DE2443270A1 - TEMPERATURE GAUGE - Google Patents

Description

Temperature meter
Priority: September 14, 1975 - Italy

The invention relates to a temperature meter and, more particularly, to a temperature meter suitable for use in a catalytic exhaust of an internal combustion engine. ·

There are many cases where it is necessary to know when to regulate a procedure or for other purposes a temperature of an element or a room has reached a certain critical value, although it is not it is necessary to determine the temperature itself or other values. Well-known temperature gauges, such as electrical ones Resistance thermometers, or thermocouples, suffer from various disadvantages when used for this purpose. Apart from the fact that they are not very sensitive they have to be calibrated (a job that is normally done by the room temperature and also by the too measuring temperature is affected). After calibration, they are still subject to considerable deviations,

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which make them inaccurate. In addition, there are such devices expensive, and when it is only necessary to determine a critical temperature and not an accurate measurement To perform over a certain area, then the cost of such devices is for the perceived function disproportionately high. Finally, the use of such devices is wasteful as their Possible applications are not fully exploited.

Such devices are also only available at a specific one Point or only sensitive within a small area or volume, while in many cases it is necessary to know whether the temperature has reached a predetermined critical value at any point in a relatively large range or has reached a relatively large volume. In these cases it is therefore necessary to use a large number of temperature meters to be used in different locations within the area or volume being monitored should be arranged so that the temperature can be monitored within substantially the entire range will. This, of course, is complicated and expensive.

The need for monitoring the temperature within a relatively large area occurs, for example, in the case of catalytic exhausts from internal combustion engines Motor vehicles in which the combustion of the exhaust gases in the exhaust is completed by the percentage to reduce the air pollutants as it is necessary within the entire area where the combustion occurs of the exhaust gases takes place to carry out a monitoring.

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The technical problem of the present invention is to create a temperature meter that works with accuracy and can determine without any calibration if the temperature is anywhere or in a part of a temperature-sensitive Element reaches a predetermined value, and which emits a clearly defined signal when this condition occurs.

The present invention was therefore based on the object to provide a temperature meter of the type mentioned which has a relatively large range or a relatively can monitor large volumes, which also has a high: he has reliability and is economical to manufacture and which ultimately has a shape that is suitable for one catalytic exhaust can be used.

Thus, according to the invention, a temperature meter of this type is proposed which has a temperature-sensitive element and a detector device responsive to the temperature sensitive Element responds, having, the characteristic being that the temperature sensitive element is a material comprises, which undergoes a physical or chemical change at a predetermined temperature, and that the Detector device responds to said change in the material and an output signal as a function of this generated which corresponds to the occurrence of said predetermined temperature.

The advantage of the temperature meter according to the invention lies in their simplicity and economy compared to the previously known temperature meters. As they only when reaching respond to a predetermined temperature and only emit an output signal when this has reached a predetermined temperature there is no need for complex and expensive calibration processes.

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The invention will now be explained in more detail with reference to the accompanying drawings.

In the drawings show:

Fig. 1 is a schematic representation of a first embodiment of the device according to the invention, which for the Use is included in a typical circuit;

Fig. 2 is a schematic representation of a temperature-sensitive Element of another embodiment of the invention Contraption;

Fig. 3 is a schematic representation of a temperature-sensitive Elements of a further embodiment of the invention Device suitable for use in a catalytic exhaust of an internal combustion engine suitable; and

4 shows a schematic representation of a temperature-sensitive Element of a fourth embodiment of the device according to the invention.

Fig. 1 thus shows a knife 2 with a bladder 10, which can be introduced into a room to be monitored to determine whether a predetermined temperature is present. The bladder 10 consists of a closed container made of conductive material, in which there is a chemical substance C, in which an electrode 20 is immersed. The container 10 is connected to the earth T via a conductor 12. When the above device is used to measure a temperature in a catalytic exhaust pipe of a motor vehicle should be, then the grounding point T from the

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Exhaust pipe or from the chassis or body of the Vehicle exists.

The electrode 20 is built into a circuit which is a Source of electrical power, in this example a battery 14, and a current sensitive circuit 30 which connected at 22 to earth. According to Pig. I the temperature-sensitive circuit J50 is connected via an amplifier 4o to a processor 50 of known design, the output of which is led to an actuator βθ, the mechanical connected to a controller (not shown) that can regulate the temperature in the room in which the Bladder 10 is located. The controller (not shown) comes into action when the processor 50 issues an output signal, indicating that a predetermined temperature has been reached so that the temperature of the exhaust is below the predetermined Value is held.

Chemical substance C can be any substance, the one Change of state or aggregate change or in particular experiences a phase change at a predetermined critical temperature, at least one of the phases being conductive is so that a power line either immediately below or immediately above said critical Temperature occurs. It is known that conductivity of many substances changes when the substance of one Phase changes into another. For some fabrics this is The change in conductivity in the case of a phase change is only very pronounced. Such substances are preferred for the temperature meter according to the invention.

The device described in Fig. 1 operates as follows: The battery 14 supplies via the electrode 20, the substance C,

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the bladder 10 and line 12 current to earth. The value of the current depends on the conductivity of the substance C and is scanned by the current-sensitive circuit J> 0. The temperature meter 2 is located in the room to be monitored, the substance C being selected so that a phase change takes place at the critical temperature, which is below the temperature at which the room in which the bladder 10 is to be maintained is introduced. When the temperature of the room reaches this critical value, substance C changes its phase, which is why the conductivity also changes. As a result, the current in the circuit including the temperature meter 2, the battery 14 and the current sensitive circuit 30 suddenly changes. This change is detected by the current sensitive circuit which sends a signal proportional to the change through amplifier 40 to processor 50 and then to actuator βθ which acts to appropriately lower the temperature in the room. The amplifier 40 is not essential because generally the signal obtained is sufficiently large that it can be fed directly into the processor 50.

The chemical substance C can be an inorganic salt that experiences a change in conductivity in the event of a phase change and which preferably does not have any corrosive properties, or be an organic salt, so that's a compound which consists of an organic acid radical and a metal. Sodium chlorite and sodium and potassium salicylate have proven to be particularly suitable for this purpose, as they cause large changes in conductivity when there is a phase change result.

Fig. 2 shows a temperature meter which can be used can, if the bladder 10 is made of an insulating material

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must stand and cannot be connected to the earth. In this case, two electrodes 102 and 104 are used, one of which is connected to and from earth the other of which is connected to a circuit which is the same as in FIG.

A further embodiment of the device according to the invention is particularly suitable for those cases when it is · desirable to detect the occurrence of a predetermined critical temperature within a certain point, a relatively large area, is overall in FIG. J>. shows. In this embodiment, the bladder 202 is of considerable length. It has an electrode ΙΟβ which extends essentially over the entire length of the bladder 202. If, in this case, the temperature of the space surrounding the bubble 202 reaches the predetermined critical value only at one point along the bubble 202, so that only a small part of the substance C experiences a phase change, then there is nevertheless a sufficient change in conductivity and thus a sufficient change in the current flow through circuit J50, so that a. Output signal arises which acts on the processor 50 and the actuator βθ, so that the necessary measures are taken to achieve a reduction in the temperature in the space surrounding the bubble 202. The bladder 202 can be of considerable length, which is particularly important when it is to be used for monitoring the temperature in a catalytic exhaust. In this way, a considerable volume can be monitored with just one device. For such an application, the bladder 202 is inserted into a bore in the exhaust so that it extends substantially the entire length thereof so that, as described above, with a single bladder the entire volume of the exhaust which is below a predetermined critical

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Value must be maintained, can be monitored. If the Bladder 202 is made of a conductive material then it may be connected to ground as shown in FIG. 3. If, on the other hand, it is necessary for the bladder 202 to be made of an insulating material, or if it is of another If the reason cannot be connected to the earth, it can be equipped with two electrodes, one of which with the earth and the other is connected to the circuit as seen in FIG.

It is not essential that the thermometer bladder be circular in cross-section. Fig. 4 shows an embodiment with an elongated bladder 502 forming a possesses elliptical cross-section. In this embodiment, the bladder is again coated with a chemical C packed. There are two thin parallel plates J504, 506 that represent the electrodes of one connected to the ground and the other connected to a circuit as shown in FIG.

Other embodiments (not shown) can be used for monitoring temperature over a wide range and not just be constructed within a length. In such an embodiment, the bladder has the Shape a flat container and the electrodes shape of flat, parallel plates. Similarly, the axis of the measuring device need not be necessarily be straight, but it can also be curved so that it follows a space of certain shape, so the temperature monitoring can be carried out within such a volume.

Numerous other shapes and dimensions are possible for the bladder and electrodes without departing from the area of the

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Invention is deviated. Similarly, the Substance C can be any suitable material that exhibits a change in conductivity having at a critical temperature. Furthermore, the field of application of the invention is not limited to catalytic exhausts, but it extends to all possibilities where a critical Temperature is to be monitored.

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Claims (12)

- ίο - Claims / IJ temperature meter of this type, which is a temperature-sensitive Element and a detector responsive to the temperature sensitive element having thereby characterized in that the temperature-sensitive element contains a material (C) which at a predetermined Temperature experiences a physical or chemical change, and that the detector (30, 40, 50) on responds to said changes in the material (C) and emits an output signal which indicates that the predetermined Temperature indicated by the temperature sensitive element. 2. Temperature meter according to claim 1, characterized in that indicates that the material (c) changes from a first state to a second at the predetermined temperature State changes and that the detector (30) has a first constant output signal below the predetermined Gives temperature when the material (C) is in the first state, and a second constant signal. above the predetermined temperature when the material (C) is in the second state. 3 · Temperature meter according to claim 1 or 2, characterized characterized in that the electrical conductivity of the material (C) changes at the predetermined temperature results, wherein the detector (14, 30, 40) works so that an electric current through the material (C) passes through it and that it is responsive to the current passing through it, which changes as the conductivity changes changes. 509832/0647 - π - 244327Ό 4. Temperature meter according to one of the preceding claims, characterized in that the material (C) has a Experiences phase change at the predetermined temperature, the phase change being a change in conductivity of the Materials (C) causes. 5 temperature meter according to one of the preceding claims, characterized in that the temperature-sensitive element has a container (10) in which at least one electrode (20) is located and which is largely filled with said material (C) * so that it surrounds the electrode (20). 6. Temperature meter according to one of the preceding claims, characterized in that the material (C) consists of consists of an inorganic salt. 7. Temperature meter according to one of claims 1 to 5, characterized in that the material (C) consists of a organic salt. 8. Temperature meter according to one of claims 5 * 6 or 7, characterized in that the container (10) consists of a conductive material and as an electrode for the passage of current acts through the conductive material to or from the electrode (20). 9. Temperature meter according to claim 5, 6 or 7> characterized in that the container (10) consists of an insulating Material consists and that two electrodes (102, 104; 304, 506) are immersed in the material (C) in the container (10) are. '■ ". · 10. Temperature meter according to one of claims 5 to 9, characterized in that the container (10) has a bubble 509832/0647 ■ 2U327Q has shape. 11. Temperature meter according to one of claims 5 to 9, characterized in that the container (10) and one or more of the electrodes (102, 1O4, J> Qk, J5O6) arranged therein have an elongated shape. 12. Temperature meter according to one of claims 5 to 9 * characterized in that the container (10) has a greater width than the depth and that the electrode or the electrodes have a plate shape. Ij5. Use of the temperature meter according to one of the claims 1 to 12 in a catalytic exhaust for an internal combustion engine. t »H-) MO. H. PlNCKE DIPt.-tNG. H. BOMK DIPL.-ING. S. STAEGSB 509832/0647