DE338157C - Adjustable electrical resistance with loose resistance mass filled into a container, especially for electrical heating - Google Patents

Description

Adjustable electrical resistance with loose, filled in a container Resistance mass, in particular for electrical heating. For this registration is according to the union treaty of June 2nd igi i the priority based on the registration in Switzerland from September 2nd. The present invention relates on electrical resistances made of loose resistance mass, especially small pieces Coal, as used in particular for electric heating, e.g. B. used by crucibles will. As is well known, carbon has the property that with increasing temperature the ohmic resistance decreases, and this decrease is quite considerable, see above that the resistance at high temperatures is less than 1 / o of the initial resistance when cold. Will such a carbon resistor without special Precautions connected to an existing constant voltage power source, which is sufficient to bring about a temperature increase, even if initially only a small one, so the ohmic resistance decreases, and increases in the same inverse proportion the current drawn from the network. The increased power consumption has an accelerated Temperature increase and thus a further decrease in resistance and this in turn a increased current consumption, which in the end leads to undesirably high currents and can lead to rapid temperature increases.

To now the current consumption of such Koh-. fuel resistances within To keep more useful limits, it was previously attempted to adjust the connection voltage accordingly to change. The facilities required for this are, however, because they are changes acts within wide limits, relatively complicated and expensive.

Now to the ohmic resistance of one made of carbon mass to be able to regulate electrical resistance in a simple and economical way, a new approach is taken according to the invention by providing mechanical means are to the carbon mass lying loosely on these agents during the temperature change to shift so that their density and their location undergoes a change. This is done the loose carbon mass is poured into a container that has so many spaces is subdivided, -as power supply lines are available, and the arrangement is made in such a way that that the carbon mass connects the individual spaces with one another, whereby the means to shift the mass of carbon, at least in part of the spaces of act below on the carbon mass in these spaces. As the carbon mass with their own weight on the displacement means rests so is the density is greatest near these displacement means, and one has it in hand, by raising the carbon mass, the cross-section of this carbon mass in the To increase the space above the partition and to decrease the resistance and to achieve the opposite by lowering.

This regulation can advantageously be automatic as a function of the current consumption take place.

Exemplary embodiments of the subject matter of the invention are shown in the drawing shown.

Fig. I is a first embodiment in vertical section.

Fig. 2 shows a second embodiment, also in the vertical Section, in this case an electric melting furnace is shown, 3 is a horizontal section along the line III-III of FIG.

FIGS. 4 to 6 show further exemplary embodiments.

The resistor shown in Fig. I has a jacket i, which consists of refractory material is made. In this jacket there is a lid at the top z, which closes a filling opening and made of the same or similar material how the coat i consists. The space enclosed by the mantle is through a partition 17 divided into two parts, and through the filling opening there is carbon mass in the filled by the jacket i enclosed space. In every part of the room there is a piston 5 made of iron or other conductive material, which piston is electrical serve as a power connection for the carbon mass, which forms the heating resistor. The carbon mass is loosely poured onto the piston 5 and rests with it Dead weight on it, but it is filled so far that there is also a carbon mass above it the partition wall 17 is located so that a connection through the carbon mass even between the two columns of carbon mass resting on the piston 5 is maintained. The pistons 5 can be displaced lengthways in the channels and thus shift the carbon mass resting on them. Because of this shift a compression of the carbon mass can be made while lowering the piston can loosen. Will now be direct current or alternating current supplied to the piston 5, while the carbon mass in the cold state on this Piston rests and is also present above the partition wall 17, so there is a electrical connection between -the two pistons 5. The through the current passage Heat generated by the carbon mass is used solely for heating purposes Space within the jacket i used. The temperature will rise and the ohmic Decrease the resistance of the carbon mass. If the pistons 5 are then lowered, so the carbon mass changes d. their location and density, d. H. the carbon mass moves down and loosens up until the ohmic resistance of the carbon mass is approximately returned to the originally desired value. With further If the temperature increases, the ohmic resistance will continuously decrease and again loosening of the carbon mass becomes necessary, which can be achieved by moving the Piston takes place. - This process is repeated until the required heat is reached is. When lowering the piston 5, the amount of carbon mass is above the Remove partition wall 17 and the resistance of the carbon mass that the two Connecting pillars, increasing.

In Fig. A and 3 the resistor is designed as an electric melting furnace, and that is used in the upper part of the shell i for the filler opening Carbon mass at the same time to accommodate a crucible 3. This crucible 3 protrudes with its lower part into the carbon mass, which is above the Partition wall 17 is located, is thus enveloped below by the carbon mass. Of the upper part of the shell i is so thick that there is still a space above the crucible 3 remains, which is through the cover a to outside. is closed. The melting pot 3 can be used either loosely or firmly connected to the jacket i; in In the latter case, the entire furnace would then be pivotable about a horizontal axis set up. In this example, too, the flow becomes piston 5 as in FIG supplied, while .the carbon mass in -cold state through the piston 5 is pushed up until the carbon mass enters the cavity under the crucible completely or for the most part. The one through the passage of current in the carbon mass generated heat is, since the jacket i is thermally insulating to the outside, almost exclusively the crucible 3 supplied. 'As soon as the temperature rises and the ohmic resistance the mass of carbon decreases above the partition wall 17, the pistons 5 somewhat lowered to by changing the location and density of the carbon mass and the thickness above the partition wall, the ohmic resistance in the desired Modify senses. This process is repeated until the necessary heat in the Crucible is reached. If the oven according to FIGS. 2 and 3 for Three-phase current are set up, so one sees three channels 18 before and arranges a piston 5 is slidably attached to each channel 18, each piston in turn serves as power supply at the same time. But it is not necessary that in all three channels 18 there is a piston 5, it could also be just a part of the channels contain such a piston. For other types of current or types of power supply however, it is at least necessary to divide the furnace chamber into as many rooms as as power supplies are available.

The adjustment of the pistons, which can be done by hand, is now achieved more advantageously by an automatic adjustment device, such as such is shown in FIG. The melting furnace i is suitable for laboratories and suitable .sich for direct connection to an existing line network 1g. The power supplies to the furnace are again marked with 5 and stand with the pistons that hold the carbon move. can, in connection. Both connections 5 are on an isolation bridge 16 placed, which is located at the end of a rod 2o. This stands with -dem Core 21 of a solenoid 6 in connection. The latter is traversed by the mains current, which via a circuit breaker 8 from the network 1g to a connection 5 from there through the carbon mass in furnace i to the other port 5, from there through the Solenoid 6 flows back to switch 8. There is another one on the rod 2o Washer 22 which rests on a spring i. This has-the endeavor, the piston and thus pushing the carbon mass upwards and thus the ohmic resistance to zoom out. This spring force is counteracted by the heating current flowing through it Solenoid 6 and overcomes the spring force as soon as the heating current has a certain value exceeds. This has the consequence that the Ohin resistance of the carbon mass is enlarged. As soon as the state of equilibrium between the spring force on the one hand and the solenoid force plus the dead weight of the controls on the other hand is, the whole thing is in the rest position. But it takes place through a change in temperature a change in resistance and, at the same time, a change in current, which is caused by the solenoid acts, a shift takes place until a new state of equilibrium is reached. Voltage fluctuations in the network, which also result in a change in current cause are also regulated by this facility.

If greater forces are required to move the pistons, this can be achieved indirectly using hydraulic forces, as shown in FIG. The furnace shown there is a medium-sized one for an output of 10 to foo kW. The furnace i is connected to a three-phase power supply network 1g by means of an automatic switch 14, ie each of the pistons 5 is connected to one phase in an electrically conductive manner. The three pistons sit together on an insulating bridge 16, which is fixed on a hydraulic piston 1o, the latter being movable in a cylinder g. A pressure line 12, which leads pressure fluid under the piston 1o, leads to this cylinder. This line 12 is provided with a control valve ii, which enables pressure fluid to flow into the open. The solenoid 6 acts on this control valve ii and closes and opens it, depending on whether the piston is to rise or fall. Since the pressure in the line and below the piston 1o decreases when valve ii is open, the dead weight of the control elements connected to the piston measured sufficient to bring the piston to .Sinking, that is, a medium pressure was measured around the control piston keep your balance. A current flows through the solenoid 6 which is generated by a current transformer 13 which is in one of the phases leading from the switch 14 to the piston 5. The movements of the control valve are therefore dependent on the amount of electricity that the furnace consumes.

In the arrangement according to FIG. 5, the inequality in the phase loads was measured be accepted. In Fig. 6, which shows a melting furnace for very large performances shows, each phase is controlled for itself, creating an even load for all three phases is achieved. There is one flask for each flask in this furnace Control is provided as shown in FIG. Also here are because the solenoids not good for larger currents. Can be built directly, current transformers 13 provided, one in each phase. Any setting of the desired currents within wide limits are possible in parallel with the solenoid Setting resistors 15 switched.

The melting heat in the furnace is mainly just below the crucible generated because there .the cross-section of the resistance mass is smallest and the mass itself is subjected to the slightest pressure, which most of the ohinschen Resistance of the entire heating resistor at this point results. Those removed from it Connecting and sliding pistons 5 are exposed to significantly lower temperatures, so that a melting off same is not possible. Because pulling out the piston 5 both a loosening and a displacement of the drag mass As a result, the shift can be almost completely interrupted the otherwise connected resistance mass are led under the crucible, which would not be possible with relaxation alone.

The increase in the ohmic resistance towards the crucible can also be achieved artificially by means of different conductive resistance masses. You can use the carbon mass z. B. add a substance, making it a lower Conductivity is obtained, in which case this conductivity is then expediently upwards decreased. The heating of the resistor mass takes place under almost complete Air exclusion so that combustion is kept to a minimum. Also is the durability of the crucible is significantly greater than z. B. at ordinary Coal firing. Last but not least, the material to be melted is prevented from entering air protected from harmful oxidation.

Instead of the arrangement according to FIG. A, in which a crucible is used one could also close the ceiling and use the upper part of the furnace as a melting room use - n.

The reversing valves can of course also act more precisely be. The automatic off switches 14 are expediently not only in one phase triggered built-in, but so that all three, but at least two phases the @ -lusklinkvorrichtung this switch act.

Claims (1)

PATENT CLAIMS: i. Adjustable electrical resistance with loose resistance mass filled into a container, in particular for electrical heating, characterized in that .cler container is divided into as many rooms as there are power supply lines, and in these rooms the resistance mass is so high that this is the connects individual rooms with each other, whereby the power leads form the base for the resistance mass and, in that they are movable, at the same time form the means to change the density of the resistance mass and the storage of its individual particles and thus to regulate the ohmic resistance. a. Adjustable resistor according to Claim i, characterized in that the mechanical means for shifting the power supply lines and the resistance mass are controlled by a hydraulic device. 3. Adjustable resistor according to claims i and a, characterized in that the piston -the hydraulic device is controlled automatically as a function of the power consumption or temperature. 4. Adjustable resistor according to claim i, characterized in that the loose resistance mass in the vicinity of the power supply lines is composed so that it shows better conductivity there than at more distant points.