JP2020016593A - Ozone sensor and ozone detector - Google Patents

Abstract

To provide an ozone sensor and an ozone detector capable of stable ozone detection operation even in extreme environments such as the normal temperature and high humidity environment, and the low temperature and high humidity environment or the extremely low temperature environment.SOLUTION: An ozone sensor 20 includes: a sensor body 21 having a gas contact surface 46 exposed to the outside and in contact with an ozone-containing atmosphere gas; and a heater 10 for heating a member constituting a gas contact surface 46 in the sensor body 21.SELECTED DRAWING: Figure 2

Description

  The present invention relates to an ozone sensor and an ozone detection device including the ozone sensor.

In recent years, ozone having a strong oxidizing power has come to be used, for example, for maintaining the freshness of food and extending the storage period, and for washing and bleaching food, deodorizing in refrigerators, and the like. ing.
For example, Patent Literature 1 discloses a storage device that irradiates an air stream with ultraviolet rays to generate ozone, and uses the generated ozone to store fresh food and sterilize it during refrigeration or thawing.

In sterilization and deodorization treatment using ozone, it is necessary to raise the ozone concentration to a required value, but it is said that depending on the concentration, it has a bad effect on the human body. Management is required.
Therefore, Patent Document 1 describes that an ozone sensor for detecting the concentration of ozone or the like is provided inside the fresh food storage, and the operation of the ultraviolet irradiation unit is controlled based on the detection value of the ozone sensor. I have. In addition, it is described that the ultraviolet irradiation unit is configured by an excimer lamp or a rare gas fluorescent lamp that can emit vacuum ultraviolet light having a single wavelength of less than 200 nm.

WO 2016/194877

Thus, as a method for measuring the concentration of ozone, for example, an ultraviolet absorption method, a thin film semiconductor method, a diaphragm polarography method, and a detection tube method are known, and even if an ozone sensor using any measurement method is used, In order to perform a stable ozone detection operation, it is indispensable that the gas contact surface with which the ozone-containing atmosphere gas comes into contact is free from dew condensation. When dew condensation occurs on the gas contact surface, the signal level of the detection signal decreases, and the detection accuracy decreases. If the ozone sensor in a state where dew condensation occurs is placed in, for example, a low-temperature environment, moisture is frozen and frost is generated, so that it becomes difficult to detect ozone.
However, in an environment where dew condensation is likely to occur, specifically, for example, a normal temperature and high humidity environment (20 to 40 ° C., 80% RH or more), a low temperature and high humidity environment (0 to 10 ° C., 80% RH or more) or a very low temperature There is no known ozone sensor capable of performing a stable ozone detection operation in an extreme environment such as an environment (-40 to -10 ° C).

  Further, when ultraviolet light emitted from an ultraviolet lamp (excimer lamp) is used to generate ozone as in Patent Document 1, since a high voltage is applied when the lamp is turned on, electromagnetic noise is reduced. Inevitably occurs. Therefore, there is a problem that the ozone detection signal output from the ozone concentration sensor may be affected by the electromagnetic wave noise and the detection accuracy may be reduced.

  The present invention has been made on the basis of the above circumstances, and has a normal temperature and high humidity environment (20 to 40 ° C., 80% RH or more) or a low temperature and high humidity environment (0 to 10 ° C., 80% RH or more). It is an object to provide an ozone sensor and an ozone detection device capable of performing a stable ozone detection operation even in an extreme environment such as an extremely low temperature environment (−40 to −10 ° C.).

  The ozone sensor of the present invention includes a sensor main body having a gas contact surface that is exposed to the outside and comes into contact with an ozone-containing atmosphere gas, and includes a heater that heats a member of the sensor main body that constitutes the gas contact surface. It is characterized by.

  In the ozone sensor according to the aspect of the invention, it is preferable that the heater is provided so as to cover an outer surface of the sensor main body except for the gas contact surface.

In the ozone sensor according to the present invention, the sensor main body includes a cylindrical sensor case having a gas inlet formed at one end in an axial direction,
It is preferable that a member constituting the gas contact surface is a gas permeable filter provided to close a gas inlet of the sensor case.

Still further, in the ozone sensor according to the present invention, the heater is configured such that a resistance heating wire is covered with a sheet-shaped member,
The sheet-shaped member may be configured such that a heat conduction characteristic of an outer surface portion located on the opposite side of the resistance heating wire with respect to an inner surface portion on a side facing the sensor body is reduced. preferable.

  Still further, in the ozone sensor of the present invention, it is preferable that a gas-permeable separator having hydrophobicity is provided on an inner surface side of the gas inlet in the sensor case.

An ozone detection device of the present invention is an ozone detection device including the above-described ozone sensor,
It has an opening, and has a housing that houses the electrical component inside,
The ozone sensor is provided so as to close an opening in the housing in a state where the gas contact surface is exposed to the outside.

  In the ozone detection device of the present invention, it is preferable that an outer surface of the ozone sensor except for the gas contact surface is covered with a heat insulating member.

ADVANTAGE OF THE INVENTION According to the ozone sensor of this invention, since the member which comprises a gas contact surface is heated by a heater, it can prevent reliably that dew condensation arises on a gas contact surface, and performs highly reliable ozone detection. be able to.
Therefore, the ozone sensor of the present invention can be used in, for example, a normal temperature and high humidity environment (20 to 40 ° C., 80% RH or more), a low temperature and high humidity environment (0 to 10 ° C., 80% RH or more), or a very low temperature environment (−40). (−10 ° C.) or the like.

  Since the heater is provided so as to cover the outer surface of the sensor body excluding the gas contact surface, high thermal efficiency can be obtained and the heater also serves as a heat insulating material for the external environment. Can be efficiently heated.

  Since the member constituting the gas contact surface is a gas permeable filter, it is possible to avoid deteriorating the original function of the gas permeable filter due to dew condensation, so that the ozone-containing atmosphere gas can be reliably supplied to the detection element. As a result, highly reliable ozone detection can be performed.

  A sheet-like member located on the side opposite to the inner surface side of the sheet-like member located on the side facing the sensor body in the heater in which the resistance heating wire is covered with the sheet-like member, with the resistance heating wire therebetween. Since the heat conduction characteristic of the outer surface side portion of the member is reduced, the heat insulation performance is enhanced, so that heat can be efficiently transmitted to the members constituting the gas contact surface, and furthermore, the gas contact surface Can be suppressed from being reduced to a predetermined temperature or lower due to the influence of the external environment.

  By providing a structure in which a gas-permeable separator having hydrophobicity is provided on the inner surface side of the gas inlet in the sensor case, intrusion of moisture from the outside into the inside of the sensor body can be prevented, thereby further improving reliability. Ozone can be detected at a high level.

  According to the ozone detection device of the present invention including the above-described ozone sensor, since the electrical component is housed in the housing, it is possible to reliably prevent the sensing from being hindered by the influence of the external environment, and to provide a reliable device. It is possible to perform highly sensitive ozone detection.

  Since the ozone sensor is configured to be covered with the heat insulating member, a decrease in the heating efficiency of the heater due to the influence of the external environment can be suppressed, and a decrease in the temperature of the gas contact surface in the ozone sensor can be suppressed. In addition, it is possible to reliably prevent dew formation on the gas contact surface of the ozone sensor.

It is a perspective view which shows the structure in an example of a heater schematically. It is sectional drawing which shows the structure in an example of an ozone sensor roughly. It is a sectional view showing roughly composition in an example of an ozone detection device of the present invention. It is explanatory drawing which shows the example of application of the ozone detection apparatus of this invention to a storage device.

  Hereinafter, embodiments of the present invention will be described in detail.

[Ozone sensor]
The ozone sensor of the present invention includes a sensor main body having a gas contact surface that is exposed to the outside and comes into contact with an ozone-containing atmosphere gas, and includes a heater that heats a member of the sensor main body that constitutes the gas contact surface. It is characterized by.

The sensor body may use any one of measurement methods such as an ultraviolet absorption method, a thin film semiconductor method, a membrane polarographic method, and a detection tube method.
In the ozone sensor of the present invention, for example, a sensor body having a substantially columnar shape as a whole and having a gas contact surface at one end in the axial direction can be used as the sensor main body. Specifically, for example, the sensor main body is provided so as to cover a cylindrical sensor case having a gas inlet formed at one end in the axial direction, an ozone detection element disposed in the sensor case, and a gas inlet of the sensor case. And a gas permeable filter having a gas permeable filter. In such a sensor body, the member constituting the gas contact surface is a gas permeable filter.
Further, it is preferable that the sensor main body has a configuration in which a gas permeable separator having hydrophobicity is provided on the inner surface side of the gas inlet in the sensor case. With this configuration, it is possible to prevent moisture from entering the inside of the sensor main body from the outside, so that more reliable ozone detection can be performed.

As the heater, for example, a heater in which a resistance heating wire made of a nickel-chromium alloy is covered with an insulating sheet-like member can be used. As the sheet-like member, for example, a silicon sponge sheet or the like can be exemplified.
In the ozone sensor of the present invention, it is preferable that the heater is provided so as to cover the outer surface of the sensor main body except for the gas contact surface. With such a configuration, a high thermal efficiency can be obtained, and the heater also plays a role as a heat insulating material with respect to an external environment, so that a member constituting the gas contact surface can be efficiently heated.
FIG. 1 shows an example of the configuration of a heater used in the ozone sensor of the present invention.

The heater 10 shown in FIG. 1 is configured such that a resistance heating wire 11 is sandwiched between a sheet member 15 on one side and a sheet member 16 on the other side. The resistance heating wires 11 are arranged in a predetermined pattern on one surface of the other side sheet member 16.
It is preferable that the heater 10 is configured to have high heat insulation performance. Specifically, one or both of the one-side sheet member 15 and the other-side sheet member 16 may be provided with a member having high heat insulation properties, or the thickness of the one-side sheet member 15 and the other-side sheet member 16 may be adjusted. By doing so, the heat insulation performance of the heater 10 can be increased.
The heater 10 has an inner surface portion facing the sensor main body and an outer surface portion which is positioned on the opposite side of the sensor main body with respect to the one surface side sheet member 15 with the resistance heating wire 11 interposed therebetween. It is preferable that the heat conduction characteristics of the sheet member 16 be reduced. With such a configuration, heat insulation performance is enhanced, so that heat can be efficiently transmitted to the members forming the gas contact surface, and the members forming the gas contact surface are affected by the external environment. As a result, it is possible to prevent the temperature from dropping to a predetermined temperature or lower.

FIG. 2 is a sectional view schematically showing a configuration of an example of the ozone sensor of the present invention.
The ozone sensor 20 is, for example, an electrochemical sensor using a diaphragm polarographic method, and quantifies ozone gas from the magnitude of current flowing between the working electrode 31 and the counter electrode 32.
The ozone sensor 20 includes a cylindrical sensor main body 21 having a gas contact surface 46 at one end in the axial direction, and a heater 10 provided to cover the outer surface of the sensor main body 21 excluding the gas contact surface 46. I have.

  The sensor main body 21 includes a sensor case 25 including a bottomed cylindrical case main body 26 having an open end, and a disk-shaped lid 27 provided to close the opening of the case main body 26. . An opening for forming a gas inlet 28 is formed in the center of the lid 27.

  Inside the sensor case 25, a gas detection element 30 composed of an electrode structure in which a working electrode 31, a counter electrode 32, and a reference electrode 33 are stacked with an electrolyte holding member 36 interposed therebetween is arranged. The electrode terminal 35 electrically connected to each of the working electrode 31, the counter electrode 32 and the reference electrode 33 is led out of the sensor case 25 in a liquid-tight manner.

The lid 27 of the sensor case 25 is provided with a gas permeable isolation membrane 40 having hydrophobicity so as to close the gas inlet 28 from the inner surface in a liquid-tight manner. Reference numeral 39 denotes a seal member made of, for example, an O-ring.
As a material constituting the gas permeable separator 40, any material that has been conventionally used as long as it can transmit an ozone-containing atmosphere gas and prevent intrusion of moisture and leakage of an electrolytic solution can be used. Can also be used.

  A gas permeable filter 45 functioning as a dust filter is provided on the outer surface of the lid 27 constituting the sensor case 25 so as to block the gas inlet 28 from the outer surface side. A surface 46 is configured.

  As described above, the heater 10 may be configured by covering the resistance heating wire with a sheet-like member having an insulating property.

Thus, in the ozone sensor 20, energization of the heater 10 is controlled such that the temperature of the gas contact surface 46 becomes a temperature set according to the temperature of the external environment atmosphere.
Specifically, for example, the set temperature of the gas contact surface 46 of the ozone sensor 20 is set to a temperature that is at least about 2 to 3 ° C. higher than the temperature of the environmental atmosphere in which the ozone sensor 20 is installed.
On the other hand, in the case where the refrigerator is used in an extreme environment such as a refrigerator or a freezer, the set temperature of the gas contact surface 46 of the ozone sensor 20 is set in consideration of the fact that the inside temperature fluctuates when the door is opened and closed. The temperature is, for example, about 5 to 6 ° C. higher than the temperature in the refrigerator.
If the heater 10 is driven under the condition that the temperature of the gas contact surface 46 is higher than necessary, power consumption increases, and heat is diffused due to a large temperature difference from the external environment. Thermal efficiency will be degraded.

  The energization of the heater 10 does not need to be controlled so that the temperature of the gas contact surface 46 of the ozone sensor 20 is maintained at a constant temperature, and may be varied according to a change in the temperature of the external environment atmosphere. That is, the temperature of the external environment atmosphere may be detected by an appropriate temperature detecting unit, and the energization to the heater 10 may be feedback-controlled based on the detection result. In such a configuration, even when the temperature of the environmental atmosphere in which the ozone sensor 20 is installed is finely changed, or when the ozone sensor 20 is taken out of the refrigerator, for example, dew condensation occurs on the gas contact surface 46. This can be reliably prevented from occurring.

In the ozone sensor 20, when an ozone-containing atmosphere gas is introduced, a reduction reaction represented by the following formula (a) occurs at the working electrode 31, and an oxidation reaction represented by the following formula (b) occurs at the counter electrode 32. As a result, a current flows between the working electrode 31 and the counter electrode 32.
Formula (a) O ₃ + 2e ⁻ + 2H ⁺ → O ₂ + H ₂ O
Formula (b) H ₂ O → １ ／ O ₂ + 2e ⁻ + 2H ⁺
Then, by detecting a current flowing between the working electrode 31 and the counter electrode 32, an ozone concentration corresponding to the magnitude of the current is detected.

Thus, according to the ozone sensor 20 having the above configuration, the dew condensation on the gas contact surface 46 is reliably prevented by heating the gas permeable filter 45, which is a member constituting the gas contact surface 46, with the heater 10. be able to. As a result, it is possible to prevent the original function of the gas permeable filter 45 from being impaired due to the dew condensation. As a result, it is possible to reliably supply the ozone-containing atmosphere gas to the detection element and to perform highly reliable ozone detection. it can.
The ozone sensor 20 having the above-described configuration may be, for example, a normal temperature and high humidity environment (20 to 40 ° C., 80% RH or more), a low temperature and high humidity environment (0 to 10 ° C., 80% RH or more), or an extremely low temperature environment (− (40 to −10 ° C.), which is extremely useful.

[Ozone detector]
FIG. 3 is a sectional view schematically showing a configuration example of the ozone detection device of the present invention.
The ozone detecting device 50 includes a housing 51 having an opening 52. The ozone sensor 20 closes the opening 52 in the housing 51 with the gas contact surface 46 exposed to the outside. It is provided in. An electrical unit 55 to which the electrode terminal 35 of the ozone sensor 20 is electrically connected is housed inside the housing 51. As a material for forming the housing 51, for example, stainless steel can be used.

As described above, for example, this ozone detection device is, for example, a normal temperature and high humidity environment (20 to 40 ° C., 80% RH or more), a low temperature and high humidity environment (0 to 10 ° C., 80% RH or more), or a very low temperature environment ( (−40 ° C. to −10 ° C.), the gas contact surface of the ozone sensor 20 is used to reliably prevent dew condensation from occurring on the gas contact surface 46 of the ozone sensor 20. It is preferable that the outer surface except 46 is covered with a heat insulating member 60.
Note that, as described above, when the heater 10 itself has a configuration in which the heat insulating performance is enhanced, the heater 10 may not have the heat insulating member 60.

  Furthermore, when the ozone detection device 50 is used under the same environmental atmosphere as an ozone generator that generates ozone using ultraviolet rays emitted from an ultraviolet lamp (excimer lamp), external electromagnetic wave noise causes It is preferable that an electromagnetic wave shielding member (not shown) is provided so as to cover a region other than the gas contact surface 46 on the outer surface of the ozone sensor 20 so that sensing is not hindered. Note that the heat insulating member 60 may be configured to have an electromagnetic wave shielding function.

Thus, according to the above-described ozone detection device 50, since the electrical component unit 55 is housed in the housing 51, it is possible to reliably prevent the sensing from being hindered by the influence of the external environment, and to improve reliability. It is possible to perform highly sensitive ozone detection.
In addition, since the ozone sensor 20 is configured to be covered with the heat insulating member 60, it is possible to suppress a decrease in the heating efficiency of the heater 10 due to the influence of the external environment and to reduce the temperature of the gas contact surface 46 of the ozone sensor 20. Therefore, the occurrence of dew condensation on the gas contact surface 46 of the ozone sensor 20 can be reliably prevented.

Hereinafter, an example of application to a fresh product storage device using the ozone detection device of the present invention will be described.
FIG. 4 is an explanatory diagram showing an application example of the ozone detection device of the present invention to a storage device.
The storage device 70 includes a fresh product storage 71, in which fresh products f are stored in a stacked basket 72 inside the fresh product storage 71 and stored at a temperature equal to or higher than a chilled state. Inside the fresh product storage 71, there are provided a temperature adjustment unit 75 for maintaining the temperature in the storage at a temperature equal to or higher than a chilled state, and an air flow generation unit 77 for generating an air flow a in the storage.

  The temperature adjustment unit 75 includes an air flow generation unit 77 composed of a fan, a defrost and temperature adjustment heater 78 inside a casing 76 having an inlet and an outlet for the air flow a, and a refrigerator provided outside the refrigerator. A heat exchanger 79 to which a refrigerant is supplied from 80 is provided. An air flow path b is formed inside the casing 76, and an air flow a is formed in the air flow path b. The temperature of the air flow a is adjusted by being heated by the heater 78 or cooled by the heat exchanger 79.

In the storage device 70, an irradiation unit 85 that irradiates vacuum ultraviolet rays is provided in the casing 76 of the temperature adjustment unit 75 and above the basket 72 in which the fresh product f is stored.
The irradiating section 85 includes a discharge lamp 87 formed of an excimer lamp or a rare gas fluorescent lamp capable of emitting vacuum ultraviolet light having a single wavelength of less than 200 nm, and the vacuum ultraviolet light from the discharge lamp 87 passes through an ultraviolet irradiation window 86. It is configured to emit light.
The irradiation unit 85 is controlled by a not-shown intermittent irradiation control unit so as to intermittently irradiate vacuum ultraviolet rays.

  In the storage device 70, radicals such as ozone and OH radicals are generated around the fresh product f by irradiating the airflow a with vacuum ultraviolet rays from the irradiating section 85. The generated ozone or radicals (hereinafter also referred to as “ozone or the like”) are diffused throughout the perishable goods storage 71 by the air flow a.

  Thus, in the storage device 70, the above-described ozone detection device 50 is provided inside the perishable product storage 71, and the ozone concentration in the perishable product storage 71 is controlled based on a detection signal from the ozone detection device 50. Is done. Specifically, a detection signal from the ozone detection device 50 is input to the intermittent irradiation control unit, and the operation of the discharge lamp 87 in the irradiation unit 85 is controlled based on the detection signal by the intermittent irradiation control unit. The ozone concentration in the storage 71 is adjusted to an appropriate size.

It is preferable that the position where the ozone detecting device 50 is installed is a position that is hardly affected by, for example, electromagnetic wave noise inevitably generated in the irradiation unit 85. Thus, ozone detection in the fresh food storage 71 can be performed with high accuracy.
Further, it is preferable that the ozone detectors 50 are installed at a plurality of locations in the fresh food storage 71. Thereby, even when the ozone concentration in the fresh food storage 71 varies, the operation control of the irradiation unit 85 can be appropriately performed.

Although the embodiments of the present invention have been described above, the present invention is not limited to the above embodiments, and various modifications can be made.
For example, the heater in the ozone sensor is not limited to the configuration according to the above-described embodiment as long as it can heat a member constituting the gas contact surface so that the gas contact surface has a predetermined temperature. Instead, those having various configurations can be used. Further, the heater does not need to be provided on the entire outer surface of the sensor main body except for the gas contact surface, and is provided so as to efficiently heat the members constituting the gas contact surface. Good.
Further, the ozone detection device of the above-described embodiment can be applied to ozone concentration detection not only in a storage in a perishable storage device but also in a space where ozone concentration management is required.

REFERENCE SIGNS LIST 10 heater 11 resistance heating wire 15 one-side sheet member 16 other-side sheet member 20 ozone sensor 21 sensor body 25 sensor case 26 case body 27 lid 28 gas inlet 30 gas detection element 31 working electrode 32 counter electrode 33 reference electrode 35 electrode terminal 36 Electrolyte holding member 39 Sealing member 40 Gas permeable separating membrane 45 Gas permeable filter 46 Gas contact surface 50 Ozone detector 51 Housing 52 Opening 55 Electrical component 60 Heat insulating member 70 Storage device 71 Fresh food storage 72 Basket 75 Temperature adjustment Unit 76 Casing 77 Air flow generation unit 78 Heater 79 Heat exchanger 80 Refrigerator 85 Irradiation unit 86 Ultraviolet irradiation window 87 Discharge lamp a Air flow b Air flow path f Fresh product

Ozone sensor of the present invention comprises a sensor body having a gas contact surface that contacts exposed outside an ozone content gas, have a heater for heating the member constituting the gas contact surface of the sensor body The heater is provided so as to cover an outer surface of the sensor main body except for the gas contact surface .

Claims (7)

  An ozone sensor comprising: a sensor main body having a gas contact surface exposed to the outside and in contact with an ozone-containing atmosphere gas; and a heater for heating a member constituting the gas contact surface in the sensor main body.   The ozone sensor according to claim 1, wherein the heater is provided so as to cover an outer surface of the sensor main body except for the gas contact surface. The sensor body includes a cylindrical sensor case having a gas inlet formed at one end in an axial direction,
The ozone sensor according to claim 1, wherein the member forming the gas contact surface is a gas permeable filter provided to close a gas inlet of the sensor case. The heater is configured such that a resistance heating wire is covered with a sheet-shaped member,
The sheet-shaped member is configured such that the heat conduction characteristic of the other surface side portion located on the opposite side across the resistance heating wire is lower than the one surface side portion facing the sensor body. The ozone sensor according to claim 2 or 3, wherein:   The ozone sensor according to claim 3, wherein a gas-permeable separator having hydrophobicity is provided on an inner surface side of the gas inlet in the sensor case. An ozone detection device comprising the ozone sensor according to any one of claims 1 to 5,
It has an opening, and has a housing that houses the electrical component inside,
The ozone sensor is characterized in that the ozone sensor is provided so as to close an opening in the housing in a state where the gas contact surface is exposed to the outside.   The ozone detection device according to claim 6, wherein an outer surface of the ozone sensor other than the gas contact surface is covered with a heat insulating member.

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