The invention relates to a capacitive sensor structure and a method for measuring content of a water soluble chemical in gas in gaseous environment.
Some embodiments of the invention are related to a capacitive sensor structure.
In the prior art humidity as such has been measured by capacitive humidity sensors, where the dielectric of the humidity sensor has been sensitive to humidity. By heating also other substances like ammonia have been measured.
Contents of substances like H2O2 (Hydrogen peroxide), ETO (Ethylene Oxide), and O3 (Ozone) have been measured by electrochemical cells or by IR-optical devices. These devices are very complicated or short-lived and thus also expensive.
Thus, there exists a need for improved sensor and method for measuring content of catalytically degradable substances.
The method is based on finding that the oxidative gas concentration has influence on observed saturation partial pressure of water vapor. So we can assume that with same partial water pressures we get different RH-values depending on exposure to oxidative gas concentrations. Actually chemical potential is the executive force which causes this phenomenon.
In one embodiment of the invention the sensor structure includes a first sensor having a sensing element sensitive to humidity of the environment, and additionally includes a second sensor having a sensing element sensitive to humidity, the second sensor comprising a catalytic permeable layer positioned on the second sensor such that it is between the sensing element of the second sensor and the environment.
The practical implementation of the invention is based using two humidity sensors: One with catalytically active layer and another without it.
In one embodiment of the invention the two sensors are integrated on the same substrate.
In another implementation the sensor elements are separate units.
In one preferred embodiment one of the sensors is heatable. In an advantageous embodiment the catalytic sensor is heatable.
More specifically, the invention is defined in the independent claims.
The invention provides considerable advantages.
With help of the invention decomposable chemicals like H2O2 (Hydrogen peroxide), ETO (Ethylene Oxide) or O3 (Ozone) may be detected and the content measured with a simple and inexpensive sensor structure instead of the complicated and expensive prior art solutions like electrochemical cells or by IR-optical devices.
The sensor enables use of novel algorithm based on the determination of the activity of an oxidative gas.
Further, the cost of instrumentation is very low.
According to one embodiment, the sensitivity may be increased by heating the catalytic sensor element.
According to one embodiment, sensor unit cost may be decreased in mass production by integrating the two sensors on the same substrate.
Next, embodiments and advantages of the invention are described in more detail with reference to the attached drawings.
The following lists shows the reference numerals used with the terms of the specification:
Basically the capacitive humidity measurement is simply an impedance measurement of a capacitive humidity sensor. The principle is described e.g. in GB-patent 2011093 of the applicant of the present application.
Referring to
Relative humidity is at all temperatures and pressures defined as the ratio of the water vapour pressure to the saturation water vapour pressure (over water) at the gas temperature:
RH=Pw/Pws·100% (1)
The total pressure does not enter the definition. Above 100° C. the same definition is valid. But as the saturation vapour pressure Pws is greater than 1 013 hPa (normal ambient pressure) the RH cannot reach 100% in an unpressurised system.
Below 0° C. the definition is also valid. Here 100% RH is also impossible because condensation will occur at a lower humidity than 100% (when the vapour is saturated over ice).
In connection with the present invention:
Ox: catalytically degradable substance to be measured for example H2O2 (Hydrogen peroxide), ETO (Ethylene Oxide), or O3 (Ozone).
RHmix: RH (=Relative Humidity) reading of standard capacitive humidity sensor
RHcat: RH reading of Pt covered capacitive humidity sensor
RHcat=(Pw+Pw(Ox))/Pws; Pws independent of oxidative gas concentration, Pw(Ox) is vapour pressure of Ox.
And RHmix=Pw/Pwsmix
As the activity of Ox is a measure for chemical potential and a good approximation for activity is:
a(Ox)=[Ox]/[Ox]sat; and [Ox]sat=f(T)
RHcat/RHmix=f(a(Ox)) and further a(Ox)=f(RHcat/RHmix)
Combining equations it is possible to calculate the hydrogen peroxide concentration if RHcat, RHmix and T are known:
[Ox]=f(RHcat/RHmix)*[Ox]sat
The measurement is possible to do with discrete sensor elements or integrated elements on one chip. The permeable catalytic layer 16 can be deposited by glancing angle evaporation technics on protective polymer layer 15. Suitable materials are Pt, Rh, silver, MnO2 etc. The oxidative molecules such as H2O2 (Hydrogen peroxide), ETO (Ethylene Oxide), and O3 (Ozone) decompose over catalytics even without elevated temperature. But it is also possible to enhance decomposition by integrating micro heater e.g. Pt-resistor on the sensor chip.
One embodiment of the sensor is described in
The metal film above the second sensor 2 is advantageously formed by a method described in the EP-patent 665303 of the applicant of this patent application. In this method the microporous metal film is attained by adjusting an angle alpha between the surface to be metallized and the source evaporating the metal to a value in the range 5-30 degrees. Here the surface to be metalized is the layer 15 or an adhesion layer e.g. of Cr above it. By altering the angle, the porosity and pore size of the metal film can be modified so that a small value of the angle alpha gives an extremely porous layer of large pore size, while a larger value of the angle alpha results in a less permeable layer of smaller pores.
Good adherence is attained by first vacuum evaporating a layer of a slightly self-oxidizing metal (such as Cr, Ni or Ti) to a thickness of 10-300 nm. The plugging of pores through oxidation is prevented by subsequently vacuum evaporating from the same angle a precious metal layer (of Au, Pt or Pd) to a thickness of 10-300 nm. Typically, the total thickness of these layers is in the range 30-400 nm.
Advantageously, the pore size (minimum diameter of the pores) is smaller than 30 nm, whereby a filtering effect against high-molecular-weight molecules is achieved.
In
This arrangement is presented in more detail in
In
In accordance with
According to
or according to
In connection with capacitive humidity sensors the relative humidity may be calculated by a known formula (VIZ) using the temperature information of the ambient air in accordance with the following known formula, when the sensor is heated above the temperature of the ambient air. This principle may be used if heating is used in connection with the present invention.
where
RHa=true relative humidity
RHs=relative humidity of a mixture contiguous with
a humidity sensitive film on a substrate
eWs=the saturation vapor pressure at the substrate
temperature measured by temperature sensor
eWa=saturation vapor pressure of the surrounding mixture at temperature Ta
Ts=substrate temperature measured by temperature sensor
Ta=ambient temperature measured by independent sensor
Specifications for the Catalytic Sensor 2 in Accordance with
2 capacitance measurements for elements 1 and 2.
2 resistance measurements.
Heating of sensor element 2 triggered by high RH-value.
The humidity sensor 2 with an evaporated catalytic layer (Pt) deposited on protective polymer film may be formed in an advantageous solution with the following parameters:
Pt-layer 16 is evaporated on 14° angle.
Thickness of Pt layer 16 is typically 1000 nm.
Adhesion layer Cr (thickness about 50 nm) is formed between polymer 15 and Pt-layer 16.
Protection layer is formed on CrNiAu-lead (LIMA: SiAlOx).
As a conclusion the measurement is based on measurement of two RH-sensors 1 and 2. One with a catalytic protection layer 2 is used to measure partial water pressure (RHcat) and the other 1 without the catalytic layer is used to indicate mixture of hydrogen peroxide and water (RHmix).
The catalytic sensor 2 comprises e.g. a Pt layer 16 as catalytic decomposer purpose to prevent H2O2 penetration in sensing polymer.
Difference between readings of the sensors RHmix (sensor 1) and RHcat (sensor 2) indicates the vapor concentration of H2O2.
In the following equations when a calibration option with sensor heating is used in accordance with
RHmix=Pw/Pwsmix
RHcat=(Pw+Pw(H2O2))/Pws
<1 ppm H2O2 then RHmix=RHcat
or
<−1 ppm H2O2 then RHmix=RHcat
This is executed by changing Cdry of RHmix sensor.
Method works if drift in one sterilization cycle is less than 1 ppm (0.4% RH in 25° C.)
Alternative Solutions of the Invention:
Suitable materials for the porous decomposition layer 16 are listed in the following:
Pt, Rh, Ag, Mn or other transition metal and their compounds.
Objects to be measured are listed in the following:
hydrogen peroxide, ozone, peracetic acid or other catalytically degradable substance.
As humidity sensors may be used any humidity sensor structures that can be measured electrically.
The measurement may be based e.g. on:
Essential for the invention is an element, typically a layer 13 sensitive to humidity, especially to relative humidity. The sensitivity may be based on change of permittivity (capacitive measurement), conductivity (measurement of resistivity) or mass (resonators). Materials sensitive for these parameters are polymers, ceramics and composites.
The material 13 sensitive to the relative humidity may be positioned on the sensor or sensor field or inside the sensor structure, typically between sensor layers. Also cylindrical structures are possible.
The catalytic layer (decomposition layer) 16 may also act as a surface electrode for the measurement.
In connection with the invention the catalytic permeable layer 16 encloses the sensing element 13 at least essentially. This means in practice that the catalytic permeable layer 16 has to cover the sensing element 13 so well that the decomposition happens to the substance Ox to be measured in such a way that content of Ox may be calculated. Typically the coverage of the sensing element 13 by the layer 16 is around 70-100%, most preferably around 90-98%.
In one embodiment of the invention only one sensor may be used but the measurement is made such that the sensor gets sequentially measurement gas in a first phase directly from the space to be measured and in the second phase through a catalytic permeable layer 16 and these results from these two phases will be compared like the results of the two sensors 1 and 2 in the other embodiments of the invention. In this embodiment the permeable catalytic layer 16 may function also as a particle filter for the sensor.
In accordance with the invention the catalytic permeable layer 16 is only one embodiment of the invention. The catalytic reaction needed for reference measurement may be performed in many ways, for example by a catalytic matrix structure, catalytic particle filter, catalytic particle cloud in a fluidized filter structure etc.
The reference measurement by one sensor on the other hand may be performed in a sequentially with alternating flows through the sensor either directly from the object to be measured or through or in contact with a material reacting catalytically with the gas to be measured. Then the two measurements will be compared repeatedly with each other in accordance with the two sensor measurement described above.
In one preferred embodiment of the invention with two sensors at least one reference measurement is made with such a gas that does not include the gas to be measured (Ox) in order to compensate any difference between the two sensor readings. By this procedure drifting or the sensors may be eliminated.
Number | Date | Country | Kind |
---|---|---|---|
20135595 | May 2013 | FI | national |
Filing Document | Filing Date | Country | Kind |
---|---|---|---|
PCT/FI2014/050416 | 5/27/2014 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2014/191619 | 12/4/2014 | WO | A |
Number | Name | Date | Kind |
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4244918 | Yasuda et al. | Jan 1981 | A |
5362975 | von Windheim | Nov 1994 | A |
6955787 | Hanson | Oct 2005 | B1 |
20020142478 | Wado | Oct 2002 | A1 |
20040026268 | Maki et al. | Feb 2004 | A1 |
20050013726 | Hill et al. | Jan 2005 | A1 |
Number | Date | Country |
---|---|---|
4244223 | Jun 1994 | DE |
19610912 | Sep 1997 | DE |
0334614 | Sep 1989 | EP |
0665303 | Aug 1995 | EP |
2009432 | Dec 2008 | EP |
2418482 | Feb 2012 | EP |
2011093 | Jul 1979 | GB |
2001183326 | Jul 2001 | JP |
WO2007122287 | Nov 2007 | WO |
WO2008009329 | Jan 2008 | WO |
Entry |
---|
Supplementary Search Report in EP 14 80 5060, dated Dec. 21, 2016. |
International Search Report received in PCT/FI2014/050416, dated Sep. 18, 2014, 7 pgs. |
Number | Date | Country | |
---|---|---|---|
20160084811 A1 | Mar 2016 | US |