DE1590190B2 - LIQUID RESISTANCE - Google Patents

Description

The invention relates to a fluid resistance with a connected to a container, a Conductive liquid containing cavity and electrodes arranged in it, through which the liquid passes a current can flow which causes part of the liquid to evaporate and another part of the Presses liquid into the container, the cavity having a vertically extending passage conduit, which enables a controlled reduction of the steam pressure that builds up there.

Such a fluid resistance is known from Swiss patent specification 3 63 703 and is intended for use as a parallel-connected damping resistor for circuit breakers. He is initially very low resistance and is due to the onset of evaporation of part of the liquid Displacement out. the cavity in the container; very high resistance relatively quickly. The absolute value the resistance is of only subordinate importance. A fluid resistance with a however, such a characteristic is available for various other applications, such as a starting resistor for asynchronous motors, unsuitable. This is where it depends, for example the starting current extremely quickly to a predetermined value, but not by a constant increase in resistance getting smaller and smaller.

From the German patent 8 41 015 also describes an electromagnetically adjustable liquid rheostat is further loading for ^telephonic: known. Here, however, the change in resistance does not take place through liquid evaporation, but through mechanical control of the electrode spacing. It is obvious that such a possibility is ruled out for heavy current engineering.

The invention is based on the object of providing a fluid resistance of the type specified in the introduction Generate in such a way that its respective resistance value changes automatically by changing the Adjusts the liquid level in the cavity so that the current is limited to a predetermined value, whereby the time constant of the resistance should be as small as possible.

This object is achieved according to the invention in the characterizing part of claim 1 specified way. Advantageous embodiments and developments are set out in the subclaims specified.

In the drawing, the fluid resistance is after of the invention based on, for example, selected embodiments and their details schematically shown in simplified form. It shows

F i g. 1 shows a longitudinal section through a fluid resistance according to the invention,

F i g. 2 and 3 cross sections according to the lines 11-11 and III-III in Fig. 1,

F i g. 4 shows a perspective illustration of the electrodes of the liquid resistance according to FIGS. 1 to 3, F i g. 5 and 7 longitudinal sections through two embodiments through the passage line to the controlled Releasing the steam,

F i g. 6 and 8 sections corresponding to lines VI-VI and VIII-VIII in FIGS. 5 and 7.

The liquid resistance shown in FIGS. 1 to 4 comprises a cuboid container 1 above a cuboid cavity 2 separated from it by a partition 3. The cavity 2 is connected to the container 1 by three lines penetrating the partition 3, namely a line 4 of large diameter, extending from the upper side of the partition 3 in the direction of the bottom of the cavity 2 up to a level N.

extends, a conduit 5 of small diameter and a passage conduit 6 of large diameter, which, starting from the lower side of the partition 3 extend up into the container 1, but terminate below a level N of the conductive liquid contained therein. The passage line 6 is closed at its upper end by a valve flap 7 which is seated on a rod which at its upper end carries a piston 9 provided with a small bore 9a. This piston 9 is movable in a cylinder 10, at the base of which there are openings 11 below the N level. The cylinder 10 is suitably attached to the upper end 6a of the outer wall of the passage 6. A spring 12 presses the valve flap 7 onto its seat at the upper end of this passage line.

The container 1 and the cavity 2 contain two electrodes 13 and 14, which are shown in perspective in FIG are shown. These electrodes are provided with external connection terminals 13a and 14a. You insist from each other on the narrow sides of the container 1 opposite parts 136 and 146 and to itself the broad sides of the cavity 2 opposite parts 13c and 14c, but only the upper part of this Occupy cavity. The parts 13c and 14c are located in the much smaller areas Electrode parts 13c / and 14c / continue, which are in substantially face greater distance than the former. In the illustrated embodiment, the electrodes are each punched in one piece from a corresponding plate or cut and bent, the parts 136, 13c and 146, 14c are connected to one another via strips.

After inserting the electrodes and filling the container with the conductive liquid, the former is applied a plate 15 is placed, which prevents liquid from splashing outwards and possibly serves to the part of the Liquid that emerges in a vaporous state to condense in order to flow back into the container permit.

The fluid resistance works as follows, assuming that between the terminals 13a and 14a such a voltage is that the resulting current in the cavity 2 located, conductive liquid at least partially evaporates: The current initially flows mainly between the widest and electrode parts 13c and 14c that are closest to one another and that generated by the power loss Heat vaporizes the liquid in the cavity 2 and drives it through the line 4 into the container 1. At the same time, the liquid in the cavity 2 is heated, so that a relatively low energy, i. H. the heat, which arises as a result of the current flow between the electrode parts 13c / and 14c /, for steam generation Displacement of the excess liquid is sufficient. When the level of conductive liquid in the Cavity 2 has sunk so far that the large-area, mutually closest electrode parts 13c and 14c are no longer immersed, only the significantly further apart and one are located electrode parts 13c / and 14c / in the circuit in cavity 2. The electrode parts 13c / and 14c / have a significantly smaller surface area The increase in resistance caused by this means that the current is now mainly between the in Electrode parts 136 and 146 lying in the container 1 flows. This fluid resistance, which is thus connected in parallel largely resembles the fluctuations in the resistance between those in the cavity 2 Parts of the electrodes. This mainly causes interruptions in the flow of current and thus overvoltages avoided in the external circuit.

If the fluid resistance is in the circuit of an asynchronous motor, this determines the parallel resistance so the maximum starting resistance through which the current flows to the same extent as that through the Resistance formed cavity 2 increases.

The parallel liquid resistance between the electrode parts 136, 146 can be achieved by a fixed, e.g. B. metallic resistance can be thought of as being replaced. However, a fluid resistance has the advantage of large Stability due to its thermal inertia, which it shows both when heating and when cooling. Therefore, such a resistor is suitable for intensive but less frequent applications; a solid resistance however, it would be used more for very frequent applications.

In the case of the fluid resistance according to FIGS. 1 to 3, the vapor development can take place in such a way that the liquid level in the cavity 2 adjusts to the level N ', the excess vapor emerging through the line 5. For this purpose, the fluid resistance can be operated with one of the devices shown in FIGS.

However, if the electrode parts 13c / and 14c / are sufficiently large, the vapor pressure in the cavity 2 continues to rise and the valve flap 7 is below Overcoming the pressure of the spring 12 is lifted from its seat, so that the steam through the openings 11 can emerge. This vapor is in the cold, conductive liquid, which is in the container 1, condenses and the liquid then penetrates again into the cavity 2 and thus enables the renewed current flow between the electrode parts 136 and 13c. Closing the valve flap again 7 is slowed down by the shock absorber formed by the piston 9 and the cylinder 10. Through appropriate Dimensioning the weight of the valve flap 7 and the bias of the spring 12 can Working pressure and the speed at which the liquid flows back into the cavity 2 is influenced will.

Such an automatic mode of operation is for use as a starting resistor for an asynchronous motor sufficient. However, the steam outlet through the line 6 is preferably from the outside controlled so that the resistance value of the liquid resistance is controllable.

This is shown in FIGS. 5 and 6 Embodiment, the valve flap 7 is connected via a rod 16 to a plunger 17, the is located inside an electromagnet 18. When the electromagnet is excited, the Valve flap. The amount of steam flowing out through line 6 can be influenced in that the Extension 19 of the valve flap 7 inside the line 6 is given a suitable shape so that the Approved cross section of the line 6 in a predetermined relationship with the opening stroke the valve flap is up. In addition, guide ribs can be provided for guiding inside the line 6.

In the embodiment according to FIGS. 7 and 8, the valve flap 7 has a tubular shape, they elongating sleeve 21 having diametrically opposed slots 22, the shape of which is as in the previous one Embodiment which determines the amount of steam escaping via line 6.

The conductive liquid is preferably one

Caustic potash solution that has a low specific resistance. The capacity of the cavities only needs to be a few cm ³ for powers of around 10 kW, and for normal mains voltage (220 V) the smallest distance between the electrodes can be 1 cm.

For this purpose 2 sheets of drawings

Claims (5)

Patent claims: 1.Liquid resistance with a cavity connected to a container, containing a conductive liquid, and electrodes arranged in it, through which a current can flow through the liquid, which allows part of the liquid to evaporate and thereby presses another part of the liquid into the container, wherein the cavity has a vertically extending passage line, which enables a controlled reduction of the steam pressure building up there, characterized in that the container (1) and the cavity (2) are cuboid and separated from each other by a horizontally extending partition (3) and the electrodes (130, 13c, \ 3d; 14b, 14c, Ud) in the container (1) on the narrower, in the cavity (2) on the wider vertical walls face each other and the electrodes (2) arranged in the cavity (2) 13c, 13d; 14c, i4d) each of large-area electrode parts (13c, 14c) in the area adjacent to the partition (3) and on the other hand over much smaller-area electrode parts {\ 3d, 14d), which face each other at a much greater distance than the large-area electrode parts (13c, 14c), in the area adjacent to its base and in both the cavity (1) arranged below the container ( 2) with the former not only via the passage line (6), but also via a second line (5) with a smaller flow cross-section than that of the passage line (6), the inlet openings of which are arranged on the lower edge of the partition (3), and via a third line (4) ), the inlet opening of which is arranged below the lower edge of the large-area electrode parts (13c, 14c) in the cavity (2). 2. Liquid resistance according to claim 1, characterized in that the passage line (6) and the second and third line (4,5 ) open below the liquid level (N) \ m container (1). 3. Liquid resistance according to claim 1 or 2, characterized in that the passage line (6) a valve flap (7) which is controlled by the steam pressure and carried by a damping cylinder (10) is braked. 4. fluid resistance according to claim 1 or 2, characterized in that the passage line (6) has a valve flap (7) with electromagnetic control (17,18). 5. fluid resistance according to claim 3 or 4, characterized in that the valve flap (7) at the end of the passage line (6) determines the outlet opening of the same with its shape, the cross section of which depends on how far the valve flap rises from its seat.