DE3344880A1 - Level-limiting value transmitter for liquid containers or the like - Google Patents

Abstract

The invention relates to a level-limiting value transmitter for liquid containers or the like having a sensor tube (3), which is arranged at the end of a probe tube (1) and has a temperature-dependent sensor (4). A specific electrical heating power is fed to this sensor (4), as a result of which an equilibrium temperature and a corresponding resistance value are set up, depending on whether the sensor tube (3) dips into the liquid or not. In order to enlarge the permissible working range of such a limiting value transmitter, there is connected upstream of the said sensor (4) a compensation resistor (9) which ensures that the heating power fed to the sensor (4) is matched to the ambient temperature. <IMAGE>

Description

Level limit switch for liquid containers or

The like The invention relates to a level limit value transmitter for liquid containers or the like with one arranged at the end of a probe tube Sensor tube with a temperature-dependent sensor to which a specific electrical Heating power can be supplied to an equilibrium temperature and a corresponding The resistance value depends on whether the sensor tube is immersed in the liquid or not.

Such level limit indicators are used in connection with filling of stationary or movable tanks (tank trucks) with flammable, other dangerous Liquids as well as liquids that are critical with regard to water protection, used to safely avoid overfilling and thus overflowing of the tanks. With such level limit indicators operate electronic monitoring circuits together, when a certain liquid level is reached, reported by address the level limit indicator and either the filling pumps automatically switch off or give clear alarm signals.

Such systems and system components as well as level limit indicators are subject to strict quality requirements that are met in an approval process before the devices can be used.

There are already level limit indicators known that these official Meet requirements in terms of reliability (DE-PS 22 60 070). The at such limit value transmitters set equilibrium temperature at the sensor tube or sensor is a certain value above the ambient temperature. With that is the resistance of the probe when not immersed depending on the ambient temperature.

This not only has the consequence that the outside temperature of the sensor tube may have reached a temperature value that is no longer permissible (dangerous with flammable Liquids), but the evaluation by the evaluation circuit is no longer reliable can be done. So far known limit indicators could therefore only be strong for one restricted range of ambient temperature.

The invention is based on the object of a level limit value transmitter to create that works safely over a larger ambient temperature range. This is achieved in that in / on the probe tube outside of the immersion area a compensation resistor is arranged to control the sensor The electrical power supplied is used depending on the ambient temperature.

Advantageous refinements of the invention are set out in the subclaims refer to. The invention is explained in more detail below with the aid of exemplary embodiments explained. They show: FIG. 1 a longitudinal section through a first embodiment of the fill level limit transmitter according to the invention and FIG. 2 shows a longitudinal section through a second embodiment.

The limit indicator shown in Figure 1 is at the end of a probe tube 1 arranged with a relatively large wall thickness an end plate 2. In a Bore of the end plate 2, a pin-shaped sensor tube 3 is used, the contains a sensor 4 at its end. All parts 1, 2 and 3 are preferably made Made of stainless steel and the parts are welded or soldered together tied together.

A silicon temperature sensor element is used as the sensor 4, as it e.g. in the "Valvo-Technische Informations für die Industrie", No. 80 1031, is described. This silicon temperature sensor element 4 is in the lower end of the sensor tube 3 and arranged in an embedding material 7 made of aluminum oxide ceramic hermetically sealed. This material has the inherent shank of good thermal conductivity with good electrical insulation properties at the same time.

The connecting lines 5 and 6 protruding from the sensor tube 3 are led out through the probe tube 1 to its other end and end in a corresponding junction box 10 (Fig 2). The probe tube 1 is filled with epoxy resin 8, to ensure proper sealing and fixing of the connecting lines 5 and 6. In the course of the connection line 6, another component 9 is looped in, which will be described later.

Although only one sensor 4 is provided in the exemplary embodiment, it is of course also possible to use two or more sensors instead 4 to be ordered for special purposes. It can in the pin-shaped sensor tube z. e. two sensors 4 can be arranged spatially one behind the other in the axial direction. the end For safety reasons, either one of the two connecting lines, 5 or 6, is with connected to the metallic probe tube 1, or there are corresponding grounding resistances provided, which are connected to one or both connecting lines 5 or 6.

As already mentioned earlier, there is another in the probe tube 1 of FIG Component 9 arranged, which serves as a compensation resistor. This compensation resistor 9 is a temperature-dependent component that serves to reduce the influence to compensate the ambient temperature on the measuring range of the sensor 4 in such a way, that when the ambient temperature rises, the heating power supplied to the sensor 4 is increased reduced in order to increase the permissible working range of the limit indicator to lead.

This compensation resistor 9 is preferably in thermal contact arranged with the inner wall of the probe tube 1, outside of the immersion area the liquid level to be monitored. This compensation resistor 9 is on cemented or glued to the inner wall and in the surrounding epoxy resin compound 8 securely embedded.

The following is carried out for the function of the compensation resistor: If the sensor 4 is supplied with a certain electrical heating power during operation, so it turns out when the sensor tube 3 is not yet in the liquid to be monitored immersed, a certain equilibrium temperature, which a corresponding Resistance value of the sensor 4 has the consequence. Immerses the sensor tube 3 in the liquid one, more heat energy is withdrawn from it, and a lower one arises Equilibrium temperature and thus a lower resistance value.

This difference between the resistance values of the probe 4 is recognized by an evaluation circuit (not shown) and used as an alarm or switch-off criterion rated.

The setting in the non-immersed state of the sensor tube 3 Equilibrium temperature is a certain value above the ambient temperature. If this is higher, there is also a higher equilibrium temperature at the same time and thus a correspondingly higher resistance value of the sensor 4. this has not only result in the outside temperature of the sensor tube reaches a temperature value that is no longer permissible (dangerous with flammable liquids), but also that the evaluation by the evaluation circuit is no longer reliable can.

This dependence on the ambient temperature leads to limit switches of the previous type only for a limited range of ambient temperature could be admitted. This disadvantage is caused by the limit indicator according to the invention avoided or at least greatly mitigated. The compensation resistor shown in FIG 9 is a positive temperature coefficient component and is in series with the Sensor 4 switched.

At a higher ambient temperature, the resistance of the compensation resistor increases 9, so that the heating power supplied to the sensor 4 is reduced. Through this the effect is that the equilibrium temperature at the sensor 4 is not so strong the ambient temperature rises, as is the case without a compensation resistor 9 were.

By suitably dimensioning the compensation resistor 9 and possible use of additional resistors connected in parallel or in series the temperature profile of the combination can be dimensioned so that it is independent from the ambient temperature to an essentially constant equilibrium temperature set on sensor 4.

It is also possible to use a compensation resistor with a negative temperature coefficient to use the - possibly together with suitable balancing resistors ° then must be connected in parallel to sensor 4.

Figure 2 shows another embodiment of the limit value transmitter according to the invention. In contrast to FIG. 1, the compensation resistor 19 is at the top here End of the probe tube 1 arranged junction box 10 arranged to here the ambient temperature to measure the air. With the reference numeral 11 is a leading out of the junction box 10 Connection cable denotes, which leads to a (not shown) measuring device.

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Claims (7)

Claims: I Level limit value transmitter for liquid containers or the like with a sensor tube arranged at the end of a probe tube a temperature-dependent sensor that has a certain electrical heating output can be fed to an equilibrium temperature and corresponding resistance value depending on whether the sensor tube is immersed in the liquid or not, characterized in that in / on the probe tube (1) outside the immersion area a compensation resistor (9, 19) is angeodnet, which is used to control the sensor (4) the electrical power supplied is used depending on the ambient temperature. 2. Level limit indicator according to claim 1, characterized in that that the compensation resistor (9) in the upper part of the probe tube (1) in thermal contact with the inner wall. 3. Level limit indicator according to claim 2, characterized in that that the compensation resistor (9) with a highly thermally conductive material on the inner wall the probe tube (1) is cemented or glued on. 4. level limit indicator according to claim 2 or 3, characterized in that that the probe tube (1) is filled with epoxy resin (8) and the § (compensation resistor (9) is poured into it. 5. level limit indicator according to claim 1, characterized in that that the compensation resistor (19) in the junction box (10) of the probe tube (1) is arranged. 6. Level limit indicator according to one or more of the claims 1 to 5, characterized in that the compensation resistance is positive Has temperature coefficients and is connected in series with the sensor. 7. Level limit indicator according to one or more of the claims 1 to 5, characterized in that the Kompensat ionswi resistance a negative Has temperature coefficients and is connected in parallel with the sensor.