JP5086195B2 - Contact combustion type gas sensor - Google Patents

Description

  The present invention provides a contact combustion type gas sensor that is resistant to thermal stress deformation.

  As a conventional catalytic combustion type gas sensor, for example, the one shown in FIG. 3 is generally known (Patent Document 1). As shown in the figure, the catalytic combustion gas sensor 1 has a sensor element 101 and a comparison element 102. The sensor element 101 includes a heater element 26 formed of a platinum coil and a support layer that supports the catalyst that promotes contact combustion with the detection target gas applied to the heater element 26. The comparison element 102 includes a heater element 26 and an alumina layer that is applied to the heater element 26 and does not react with the detection target gas.

  The heater element 26 of the sensor element 101 and the heater element 26 of the comparison element 102 are provided so as to have the same resistance value in the air without the detection target gas. The sensor element 101 and the comparison element 102 described above constitute a bridge circuit 103 together with the resistors R1 and R2 and become a sensor unit of the catalytic combustion gas sensor 1. A driving voltage Eo is supplied between the terminal a and the terminal b of the bridge circuit 103. When the drive voltage Eo is supplied, the sensor element 101 is heated and combusts in contact with the detection target gas.

  In the air containing the detection target gas, the temperature of the sensor element 101 rises due to the combustion heat with the detection target gas, and the resistance value of the heater element 26 of the sensor element 101 increases accordingly. The equilibrium current Iu increases. The unbalanced current Iu is a value corresponding to the concentration of the detection target gas. A meter connected between the terminals c and d of the bridge circuit 103 converts the unbalanced current Iu into a voltage and outputs it as an output Vs corresponding to the detection target gas.

  In the conventional catalytic combustion gas sensor 1 described above, by configuring the bridge circuit 103 including the sensor element 101 and the comparison element 102, the output Vs is affected by the influence of the change in the ambient temperature and the change of the sensor element 101 over time. It can be a value that is hardly received. That is, when the resistance value of the heater element 26 that constitutes the sensor element 101 increases or decreases as the ambient temperature varies, the resistance value of the heater element 26 that constitutes the comparison element 102 similarly decreases. For this reason, the output Vs is not affected by changes in the ambient temperature (environmental temperature), and a value corresponding to the concentration of the detection target gas can be calculated to detect the concentration of the detection target gas.

  In recent years, these catalytic combustion type gas sensors 1 can save power by reducing the thermal time constant when energizing the heater element 26 as much as possible so that the required heating temperature can be obtained even when intermittently energized. In order to meet this demand, the contact combustion type gas sensor 1 in which the sensor element 101 and the comparison element 102 are provided on the diaphragm is often used. The configuration of such a catalytic combustion type gas sensor 1 will be described below with reference to FIGS.

FIG. 4 shows a top view of the catalytic combustion type gas sensor 1 described above, and FIG. 5 shows a cross-sectional view taken along the line II of FIG. The catalytic combustion gas sensor 1 includes a support base 22, an electrode terminal 13, and a diaphragm D in addition to the sensor element 101 and the comparison element 102. The support base 22 is made of, for example, silicon. As shown in FIG. 5, the support base 22 includes a depressed portion 27. The pair of electrode terminals 13 are provided on the support base 22. A diaphragm D is formed on a depression 27 formed on the support base 22. The diaphragm D includes a first connecting portion 14A and a second connecting portion 14B . The plurality of connecting portions 14 are connected to the diaphragm D and the support base 22 to support the diaphragm D. The heater element 26 constituting the sensor element 101 and the comparison element 102 includes a main body portion 28 and a connection portion 29. In the main body 28, the heater element 26 is provided on the diaphragm D. In the connection portion 29, the heater element 26 extends from the main body portion 28 and is connected to the pair of electrode terminals 13. A connecting portion 29 of the heater element 26 is mounted on the first connecting portion 14A .

  A sensor element 101 and a comparison element 102 are provided on the diaphragm D, respectively. A pair of electrode terminals 13 are connected to both ends of each of the sensor element 101 and the comparison element 102. When a voltage is applied to the electrode terminals 13, the heater element 26 is heated and contacted and combusted with the detection target gas. The detection target gas concentration is detected by capturing the change in the resistance value accompanying the rise of the gas.

In the catalytic combustion gas sensor 1 described above, the heater elements 26 are provided on the two first connecting portions 14A among the four connecting portions 14 that connect the support base 22 and the diaphragm D. The heater element 26 is not provided on the remaining two second connecting portions 14B .
JP 2001-99798 A

However, in the method described above, a difference occurs in the film stress depending on the presence or absence of the heater element 26 provided on the connecting portion 14 . In addition, there is a difference in the heat transmitted depending on the presence or absence of the heater elements 26 provided on the plurality of connecting portions 14 during heat generation. Distortion of warpage or twisting, etc. the connecting portion 14 by this reason aging occurs, there is a possibility that connecting section 14 is broken.

  Therefore, the present invention pays attention to the above-described problems, and an object thereof is to provide a contact combustion type gas sensor 1 that is resistant to thermal stress deformation.

In order to solve the above-mentioned problems, an invention according to claim 1 comprises a support base having a recess, a pair of electrode terminals provided on the support base, and a recess on the support base. A heater element having a membraned diaphragm, a main body provided on the diaphragm, and a connection portion extending from the main body and connected to the pair of electrode terminals, and the pair of electrodes When a voltage is applied to the terminal, the heater element heats, and in contact combustion type gas sensor that captures a change in resistance value accompanying a temperature rise due to contact combustion with the detection target gas, the diaphragm further extends from the main body. A dummy member that conducts heat from the heater element in response to application of a voltage to the electrode terminal is provided; the diaphragm is connected to the support base; and a connecting portion of the heater element is provided Tower A first connecting portion which is, the support connected to the base, and a second connecting portion in which the dummy member is mounted, a catalytic combustion type gas sensor characterized in that it comprises a.

As described above, according to the first aspect of the present invention, the heat from the heater element 26 is generated according to the application of the voltage to the electrode terminal 13 among the plurality of connecting portions 14 provided in the catalytic combustion gas sensor 1. by mounting a dummy member C to conduct the second connecting portion 14B to the second coupling portion 14B, it is possible to relieve the stress balance due to the difference in the film configuration of the first connecting portion 14A and the second connecting portion 14B. When a voltage is applied to the electrode terminals 13, the heater element 26 is heated, the first connecting portion 14A and, by equalizing the heat transmitted to the second connecting portion 14B, Ya warpage of the connecting portion 14 due to aging Provided is a catalytic combustion type gas sensor 1 which can be used for a long period of time by reducing breakage due to distortion such as torsion.

  Hereinafter, an embodiment of the present invention will be described with reference to the drawings. FIG. 1 is a top view of the catalytic combustion type gas sensor 1, and FIG. 2 is a cross-sectional view taken along the line II of FIG.

The catalytic combustion type gas sensor 1 includes a support base 22, a pair of electrode terminals 13, a diaphragm D, a sensor element 101, a comparison element 102, a heater element 26, a first connecting portion 14A, and a second connecting portion. 14B and a dummy member C. The sensor element 101 and the comparison element 102 have the same shape. The difference in configuration will be described later.

  The support base 22 is made of, for example, silicon. The substantially rectangular support base 22 includes a pair of depressions 27. The depression 27 is formed by different direction etching. An insulating thin film 32 is formed on the support base 22.

  The three electrode terminals 13 are located on the support base 22.

The diaphragm D is made of, for example, silicon oxide (SiO ₂ ), silicon nitride (SiN), hafnium oxide (HfO ₂ ), or the like. The diaphragm D is a part of the insulating thin film 32 that is formed on each of the pair of depressions 27 on the support base 22. The diaphragm D has a small heat capacity when formed in a thin film. A sensor element 101 and a comparison element 102 to be described later are formed on the diaphragm D having a small heat capacity. A hole 25 is formed in the diaphragm D by etching in different directions. As shown in FIG. 1, four holes 25 are formed in a substantially L shape.

The sensor element 101 includes a heater element 26 and a support layer 24A that supports a catalyst that promotes contact combustion with the detection target gas. The heater element 26 includes a main body portion 28 and a connection portion 29. A main body 28 of the heater element 26 is formed on the diaphragm D. The connection portion 29 of the heater element 26 is formed by extending the connection portion 29 from the main body portion 28 and connecting to the pair of electrode terminals 13. The heater element 26 is made of, for example, platinum (Pt). The support layer 24A is made of alumina (Al ₂ O ₂ ) and a catalyst. The catalyst is a catalyst for promoting catalytic combustion with the detection target gas. As shown in the cross-sectional view of FIG. 2, the sensor element 101 has a heater element 26 formed on a diaphragm D made of an insulating thin film 32, and an insulating thin film 21 formed on the diaphragm D for the purpose of protecting the heater. A layer 24A is formed. According to the above configuration, when a voltage is applied to the pair of electrode terminals 13, the heater element 26 is heated and combusts in contact with the detection target gas.

  The sensor element 101 and the comparison element 102 have the same shape. The difference in configuration will be described below.

The comparison element 102 includes a heater element 26 and an alumina layer 24B. The heater element 26 includes a main body portion 28 and a connection portion 29. A main body 28 of the heater element 26 is formed on the diaphragm D. The connection portion 29 of the heater element 26 is formed by extending the connection portion 29 from the main body portion 28 and connecting to the pair of electrode terminals 13. The heater element 26 is made of, for example, platinum (Pt). The alumina layer 24B is formed of alumina (Al ₂ O ₂ ). As shown in the cross-sectional view of FIG. 2, the comparison element 102 has a heater element 26 formed on a diaphragm D made of an insulating thin film 32, and an insulating thin film 21 formed thereon for the purpose of protecting the heater. An alumina layer 24B is formed. According to the above configuration, when a voltage is applied to the pair of electrode terminals 13, the heater element 26 is heated.

The first connecting portion 14A is connected to the support base 22 and supports the diaphragm D. A connecting portion 28 of the heater element 26 is mounted on the first connecting portion 14A . Two first connecting portions 14A are formed on the diaphragm D.

The second connecting portion 14B is connected to the support base 22 and supports the diaphragm D. Two second connecting portions 14B are formed. The first connecting portion 14 < / b > A and the second connecting portion 14 </ b> B are formed in a square shape and connected to the support base 22. It is equipped with dummy member C to conduct heat from the heater element 26 to the second connecting portion 14B in accordance with the application of voltage to the electrode terminals 13 in the second connecting portion 14B. The dummy member C is provided to extend from the heater element 26. Thereby, the heater element 26 is mounted on the first connecting portion 14A, and the dummy member C made of the material forming the heater element is mounted on the second connecting portion 14B .

As described above, the heater element 26 is mounted on the first connecting portion 14A, and the dummy member C made of the material forming the heater element is mounted on the second connecting portion 14B . The film stress of the two connecting portions 14B is equal. Thereby, the thermal stress balance by the difference in the film | membrane structure of the 1st connection part 14A and the 2nd connection part 14B can be eased. Further, when an electrode is applied to the electrode terminal 13, the transmitted heat is equalized to the plurality of connecting portions 14 to alleviate breakage due to distortion such as warpage or twisting of the connecting portions 14 due to changes over time, and for a long time. Provided is a contact combustion type gas sensor 1 that can be used over a wide range.

In the above-described embodiment, the connecting portion 14 is formed in a square shape, but the present invention is not limited to this. In the embodiment described above, the dummy member C is formed by extending a part of the heater element 26, but the present invention is not limited to this. For example, a separate member from the heater element 26 may be used as the dummy member C.

  The above-described embodiments are merely representative forms of the present invention, and the present invention is not limited to the embodiments. That is, various modifications can be made without departing from the scope of the present invention.

It is a top view which shows one Embodiment of the contact combustion type gas sensor of this invention. It is the II sectional view taken on the line of FIG. It is a circuit diagram which shows an example of the conventional catalytic combustion type gas sensor. It is a top view which shows an example of the conventional catalytic combustion type gas sensor. It is the II sectional view taken on the line of FIG.

DESCRIPTION OF SYMBOLS 1 Contact combustion type gas sensor 13 Electrode terminal 14A 1st connection part 14B 2nd connection part 22 Support base 26 Heater element 28 Main-body part 29 Connection part C Dummy member D Diaphragm

Claims (1)

A support base with a recess,
A pair of electrode terminals provided on the support base;
A diaphragm formed on the concave portion of the support base;
A heater element having a main body portion provided on the diaphragm and a connection portion extending from the main body portion and connected to the pair of electrode terminals ,
When a voltage is applied to the pair of electrode terminals, the heater element is heated, in contact combustion with a detection target gas, and in a contact combustion type gas sensor that captures a change in resistance value accompanying a rise in temperature,
A dummy member extending from the main body portion and conducting heat from the heater element in response to application of a voltage to the electrode terminal is provided on the diaphragm.
The diaphragm is connected to the support base, and a first connecting portion on which the heater element connecting portion is mounted;
A contact combustion type gas sensor comprising: a second connection portion connected to the support base and mounted with the dummy member .

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