DE2305994B2 - MEASURING CAPACITOR FOR THE ELECTRICAL MEASUREMENT OF A QUANTITY OF LIQUID IN A LOCKED ROOM OF A FLIGHT BODY - Google Patents

Description

The invention relates to a measuring capacitor, of the type identified in the preamble of claim 1 above.

Such a capacitor can be used to indirectly measure the quantity or flow of liquids in principle in every closed space ;; ngewencict will; most effective, however, it can be used to measure the level of fuels, oils and other liquids in Missiles are used. Under soil conditions it can measure the filling up of each fuel tank with the required amount of fuel to be used. Under flight conditions he can measure the fuel supply in individual Fuel tanks, for totaling the fuel supply in individual containers of various shapes and volumes as well as for dispensing the Information about the fuel supply to the center of gravity computer of the missile and to the calculating machines to determine the remaining flight time, the available flight distance and for the solution serve other purposes. It can also be used in remote automatic measurement systems.

Such a measuring capacitor is used as a liquid content indicator for the fuel content in aircraft known (DT-AS 10 55 833). The known measuring capacitor has concentric, coaxially arranged, electrodes separated by a continuous, spiraling, non-conductive spacer. Its function is based on the change in the capacitance between the electrodes of the electrical Condenser due to the displacement of the air by the liquid, its dielectric constant differs from the size of the dielectric constant of the air. The well-known capacitor possesses although good mechanical stability and is largely free of because of the continuous spacer Moisture build-up that could affect capacity; but it can only be left in the fuel tank arrange locally so that there is also a possible temperature compensation for the type of liquid to be measured a measurement error caused by a temperature gradient in the tank does not appear.

It is also known in connection with a measuring capacitor for the fuel tanks of aircraft! (DT-AS 10 51 020) to strive for a linear wetting between the capacitance of the measuring capacitor and the filler material by providing an electrode surface calculated _{according to the shape of the container J 3n Lc.} To eliminate the influence of the edge scattering, an auxiliary electrode is arranged to intercept the edge scattering. In the known case, there is again a coaxial system of the electrode arrangement. The simulated profile is applied as a conductive layer on an insulating part. The change in the dielectric constant can only be recorded locally; a temperature-related measurement error is of course not compensated for by the shape of the electrode.

The invention has for its object to provide a reliable and compact measuring capacitor for Measuring an amount of liquid to provide a high level of measurement accuracy under all operating conditions guaranteed.

The solution to this problem is characterized by the features of claim 1 above.

The tarpaulins themselves expediently have a shape that is similar to the cross-sectional shape of the room. in which the liquid to be measured is located.

The measuring capacitor allows the actual amount of liquid present among different Conditions of use, both at negative as well as at positive ambient temperatures, without assistance of special compensation transducers for the quantity measurement of liquids with any dielectric constant to determine.

The plates represent because of their high thermal conductivity and their possible extension along or across the enclosed space itself On the other hand, they make measurement errors even if they remain different Compensated for temperature distribution.

The linear dependence of the elegiac output signal of the actual amount of liquid is due to the simulation of the cross-sectional shape of the Guaranteed space and the large extent of the large plates.

Furthermore, the plates with the wave-shaped spacers in the force association of the wing of the Missile be integrated, while the known coaxial measuring capacitors the weight of the missile; increase completely unnecessarily.

In the following the invention is explained in more detail by means of an exemplary embodiment shown in the drawings explained. It shows

F i g. 1 shows an overall view of the measuring capacitor,

FIG. 2 shows a section along the line H-II in FIG. 1,

F i g. 3 shows an arrangement of the measuring capacitor on the partition wall of the fuel tank of a missile and

4 shows an arrangement of the measuring capacitor in the wing of a missile.

The insulated electrodes that form the measuring capacitor are designed as plates 1, 2 and 3 (FIG. 1, 2). in the Embodiment of the measuring capacitor there are three plates 1, 2 and 3, but the number of plates

can also be limited to two or considerably larger if this results from the conditions for achieving it the required capacitor capacity.

The plates. , 2, and 3! Sine rigidly interconnected ¹ by means of wave-like surface portions 4 and 5. FIG. The plates 1 and 2 are connected to one another by means of the wave-shaped part 4, the plates 2 and 3 by means of the wave-shaped part 5. The number of surface parts 4, 5 is usually one less than the number of plates 1, 2 and 3. The plates consist either of metallic ig or of metallized panels; the undulating surface parts, however, are made of an insulating material. In the example given, the surface parts 4 and 5 consist of glass fabric that is impregnated with resins, for example with silicone resins. Between the plates 1, 2 and 3 of the measuring capacitor, the surface parts 4, 5 form vertical channels € and 7 (FIG. 2), which are filled by the liquid to be measured when the measuring capacitor is immersed in the same. These vertical channels 6 and 7 represent, as it were, elementary electrocapacitive capacitors connected in parallel. At the same time, the wave-shaped parts 4, 5 form the supporting element of the capacitor construction, which determines the mechanical strength of the encoder.

The electrical connection lines 8 of the plates 1, 2 and 3 are connected to one of the outer plates (in FIG. 1 the Plate 1) attached by a bandage 9 made of glass fabric or another electrical insulating material.

The measuring capacitors can also be designed as individual sections 10 and 11 (FIG. 3) which run through Conductors 12 and 13 connected to one another and attached to a partition 14 of a fuel tank 15 (Fig. 4) are arranged, which is mounted for example in a wing 16 of a missile.

Since the measuring capacitor in the described embodiment is used to measure the amount of fuel in the containers of a missile, which have different shapes and volumes, the Shape of the plates 1, 2 and 3 (Fig. 1. 2) of the measuring capacitor of the shape and volume of the Determined fuel tank in which this measuring capacitor is arranged, for example by the shape of the fuel tank 15 in the wing 16 of the missile in question. In the general case own The capacitor plates have a shape that is similar to the shape of the room in which the one to be measured is located Liquid is located.

The linear dependence of the change in the electrical capacitance of the measuring capacitor on the Changing the amount of the liquid to be measured in the room is made possible by such a design Capacitor plates 1, 2 and 3 guaranteed, in which the Plate area per height unit (mm or cm) of the filling space of the amount of liquid in the same volume section is proportional, d. H. in the general case:

S = ArV.

where S - the area of the capacitor plates 1, 2 and 3.
V - the amount of liquid to be measured and
A- - means a proportionality factor.

In any case, the proportionality factor k must be constant for each container 15 (FIG. 4) or for all containers 15 of the missile. the capacitor capacity ie the height unit of the container 15 must be proportional to the amount of fuel.

As a result, in each height section of the room, the liquid-covered board area is the amount of to measuring liquid is always proportional.

This selection of the plate shape allows it. on the complicated special profiling of the measuring capacitors to achieve a linear dependence of the electrical capacitance on the amount of to dispense measuring liquid.

The electrical capacitances of the measuring capacitors, which are arranged in the individual containers, are simply summed up. The measurement of the total amount of fuel in several containers of the missile results from the parallel connection of the measuring capacitors of the individual containers.

The measuring capacitor is inside the Kraltstoffbehähers 15 arranged vertically and on the walls of this container by means of screws, not shown via sockets 17 (F i g. 1) attached so that it is as mechanical reinforcement element of the structure of the missile is used, or its wave-shaped Flat parts 4.5. which is the supporting element of the capacitor structure represent.

Since the fuel tanks are usually mounted in the wing 16 of the missile (Figure 4), the Capacitors are used and replace as mechanical reinforcing elements of the construction thereof Stiffeners at their usual miles of arrangement, both longitudinally and longitudinally Cross brace.

The measuring capacitor works as follows:
If the level of the fuel to be measured drops as the fuel tank 15 is emptied (FIG. 4). so the fuel level also drops in channels 6 and 7 (FIG. 2) of the condenser. The void is filled with air and the capacitance of the capacitor decreases because the dielectric constant of the fuel is always greater than the dielectric constant of the air. The change in the electrical capacitance of the capacitor in both directions corresponds to the change in the amount of fuel and the container in which it is arranged.

The condenser allows:

a high measurement precision of the fuel supplies in individual fuel tanks as well as the total amount of the fuel, which is located in several separate containers, with any Obtain missile pitch and roll angles;

to measure the amount of fuel without additional errors in a wide temperature range of the ambient temperature from positive temperatures of 200 to 300 ⁰ C to negative temperatures of 60 C;

to simplify the plate shape in view of the linear dependence of the electrical capacitance on the amount of fuel;
to reduce the weight of the missile by integrating it into the power unit of the wing of the fuel tank and thereby not requiring additional mounting flanges, no special boxes for its arrangement, no electrical ducts and hatches in the fairing of the missile;
to compensate for the temperature inside the fuel tank due to its high thermal conductivity and the elongated interior of the tank, which is special for supersonic missiles

Meaning is;

to ensure in vapors of the fuel flow or the fuel overflow in the fuel tanks in the event of changes in position;
in connection with this to build facilities that guarantee a high level of accuracy of the automatic attitude control of the missile's center of gravity in all flight conditions and any pitch and bank angles;
to ensure that the individual fuel tanks are filled with fuel up to the maximum possible amount (up to the upper tank edge);
increase the fire safety of the missile;
the safety against electrical discharges

raise;

the necessary accuracy of the Kraftsiol'fvorräle in the presence of floating and deposited foreign matter and moisture in the fuel (mechanical dust, dirt, water etc.) to ensure:

the required measuring accuracy of the fuel supply with the artificial introduction of electrically conductive components into the fuel to ι To secure the fight against electrical static charges that arise as a result of the friction dci Form liquid on the walls of the pipes unc of the fuel tank.

For this purpose 2 sheets of drawings

Claims (3)

Patent claims: 1. Measuring capacitor for the electrical measurement of a quantity of liquid in a closed Space of a missile, which measuring capacitor at least two isolated from each other and through at least one spacer made of non-conductive material at a certain distance from one another held electrodes urirl whose capacity is a function of the amount of liquid in the Space is characterized in that between the large-area plates (1,2,3) forming Electrodes, the spacers are designed as wave-shaped surface parts (4, 5), which the Connect electrodes siarr and form channels (6, 7) for the passage of the liquid to be measured. 2. measuring capacitor according to claim I, characterized in that the plates (1, 2, 3) themselves a Have a shape that is similar to the cross-sectional shape of the space (15) in which the to be measured Liquid is located. 3. measuring capacitor according to claim 1 and 2, characterized in that the plates (1, 2,3) with the wave-shaped parts (4, 5) as mechanical reinforcement elements in the force association of the wing (16) of the missile are integrated.