozonated oxygen is conveyed to the adsorption / desorption tower 4. The adsorbent in the adsorption / desorption tower 4 selectively adsorbs ozone from ozonated oxygen, and the remaining oxygen is returned to the circulation blower 3 through the switching valve 8-3.

  Note that the oxygen consumed as ozone is replenished into the circulation system by oxygen obtained by vaporizing liquid oxygen produced by the cryogenic separator 20. At this time, since the adsorbent has a property that the adsorption capacity of ozone increases as the adsorbent is cooled, the cooling temperature is usually set to −40 ° C. or lower by the cold heat source 5. Further, it is desirable to select an adsorbent having a low decomposition rate when it comes into contact with ozone, and examples thereof include silica gel, porous material impregnated with activated alumina and fluorocarbon.

  When the adsorbent in the adsorption / desorption tower 4 is adsorbed to near the ozone saturated adsorption amount, the operation proceeds to the desorption operation. In the desorption operation, the operation of the ozone generator 1, the circulation blower 3, and the cold heat source 5 is stopped, and the switching valves 8-1, 8-2, 8-3, and 8-4 are closed. Thereafter, the gas suction pump 13 starts to operate, and the ozone gas flow control device 12 is gradually opened, and ozone is sucked into the gas mixer 17 from the adsorbent. In accordance with this, the medium gas is supplied from the medium gas production machine 16 to the gas mixer 17, and ozone and the medium gas are mixed in the gas mixer 17 and sent to the ozone consuming object 15 as an ozone-containing gas. Further, when ozone having a set concentration leaks from the adsorption / desorption tower 4, the desorption operation may be started.

  Next, an ozone desorption method by the ozone release means 11 and the ozone concentration control means 13 will be described. The ozone concentration in the ozone-containing gas discharged from the gas mixer 17 is measured by the ozone concentration meter 18, and a control signal is sent to the control device 19. When the ozone concentration in the released ozone-containing gas is higher than the set ozone concentration, a control signal is sent from the control device 19 to the ozone gas flow rate adjusting device 12, the ozone gas flow rate adjusting device 12 is slightly closed, and the gas suction is performed. A control signal is also sent to the pump 13 to weaken the ability to extract ozone from the adsorption / desorption tower 4, thereby reducing the amount of ozone released from the adsorption / desorption tower 4 and lowering the ozone concentration in the ozone-containing gas.

  On the other hand, when the ozone concentration in the released ozone-containing gas is lower than the set ozone concentration, a control signal is sent from the control device 19 to the ozone gas flow rate adjustment device 12, and the ozone gas flow rate adjustment device 12 is slightly opened, A control signal is also sent to the gas suction pump 13 to increase the amount of ozone released from the adsorption / desorption tower 4 by increasing the ability to extract ozone from the adsorption / desorption tower 4, and the ozone concentration in the ozone-containing gas is high. Become.

  At this time, the control device 19 sends a control signal to the medium gas production machine 16 in accordance with the change in the amount of ozone flowing into the gas mixer 17, and sets the flow rate of the ozone-containing gas supplied to the ozone consuming object 15 to the set flow rate. It is matched. As a result, an ozone-containing gas containing a constant concentration of ozone can be supplied to the ozone consuming object 15 by a fixed amount. Furthermore, it is possible to reduce energy used when storing ozone and to perform stable ozone treatment.

  Since the cryogenic separator 20 is made by liquefying oxygen as a raw material of ozone from air, it is possible to prevent nitrogen from being mixed into the circulation path. Therefore, the oxygen purity can be kept high. Further, nitrogen oxides are not generated in the ozone generator 1, and it is possible to prevent the adsorption efficiency of ozone from being reduced due to adsorption of nitrogen oxides to the adsorbent.

Next, the ozone concentration released from the adsorption / desorption tower 4 after ozone adsorption is always kept below a predetermined concentration until the temperature in the adsorption / desorption tower 4 reaches a set temperature, so that the temperature in the adsorption / desorption tower 4 is reduced. An ozone storage method according to this reference example in which ozone is adsorbed and stored while being lowered step by step will be described.

  FIG. 2 shows the relationship between the ozone adsorption amount and the cooling temperature of the adsorbent (silica gel). Thus, it is recognized that the ozone adsorption amount increases exponentially as the cooling temperature of the adsorbent is lowered. Thereby, in order to store ozone efficiently, it turns out that it is important to reduce the temperature of an adsorbent as much as possible.

  However, the relationship between the adsorbent temperature and the cooling time is expressed as shown in FIG. 3, and as the adsorbent temperature is further lowered, the time required for cooling increases, and as the adsorbent temperature is lowered, the cooling is increased. It turns out that it is necessary to equip the cooler which requires capacity.

  On the other hand, the adsorption breakthrough curve at a certain temperature (relationship between the ozone concentration at the outlet of the adsorption / desorption tower 4 and the time for injecting ozone into the adsorption / desorption tower 4) is shown in FIG. Thus, when a certain period of time elapses, ozone leaks out of the adsorption / desorption tower 4 rapidly (adsorption breakthrough state), and the ozone generated by the ozone generator 1 cannot be stored efficiently. At this time, it is assumed that the adsorption breakthrough time is reached when the ozone concentration in the ozonized gas leaking from the adsorption / desorption tower 4 becomes 5 to 10% of the injected ozone concentration.

  Therefore, the time until the adsorbent is cooled to a certain temperature is shorter than the time until adsorption breakthrough occurs due to ozone injection at a certain temperature. That is, the generated ozone can be efficiently stored by cooling the adsorbent and storing ozone so that adsorption breakthrough does not occur until the set temperature is reached. Accordingly, it is not necessary to equip a cooler having a high-performance cooling capacity, and it is only necessary to equip a cooler having a cooling ability capable of cooling the adsorbent in the adsorption / desorption tower 4 before adsorption breakthrough occurs. Therefore, there is an effect that the equipment cost for the cooler can be reduced.

Moreover, in the above-mentioned reference example , the case of introducing ozonized oxygen from the floor of the adsorption / desorption tower 4 during ozone adsorption and taking out ozone from the floor of the adsorption / desorption tower 4 during ozone desorption is shown. Except for the case where the adsorbent in 4 is completely in an adsorption equilibrium state, the position where the ozonized oxygen is introduced during adsorption and the position where ozone is extracted during desorption are the center of the adsorption / desorption tower such as the ceiling and floor. It is desirable to make it symmetrical with respect to.

  This is because ozone is sufficiently adsorbed in the adsorbent in the vicinity where the ozonized oxygen is introduced, but the adsorbent located at a position away from the gas inlet has a lower ozone adsorption rate. Therefore, by removing ozone from a position away from the gas inlet at the time of desorption, desorption from the adsorbent where ozone is not so much adsorbed occurs first, so the amount of ozone taken out is suppressed and ozone is depleted at the start of desorption. It can be prevented from being taken out suddenly.

In the above reference example , the ozone concentration in the ozone-containing gas discharged from the gas mixer 17 is measured, and the ozone-containing gas containing a certain concentration of ozone is supplied to the ozone consuming object 15 using the control device 19. The case where the ozone gas flow rate adjusting device 12, the gas suction pump 13 and the medium gas production machine 16 are driven by a timer (not shown) is shown, and the ozone-containing gas containing a constant concentration of ozone is consumed. A certain amount may be supplied to the object 15 in this case. In this case, the control accuracy of the ozone concentration in the ozone-containing gas is slightly deteriorated, but the equipment configuration is simplified and the equipment cost can be reduced. is there.

Moreover, although the case where the adsorption / desorption tower 4 is a single tower was shown in the above reference example , it is desirable to provide a plurality of adsorption / desorption towers 4, and the desorption amount of ozone from a certain adsorption / desorption tower 4 is reduced. When the ozone gas flow rate adjusting device 12 of the other adsorption / desorption tower 4 is opened, ozone desorbed from the plurality of adsorption / desorption towers 4 is mixed and supplied to the gas mixer 17, so that a constant concentration is obtained. Ozone-containing gas containing ozone can be easily supplied to the ozone consuming object 15 by a certain amount.

Furthermore, in the above reference example , the case where the adsorption / desorption tower 4 is equipped with only the cold heat source 5 and the cold heat source 5 is stopped at the time of desorption to facilitate the desorption of ozone. However, the adsorption / desorption tower 4 may be provided with the cold heat source 5 and the heating source, and the temperature in the adsorption / desorption tower 4 may be controlled so that ozone can be easily desorbed. Thereby, the amount of ozone taken out from the adsorption / desorption tower 4 can be controlled with higher accuracy and supplied to the ozone consuming object 15.

Furthermore, in this reference example , the case where ozone taken out from the adsorption / desorption tower 4 passes through the ozone gas flow rate adjusting device 12 and the gas suction pump 13 and is mixed with the medium gas and supplied to the ozone consuming object 15 is described. did. However, an ozone buffer device is provided between the adsorption / desorption tower 4 and the ozone gas flow rate control device 12, and the ozone taken out from the adsorption / desorption tower 4 is temporarily held in the ozone buffer device so that ozone is removed at the initial stage of desorption. A large amount may be prevented from being released. Thereby, the amount of ozone taken out from the adsorption / desorption tower 4 can be controlled with higher accuracy, and the ozone concentration in the ozone-containing gas supplied to the ozone consuming object 15 can be controlled with high accuracy. At this time, a packed tower filled with an adsorbent such as silica gel may be used as the ozone buffer device, or an ozone filling tank having a predetermined volume may be used.

Reference Example 2
In Reference Example 1, the ozone gas sucked by the gas suction pump 13 of the ozone release means 11 is mixed with the medium gas produced by the medium gas production machine 16 of the ozone concentration control means 14 to generate an ozone-containing gas. In addition, a configuration in which a certain amount is supplied to the ozone consuming object 15 is shown.

  On the other hand, in this reference example, as shown in FIG. 5, the ozone gas flow rate adjusting device 12 for controlling the amount of ozone released from the adsorption / desorption tower 4 and the adsorption / desorption tower 4 by reducing the pressure in the adsorption / desorption tower 4. A gas ejector 21 that desorbs ozone from the gas ejector 21 through the ozone gas flow rate control device 12, a bypass pipe 22 that connects the gas ejector 21 in parallel with the gas ejector 21, and a compressed medium gas that drives the gas ejector 21 are created. A compressed gas production machine 23, a two-way flow rate control valve 24 that regulates the flow rate ratio of the compressed medium gas that flows from the compressed gas production machine 23 to the gas ejector 21 and the bypass pipe 22, and an ozone-containing gas produced by mixing with the gas ejector 21. Ozone concentration meter 18 that measures the ozone concentration in the atmosphere, and the ozone concentration measurement result in the ozone-containing gas by the ozone concentration meter 18 Based consist ozone gas flow regulating device 12, the compressed gas making machine 23 and the two-way flow control valve 24 control device 19 sends a control signal to be. Therefore, the gas suction pump 13 is unnecessary in this reference example.

Next, the operation of this reference example will be described.
The ozone concentration in the ozone-containing gas released by the gas ejector 21 is measured by the ozone concentration meter 18 and a control signal is sent to the control device 19. At this time, if the ozone concentration in the ozone-containing gas is higher than the set ozone concentration, a control signal is sent from the control device 19 to the ozone gas flow rate adjusting device 12, the ozone gas flow rate adjusting device 12 is slightly closed, and the two directions A control signal is also sent to the flow control valve 24.

  As a result, since the compressed medium gas bypasses the gas ejector 21 through the bypass pipe 22, the flow rate of the compressed medium gas supplied to the gas ejector 21 is reduced, and the flow rate of the compressed medium gas passing through the nozzle of the gas ejector 21. As a result, the pressure in the adsorption / desorption tower 4 increases, the amount of ozone desorbed decreases, and the ozone concentration in the ozone-containing gas released from the gas ejector 21 decreases.

  On the other hand, when the ozone concentration in the ozone-containing gas discharged from the gas ejector 21 is lower than the set ozone concentration, a control signal is sent from the control device 19 to the ozone gas flow rate control device 12, and the ozone gas flow rate control valve 12 is slightly opened. In addition, a control signal is also sent to the two-way flow rate control valve 24 to increase the flow rate of the compressed medium gas supplied to the gas ejector 21.

  By controlling these valves, the flow rate of the compressed medium gas passing through the nozzle of the gas ejector 21 is increased, and the amount of ozone taken out is increased as the pressure in the adsorption / desorption tower 4 is reduced, so that the ozone concentration in the ozone-containing gas is increased. Becomes higher. At this time, the control device 19 sends a control signal to the compressed gas production machine 23 in accordance with the change in the amount of ozone-containing gas flowing into the gas ejector 21, adjusts the flow rate of the compressed medium gas, and supplies ozone to the ozone consuming object 15. The flow rate of the contained gas is adjusted to the set flow rate.

Thereby, since the gas mixer 17 and the gas suction pump 13 in Reference Example 1 can be substituted by the gas ejector 21, the configuration of the apparatus can be simplified, energy required for desorption can be reduced, and adsorption / desorption can be performed. There is an effect that the apparatus can be made compact.

  In the above reference example, the ozone concentration in the ozone-containing gas released from the gas ejector 21 is measured, and from this measurement result, the control device 19 supplies the ozone-containing gas containing a constant concentration of ozone to the ozone consuming object 15 by a certain amount. The control method to supply was shown. However, regardless of the control device 19, the ozone gas flow rate adjusting device 12, the compressed gas production machine 23, and the two-way flow rate adjusting valve 24 are driven by a timer (not shown), so that the ozone-containing gas containing a constant concentration of ozone is generated. A certain amount may be supplied to the ozone consuming object 15 at a time. In this case, the control accuracy of the ozone concentration in the ozone-containing gas is slightly deteriorated, but the equipment configuration is simplified and the equipment cost can be reduced.

  Further, in this reference example, the two-way flow rate adjustment valve 24 is used to adjust the flow rate ratio of the compressed medium gas flowing through the gas ejector 21 and the bypass pipe 22. However, there are problems such as an increase in equipment and equipment costs and a difficulty in the control method. However, a compressed gas flow rate control device is provided in each of the piping to which the gas ejector 21 is attached and the bypass piping 22, and the ozone. Even if the flow rate of the compressed gas flowing through each pipe is controlled while the flow rate of the ozone-containing gas supplied to the consumption object 15 is kept constant, the same ozone concentration control effect can be obtained.

Reference Example 3
In Reference Example 2 , the ratio of the compressed medium gas produced by the compressed gas production machine 23 to the gas ejector 21 or the bypass pipe 22 is adjusted by the control of the two-way flow rate control valve 24, and the ozone-containing gas The ozone concentration was adjusted.

  On the other hand, in this reference example, as shown in FIG. 6, as shown in FIG. 6, an ozone concentration meter 18 that measures the ozone concentration in the ozone-containing gas mixed and produced by the gas ejector 21, and ozone that is sucked under reduced pressure from the adsorption / desorption tower 4. An ozone gas flow rate adjusting device 12 for adjusting the flow rate of the ozone gas, and a control device 19 for changing the nozzle diameter in the ozone gas flow rate adjusting device 12 and the gas ejector 21 in response to a control signal from the ozone concentration meter 18 are provided in the bypass pipe 22 and two directions. The flow control valve 24 is deleted.

Next, the operation of this reference example will be described.
First, the ozone concentration in the ozone-containing gas discharged from the ejector 21 is measured by the ozone concentration meter 18, and a control signal is sent to the control device 19. When the ozone concentration in the ozone-containing gas is higher than the set ozone concentration, a control signal is sent from the control device 19 to the ozone gas flow rate adjusting device 12 and the gas ejector 21, and the ozone gas flow rate adjusting device 12 is slightly closed and the gas ejector. The nozzle diameter inside 21 becomes larger, and the flow rate of the compressed gas passing through the nozzle becomes slower. As a result, when the pressure in the adsorption / desorption tower 4 increases, the amount of ozone extracted decreases, and the ozone concentration in the ozone-containing gas decreases.

  On the other hand, when the ozone concentration in the ozone-containing gas is lower than the set ozone concentration, a control signal is sent from the control device 19 to the ozone gas flow rate adjusting device 12 and the gas ejector 21, and the ozone gas flow rate adjusting device 12 is slightly opened. The control signal is also sent to the gas ejector 21, the nozzle diameter inside the gas ejector 21 is reduced, the flow rate of the compressed gas passing through the nozzle is increased, and the pressure in the adsorption / desorption tower 4 is lowered. Therefore, the amount of ozone extracted increases, and the ozone concentration in the ozone-containing gas increases.

At this time, the control device 19 sends a control signal to the compressed gas production machine 23 in accordance with the change in the amount of ozonated oxygen flowing into the gas ejector 21 and sets the flow rate of the ozone-containing gas supplied to the ozone consuming object 15 to the set flow rate. To match.
Thereby, since the bypass piping 22 and the two-way flow rate control valve 24 can be eliminated, the number of parts is reduced, and the apparatus configuration can be simplified.

In the above reference example, the ozone concentration in the ozone-containing gas discharged from the gas ejector 21 is measured, and the ozone-containing gas containing a certain concentration of ozone is supplied to the ozone consuming object 15 by a certain amount using the control device 19. The case of supplying was shown.
However, the ozone gas flow control device 12, the gas ejector 21, and the compressed gas production machine 23 are driven by a timer (not shown), and an ozone-containing gas containing a certain concentration of ozone is supplied to the ozone consuming object 15 by a certain amount. You may do it. In this case, the control accuracy of the ozone concentration in the ozone-containing gas is slightly deteriorated, but the equipment configuration is simplified and the facility cost can be further reduced.

Reference Example 4
Although not particularly considered with respect to the upper Symbol released to effectively utilize the cold of liquid oxygen and liquid nitrogen produced from the cryogenic separation unit 20 in each reference example, in the present embodiment using a cold cooling of the ozone generator 1.
FIG. 7 is a block diagram showing an ozone storage device according to Reference Example 4 of the present invention, in which the same reference numerals as those in FIG. 1 denote the same or corresponding parts. In the figure, reference numeral 25 denotes a gas cooler that extracts the latent heat of vaporization of liquid oxygen or liquid nitrogen. The gas cooling device 25 vaporizes the liquid oxygen produced by the cryogenic separation device 20 and places it in the circulation system, and also vaporizes the liquid nitrogen produced by the cryogenic separation device 20 to compress the liquid oxygen. The gas cooler 25-2 is a gas, and the cooler 25-3 cools the ozone generator 1 by the cold heat released by liquid oxygen and liquid nitrogen.

Next, the operation of this reference example will be described. This operation includes two operations, an operation for adsorbing ozone and an operation for desorbing ozone. Since the operation for desorbing ozone is the same as that in Reference Example 1 described above, it is omitted here.
In performing the ozone adsorption operation, first, air is supplied to the cryogenic separator 20 and the air is liquefied to produce liquid oxygen, liquid nitrogen, or the like. The produced liquid oxygen is vaporized by the gas cooler 25-1 and supplied to the circulation system as needed so that the pressure in the circulation system is always constant. At this time, the pressure in the circulation system is normally maintained at 1.5 to 2.0 kg / cm 2.

  On the other hand, the liquid nitrogen produced simultaneously with the liquid oxygen is vaporized by the gas cooler 25-2 and stored as a compressed medium gas used at the time of desorption. The cooler 25-3 cools the discharge part of the ozone generator 1 by the cold heat released by liquid oxygen and liquid nitrogen. For this reason, the heat medium of the ozone generator 1 is cooled, and ozone generation is performed efficiently and stably. Note that water, brine, or an antifreeze liquid such as ethylene glycol is normally used as a heat medium for cooling the discharge part of the ozone generator 1.

  In this way, when oxygen is supplied into the circulation path and the switching valves 8-3 and 8-4 are opened, oxygen is circulated through the circulation system path by the circulation blower 3, and the oxygen is generated by the ozone generator. While passing through one discharge gap, part of oxygen is converted into ozone by silent discharge to become ozonated oxygen, and this ozonated oxygen is conveyed to the adsorption / desorption tower 4.

  The adsorbent in the adsorption / desorption tower 4 selectively adsorbs ozone from ozonated oxygen, and the remaining oxygen is returned to the circulation blower 3 via the switching valve 8-3. The oxygen consumed as ozone is replenished by the liquid oxygen produced by the cryogenic separator 20 being vaporized by the gas cooler 25-1. At this time, since the adsorbent has a property that the adsorption capacity of ozone increases as the adsorbent is cooled, the cooling temperature is normally kept at −40 ° C. or lower by the cold heat source 5. Further, it is desirable to select an adsorbent having a low decomposition rate when it comes into contact with ozone, and examples thereof include silica gel, porous material impregnated with activated alumina and fluorocarbon.

  Thereby, energy required in order to cool the discharge part of the ozone generator 1 can be reduced, and electric power saving can be implement | achieved compared with the past at the time of adsorption | suction operation.

Further, as shown in Reference Example 1, the oxygen vaporized in the gas cooler 25-1 can be used as a raw material oxygen for making ozonized oxygen, while it was vaporized in the gas cooler 25-2. Nitrogen is temporarily stored in the gas storage device 26 under pressure until the desorption operation starts as shown in FIG. Then, the nitrogen stored under pressure is transmitted through the gas flow meter 27 as shown in FIG. 8 through the gas flow meter 27, or through the gas flow meter 27 as shown in FIG. It can be used as a compressed medium gas for driving the gas ejector 21. Therefore, the liquid nitrogen produced by the cryogenic separator 20 can be used effectively.

  As a result, it is possible to reduce the power required for producing the medium gas or the compressed medium gas used at the time of desorption and to eliminate the need for the medium gas production machine 16 or the compressed gas production machine 23, thereby reducing the equipment cost. Can do.

Reference Example 5
In Reference Example 4 , the liquid oxygen and liquid nitrogen produced in the cryogenic separator 20 are vaporized by the gas cooler 25, and the discharge part of the ozone generator 1 is changed by the cold heat released from the liquid oxygen by the gas cooler 25. The example which cools the heat carrier to cool was shown. However, as shown in FIG. 10, the adsorption / desorption tower 4 may be used as a part of the cold heat required for cooling the adsorption / desorption tower 4 by using the cold heat released by the gas cooler 25 when the liquid oxygen and liquid nitrogen are vaporized. It is possible to reduce the energy required for cooling the battery.
Further, there is an effect that it is possible to realize power saving of the refrigerator that is the cold source 5 during the adsorption operation.

  Further, during the adsorption operation, even if the refrigerator serving as the cold heat source 5 is in an emergency stop, the adsorption / desorption tower 4 rapidly rises in temperature due to the cold heat of the liquid oxygen and liquid nitrogen, and the ozone desorption is promoted. There is an effect that the ozone concentration in 4 becomes high and the adsorption / desorption tower 4 is prevented from being in a dangerous state, and ozone can be stored safely.

Reference Example 6
Although in the above SL respective reference examples are provided cooling source 5 for cooling the desorption tower 4, the ozone storage apparatus according to the present embodiment, as shown in FIG. 11, has the ozonized oxygen released from the ozone generator 1 A heat exchanger is provided for exchanging warm heat and cold heat of the oxygen-containing gas released from the adsorption / desorption tower 4.

Next, the operation will be described. This operation includes two operations, an operation for adsorbing ozone and an operation for desorbing ozone. However, the operation for desorbing ozone is the same as in Reference Example 1 described above, and is omitted here to adsorb ozone. The operation will be described. Oxygen is supplied from the oxygen supply source 2 so that the inside of the circulation system is always at a constant pressure.

  The pressure at this time is normally maintained at 1.5 to 2.0 kg / cm 2. When oxygen is circulated in the circulation system by the circulation blower 3 with the switching valves 8-3 and 8-4 opened, a part of oxygen is ozone by silent discharge while passing through the discharge gap of the ozone generator 1. Converted into ozonated oxygen. When the ozonized oxygen is transported to the adsorption / desorption tower 4, the adsorbent in the adsorption / desorption tower 4 selectively adsorbs ozone over the ozonated oxygen, and the remaining oxygen passes through the switching valve 8-3 to the circulation blower 3 Will be returned. Note that oxygen consumed as ozone is replenished from the oxygen supply source 2.

  The ozonized oxygen released from the ozone generator 1 passes through the discharge space, so that the gas temperature becomes higher than when it is introduced to the entrance of the ozone generator 1, while from the adsorption / desorption tower 4. Since the released oxygen passes through the cooled adsorbent such as silica gel, the gas temperature becomes lower than when it is led to the entrance of the adsorption / desorption tower 4.

  Therefore, the heat exchanger 28 exchanges the cold and warm heat of these gases. As a result, when ozone is adsorbed to the adsorption / desorption tower 4, it is possible to reduce the warm heat released from the ozonized oxygen, and to reduce the cold heat taken by the oxygen gas from the adsorbent in the adsorption / desorption tower 4. effective. In addition, there is an effect that energy necessary for cooling the adsorption / desorption tower 4 to -40 ° C. or lower can be reduced.

Reference Example 7
Although in the above SL each Reference Example was placed in special consideration for pressure regulation of the circulatory system, it performs pressure adjustment provided pressure regulator into the circulatory system in this embodiment. FIG. 12 is a block diagram showing an ozone storage device according to this reference example, in which 29 is a pressure adjusting device for adjusting the pressure in the circulation pipe connecting the ozone generator 1 and the adsorption / desorption tower 4, and 30 is an adsorption / desorption tower. 4 is an upstream ozone detector that detects ozone leaking out from the adsorption / desorption tower 4, and 31 is a controller that receives a control signal from the ozone detector 30 and sends a control signal to the pressure regulator. It is.

Next, the operation will be described. This operation includes two operations, an operation for adsorbing ozone and an operation for desorbing ozone. However, the operation for desorbing ozone is the same as in Reference Example 1 described above, and is omitted here to adsorb ozone. The operation will be described. Oxygen is supplied from the oxygen supply source 2 through the pressure control device 29 so that the pressure in the circulation pipe L1 connecting the ozone generator 1, the circulation blower 3, and the adsorption / desorption tower 4 becomes a certain pressure.

  When oxygen is circulated through the circulation pipe L1 by the circulation blower 3 with the switching valves 8-3 and 8-4 opened, the oxygen is silently discharged while the oxygen passes through the discharge gap of the ozone generator 1. As a result, a part is converted into ozone to become ozonated oxygen, and this ozonated oxygen is conveyed to the adsorption / desorption tower 4. The adsorbent in the adsorption / desorption tower 4 selectively adsorbs ozone from ozonated oxygen, and the remaining oxygen is returned to the circulation blower 3 via the switching valve 8-3. The oxygen consumed as ozone is replenished from the oxygen supply source 2.

  When ozone is adsorbed to some extent by the adsorbent in the adsorption / desorption tower 4, the adsorption breakthrough phenomenon of the adsorbent begins to occur, and ozone leaks from the adsorption / desorption tower 4. When ozone leaks from the adsorption / desorption tower 4 in this way, the ozone detector 30 provided on the upstream side of the circulation pipe L1 connecting the adsorption / desorption tower 4 senses the ozone leak, A control signal is sent from the detector 30 to the controller 31.

  The controller 31 sends a control signal to the pressure adjusting device 29 to increase the pressure in the circulation pipe L1. At this time, the pressure in the circulation pipe L1 is increased so that the ozone partial pressure in the ozonized oxygen supplied to the adsorption / desorption tower 4 constantly increases. This operation is repeated until the final pressure is reached.

Next, an experimental example of the effect of pressure in the adsorption / desorption tower 4 when ozone is adsorbed and stored will be described with reference to FIGS.
FIG. 13 is a diagram showing the relationship between the ozone adsorption amount and the pressure of ozonized oxygen fed into the adsorption / desorption tower 4. From the relationship shown in FIG. 13, it was recognized that the ozone adsorption amount increased as the ozonized oxygen pressure increased. On the other hand, FIG. 14 is a graph showing the relationship between ozone generation efficiency and supply pressure of raw material oxygen. From the relationship shown in FIG. 14, it was recognized that the generation efficiency of ozone decreases as the supply pressure of the raw material oxygen increases.

  Therefore, it can be seen that when the pressure in the circulation pipe L1 is increased, ozone can be efficiently stored in the adsorbent, but the amount of power required to generate ozone increases. That is, as shown in the time variation of the ozone generation power consumption in FIG. 15, the final ozone adsorption amount is the same, but at the time of the adsorption start, rather than performing the adsorption operation with the target pressure set from the beginning of the adsorption. If the adsorption operation is performed by gradually increasing the pressure from the beginning, the amount of electric power required for ozone generation can be reduced during the adsorption operation time period.

  In addition, the final ultimate pressure when performing the adsorption operation is that if the pressure in the adsorption / desorption tower 4 is set too high, the oxygen partial pressure also increases, so the amount of oxygen adsorbed on the adsorbent increases and ozone adsorption occurs. Since the rate of increase in quantity is dull, it is most efficient to set the absolute pressure to about 4 ± 2 kg / cm 2.

  Therefore, storing ozone in such a manner that the partial pressure of ozone in the ozonized gas supplied to the adsorption / desorption tower 4 is increased is effective in reducing energy required for storing ozone.

Reference Example 8
In the reference example 7 , the ozone leaking out from the adsorption / desorption tower 4 is detected by the ozone detector 30, and the pressure regulator 29 gradually increases the pressure in the gas circulation pipe L1. As shown in FIG. 16, the same effect can be obtained even if the pressure adjusting device 29 is driven by the timer 32 and the pressure in the circulation path gradually increases as time elapses.

  The same effect can be obtained by operating the pressure adjusting device 29 so as to increase the pressure in accordance with a program prepared in advance. Furthermore, as a result, the ozone detector 30 and the controller 31 can be eliminated, and there is an effect that equipment costs can be reduced.

Reference Example 9
In the above reference example 8 , the pressure in the circulation system is made constant, but in this reference example, the flow rate of the gas flowing in the circulation pipe L1 is adjusted. FIG. 17 is a block diagram showing an ozone storage device according to this reference example. In the figure, the same reference numerals as those in FIG. 16 denote the same or corresponding parts. In the figure, 33 is a flow rate control device for adjusting the flow rate of gas (oxygen) flowing in the circulation pipe L1.

Next, the operation of this reference example will be described. This operation includes two operations, an operation for adsorbing ozone and an operation for desorbing ozone. However, the operation for desorbing ozone is the same as in Reference Example 1 described above, and is omitted here to adsorb ozone. The operation will be described. Oxygen is supplied from the oxygen supply source 2 so that the inside of the circulation pipe L1 is always at a constant pressure.

  The pressure at this time is normally maintained at 1.5 to 2.0 kg / cm 2. When oxygen is circulated through the circulation pipe L1 by the circulation blower 3 with the switching valves 8-3 and 8-4 being opened, the oxygen is partially discharged by silent discharge while passing through the discharge gap of the ozone generator 1. Is converted into ozone to become ozonated oxygen, which is transported to the adsorption / desorption tower 4. The adsorbent in the adsorption / desorption tower 4 selectively adsorbs ozone from ozonated oxygen, and the remaining oxygen is returned to the circulation blower 3 via the switching valve 8-3. The oxygen consumed as ozone is replenished from the oxygen supply source 2.

  When ozone is adsorbed to some extent by the adsorbent in the adsorption / desorption tower 4, the adsorption breakthrough phenomenon of the adsorbent begins to occur, and ozone leaks from the adsorption / desorption tower 4. When ozone leaks out from the adsorption / desorption tower 4 in this way, the ozone detector 30 detects the leakage of ozone and sends a control signal from the ozone detector 30 to the flow rate control device 33 to enter the circulation pipe L1. The flow rate of the flowing gas is decreased, and the ozone concentration in the ozonized oxygen reaching the entrance of the adsorption / desorption tower 4 is increased. At this time, the flow rate in the circulation pipe L1 is gradually decreased so that the ozone partial pressure in the ozonized oxygen supplied to the adsorption / desorption tower 4 constantly increases. This operation is repeated until the final ozone concentration is reached.

Next, an experimental example will be described with reference to FIGS. 18 and 19 regarding the influence of the ozone concentration in the ozonized oxygen supplied to the adsorption / desorption tower 4 when ozone is adsorbed and stored.
FIG. 18 is a graph showing the relationship between the ozone adsorption amount and the ozone concentration of the ozonized gas sent to the adsorption / desorption tower 4. From this figure, it was recognized that the ozone adsorption amount increased as the ozone concentration increased.

  On the other hand, FIG. 19 is a graph showing the relationship between the ozone generation efficiency and the ozone concentration in the generated ozonated oxygen. From this figure, it was recognized that the ozone generation efficiency decreased as the ozone concentration in the ozonated oxygen was increased. Therefore, when the ozone concentration in the ozonized oxygen reaching the entrance of the adsorption / desorption tower 4 is increased, ozone can be efficiently stored in the adsorbent, but the amount of electric power necessary to generate ozone may increase. Recognize.

  That is, as shown in the time variation of the ozone generation power consumption in FIG. 20, the final ozone adsorption amount is the same, but the adsorption start is performed rather than the adsorption operation is performed by setting the target ozone concentration from the beginning of the adsorption. When the adsorption operation is performed by gradually increasing the ozone concentration from the time, the amount of electric power required for generating ozone during the adsorption operation time period can be reduced.

  Therefore, storing ozone in such a manner that the partial pressure of ozone in the ozonized oxygen supplied to the adsorption / desorption tower 4 is increased stepwise has an effect of reducing energy required for storing ozone.

  In the above reference example, an example in which the ozone concentration is detected and the ozone concentration supplied to the adsorption / desorption tower 4 is gradually increased using the flow rate control device 33 is shown. The same effect can be obtained even if the flow rate of the gas flowing in the circulation pipe L1 is gradually decreased as time elapses.

  The same effect can be obtained by operating the flow rate control device 33 so as to decrease the gas flow rate according to a program prepared in advance. Furthermore, the use of a timer (not shown) can eliminate the ozone detector 30 and can reduce the equipment cost.

Reference Example 10
In Reference Example 10 , when ozone leaking out from the adsorption / desorption tower 4 is detected by the ozone detector 30, the flow rate control device 33 gradually decreases the flow rate of gas flowing into the circulation pipe L1 to increase the ozone concentration. An example of However, as shown in FIG. 21, a power control device 34 is provided to increase the power supplied to the ozone generator 1 by sensing ozone leaking from the adsorption / desorption tower 4 with the ozone detector 30. The same effect can be obtained by gradually increasing the concentration of ozone supplied to the adsorption / desorption tower 4 by increasing the generation of ozonized oxygen as the electric power increases.

  In this reference example, an example in which the ozone concentration is sensed and the ozone concentration supplied to the adsorption / desorption tower 4 is gradually increased using the power control device 34 is shown. The same effect can be obtained even if the ozone concentration in the ozonized oxygen supplied to the adsorption / desorption tower 4 is gradually increased as time passes.

  Further, the same effect can be obtained by increasing the power control device 34 in accordance with a program prepared in advance so as to increase the ozone concentration in the ozonated oxygen.

Embodiment 1 FIG.
In the reference examples 7 to 10 , the oxygen supply source 2 supplies oxygen to the circulation system, but the ozone storage device according to the present embodiment supplies oxygen to the adsorption / desorption tower 4 while adjusting the flow rate of oxygen during ozone desorption. Supply. FIG. 22 is a block diagram showing an ozone storage device according to the present embodiment. In the figure, the same reference numerals as those in FIG. 12 denote the same or corresponding parts. In the figure, 35 is an oxygen flow rate control device, and this oxygen flow rate control device 35 adjusts the flow rate of oxygen supplied from the oxygen supply source 2 to the adsorption / desorption tower 4 during ozone desorption.

Next, the operation of the present embodiment will be described. This operation includes two operations, an operation for adsorbing ozone and an operation for desorbing ozone. However, the operation for adsorbing ozone is the same as in Reference Example 1 described above, and is omitted here. When the adsorbent adsorbs up to the ozone saturated adsorption amount, the operation proceeds to the desorption operation. In the desorption operation, the operation of the ozone generator 1, the circulation blower 3, and the cold heat source 5 is stopped, and the switching valves 8-1, 8-2, 8-3, and 8-4 are closed.

  Thereafter, first, the gas suction pump 13 starts operating, the ozone gas flow rate adjusting device 12 is gradually opened, and ozone is supplied to the gas mixer 17. The gas mixer 17 is also supplied with a medium gas from the medium gas production machine 16 so as to be mixed therewith, and is mixed with ozone in the gas mixer 17 and sent to the ozone consuming object 15 as an ozone-containing gas.

  At the initial stage of desorption when ozone is sufficiently discharged from the adsorption / desorption device, the ozone concentration in the ozone-containing gas discharged from the gas mixer 17 is measured by the ozone concentration meter 18 and a control signal is sent to the control device 19. When the ozone concentration is higher than the set ozone concentration, a control signal is sent from the control device 19 to the ozone gas flow rate adjusting device 12, the ozone gas flow rate adjusting device 12 is closed a little, and a control signal is also sent to the gas suction pump 13. As a result, the amount of ozone released from the adsorption / desorption tower 4 is reduced and the ozone concentration in the ozone-containing gas is lowered.

On the other hand, when the ozone concentration is lower than the set ozone concentration, a control signal is sent from the control device 19 to the ozone gas flow rate adjusting device 12, the ozone gas flow rate adjusting device 12 is opened a little, and a control signal is also sent to the gas suction pump 13. By increasing the force for extracting ozone from the adsorption / desorption tower 4, the amount of ozone released from the adsorption / desorption tower 4 increases, and the ozone concentration in the ozone-containing gas increases. At this time, the control device 19 sends a control signal to the medium gas production machine 16 in accordance with the change in the amount of ozone flowing into the gas mixer 17 to set the flow rate of the ozone-containing gas supplied to the ozone consuming object 15 to the set flow rate. It is matched.
As a result, an ozone-containing gas containing a constant concentration of ozone can be supplied to the ozone consuming object 15 by a fixed amount.

  In the second half of the desorption, when the amount of ozone drawn from the adsorption / desorption tower 4 by the gas suction pump 13 decreases and the gas suction capacity of the gas suction pump 13 reaches the maximum, the oxygen flow rate control device 35 begins to gradually open, supplying oxygen Oxygen begins to be supplied from the source 2 to the adsorption / desorption tower 4. When oxygen begins to be supplied into the adsorption / desorption tower 4, a gas substitution phenomenon occurs, and ozone desorption from the adsorption / desorption tower 4 becomes active again.

  At this time, the desorption amount of ozone can be controlled by the flow rate of oxygen. That is, in order to make the flow rate of the ozone-containing gas supplied to the ozone consuming object 15 constant, the flow rate of the medium gas sent from the medium gas production machine 16 to the gas mixer 17 is gradually decreased, and the adsorption / desorption tower By gradually increasing the amount of oxygen supplied to 4, an ozone-containing gas containing a constant concentration of ozone can be continuously supplied to the ozone consuming object 15 by a certain amount.

  In this way, a gas purge system in which oxygen is simply fed into the adsorption / desorption tower 4 by supplying oxygen to the adsorption / desorption tower 4 and desorbing ozone while keeping the inside of the adsorption / desorption tower 4 in a negative pressure state. As compared with the above, the amount of oxygen to be used can be reduced, the cooling heat deprived of oxygen from the adsorption / desorption tower 4 can be reduced, and the power required for supplying oxygen to the adsorption / desorption tower 4 can be reduced. effective.

  In addition, the power for driving the gas suction pump 13 can be reduced and the suction capacity of the gas suction pump 13 can be reduced as compared with a gas suction method in which the gas suction pump 13 only takes out ozone. Thus, the gas suction pump 13 can be reduced in size.

In the above embodiment, the ozone concentration in the ozone-containing gas supplied to the ozone consuming object 15 is detected by the ozone concentration meter 18 and a control signal is sent to the control device 19, which controls the ozone gas flow rate adjustment device 12, gas An example in which the operation of the suction pump 13, the medium gas production machine 16, and the oxygen flow rate control device 35 is changed to supply a certain amount of ozone-containing gas containing a constant concentration of ozone to the ozone consuming object 15. However, the same effect can be obtained by operating the ozone gas flow control device 12, the gas suction pump 13, the medium gas production machine 16, and the oxygen flow control device 35 according to a preset program.
This also eliminates the ozone concentration meter 18 and the control device 19 and has the effect of reducing equipment costs.

  Further, in the present embodiment, the ozone concentration in the ozone-containing gas supplied to the ozone consuming object 15 is detected by the ozone concentration meter 18 and a control signal is sent to the control device 19. When the operation of the gas suction pump 13, the medium gas production machine 16, and the oxygen flow rate control device 35 is changed, an ozone-containing gas containing a constant concentration of ozone is supplied to the ozone consuming object 15 by a certain amount. An example of was shown.

  However, as shown in FIG. 5, the suction pump 13 constituting the ozone releasing means is made to absorb and desorb the ozone gas flow rate control device 12 for controlling the amount of ozone released from the adsorption / desorption tower 4 and the adsorption / desorption tower 4 in a reduced pressure state. The medium gas production machine 16 and the gas mixer 17 constituting the ozone concentration control means are arranged in parallel with the gas ejector 21 as shown in FIG. A bypass pipe 22 that connects the inlet / outlet of the gas ejector 21, a compressed gas production machine 23 that produces a compressed medium gas that drives the gas ejector 21, and two directions that adjust the flow ratio of the compressed medium gas flowing through the gas ejector 21 and the bypass pipe 22. It can replace with the flow control valve 24, and can also comprise.

As a result, the control device 19 by sending a control signal in response to a control signal from the ozone concentration meter 18 ozone gas flow regulating device 12, the compressed gas production unit 23 and the two-way flow control valve 24, in the same manner as in Reference Example 2 An ozone-containing gas containing a constant concentration of ozone can be supplied to the ozone consuming object 15 by a certain amount.

  In addition, since oxygen is supplied to the adsorption / desorption tower 4, it is possible to prevent the adsorbent filled in the adsorption / desorption tower from adsorbing objects other than oxygen and to prevent the performance of the adsorbent from deteriorating. It is possible to extend the life of the adsorbent.

Embodiment 2 FIG.
In the first embodiment, an example in which oxygen is supplied from the oxygen supply source 2 to the adsorption / desorption tower 4 at the time of desorption has been shown. However, as shown in FIG. A similar effect can be obtained by supplying cooling oxygen produced by vaporizing the produced liquid oxygen to the adsorption / desorption tower 4 at the time of desorption.

  Further, since the cooled oxygen is supplied to the adsorption / desorption tower 4, it is possible to prevent the heat from being absorbed from the adsorption / desorption tower 4, the temperature inside the adsorption / desorption tower 4 is prevented from rising, and the operation moves to the adsorption operation again. In this case, the energy required for cooling the adsorption / desorption tower 4 can be reduced.

Reference Example 11
In the second embodiment, oxygen separated from the air and cooled by the cryogenic separator 20 is supplied to the adsorption / desorption tower 4 to prevent the temperature in the adsorption / desorption tower 4 from rising. In this reference example, a part of the oxygen recirculated from the adsorption / desorption tower 4 is cooled and supplied to the adsorption / desorption tower 4.

  FIG. 24 is a block diagram showing an ozone storage device according to this reference example. In the figure, the same reference numerals as those in FIG. 22 denote the same or corresponding parts. In the figure, 36 is a gas cooling pipe that is arranged downstream of the circulation blower 3 and in parallel with the ozone generator 1, and 37 is a part of oxygen recirculated to the ozone generator 1 through the circulation blower 3. A cooling device 38 that is introduced through the cooling pipe 36 to cool it and supplies it to the adsorption / desorption tower 4 is a flow meter that adjusts the flow rate of oxygen flowing through the gas cooling pipe 36.

Next, the operation of this reference example will be described. This operation includes two operations, an operation for adsorbing ozone and an operation for desorbing ozone. However, the operation for desorbing ozone is the same as in Reference Example 1 described above, and is omitted here to adsorb ozone. The operation will be described.

  Oxygen is supplied from the oxygen supply source 2 so that the inside of the circulation system is always at a constant pressure. The pressure at this time is normally maintained at 1.5 to 2.0 kg / cm 2. When oxygen is circulated in the circulation system by the circulation blower 3 with the switching valves 8-3 and 8-4 being opened, the oxygen is discharged by silent discharge while oxygen passes through the discharge gap of the ozone generator 1. A part is converted into ozone to become ozonated oxygen, which is conveyed to the adsorption / desorption tower 4. The adsorbent in the adsorption / desorption tower 4 selectively adsorbs ozone from ozonated oxygen, and the remaining oxygen is branched to the circulation pipe L1 and the cooling pipe 36 via the switching valve 8-3 and the circulation blower 3. To the confluence. The oxygen consumed as ozone is replenished from the oxygen supply source 2.

  At the branch point, oxygen having a flow rate that matches the flow rate set in the flow meter 38 flows into the cooling pipe 36, and the remaining oxygen flows through the circulation pipe L 1 and is returned to the ozone generator 1. The oxygen that has flowed into the cooling pipe 36 is sufficiently cooled by the cooling device 37 and guided to the junction with the circulation pipe L1 near the entrance of the adsorption / desorption tower 4.

At the junction, the ozonated oxygen produced by the ozone generator 1 and the cooled oxygen are mixed and supplied as cooled ozonated oxygen into the adsorption / desorption tower 4.
At this time, the cooled ozonized oxygen cools the adsorbent filled in the adsorption / desorption tower 4, and after the ozone in the ozonized oxygen is adsorbed to the cooled adsorbent, the excess oxygen is adsorbed / desorbed. Released from the tower 4.

  Thereby, the adsorbent filled in the adsorption / desorption tower 4 can be directly cooled, the adsorbent can be efficiently cooled, and the energy required for cooling the adsorption / desorption tower 4 during the adsorption operation can be reduced. There is.

  In the above reference example, the oxygen released from the adsorption / desorption tower 4 is separated into ozone generation and adsorbent cooling, and the adsorption operation is performed efficiently. A similar effect can be obtained by providing a cooling device 35 at the outlet of the ozone generator 1 to cool the entire gas flowing in the circulation pipe L1 and supplying the cooled ozonated oxygen to the adsorption / desorption tower 4. can get. However, energy required to cool all the ozonated oxygen heated by the ozone generator 1 is required, and only a part of the ozonated oxygen shown in the reference example is heated by the ozone generator 1. In comparison, a large amount of energy is required.

Reference Example 12
In Embodiments 1 to 2 and Reference Examples 1 to 11 described above, the ozone storage device in the case where there is one adsorption / desorption tower 4 is described. In this reference example, three adsorption / desorption towers 4 are connected in series, The oxygen released from the adsorption / desorption tower 4 flows into the next adsorption / desorption tower 4, and ozone is adsorbed by the adsorption / desorption tower 4.

  FIG. 25 is a block diagram showing an ozone storage device according to this reference example. In the figure, the same reference numerals as those in FIG. 24 denote the same or corresponding parts. In the figure, reference numerals 4-1 to 4-3 denote first to third adsorption / desorption towers, and the oxygen-containing sides of the inner cylinders of the adsorption / desorption towers 4-1 to 4-3 are switching valves 40-1 to 40-. 3 is connected to the oxygen outlet side of the ozone generator 1 by piping.

Further, the ozonized oxygen outlet side of each of the adsorption / desorption towers 4-1 to 4-3 is connected to the ozonized oxygen outlet side of the ozone generator 1 through a pipe provided with a circulation blower 3 in the middle of the switching valves 8-7 to 8-10. It is connected. Accordingly, oxygen is circulated through the switching valves 40-1 to 40-2, 8-7 to 8-10 and the circulation blower 3 in the inner cylinders of the adsorption / desorption towers 4-1 to 4-3.

  The coolant inlet side and outlet side of the outer cylinder of each of the adsorption / desorption towers 4-1 to 4-3 are connected to the cooling heat source 5 through the switching valves 8-1 to 8-6 and through the circulation pipe L2. Accordingly, the coolant is circulated in the outer cylinders of the adsorption / desorption towers 4-1 to 4-3 through the switching valves 8-1 to 8-6 and the circulation pipe L2.

  The outlet of the switching valve 8-10 provided on the ozonized oxygen outlet side of the first adsorption / desorption tower 4-1, and the outlet of the switching valve 8-13 provided on the oxygen inlet side of the second adsorption / desorption tower 4-2. A pipe 39-2 provided with a midway switching valve 40-2 is connected to the side.

  The outlet of the switching valve 8-8 provided on the ozonized oxygen outlet side of the second adsorption / desorption tower 4-2 and the outlet of the switching valve 8-14 provided on the oxygen inlet side of the third adsorption / desorption tower 4-3. A pipe 39-1 provided with a midway switching valve 40-1 is connected to the side.

  Switching valves 8-11 and 8-12 are respectively provided after the connection point between the circulation pipe L1 and the pipe 39-2 and after the connection point between the circulation pipe L1 and the pipe 39-1. These switching valves 8-11 and 8-12 are normally open, and oxygen released from the switching valves 8-10 and 8-11 is circulated to the ozone generator 1 through a circulation blower.

When the switching valve 40-2 is opened, the switching valve 8-11 is closed and the ozonated oxygen released from the switching valve 8-10 is supplied to the second adsorption / desorption tower 4-2.
Further, when the switching valve 40-1 is opened, the switching valve 8-12 is closed and the ozonized oxygen released from the switching valve 8-8 is supplied to the third adsorption / desorption tower 4-3.

Next, the operation of this reference example will be described. This operation includes two operations: an operation for adsorbing ozone and an operation for desorbing ozone.
First, the operation | movement which adsorb | sucks ozone is demonstrated. Oxygen is supplied from the oxygen supply source 2 so that the inside of the circulation system is always at a constant pressure. The pressure at this time is normally maintained at 1.5 to 2.0 kg / cm 2.

When oxygen is circulated through the circulation pipe L1 by the circulation blower 3 with the switching valves 8-9, 8-10, 8-11 and 8-12 open, oxygen passes through the discharge gap of the ozone generator 1. In the meantime, a part of oxygen is converted into ozone by silent discharge to become ozonated oxygen, and this ozonated oxygen is first transported to the first adsorption / desorption tower 4-1. The adsorbent in the first adsorption / desorption tower 4-1 selectively adsorbs ozone from ozonated oxygen, and the remaining oxygen passes through the switching valves 8-10, 8-11 and 8-12 to the circulation blower 3. Will be returned. The oxygen consumed as ozone is replenished from the oxygen supply source 2.

  Next, when the adsorption operation in the first adsorption / desorption tower 4-1 is almost finished and ozone leaks out from the first adsorption / desorption tower 4-1, the switching valve 8-11 is closed and the switching valve is closed. 8-8 and 40-2 are opened, and ozonized oxygen released from the first adsorption / desorption tower 4-1 is supplied to the second adsorption / desorption tower 4-2, and the adsorption operation is started.

  Further, when the adsorption operation in the second adsorption / desorption tower 4-2 is almost finished and ozone leaks out from the second adsorption / desorption tower 4-2, the switching valve 8-12 is closed and the switching valve 8 is closed. -7 and 40-1 are opened, and the ozonated oxygen released from the second adsorption / desorption tower 4-2 is supplied to the third adsorption / desorption tower 4-3 to start the adsorption operation. And this operation | movement is repeated and ozone is stored one after another by the adsorption / desorption tower 4 with two or more towers. Thereby, there is an effect that the generated ozone can be efficiently stored.

  Further, the first adsorption / desorption tower 4-1 is in an equilibrium adsorption state (the ozone concentration in the ozonated oxygen released from the first adsorption / desorption tower 4-1 is close to the ozone concentration in the supplied ozonized oxygen). And the switching valves 8-9, 8-10 and 40-2 are closed and the switching valve 8-13 is opened, and the second adsorption / desorption tower 4-2 is subjected to ozonated oxygen. Will be supplied directly.

  Then, this operation is repeated, and ozone is stored in a plurality of adsorption / desorption towers 4-1 to 4-3. By storing ozone in this way, pressure loss when supplying ozonated oxygen to the adsorption / desorption towers 4-1 to 4-3 can be reduced, the load on the circulation blower 3 is reduced, and ozone adsorption is achieved. There is an effect that energy used during operation can be reduced.

  At this time, whether the adsorption / desorption towers 4-1 to 4-3 have reached the equilibrium adsorption state is determined by monitoring the ozone concentration in the ozonized oxygen released from the adsorption / desorption towers 4-1 to 4-3. Alternatively, the time to reach the equilibrium adsorption state may be checked in advance, and ozonized oxygen may be directly supplied using a timer (not shown).

  Next, the serial connection storage method according to this reference example will be described. The amount of ozone adsorbed when ozone leaks from the adsorption / desorption tower 4 (the adsorption breakthrough time has been reached) is 40% of the ozone adsorption quantity when the adsorbent in the adsorption / desorption tower 4 reaches adsorption equilibrium. It was found from experiments that Therefore, if ozone is adsorbed until the adsorption equilibrium is reached, the adsorption efficiency of ozone adsorbed by the adsorbent per unit weight can be increased, and the adsorption / desorption tower 4 can be made compact. However, since the amount of ozone discharged from the adsorption / desorption tower 4 without being used for adsorption is increased, the use efficiency of ozone is reduced.

  Therefore, the ozone was absorbed and stored in the second adsorption / desorption tower 4-2 using the ozonated oxygen leaked from the first adsorption / desorption tower 4-1, as in this reference example. Since ozone can be used efficiently and ozone can be adsorbed until the adsorbent packed in the first adsorption / desorption tower 4-1 reaches an equilibrium adsorption state, adsorption of ozone adsorbed on the adsorbent per unit weight Efficiency can be increased. That is, ozone leaking out from the last adsorption / desorption tower 4 cannot be used for adsorption as in the case of one adsorption / desorption tower 4, but the generated ozone can be efficiently stored. Moreover, the adsorption / desorption tower 4 can be made small by improving the adsorption efficiency of ozone.

When performing adsorption, it is energetically efficient to start cooling the adsorption / desorption tower 4 immediately before the start of ozone injection. However, until the temperature in the adsorption / desorption tower 4 reaches the set temperature, the ozone concentration in the ozonized oxygen released from the adsorption / desorption tower 4 after ozone adsorption is always kept at a predetermined concentration or less by adsorbing and storing ozone. It is important to.
The adsorption / desorption tower 4 that has been charged with ozone is kept cooled to the set temperature until the adsorption operation is completed.

  When the ozone concentration in the ozonized oxygen released from the third adsorption / desorption tower 4-3 in the final stage becomes equal to or higher than the set concentration, the operation proceeds to the desorption operation. In the desorption operation, the operation of the ozone generator 1, the circulation blower 3, and the cold source 5 is stopped, and the switching valves 8-1, 8-2, 8-7, and 8-14 are closed. Thereafter, the gas suction pump 13 starts to operate, the ozone gas flow rate adjusting device 12 is gradually opened, and ozone is supplied to the gas mixer 17. The gas mixer 17 is also supplied with the medium gas from the medium gas production machine 16 so as to be matched therewith, mixed in the gas mixer 17 and sent to the ozone consuming object 15 as an ozone-containing gas.

  When ozone is desorbed in this way and the desorption operation of the third adsorption / desorption tower 4-3 is close to completion, the switching valves 40-1 and 8-8 are opened and stored in the second adsorption / desorption tower 4-2. The generated ozone is sent to the third adsorption / desorption tower 4-3. At this time, the ozone that has flowed into the third adsorption / desorption tower 4-3 is again adsorbed by the adsorbent in the third adsorption / desorption tower 4-3, and the third adsorption / desorption tower 4-3 becomes a buffer (buffer device). By playing the role, it is possible to prevent a large amount of ozone from being released in the initial stage of desorption. In this way, ozone is desorbed from the adsorption / desorption tower 4 one by one so that it always passes through the third adsorption / desorption tower 4-3, so that the ozone-containing gas containing ozone at a constant concentration is ozone. It can be supplied to the consumption object 15.

  In this reference example, when ozone is taken out from the remaining multiple adsorption / desorption towers 4 except for the third adsorption / desorption tower 4-3 from which ozone is first taken out, the adsorption / desorption tower 4 and the third adsorption / desorption tower that desorb ozone. Although two groups 4-3 are connected in series and ozone is extracted, all the adsorption / desorption towers 4 are connected in series before desorption is started, and then from the third adsorption / desorption tower 4-3. You may make it take out ozone.

  Thereby, ozone can be desorbed continuously from the start to the end of desorption, and there is an effect that the desorption control of ozone becomes easy. However, in this case, the ozone desorption amount increases as the number of adsorption / desorption towers 4 that must pass through increases as ozone is desorbed from the adsorption / desorption tower 4 connected at the rear. Decrease. Moreover, since the pressure loss at the time of sucking ozone increases, there is a problem that a large capacity gas suction pump 13 is required.

  First, ozone is taken out from the third adsorption / desorption tower 4-3, and when the desorption amount decreases, the second adsorption / desorption tower 4-2 is connected in series with the third adsorption / desorption tower 4-3. Then, when ozone is taken out and the amount of desorption decreases, the adsorption / desorption tower 4 is connected one after another, such as connecting the first adsorption / desorption tower 4-1 in series and taking out ozone. In the end, all the adsorption / desorption towers 4 may be connected in series, and ozone may be taken out.

  Thereby, compared with the case where ozone is taken out from the single adsorption / desorption tower 4 one by one, there is an effect that the control of the ozone concentration in the ozonized oxygen supplied to the ozone consuming object 15 is facilitated. However, in this case as well, as in the case where all the adsorption / desorption towers 4 are connected in series at one time, the adsorption / desorption tower 4 that has to pass as much as ozone is desorbed from the adsorption / desorption tower 4 connected at the rear. The number of ozone increases, the amount of ozone decomposition increases, and the amount of ozone extracted decreases. Moreover, since the pressure loss at the time of sucking ozone increases, there is a problem that a large capacity gas suction pump 13 is required.

Reference Example 13
In each of the above embodiments and each reference example, the safety measures at the time of the power failure of the apparatus were not described. However, in this reference example, ozone stored in the adsorption / desorption tower 4 at the time of the power failure of the apparatus was decomposed with an ozone decomposing agent. It is released into the air as a gas that does not contain.
FIG. 26 is a block diagram showing an ozone storage device according to this reference example. In the figure, the same reference numerals as those in FIG. 24 denote the same or corresponding parts. In the figure, reference numeral 41 denotes an ozonolysis tower filled with an ozonolysis agent for decomposing ozone, and this ozonolysis tower 41 is adsorbed and desorbed by a pipe 45 provided with a non-energized open electromagnetic valve 43-2 in the middle. 4 is connected to the ozonated oxygen outlet side.

  42 is a compressed gas storage tank for storing compressed gas in case of an emergency, and this compressed gas storage tank 42 is provided with oxygen in the adsorption / desorption tower 4 by a pipe 45 provided with a non-energized open-type electromagnetic valve 43-1 in the middle. Connected to the entrance side. Usually, the ozonolysis tower 41 is filled with an ozonolysis agent such as activated carbon or secard.

Next, the operation will be described. This operation includes two operations of adsorbing ozone and desorbing ozone. Since these operations are the same as those in Reference Example 1, they are omitted here and the operation of the ozone storage device during a power failure is described. To do. When a power failure occurs during the adsorption operation, the operation of the control device (not shown) causes the ozone generator 1, the circulation blower 3, and the cold heat source 5 to stop operating, and the switching valves 8-1, 8-2, 8-3, 8- 4 closes.

  Next, the non-energized open electromagnetic valve 43-1 is opened, and the compressed gas stored in the compressed gas storage tank 42 is supplied to the adsorption / desorption tower 4. The ozone stored in the adsorption / desorption tower 4 by the purge of the compressed gas is desorbed from the adsorbent and led to the ozone decomposition tower 41 through the non-energized open electromagnetic valve 43-2 opened as an ozone-containing gas. In the ozonolysis tower 41, ozone is decomposed by an ozone decomposing agent and released into the air as a gas not containing ozone.

  As a result, the ozone adsorbed by the adsorbent is desorbed due to the temperature rise, and the adsorption / desorption tower 4 is filled and the ozone concentration in the adsorption / desorption tower 4 becomes high, thereby preventing an accident that causes an explosion. be able to. In general, it is considered extremely dangerous when the ozone concentration in gas is about 30% by weight.

  In the above reference example, when the power failure occurs, the case where the non-energized open type solenoid valves 43-1 and 43-2 are activated immediately is shown. However, a mechanical timer (not shown) is provided. The same effect can be obtained even if the non-energized open solenoid valve 43 is operated after a certain period of time has elapsed since the occurrence of a power failure. Further, when the power failure recovers relatively quickly, it is possible to immediately return to the state immediately before the power failure, and there is an effect that efficient operation can be performed.

Reference Example 14 .
In the reference example 13 , when a power failure occurs, the compressed gas stored in the compressed gas storage tank 42 is supplied to the adsorption / desorption tower 4, and ozone stored in the adsorption / desorption tower 4 by the purge of the compressed gas is supplied from the adsorbent. It was desorbed to become ozone-containing gas and led to the ozonolysis tower 41.

  In this reference example, when ozone adsorbed by the adsorbent during a power failure is desorbed due to a temperature rise, the ozonized oxygen is released from the adsorption / desorption tower 4 by effectively utilizing the increase in pressure in the adsorption / desorption tower 4. Then, it is guided to the ozonolysis tower 41.

  FIG. 27 is a block diagram showing an ozone storage device according to this reference example. In the figure, the same reference numerals as those in FIG. 26 denote the same or corresponding parts. In the figure, 44 is a pressure-driven safety valve provided in the middle of a pipe 45 connecting the ozonolysis tower 41 and the adsorption / desorption tower 4.

Next, the operation of this reference example will be described. This operation includes two operations, an ozone adsorbing operation and an ozone desorbing operation, but these operations are the same as those in Reference Example 1, and are omitted here. The operation when this occurs will be described.

  When a power failure occurs during the adsorption operation, the cold heat source 5, the ozone generator 1, and the circulation blower 3 stop operating, and the switching valves 8-1, 8-2, 8-3, and 8-4 close. And by the operation stop of the cold heat source 5, the ozone adsorbed by the adsorbent is desorbed due to the temperature rise, the ozone is filled, and the pressure in the adsorption / desorption tower 4 rises. As a result, the pressure-driven safety valve 44 starts operating, and ozonized oxygen is released from the adsorption / desorption tower 4 and guided to the ozonolysis tower 41. In the ozonolysis tower 41, ozone is decomposed by an ozone decomposing agent and released into the air as a gas not containing ozone.

  At this time, the pressure value when the ozone concentration in the adsorption / desorption tower 4 becomes 30% by weight is examined in advance, and the pressure-driven safety valve 44 may be driven before reaching the value, or the adsorption / desorption tower 4 An ozone concentration meter for checking the ozone concentration in the inside may be provided, and the pressure driven safety valve 44 may be driven according to the value.

  As a result, ozone adsorbed by the adsorbent is desorbed due to a temperature rise, and the adsorption / desorption tower 4 is filled and the ozone concentration in the adsorption / desorption tower 4 becomes high, thereby preventing an explosion from occurring. be able to.

It is a block diagram which shows the ozone storage apparatus by the reference example 1 of this invention. It is a table | surface figure which shows the relationship between adsorbent cooling temperature and ozone adsorption amount. It is a table | surface figure which shows the relationship between cooling time and adsorbent temperature. It is a table | surface figure which shows the relationship between adsorption time and adsorption / desorption tower exit ozone concentration. It is a block diagram which shows the ozone storage apparatus by the reference example 2 of this invention. It is a block diagram which shows the ozone storage apparatus by the reference example 3 of this invention. It is a block diagram which shows the ozone storage apparatus by the reference example 4 of this invention. It is a block diagram which shows the ozone storage apparatus by the reference example 4 of this invention. It is a block diagram which shows the ozone storage apparatus by the reference example 4 of this invention. It is a block diagram which shows the ozone storage apparatus by the reference example 5 of this invention. It is a block diagram which shows the ozone storage apparatus by the reference example 6 of this invention. It is a block diagram which shows the ozone storage apparatus by the reference example 7 of this invention. It is a table | surface figure which shows the relationship between gas pressure and ozone adsorption amount. It is a table | surface figure which shows the relationship between gas pressure and ozone generation efficiency. It is a table | surface figure which shows the relationship between adsorption | suction time and the power consumption at the time of adsorption | suction. It is a block diagram which shows the ozone storage apparatus by the reference example 8 of this invention. It is a block diagram which shows the ozone storage apparatus by the reference example 9 of this invention. It is a table | surface figure which shows the relationship between the ozone concentration in ozonated oxygen, and ozone adsorption amount. It is a table | surface figure which shows the relationship between the ozone concentration in ozonated oxygen, and ozone generation efficiency. It is a table | surface figure which shows the relationship between adsorption | suction time and the power consumption at the time of adsorption | suction. It is a block diagram which shows the ozone storage apparatus by the reference example 10 of this invention. It is a block diagram which shows the ozone storage apparatus by Embodiment 1 of this invention. It is a block diagram which shows the ozone storage apparatus by Embodiment 2 of this invention. It is a block diagram which shows the ozone storage apparatus by the reference example 11 of this invention. It is a block diagram which shows the ozone storage apparatus by the reference example 12 of this invention. It is a block diagram which shows the ozone storage apparatus by the reference example 13 of this invention. It is a block diagram which shows the ozone storage apparatus by the reference example 14 of implementation of this invention. It is a block diagram which shows the conventional intermittent ozone supply apparatus.

  DESCRIPTION OF SYMBOLS 1 Ozone generator, 2 Oxygen supply source, 3 Circulation blower, 4 Adsorption / desorption tower, 5 Cooling source, 6 Heating source, 7 Water flow ejector, 8 Switching valve, 11 Ozone discharge means, 12 Ozone gas flow control device, 13 Gas suction pump , 14 Ozone concentration control means, 15 Ozone consumption object, 16 Medium gas production device, 17 Gas mixer, 18 Ozone concentration meter, 19 Control device, 20 Cryogenic separator, 21 Gas ejector, 22 Bypass piping, 23 Compressed gas production Machine, 24 two-way flow control valve, 25 gas cooler, 26 gas storage device, 27 gas flow meter, 28 heat exchanger, 29 pressure control device, 30 ozone detector, 31 controller, 32 timer, 33 flow control device, 34 Electric power control device, 35 Oxygen gas flow control device, 36 Gas cooling pipe, 37 Cooling device, 38 The amount meter 39 piping 40 switching valve, 41 an ozone decomposing column, 42 the compressed gas storage tank, 43 de-energized during open solenoid valve, 44 pressure-driven safety valve, L1, L2 circulation pipe.

Claims (1)

Ozone generating means for generating ozonated oxygen from oxygen-containing gas;
An adsorption / desorption means for selecting ozone from the ozonated oxygen generated by the ozone generation means and adsorbing the ozone to the adsorbent, and desorbing ozone from the adsorbent;
A ozone supply device that includes a circulation path for returning the oxygen-containing gas after the ozone adsorbed on the ozone generator from the adsorption-desorption unit,
Ozone suction means for suctioning and desorbing ozone absorbed and stored by the adsorption / desorption means;
A first gas flow control device for controlling the flow rate of the gas flowing through the ozone suction means;
Oxygen supply means for supplying oxygen to the adsorption / desorption means;
A second gas flow rate control device for controlling the flow rate of oxygen gas supplied from the oxygen supply means;
A medium gas generator for controlling the flow rate of medium gas added to ozonated oxygen taken out by the ozone suction means;
An ozone concentration meter that measures the ozone concentration in the ozone-containing gas supplied to the ozone-consuming object;
Receiving a signal from said ozone concentration meter, the first gas flow rate control equipment, the second gas flow rate control equipment and the control for controlling the flow rate of the gas flowing by changing the operation of the medium gas generator And an ozone supply device.

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