JP5266816B2 - Air sterilization system - Google Patents

Description

  The present invention relates to an air sterilization system for sterilizing or sterilizing microorganisms contained in a room such as a clean room.

  Conventionally, plasma ion sterilizers and negative ion generators have been proposed for inactivation and sterilization of airborne bacteria. These all inactivate and sterilize bacteria by utilizing negative ions and oxygen radicals generated by plasma by corona discharge.

  Moreover, there exists an ozone generator of patent document 1 as a generation | occurrence | production mechanism of the negative ion by a corona discharge system. It has been proposed that this ozone generator generates ions and ozone simultaneously by applying a high voltage between electrodes combining a needle electrode and a cylindrical electrode.

  On the other hand, the use of ozone has been proposed as a method for inactivating and sterilizing bacteria including adherent bacteria. This is to deodorize and sterilize by the oxidizing power of ozone generated by using discharge or the like. For ozone sterilization, a sealed room is filled with ozone and sterilized, and an ozone generation area is provided in a part of the air flow path. After sterilization, excess ozone is decomposed and discharged downstream. It is known that

  Furthermore, since sterilization using ozone may adversely affect the human body when the ozone concentration is high, various precautions have been taken to maintain safety. Patent Document 2 proposes a purifier that performs operation control using sensing. This is provided with an ozone detection sensor at the air outlet of the ozone sterilizer to control the amount of ozone generated so that ozone does not exceed a certain concentration.

As a solution to the low practical sterilization performance, for example, as disclosed in Patent Document 3, a combination of negative ions by corona discharge and sterilization by a small amount of ozone is employed. As disclosed in Patent Document 4, there is a system that combines ozone sterilization with an antibacterial filter, a high-performance filter, and UV, and a system that combines a plurality of sterilization mechanisms with low sterilization performance is employed.
Japanese Patent No. 3017146 Japanese Patent No. 3340982 JP 2004-160383 A JP 2004-357775 A

  However, since an ozone generator such as that disclosed in Patent Document 1 causes a corona discharge to cause a significant concentration of electric field at the tip of the electrode, locally high electric field strength is generated and an unequal electric field is generated. Such an unequal electric field becomes electrically unstable. In addition, it is necessary to suppress the generation of high-concentration ozone that may harm people. For this reason, the applied voltage and the distance between the electrodes must be limited. Thus, in plasma ion sterilization, in order to maintain safety, performance must be set low or operating conditions must be limited, and there has been a problem that actual sterilization performance is extremely low.

Moreover, in patent document 2, since only the density | concentration of the ozone which the sensor generate | occur | produced is measured, sterilization may stop irrespective of the contamination degree of object air, and the problem that it cannot fully sterilize depending on setting conditions. there were.
The devices as disclosed in Patent Documents 3 and 4 have a problem that the device configuration is complicated and the cost of the entire system is increased.

  SUMMARY OF THE INVENTION Accordingly, in order to solve the above-described problems of the prior art, an object of the present invention is to provide an air sterilization system that has safety without adversely affecting the human body and that operates sterilization means efficiently to perform sterilization. It is said.

In order to achieve the above object, the air sterilization system of the present invention is a sterilization means capable of switching between a sterilization method by an electric field and a sterilization method by ozone using a pair of electrodes, a control means for controlling the operation of the sterilization means, A dust meter that detects the degree of contamination of germs floating in the air in the area, a human sensor that detects the entry and exit of people in the area, and a timer that switches between the daytime and nighttime operation modes of the area, The control means switches, in priority order, the output of the sterilization means and the sterilization method based on the output value of the operation mode of the timer, the output value of the human sensor, and the output value of the dust meter. The cleanliness within the area is maintained.

  According to the air sterilization system of the present invention having the above configuration, the sterilization means can perform sterilization processing according to outputs from the contamination level monitor, the human sensor, and the timer via the control means. Therefore, it is possible to automatically turn on / off the sterilization process according to the degree of contamination of the target air, the entry / exit of a person into / from the target area, or the time.

  The sterilization unit switches the sterilization strength and the sterilization method (electric field, ozone) according to the outputs from the contamination level monitor, the human sensor, and the timer via the control means. Therefore, efficient sterilization can be selected by automatic operation in accordance with the degree of contamination of the target air, the entry / exit of humans into / from the target region, or time.

  Furthermore, it is possible to change the setting of the operating conditions, that is, to determine what processing is performed under what conditions with respect to conditions such as the degree of contamination of the target air, the presence or absence of humans, and time. Therefore, the sterilization system can be customized and operated in accordance with the cleanliness required for the target area, the type of facility, and the purpose of use. For example, it is possible to set multiple driving modes for daytime driving modes where people go in and out, and driving modes for unattended times such as nighttime and holidays, and by switching the driving mode, Automatic operation that manages sterilization treatment on a daily or weekly basis is possible. In addition, it is possible to set an operation mode for cases where extraordinary sterilization is required, such as during maintenance or emergency, and it is possible to manage from a normal use to an emergency in a single sterilization system. it can.

Hereinafter, embodiments of the air sterilization system of the present invention will be described in detail with reference to the accompanying drawings.
FIG. 1 is a schematic explanatory diagram of the air sterilization system of the first embodiment. As shown in the figure, the air sterilization system 10 includes a sterilization unit 12, a control unit 14, and an air conditioning unit 15. Further, the control unit 14 has a configuration in which a pollution degree monitor 16 and a human sensor 18 are connected. It is said.

  The sterilizing means 12 supplies an electric field, ozone, etc., and sterilizes the air passing through the duct 36. The sterilizing means 12 of the present embodiment is configured so that the sterilizing power can be adjusted stepwise. As an example, the sterilizing means 12 uses a pair of electrodes and adjusts the voltage of the electrodes to generate various sterilizing powers. A low voltage is applied to the electrode to generate an electric field, and a relatively weak sterilizing power that does not affect the human body is generated. In addition, a high voltage is applied to the electrode to generate ozone, thereby generating a strong sterilizing power that affects the human body.

  FIG. 2 is a block diagram of the control means 14. As illustrated, the control means 14 includes a processing unit 20, a timer 22, and a sterilization method switching unit 24. The control means 14 controls the sterilization method and sterilization power of the area 30 with respect to the sterilization means 12 installed in any one of the area 30 serving as the flow path of the sterilization target air, the air conditioning means 15 and the duct.

The processing unit 20 receives information (measurement values) from a contamination level monitor 16, human sensor 18, and timer 22 described later. The sterilization method switching unit 24 is controlled based on the input value.
The sterilization method switching unit 24 can perform multi-stage switching operation by stepwise switching of the type of sterilization method and the strength of sterilization (sterilization power).

  The control means 14 is provided with an operation panel on the surface of the main body, the machine room, the wall of the area, or the like. In addition to the main power switch and the operation mode switching switch, the operation panel includes an input terminal for inputting operation conditions of the sterilization system such as a key input screen and a dial.

  The air conditioner 15 is connected to an air outlet 32 and an air inlet 34 formed in the area 30 via a duct 36. The air conditioning means 15 gradually cleans the dust in the air flowing in from the air suction port 34 with a filter, and supplies clean air from the air outlet 32 to the area through the duct.

  The contamination level monitor 16 is a monitor that measures the contamination level of an area, and uses a dust meter as an example. The contamination level monitor 16 is attached in the area or in the air conditioning means.

  In the present embodiment, the human sensor 18 is a thermal sensor or a gravity sensor. The human sensor 18 is installed in the vicinity of a door in an area where people enter and exit.

  The air sterilization system 10 sets a plurality of operation modes in advance. As an example, the operation mode is divided into the day when the worker performs the work in the area, the night outside the working hours, the emergency when the cleanliness in the area is not maintained due to maintenance or the like. The timer 22 sends an output signal to the control means 14 at the time of switching operation modes such as daytime, nighttime, and emergency that are set in advance according to the work time of the area.

Next, the operation of the sterilization system of the present invention having the above configuration will be described below.
The area 30 forms the following air circulation path. That is, when the fan of the air conditioning means 15 is driven, air blows out from the air outlet 32 to the area 30 through the duct 36. Then, the air ventilated in the area 36 returns to the air conditioning means 15 from the air suction port 34 through the duct 36 again.

  The air sterilization system 10 of the present invention includes information on any or all of the contamination level monitor 16, the human sensor 18 and the timer 22 of the control means 14 in the area 30, that is, the contamination level of the target air, Specifically, the following sterilization treatment is performed based on the entry / exit and time.

FIG. 3 is an explanatory diagram showing the operating state of the air sterilization system. In the air sterilization system, as an example, a case will be described in which a food factory having a clean room cleanliness class of 10,000 (a dust density of 0.5 μm of 350,000 / m ³ or less) is targeted. Generally, a clean room is designed to maintain a cleanness of 10% of a set value in an unattended state. Therefore, the switching condition in the area in the present embodiment 35,000 dust concentration / ^m less than ^3, 35,000 / ^{m 3} or more and less than 350,000 / ^{m 3,} of 350,000 / ^{m 3} or more Three stages are set. This numerical value can be arbitrarily changed, and can be customized in accordance with the purpose of the target facility and the required cleanliness.

  The output of the sterilization means 12 (strength of sterilization power) and the sterilization method are set as follows. In the present embodiment, as an example, four levels of a to d having different sterilization strengths are set. The strength of the sterilization power (sterilization method a) applies a low voltage to the pair of electrodes of the sterilization means 12. Only an electric field is generated between the electrodes, and the passing air is sterilized. The strength a of the sterilizing power is a sterilizing power that does not affect the human body. The strength of the sterilization power (sterilization method b) applies a voltage to the pair of electrodes. The area around the electrode is ionized to widen the electric field region and sterilize the air. The strength of the sterilization power (sterilization method c) is that a small amount of ozone is generated from the electrode by the applied voltage. The strength of sterilization power (sterilization method d) generates a large amount of ozone from a pair of electrodes. The relationship between the strengths a to d of the sterilization power increases in the order of a <b <c << d, and can be switched by the strength of the sterilization power and the sterilization method by changing the applied voltage of the electrode. it can.

  The air sterilization system 10 controls the operation mode by the timer 22. The operation mode is divided into conditions such as daytime when an operator performs work in the area, nighttime outside work hours, and emergency when the cleanliness in the area is not maintained due to maintenance or the like.

  First, operation mode A (daytime) is a condition for the daytime when workers work in the area, and for each case where the target area is manned and unmanned, depending on the degree of contamination of the target air, As shown in FIG. 3, the sterilizing means is switched in three stages (sterilizing power strengths a to c).

The contamination level monitor 16 switches between dust concentrations of less than 35,000 / m ³ , 35,000 / m ³ or more and less than 350,000 / m ³ , and 350,000 / m ³ or more. When the measured value of the contamination level monitor 16 is less than 35,000 particles / m ³ , the predetermined cleanliness in the area 30 is maintained. Is stopped. At 35,000 / m ³ or more and less than 350,000 / m ³ and 350,000 / m ³ or more, the strength of the sterilizing power is changed depending on the presence or absence of a person. When a person enters the area, the sterilization power is switched to strength a, which is a sterilization power that does not affect the human body. On the other hand, when a person does not enter the area, it is sterilized with strong bactericidal powers b and c depending on the degree of contamination in the area.

  At this time, the germs floating in the air in the area 30 are sterilized by the sterilization means 12 provided in the circulation path. For example, when the sterilizing unit 12 performs ozone sterilization, the entire circulation path is sterilized. When the electric field sterilization is performed, the sterilizing unit 12 is performed only when passing through the sterilizing unit 12.

  In addition, the pollution level of air, which is a condition for switching the sterilization method, not only switches to the upper stage when the pollution level monitor value exceeds this value, but also when the sterilization process proceeds and the pollution level monitor value falls below this level, Since it switches to a stage, it can sterilize safely and efficiently.

  The operation mode B (nighttime) is a condition outside the working hours (nighttime) when the worker does not enter or leave the area. The operation mode B is automatically switched from the operation mode A at night in conjunction with the timer 22, and sterilization is performed by the set sterilization method. In this embodiment, the sterilization strength c that can maintain the cleanliness of class 10,000 is set. When a person enters the area 30 at night, it is detected by the human sensor 18 and a detection signal is sent to the control means 14 to stop the sterilization means 12.

The operation mode C (emergency) is a condition for maintenance or when significant sterilization is required. Such switching of the operation mode is directly selected by a mode switch on the operation panel of the control means 14 or the like. At this time, the sterilization means 12 is continuously operated with the maximum sterilization strength d. That is, air is sterilized with ozone. When a person enters the area 30 at night, it is detected by the human sensor 18 and a detection signal is sent to the control means 14 to stop the sterilization means 12.
The selection of the sterilization method according to each condition can be set in accordance with the use of the target facility and the required cleanliness, and can be stored in the control means.
The priority order of the contamination level monitor, the human sensor, and the timer switches the operation mode (time unit) by the timer, and then controls the output of the sterilization means in the order of the human sensor and the contamination level monitor.

FIG. 4 is an explanatory diagram of the air sterilization system of the second embodiment.
The sterilizing means 12 capable of changing the strength of the sterilizing power and the sterilizing method may be arranged in the middle of the air circulation channel in the area 30. In addition, a plurality can be provided according to the purpose. The same applies to the installation position of the contamination degree monitor 16, and it is preferable to provide it at a plurality of points, particularly when the sterilization target area is wide. FIG. 4 shows an air sterilization system 10A including a plurality of sterilization means 12a and 12b and contamination degree monitors 16a and 16b. The sterilizing means 12 and the contamination degree monitor 16 are individually attached to the area 30 and the air conditioning means 15 which are considered to be sources of contamination, and are controlled by the control means 14 respectively. As a result, only the contaminated area can be sterilized, and an energy saving operation can be performed.

  Moreover, what is necessary is just to use the surplus space of an object facility for the installation position of the control means 14. FIG. When installing in the wall around the duct, behind the ceiling, under the floor, etc., an operation panel for remotely operating the control means 14 can be installed in the machine room or the target area.

FIG. 5 is an explanatory diagram of the air sterilization system of the third embodiment.
In the air sterilization system 10B of the third embodiment, as shown in FIG. 5, a door opening / closing sensor 19 installed on a door in an area 30 is used as a human sensor that detects the entry and exit of a person. Based on the detection value of the door opening / closing sensor 19, the control means 14 can control the strength of the sterilizing power by the sterilizing means and the sterilization method in the same manner as the operation state shown in FIG.

  If the sterilization means performs ozone sterilization, install an ozone decomposition unit in the air circulation flow path, or install an ozone concentration monitor in the target area, etc., and connect it to the control means to perform safe automatic operation. It can also be. In this case, sterilization can be performed under conditions where no person is present in the area based on the information of the human sensor, or the ozone concentration is a constant concentration, for example, a safety reference value at the workplace. The door may be locked as long as it is not below 1 ppm.

  The present invention is a highly safe sterilization apparatus using an electrically stable equal electric field, and can be sterilized even in an environment where people and living things are present in the vicinity. In addition, the structure of the electrode and the support plate in which the entire amount of fluid to be treated passes through the electric field region enables high efficiency and sterilization in a short time. For this reason, it can be used as a sterilizer for gases and liquids in a wide range of fields such as pharmaceutical factories, medical engineering research facilities, hospitals and food factories that require a sterilizer having both safety and high functionality.

It is a schematic block diagram of the air sterilization system of 1st Embodiment. It is a block diagram of a control means. It is explanatory drawing showing the operation state of an air sterilization system. It is explanatory drawing of the air sterilization system of 2nd Embodiment. It is explanatory drawing of the air sterilization system of 3rd Embodiment.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 ......... Air sterilization system, 12 ......... Sterilization means, 14 ......... Control means, 15 ......... Air-conditioning means, 16 ......... Contamination degree monitor, 18 ......... Human sensor, 20 ......... Process Part, 22 ......... timer, 24 ......... sterilization method switching part, 30 ..... area, 32 .... air outlet, 34 .... air inlet.

Claims (1)

Sterilization means capable of switching between a sterilization method by an electric field and a sterilization method by ozone using a pair of electrodes;
Control means for controlling the operation of the sterilization means;
A dust meter that detects the degree of contamination of germs floating in the air in the area;
A human sensor that detects the entry and exit of people in the area,
A timer for switching between the daytime and nighttime operation modes of the area;
With
The control means switches, in priority order, the output of the sterilization means and the sterilization method based on the output value of the operation mode of the timer, the output value of the human sensor, and the output value of the dust meter. An air sterilization system for maintaining cleanliness in the area.

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