DE4320357C2 - Level sensor for limit value detection of electrically or capacitively conductive liquids - Google Patents

Description

The invention relates to a level sensor for limit value detection of electrically or capacitively conductive liquids.

The level controls of in particular water-polluting substances often work on the principle of capacitive proximity sensors. These are used for level detection and control of liquids, but also free-flowing bulk goods.

The function of these proximity sensors is based on the Capacity change in the active area of the Proximity sensor located electrode. This Capacity change is due to the approximation or Touching the liquid or the pourable Bulk goods caused themselves.

An example of one state-of-the-art capacitive Proximity initiator is the subject of DE 32 21 223 A1. A capacitive proximity initiator is known from this, which has a fully insulated tubular housing on the A sensor electrode is arranged at the end. Of the Sensor electrodes are a protective electrode and a Assigned shield electrode. Inside the case is an electronic circuit arranged over a Two-wire line, in which a consumer lies, to one AC network is connected and dependent on the capacitance between the sensor electrode and the Circuit ground the current flow over the two-wire line controls. A power supply unit housed in the housing creates those for the operation of the electronic circuit required DC voltage energy from the over the Two-wire line transmitted AC energy.  

The protective electrode and the shield electrode have the shape of cylindrical rings that are inside the case are arranged coaxially to each other.

The protective electrode connects at a short distance the sensor electrode. The shield electrode closes at a short distance to the protective electrode and is with the circuit mass of the electronic circuit connected.

A particular disadvantage of this proximity initiator lies in the frontal arrangement of the sensor electrode.

If the medium to be detected is strongly adhered to, is a not exactly defined response of the proximity sensor more guaranteed. By deposits of the medium on the Sensor or on the protective tube enveloping this an uncontrolled activation.

From US 4,295,370 it is known two a defined distance electrodes to be used with each other. The disadvantage exists in the presence of a high susceptibility to failure if on a deposit appears in the electrodes. Then changed the distance between the electrodes. This Functional principle therefore requires the use of a Reference electrode and a sensor electrode and is on it instructed that the liquid disturb the capacitive field. A limit value detection is not possible, but it is only one level measurement can be carried out.

In DD 2 82 515 A5 and in DD-PS 1 19 088 proportional level measurements described. It will here the use for electrically non-conductive  Considered liquids, especially at the DD 2 82 515 A5 describes a single measuring capacitor is, however, these publications do not provide any Limit indicator.

DE 37 20 473 A1 describes a capacitive Level measurement known in which a probe for Level measurement is provided by immersion in the contents, the Capacity increase on a probe rod is evaluated. The evaluation circuit enables a plurality of n electrodes lined up in the rod. For plants according to DE 37 20 473 A1 is with a sinusoidal Vibration worked. The result is a geometric one Structure of the probe, which is limited Has possible application. Furthermore, with sinusoidal Vibrations with a high frequency power at the Electrode to be worked. This means that others Devices with a similar procedure can be disrupted. Further is a high level of circuitry and wiring required.

Through the detection means arranged one above the other can according to DE 37 20 473 A1 measurement errors only conditionally turned off. Deposits of the medium on the Guide the sensor, for example on the lower end face no more to an uncontrolled activation. However there is a risk that the stacked sensors during operation interfere with each other what is caused by the sinusoidal Vibrations of high frequency power for the purpose of Operation of the electrodes is caused. At least this disrupts devices with similar procedures.

The present invention is therefore based on the object based on a level sensor of the type mentioned to improve and develop, in which the sensors used with each other during operation do not bother. Furthermore, a Pollution independence can be achieved, so that residues of the medium to be recorded, which on Thermowell can occur for detection and Signaling are harmless. Here, a little effort in terms of circuitry may be required.

This task is performed by the level sensor Claim 1 solved.

Special developments of the invention are in the Subclaims marked.

It has now been recognized that a vertical aligned detection surface of the electrodes Protection against pollution is achieved, for example a baking or crusting of certain media on Protective tube end no significant influence on the Function of the level sensor. This is at Level sensors, which cover their detection area have arranged end-to-end in the protective tube, i.e. flat are appropriate, the case. But it was also recognized that due to the vertical alignment of the detection areas Subdivision of the detection areas can take place. The Subdivision can, for example, by the Superimposition of several  Sensors are made, which makes a differentiated Fault reporting and evaluation can be guaranteed.

A fill level sensor with at least is now preferably partially closed plastic pipes provided in where two rigid wires are installed over the entire length and can be pulled out upwards. These wires serve at the same time as supply and measuring lines for the Sensor electronics. As many as you want on these wires Sensors, for example jacket-shaped or tubular Shape, clamped and are therefore variable in height can be arranged. The sensor electronics is either through different current consumption or frequency contacted so that the evaluation electronics can recognize which sensor is active. The distinction of Switching points take place e.g. B. on the current band monitoring or by connecting the two conductors with one Sensor electronics acted on a frequency. This Frequencies modulate on the conductor, with which one Differentiation is possible. The evaluation electronics recognizes the different signal values.  

It is also provided that the detection means at vertically aligned detection areas with at least a high frequency generator via a main line communicate, which is at least as a two-wire line is formed, which is rigid at least in the protective tube Head of the variable-height recording of the detection means is trained.

A rectangular generator is used here as a high-frequency generator used, which has a high resistance with that with the medium to be detected contacting electrode in Connection is made, between electrode and resistor an evaluation unit is arranged. So can be independent only one of the amount of the detection means Two-wire line can be used as the bus line acts. This two-wire line is through the Detection means loaded with the same current. At proper functioning of all control points is the Level can be derived from the system's power consumption. This is an easy first Design variant.

The use in certain measuring ranges is already here sufficient.

However, it can also apply to another Design variants can be achieved that everyone Checkpoint the two-wire supply with one of the Self-consumption of the control point independent electricity charged. Other checkpoints burden with the double current of the previous point.  

example

KP1- 1 mA, KP2- 2 mA, KP3- 4 mA, because such a safe one Differentiation, which control point reports, is possible. In the event of a checkpoint failure, proof is provided the malfunction is possible when the next one Checkpoint works again.

In a further embodiment variant, the Possibility that each control point the two-wire line with a frequency assigned to it. The Frequency becomes "level applied", and "No level present" and "HF generator defect" with different distinguishable amplitudes acted upon.

In a particularly preferred development of Invention it is possible to have multiple switching points in a tube in two-wire technology to integrate.

The level sensor can thus be customized Switching points can be set. Only when installing the The level sensor must be adjusted. After that is the level sensor is absolutely adjustment-free and does not require any Sensitivity setting more.

The protective tube in which the sensors are integrated is located as a closed coat with a closed bottom, so that the medium to be detected is not connected to the electronics can approach. It can now use the means of registration one above the other within the protective tube  be arranged, the detection means for example from a metallic cylinder and one in this arranged board with IC, capacitor and other associated building blocks exist. For example is the detection area of the metallic cylinder formed into a tab and bent. Between two superimposed Detection means is a spacer, preferably made of plastic, arranged.

The corresponding circuit arrangement enables electrically conductive sensors, regardless of their design use. It is also irrelevant whether this directly in contact with the liquid to be detected kick or be isolated from this. There is also a fundamental effect of Invention in that this circuit arrangement without directly built-in reference electrode is functional.

Using the attached drawings, which is a particular represent preferred embodiment of the invention, this will now be described in more detail.

Show:

Figure 1 shows a cross section through the level sensor shown schematically.

Fig. 2 is a schematic representation of a circuit diagram;

3 shows a possible mounting of the detecting means on the two-wire line in a side view / partial cross-section.

Fig. 4 is a sectional view of the mounting arrangement shown in Fig. 3;

Fig. 5 shows the current band.

Fig. 1 shows a cross section through the operated with a circuit arrangement new level sensor 1. In this exemplary embodiment, two detection means 2 arranged one above the other are arranged within a protective tube 7 , which is made of plastic with a closed bottom 8 . In this exemplary embodiment, the detection means 2 consist of a metallic cylinder 10 and a circuit board 11 arranged inside it, on which an IC 12 and further associated required components are arranged.

The jacket of the metallic cylinder 10 represents the detection surface 3 , which is aligned vertically. The detection means communicate with the circuit arrangement, which will be described later in FIG. 2, via a common bus line 5 (two-wire line). A spacer sleeve 13 spaced apart from one another is arranged between two detection means 2 .

Fig. 2 shows a schematic representation of a circuit diagram for the functional operation of the level sensor.

A radio frequency generator is identified by reference number 4 . . The electrode of the detection means 2 is connected to the high-frequency generator 4 via a resistor 14, an evaluation unit 15 being interposed between the electrode or detection means 2 and the high-frequency generator 4 or between the resistor 14 and the electrode or detection means 2 . A rectifier 16 is assigned to the evaluation unit 15 .

FIGS. 3 and 4 show a mounting example of the detection means 2 to the bus line 5 (two-wire line). It is easy to see here that a mechanical arrangement of the detection means 2 on the bus line 5 corresponding to the desired switching points ensures a height arrangement of the detection means 2 , which results in the height variability.

By the high-frequency signal (rectangular), which on the Abandoned electrode can have a low frequency and a low high-frequency AC voltage can be used. So it has the advantage over sinusoidal signals, that here with significantly less High-frequency power can approach the electrode. Thus devices with the same or similar can Do not disturb process operations.

By operating with a low RF power can have almost any number of devices side by side or work in parallel.

Reference list

1 level sensor
2 means of registration
3 vertical detection area
4 HF generator
5 bus line (two-wire line)
7 protective tube
8 floor of 7
10 metallic cylinders
11 circuit board
12 IC
13 spacer sleeve
14 resistance
15 evaluation unit
16 rectifiers

Claims (11)

1. Level transmitter for limit value detection of electrically or capacitively conductive liquids with capacitors as detection means with the further features that the detection means are arranged one above the other within a protective tube and each have only one electrode surface,
that the electrode surfaces are aligned vertically,
that the electrode surfaces ( 2 ) communicate with a high-frequency generator ( 4 ) via a bus line ( 5 ) designed as a two-wire line, which is designed at least in the protective tube ( 7 ) as a rigid line for the variable-height reception of the detection means,
that only a two-wire line is provided regardless of the number of detection means,
that the high-frequency generator ( 4 ) is designed as a rectangular generator and is connected to the electrode surface ( 2 ) via a high-resistance resistor ( 14 ), and that an evaluation unit ( 15 ) is connected between the detection means ( 2 ) and the resistor ( 14 ). 2. Level sensor according to claim 1, characterized in that the protective tube ( 7 ) is designed as a closed jacket with a closed bottom ( 8 ). 3. Level sensor according to claim 1 or 2, characterized in that the detection means ( 2 ) consists of a metallic cylinder ( 10 ) and a circuit board ( 11 ) arranged in this with IC ( 12 ) and other associated components. 4. Level sensor according to claim 3, characterized in that for receiving the board ( 11 ), the detection surface ( 3 ) of the metallic cylinder ( 10 ) is bent into a tab ( 12 ). 5. Level sensor according to one of claims 1 to 4, characterized in that a spacer sleeve ( 13 ) is arranged between two detection means ( 2 ) arranged one above the other. 6. Level sensor according to claim 5, characterized in that the spacer sleeve ( 13 ) consists of plastic. 7. Level sensor according to one of claims 1 to 6, characterized in that the protective tube ( 7 ) consists of plastic. 8. Level sensor according to claim 1 or 2, characterized in that the detection means ( 2 ) has a plate-shaped electrode surface ( 3 b). 9. Level sensor according to one of claims 1 to 8, characterized in that the two-wire line through the detection means ( 2 ) can be loaded with the same current and the level of the medium to be monitored can be derived via the power consumption of the system. 10. Level sensor according to one of claims 1 to 8, characterized in that the detection means ( 2 ) each load the two-wire line with twice the current of the previous detection means. 11. Level sensor according to one of claims 1 to 8, characterized in that each detection means ( 2 ) is assigned a frequency with which it loads the two-wire line.