DE19756161A1 - Sensor for detecting electrically insulating fluid or loose material - Google Patents

Abstract

The sensor has a casing (1) screwed into a mounting in a wall, with an electrically insulating plastics insert (3) having a metallic sensor point (4) in direct contact with the material to be detected, and coupled to the inner conductor (11) of a coaxial cable (5). A high frequency oscillator has an inverting input coupled to the inner conductor and an output coupled to the relatively insulated outer screening (12) of the coaxial cable.

Description

The sensor is used to detect the presence of electricity insulating liquids or granules. It consists of a housing that can be screwed into a wall, which is preferred is made of metal, and is with a coaxial built connection cable to a high-frequency oscillator connected.

Sensors of the type mentioned are used for this Fill levels of different media inside of Rohrlei detections or containers. The principle of operation be rests on an electrode immersed in the medium acts as part of a capacitor, the electrode first capacitor plate and the preferably metallic Container wall forms the second capacitor plate. Each Medium that occurs between the electrode and the container wall, acts as a dielectric of this capacitor described in this way and changes its capacity. They are different ver known to take advantage of this change in capacity derive a measurement signal from this. In the scriptures DE 27 44 820 A1, DE 30 26 342 A1, DE 38 43 339 A1, DE 42 38 992 A1 an oscillator is affected when the electrode capacity is increased, whose vibrations after demodulation of an electri be evaluated.  

Another method is that the charging current capacitance to be detected evaluated and ver to a signal will work. This is in the document DE 197 01 899 A1 described in detail. All known technical solutions has in common that it is assumed that the in the Medium inserted sensor in relation to the to be detected the amount of liquid or in relation to the container dimensions in which he screwed in is small. Also with the be applications knew the detection electrode from an iso lating material includes, so that the direct to an amplifier closed electrode electrically in no direct contact with the medium to be recorded.

Such sensor designs described above fail if the dielectric constant of the medium is small, such as this is often the case with electrically insulating media, and if the distance between the sensor electrode and the container wall is small if it is only a fraction of the electrical diameter is.

The object of the invention is to design a sensor that the above Avoids disadvantages of good mechanical Stability a distance between the sensor tip and the container wall of only a few millimeters, the electric insulating media with a small dielectric constant safely detected and for use at temperatures up to 300 ° C is suitable, this suitability not only the includes thermal and mechanical stability, but wherever the drift of the electrical signal due to thermal influences suppressed or at least significantly reduced and a Process for drift-free and interference-free evaluation of the Change in capacitance of the sensor when immersing the sensor to indicate peak in medium.  

The solution to this problem is in claim 1 and the related claims.

The sensor consists of a housing that can be screwed into a container wall and has a metallic pin on the medium side, which plunges into the medium. The housing is open on the side facing away from the medium, a coaxial cable being inserted into this opening. The cable entry is preferably completed by a suitable cable gland. The coaxial cable has an inner conductor that is electrically connected to the metallic probe tip. The inner conductor of the coaxial cable is surrounded by a first screen, which in turn is isolated by a second screen. If the sensor housing is made of metal, the second screen is electrically connected to the sensor housing. The open side of the sensor housing facing the medium is provided with a thread into which a high-temperature-resistant plastic or ceramic insert is screwed. In this application, the metallic sensor tip is preferably anchored via a thread. The first shield of the coaxial cable is brought into the insert near the connection point between the sensor tip and the inner conductor of the coaxial cable, but is not connected to it. This design suppresses parasitic capacitances that act on the metallic sensor tip inside the sensor housing. The high-strength material of the insert prevents the connection between the inner conductor of the coaxial cable and the sensor tip from being tired, torn off or damaged when the sensor tip is subjected to mechanical stress. Since by that the sensor tip 4 is not electrically insulated from the medium to be detected, a medium washing around the sensor tip, with a gap width of the sensor tip to the surrounding container wall of a few millimeters, e.g. B. 1.5 mm, can be detected safely. A reliable detection is obtained even if the sensor tip is only a short distance from the container wall, e.g. B. 1 mm.

Due to the stable construction of the sensor, no bending of the sensor system can occur even at high temperatures up to 300 ° C, so that a drift of the detected capacitance is suppressed. The drift of the electrical evaluation can preferably be significantly reduced by the fact that a periodically switched switch is provided by an oscillator, which periodically connects the input of the evaluating high-frequency oscillator to the inner conductor of the coaxial cable and a reference capacitor connected to the ground. This system is adjusted so that when the medium is not detected and the sensor is installed, the comparison capacitor is dimensioned such that the high-frequency oscillator 8 changes its frequency only insignificantly during the switching process. If the capacitance of the sensor tip increases when immersed in a medium, there is a periodic frequency change at the output of the oscillator amplifier 8 . This frequency change is converted into an evaluable signal in the frequency demodulator connected downstream of the high-frequency oscillator output.

The invention is based on several exemplary embodiments explained in more detail.

Fig. 1 shows a screw-in a container sensor part 1. It has a threaded part 2 , which ensures the sealing of the interior of the container from the outside. On the medium side, a high-temperature-resistant, electrically insulating insert 3 is screwed into the housing 1 . In this insert, the sensor tip 4 is embedded on the face, preferably screwed in.

The sensor tip 4 is electrically connected to the inner conductor of the coaxial cable 5 . The first screen 12 is brought up to the connection point of the inner conductor with the sensor tip, but is not electrically connected to it. The second screen 13 is inserted into the housing 1 in an electrically insulated manner from the first screen and is electrically connected 6 to it . The coaxial cable 5 is inserted into the housing 1 through a cable screw connection (not shown here). The remaining interior between the coaxial cable and the inner part of the housing 1 is covered with a high temperature resistant medium, e.g. B. ceramics.

Fig. 2 shows the electrical connection of the sensor part above be written to the electrical evaluation. The inner conductor of the coaxial cable 11 is connected directly to the inverting input of a high-frequency oscillator 8 . The output of the high-frequency oscillator 8 is connected to the first screen. The phase position of the high-frequency oscillator between points 11 and 12 is approximately 180 °. The second screen 13 is connected to the ground point of the high frequency oscillator. The output of the oscillator is connected to a demodulator 9 , which forwards the demodulated signal to an evaluating amplifier 10 , which can have both a switching and an analog output.

A further development of the evaluating electronics is shown in FIG. 3. The input 11 of the evaluating high-frequency oscillator 8 is connected to a switch 22 which is periodically controlled by a second oscillator 21 .

The switch alternately connects the inner conductor of the coaxial cable 5 and the capacitor 23 , which is at ground potential, to the input 11 of the oscillator 8 . The capacitor 23 is tuned so that the resulting frequency change of the oscillator during the switching process is small when the medium is not detected. If the capacitance of the sensor tip increases due to contact with the medium, the frequency change of the oscillator is greater, so that periodic frequency changes of the oscillator 8 are present. The output of the oscillator 8 is connected to a frequency modulator, which preferably converts the frequency change into an analog signal. In a further development of the electrical evaluation, the demodulator 9 is designed as a frequency voltage converter, to the output of which a circuit 25 is connected, which causes the electrical voltages which are at its input to be differentiated. An integrator 26 is advantageously connected to the output of the circuit 25 . The formation of the differential voltage is caused in this representation in that a second switch 24 is controlled by the second oscillator and this switch with the two inputs of the switching circuit 25 on the one hand and the demodulator 9 on the other hand is connected. The first switch 22 and the second switch 24 are synchronously controlled by the oscillator, which can also be formed as a clock, so that the capacitance of the sensor tip 4 to its surroundings and the capacitance 23 mutually determine the frequency of the high-frequency oscillator 8 . This arrangement is particularly of great advantage because common mode signals, which are superimposed on the leads to both capacities, are added after demodulation and integration with the opposite sign and are therefore significantly reduced.

Claims (9)

1. Sensor for detecting the presence of electrically insulating liquids or granules, with a screw-in housing into a wall ( 1 ), with an electrically insulating plastic insert ( 3 ), with a metallic sensor tip ( 4 ), which is in direct contact with the sensor medium to be detected, with a coaxially constructed connecting cable ( 5 ), the inner conductor ( 11 ) of which is electrically connected to the sensor tip ( 4 ) and where the inner conductor ( 11 ) and the first screen ( 12 ) are electrically insulated from each other, close to the Connection point of the inner conductor ( 11 ) is brought up to the sensor tip ( 4 ) with a high-frequency oscillator ( 8 ), at the inverting input of the inner conductor ( 11 ) and at the output of which the first screen ( 12 ) is connected. 2. Sensor according to claim 1, characterized in that the high-frequency oscillator ( 8 ) consists of a he the oscillator amplitude generating and an amplitude inverting part. 3. Sensor according to one or more of claims 1-2, characterized in that a second oscillator ( 21 ) is provided which actuates a first switch ( 22 ) which periodically the inner conductor ( 11 ) and one with the ground point ( 13 ) connected capacitor ( 23 ) with the input of the high-frequency oscillator ( 8 ). 4. Sensor according to one or more of claims 1-3, characterized in that the demodulator ( 9 ) is a frequency demodulator. 5. Sensor according to one or more of claims 1-4, characterized in that the housing ( 1 ) consists of metal and the second screen ( 13 ) is electrically connected to the housing. 6. Sensor according to one or more of claims 1-5, characterized in that the housing ( 2 ) consists of plastic and that the plastic insert ( 3 ) together with the housing ( 1 ) is made in one piece. 7. Sensor according to one or more of claims 1-6, characterized in that a second switch ( 24 ) is provided which is controlled by a second oscillator ( 21 ) and which with the electrical inputs of a differential circuit ( 25 ), is preferably connected to the inverting and the non-inverting input of an operational amplifier on the one hand and the output of the demodulator ( 9 ) on the other. 8. Sensor according to claim 7, characterized in that the de modulator ( 9 ) is designed as a frequency-voltage converter. 9. A method for detecting the presence of electrically insulating liquids or granules with a sensor having a housing which can be screwed into a wall, with a high-frequency oscillator which is influenced by the change in capacitance of the sensor as soon as the sensor tip of the sensor is immersed in a medium , with a second oscillator ( 21 ) which controls a first switch ( 22 ) which periodically connects the inner conductor ( 11 ) and a capacitor ( 23 ) connected to the ground point ( 13 ) to the input of the first high-frequency oscillator (B) a second switch ( 24 ) which is controlled by a second oscillator ( 21 ) and which is connected to the electrical inputs of a differential circuit, preferably to the inverting and the non-inverting input of an operational amplifier on the one hand and the output of a demodulator ( 9 ) on the other hand is.