DE20011284U1 - Level sensor - Google Patents

Description

J I Il

J ,· , · < · I Il I

ABG104_T1.doc

Level sensor

The invention relates to a device for determining the fill level of a liquid whose quantity changes in a container, which device has at least one pressure sensor device.

A device of the type mentioned above is known from DE 196 43 753 Al, which has the following parts:

- a one-sided fixed force measuring element and

- a buoyancy body, through which the free end of the force measuring element is subjected to a force by contact. A compensation rod resting on a pivot point support is arranged between the force measuring element and the buoyancy body, with a compensation weight attached to the opposite end. The force measuring element fixed at one end is a piezoelectric transducer, a spring displacement measuring system or a bending body element on which a sensor structure for detecting surface tensions is arranged.

This device has proven itself, but its construction is too complex.

Also known are level sensors using pressure sensors, which act as submersible probes to measure the hydrostatic pressure

» 3 &iacgr; .

a liquid column above it. These immersion probes are particularly suitable for stationary vessels, since when accelerations occur, the pressure peaks that arise correspond directly to x times the acceleration due to gravity occurring on the L axis. In addition, when using absolute pressure sensors, measurement errors occur when the pressure inside the vessel fluctuates, since this also affects the hydrostatic pressure of the liquid column. If relative pressure sensors are used, a pressure compensation line must be laid above the maximum liquid level.

The disadvantage here is that if condensate forms in the pressure equalization line, liquid accumulations can occur which distort the measurement result and are difficult to remove.

Also known are level sensors with a connected pitot tube, in which the pressure sensor is located above the maximum level to be measured.

The disadvantage here is that the volume of gas enclosed in the Pitot tube is temperature-dependent, and therefore large temperature fluctuations can lead to measurement errors. Furthermore, the fill level characteristic is not linear due to the compressibility of the enclosed gas.

The task is therefore to further develop a device for determining the fill level of the type mentioned above in such a way that its construction is less complex and precise measurements are possible.

According to the invention, the object is achieved by the features of claim 1.

The advantages achieved with the invention are in particular that all essential parts are combined in the sensor head. In addition, the level sensor can be used in a wide temperature range and can also be operated in moving vessels. A further advantage is that the level characteristic curve is linear and measurement errors caused by temperature fluctuations are reduced.

By means of the measures listed in the subclaims, advantageous further developments and improvements of the device for determining the fill level specified in claim 1 are possible.

An embodiment of the invention is shown in simplified form in the drawing and is explained in more detail in the following description. They show:

Fig. 1 shows a level sensor installed in a fuel tank in a schematic, partially sectioned view and

Fig. 2 shows a level sensor according to Fig. 1 in an enlarged sectional view.

In Fig. 1 and 2 a level sensor is shown, which consists of

a sensor head 1, in which

- a pressure sensor 2 with electronics,
a pump 3,

- a pressure relief valve and

- at least one valve 14 is arranged.

·

·

The sensor head 1 has a sensor head housing 8 in which the components 1 to 4 are arranged. The sensor head housing 8 extends into a connector housing 7. In the connector housing 7 there is a connector 6 which is connected to the electronics of the pressure sensor 2.

The sensor head housing 8 merges into a pitot tube 5. The pitot tube 5 is connected to a bubble throttle body 13 via an elastic immersion hose 12, as shown in particular in Fig. 1.

While the sensor head 1, as shown in particular in Fig. 1, is sealingly inserted into a container wall 22 of a fuel tank 20 with a sealing ring, the bubble throttle body 13 is fastened to a container bottom 21 of the fuel tank 20.

If the fuel tank 20 has a complicated geometry, the pitot tube 5 is designed as a movable hose 12. If simple containers are used, a straight piece of pipe is used.

The level sensor uses a diaphragm pump with a piezoelectric oscillator, a rotary piston pump, a pump with a peltier element or an electromagnetic system comparable to a loudspeaker membrane as pump 3. The pump 3 balances a gas volume inside the fuel tank 20. The gas is taken from the interior of the tank 20 above the maximum liquid level, whereby the system remains functional when the tank internal pressure differs from the tank's ambient pressure.

· «4

A capillary system with appropriate baffles prevents large amounts of liquid from entering the sensor head 1. Small amounts of liquid and condensate are pumped by the pump 3 into the pitot tube 5 and flow downwards.

The pressure sensor used works as a relative sensor and its sensitivity is adapted to the expected dynamic pressure of the liquid. The pressure relief valve 5 is designed in a simple form as a spring-ball valve or spring-plate valve and is set to a permissible maximum pressure to protect the pressure sensor 2 by dimensioning the valve cross-section and spring force.

The level sensor constructed in this way works according to the principle of the immersion tube sensor. This creates the possibility of cushioning pressure errors in the short term by utilizing the compressibility of the gas column. Too rapid penetration of liquids into the pitot tube 5 is prevented by an appropriately dimensioned inlet opening, which acts as a throttle element 10.

Extreme pressure peaks can be counteracted with the pressure relief valve 4, which is located above the maximum level of the liquid.

The problem of the temperature dependence of the connected gas column, the gas losses and the function of the pressure relief valve and the non-linearity of the characteristic curve are avoided by the pump 3. This pump 3 conveys gas from the fuel tank 20 beyond the liquid maximum into the pitot tube 5. This always creates a gas column corresponding to the pitot length and the exact hydrostatic!

see pressure measured at the end of the pitot tube 5 to the current liquid level.

A "pulsation" of the gas exiting at the outlet opening is avoided by at least one bubble divider 11.

Claims (8)

1. Device for determining the level of a liquid in a container which changes its quantity, which has at least one pressure sensor device ( 2 ), characterized in that - that the pressure sensor device is a pressure sensor ( 2 ) with electronics, which is arranged with a pump ( 3 ) and at least one pressure relief valve ( 4 ) in a housing body ( 7 , 8 ) of a sensor head ( 1 ), and - that a jam pulsation device ( 5 , 12 , 13 ) is arranged on the housing body ( 7 , 8 ) of the sensor head ( 1 ). 2. Device according to claim 1, characterized in that the pulsation device has a pulsation tube ( 5 ) which is arranged on the housing body ( 7 , 8 ) of the sensor head ( 1 ). 3. Device according to claim 1 or 2, characterized in that the congestion pulsation device has a bubble throttle body ( 13 ). 4. Device according to one of claims 1 to 3, characterized in - that the housing body ( 7 , 8 ) of the sensor head ( 1 ) is arranged in a container wall ( 22 ) and the bubble throttle body ( 13 ) is arranged on a container bottom ( 21 ) of the container ( 20 ) and - that the pitot tube ( 5 ) and the bubble throttle body ( 13 ) are connected by a straight pipe section or a movable immersion hose ( 12 ). 5. Device according to claim 4, characterized in that the container is a fuel tank ( 20 ). 6. Device according to one of claims 1 to 5, characterized in that the bubble throttle body ( 13 ) has at least one bubble divider ( 11 ) which is connected to a throttle element ( 10 ). 7. Device according to one of claims 1 to 6, characterized in that at least one valve ( 14 ) is arranged in the housing body ( 7 , 8 ) at least partially opposite the pressure relief valve ( 4 ). 8. Device according to one of claims 1 to 7, characterized in that the housing body consists of a sensor head housing ( 7 ) and a plug housing ( 8 ), wherein the sensor head housing ( 7 ) at least partially encloses the pressure sensor ( 2 ) with electronics, the pump ( 3 ), the pressure relief valve ( 4 ) and the valves ( 14 ) and is connected to the pitot tube ( 5 ) and wherein the plug housing ( 7 ) at least partially encloses a plug ( 6 ) and is connected to the electronics of the pressure sensor ( 2 ).