DE2927093A1 - UNIVERSAL RESONANCE MATERIAL LEVEL INDICATOR - Google Patents

Description

LEINWEBER & ZIMMERMANN

PATENT LAWYERS

Dipl.-Ing. H. Leinweber Dipl.-Ing. Heinz Zimmermann Dipl.-Ing. A. Gf. v. Wengersky

Rosental 7 D-8000 Munich

2. Ascent (Kustermann-Passage) Telephone (089) 2603989 Telex 528191 lepatd Telegr. Addr. Leinpat Munich

^the July 4, 1979

Our sign

Wy / Sm - AA / 4038

ENERGOINVEST, 71 000 Sarajevo, Yugoslavia
Universal resonance material level indicator

In containers filled with different types of materials, it is often necessary to have an indicator or to have control of the material level. Usually it is enough to have an ad for achieving a particular one To have level levels at one point. Measuring devices that provide data about the fill level of the container are called Level indicator or material level indicator called. The display is ensured via relay contacts that are in the moment the material to be measured comes into contact with a probe of the indicator. The relay contacts can also be used to generate an audible or visible display or a level control Activate using the appropriate actuator.

In view of the wide range of different

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Materials and different demands on the indicator, different types of indicators have already been designed, which are based on different functional principles.

Indicators that work electrically belong to the high quality equipments. Their characteristics are high reliability in operation, high display accuracy, small size and low price. Such a material level indicator is for example the capacitive material level indicator. The probe of this indicator forms with the surface of the material to be measured with regard to its fill level has a capacity. The material level is checked by Measure this capacity.

The universal resonance material level indicator is part of the Group of electrical transformers. In addition to the features of this group of indicators mentioned above, it is important to to advocate the universal applicability of the scoreboard. It can be used for the display of all types of materials, whether liquids, bulk or dielectric Materials or electrically conductive materials.

Typical application examples for the universal resonance material level indicator are display and level control in silos that contain forage and grain, in tanks that contain oil derivatives, in bunkers that contain ores or building materials, or in liquid reservoirs that contain water or chemical substances.

Before a detailed description of the universal resonance material level indicator some of its main features, especially its new features, should be explained.

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The principle of the display is based on the effect of the resonance of oscillating circuits. The indicator probe is in Constructed in the form of an inductance, which together with an additional capacitance forms an oscillating circuit. The oscillating circuit is fed with a sinusoidal signal from an electronic oscillator, which is a component of the device. the The oscillation frequency is equal to the resonance frequency of the oscillating circuit. The resonance condition of the oscillating circuit leads to a maximum voltage in the detector circuit. When the sensing portion of the probe is immersed in the material to be measured, the The resonance condition of the oscillating circuit is disturbed and the amplitude of the detected voltage is significantly reduced. The amplitude the detected voltage is processed in an electronic circuit and an output relay is actuated accordingly.

The resonance condition in oscillating circuits is very stable. Small changes in the parameters do not yet cause any Disturbance of the resonance. Therefore the device is practically insensitive with regard to small material deposits on the sensing section of the probe and also insensitive to temperature fluctuations. The change in the observed voltage due to these factors is thus negligibly small.

If the sensing section of the probe is immersed in any kind of material, be it a bulk material or a liquid, electrically conductive or dielectric, there is a considerable change in the detected voltage. You get so a material level indicator that is universal for use in material level control in a wide range of materials suitable is.

In the following description, the invention will be illustrated with reference to

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of the figures referred to because of the revelation of all below details not explained in more detail are expressly referred to, explained in detail. Show it

1 shows the construction of a universal resonance material level indicator highlighting the most important features,

Fig. 2 shows a block diagram for this, and

3 shows an electrical circuit with details of the individual components.

The universal resonance material level indicator consists from two main parts, namely the probe (53-5 7, 26) and the electronics part (1, 2, 51, 52), see Fig. 1. The probe and the Electronic parts are connected to one another by a multi-core shielded connection cable 11 (Fig. 1).

The sensing portion of the probe consists of a wire 26 wound in the form of an Archimedean spiral and to protect is covered by a synthetic resin cap 56, which has the shape of a hemisphere. The probe housing 54 contains a board with a printed circuit and the electronic components of the probe 55, and one as a feedthrough trained cable socket 53 for the multi-core connecting cable 11. A flange 57 of the probe housing 54 is used for the installation of the probe in such a way that the sensing portion of the probe formed by the wire 26 faces the inside of the material filled container is facing. For this purpose, the probe protrudes into the interior of the container with the synthetic resin cap 56, for example a wall opening, around which the flange 57 is supported with a seal on the outer wall.

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The electronic part comprises a housing 51 and a board 52 which is provided with a printed circuit and electronic Carries components, such as a transformer Tr and connection terminal strips 1, 2 (Fig. 1) .-

The device works as follows:

2 shows the electronics unit on the left and the probe on the right in two blocks enclosed by broken lines. The probe has an oscillator 64. This comprises the sensing section formed by the wire 26 and representing an inductance Probe and capacitors 24 and 25 (see Fig. 3).

A sinusoidal wave-shaped signal is fed to the oscillator 64 from a sine wave generator. The sine wave generator 63 is one of the components of the probe electronics. Its oscillation frequency is equal to the resonance frequency of the Oscillator 64 when the wire 26 forming the sensing portion of the probe is not in contact with the material to be measured. In this case, the probe is in resonance oscillation.

The electronic sine wave generator 63 has a transistor 20, the oscillation frequency of which is determined by an LC circuit is determined from capacitance 19 and inductances 22 and 23 (Fig. 3). The oscillation frequency can be adjusted with the help of the inductances 22 and 23 to the resonance frequency of the probe oscillator 64 can be set.

The output signal of the oscillator 64 in the probe is given to a demodulator 65 (FIG. 2), the output voltage of which is a direct voltage, the voltage value of which is proportional to the amplitude of the oscillation voltage of the oscillator 64. the determined and demodulated voltage is therefore a maximum,

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when the oscillator 64 resonates.

The demodulator 65 comprises diodes 28, 29 and an RC circuit from a resistor 30 and a capacitance 31.

The DC voltage Vdet at the output of the demodulator 65 is applied to the input of a comparator 66 and in this compared with a preset reference voltage Vref.

The comparator 66 includes an operational amplifier (FIG. 3). The demodulated voltage determined is applied to the comparator input via a resistor 33. The reference voltage, which can be set via a potentiometer 32, is applied to another comparator input via a resistor 34 (FIG. 3). - ■ ■. ■

Depending on the difference between the two voltages, the logic signal is at the output of the comparator 66 "1" or the logic signal "0".

If the sensing section of the probe is immersed in the material or if the wire 26 according to FIG. 1 is removed from the material, so there is a change in the inductance and the parasitic capacitance of the probe and thus also a Change in the resonance oscillation state of the oscillator 64. The change in the resonance oscillation state is through the Detected demodulator 65 and changed the output signal at the comparator 66.

The output signal from the comparator 66 passes through a delay circuit 67 (Fig. 2), the task of which is a certain time delay of the output signal of the comparator to introduce.

The delay circuit 67 has a transistor 40

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and determines the / time delay Z ^ t by the value of the Components of an RC circuit, namely a resistor 38 and a capacitor 39.

The output signal from the comparator 66 is after passing through the delay circuit 67 from the probe via the Multi-core connecting cable 11 transferred to the electronics part of FIG. In the electronics part, the signal is in a relay circuit 62 processed with DT contacts.

Depending on whether the output signal of the comparator 66 is a logic signal "0" or a logic signal "1", a Transistor 10 blocked or brought into the saturation state, whereupon a relay (Fig. 3) is energized or de-energized.

The relay contacts are connected by wires to the terminal block 2 and indicate by their position whether the probe is outside the material or immersed in the material. The relay contacts can be used to carry out display or control functions can be used.

The level indicator works with a power supply of 220 V / 50 Hz. The energy source 61 is in the electronics part included and designed in such a way that, when connected to 220 V, it has an unregulated DC voltage at its output gives away. The transformer Tr is part of the energy source 61. The same applies to the diode rectifier 3 and the Zener diodes 5 and 6, which are used to limit the voltage.

The necessary operating voltages are also supplied from the electronics part with the energy source 61 via the connecting cable 11 for a voltage regulator 15 of the probe ga (Fig. 2, Fig. 3) This voltage regulator 15 built in an integrated circuit

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is part of the probe electronics and provides a stabilized Voltage for supplying the probe components, as indicated in FIG. 2.

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List of reference symbols

1 Terminal 57 flange 2 management 61 Energy source 3 Diode rectifier 62 Relay circuit 5 Zener diodes 63 Sine wave generator 6th ti 64 oscillator 9 relay 65 Demodulator 10 transistor 66 Comparator 11 connection cable 67 Runtime switching

15 voltage regulator

19 capacity

20 transistor

22nd Inductors 23 ti 25th capacitor 26th wire 28 Diodes 29 Il 30th resistance 31 capacities 32 Potentiometer 33 resistance 35 Operational amplifier 38 resistance 39 capacitor 40 transistor 51 casing 52 plate 53 Cable socket 54 Probe housing 55 probe 56 Resin cap

The meaning of the other reference symbols results from those used in the figures Switching symbols

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Claims (5)

Claims ^ Universal resonance material level indicator for all types of materials, with a probe (53-57, 260 and an electronic part (1, 2, 51, 52) which are connected to one another by a connecting cable (11), characterized in that the Probe sensing section consists of a wire (26) wound into an Archimedean spiral and embedded in a rigid synthetic resin cap in a sealed manner. 2. Display device according to claim 1, characterized in that the wire (26) connected in parallel to a capacitor (25) is, with which it forms an oscillator (64) with a defined resonance frequency. 3. Display device according to claim 1 or 2, characterized in that that the oscillator (64) is fed with a signal from an oscillation generator (63), the frequency of which on the Resonant frequency of the oscillator (64) is tuned. 4. Display device according to claim 3, characterized in that upon contact of the sensing portion formed by the wire (26) between the probe and the material to be measured, the oscillation state of the oscillator (64) is out of tune. 5. Display device according to claim 3 or 4, characterized in that the oscillation state of the oscillator (64) through a demodulator (65) is queried in the form of the change in the amplitude of the demodulated voltage. 909883/0864 · - ORIGINAL INSPECTED