DE646017C - Device for mixing different materials in the given mixing ratio - Google Patents

Description

The invention relates to material handling equipment in which various Materials ,, which are on special conveyors of a third conveyor are supplied, are to be mixed in a predetermined ratio. It is known, the speed of a feeding conveyor and thus the Amount of fed material depending on the amount of material that is fed by the other conveyor to control. This control happens mostly using a weighing pan with a balance lever, which is attached to a specific Place is attached under the collecting conveyor and its setting of the Weight of the material falling on the conveyor is dependent.

According to the invention, this control is now carried out by using an on Gas discharge vessels connected to the alternating current network, their control grid voltages expedient in terms of their phase position by means of a solenoid through the balance lever are influenced by the fact that the anode current is the excitation of the with respect to his Speed controllable drive motor which influences a feeding conveyor. This control according to the invention has the advantage that the control device immediately to a change in the one supplied by the conveyor device Material quantity responds, so that even then a constant mixing ratio of the materials is guaranteed if the amount of material supplied by the one conveyor device changes only briefly.

The following description will serve to provide a better and more complete understanding of the invention and the accompanying drawing, which is a schematic representation of an embodiment of the invention shows.

In the drawing, a conveyor 10 is driven at a speed which preferably by any suitable propellant, such as. B. the electric motor 11, whose shaft is directly connected to the drive roller 12 of the conveyor is kept substantially constant. Each of the larger number of feeder conveyors 13 and 14 is intended to be a separate material from matching Storage devices, e.g. B. containers or vessels (not shown) to the common To deliver conveyor 10. The feeder conveyor 13 introduces Material such as B. coke, and the infeed conveyor 14 another material, such as z. B. limestone, while the common conveyor 10 serves to provide a mi

Schung these materials in the direction of the arrow in a shaft furnace or other suitable To supply apparatus in which this is necessary for the execution of a desired process 5 or another work process can be used.

Although the feeder conveyors 13 and 14 have been drawn in the usual manner in the manner of the belt conveyors, it goes without saying that they can also (and in practice this is also done) in the manner of the bucket conveyors. The conveyor 13 is driven by a suitable drive means, for. B. the DC motor 15, which is driven by a suitable DC power source, ζ. B. by the feed lines 16 and 17 shown in the drawing in the usual way, with the two poles of the terminals of the motor through the conductors 18 and i8 _fl and the contacts of the switch 19 are connected accordingly when the switch is in its upper or closed position; a series field winding 20 and a reversing pole winding 21 is, as shown, connected in series with the armature circuit of the motor.

A suitable starting device 22, which is shown schematically for the sake of simplicity, is used to automatically adjust the starting resistance in the armature circuit in a known manner gradually decrease as soon as the main switch 19 is brought into the closed position became.

A suitable propellant, such as. B. electric motor 23 is used to drive the conveyor 14 at a preferably substantially constant speed, and this motor as well as motor 11 which is the common conveyor 10 drives, is by means of cables and switches (not shown) with a suitable power source, preferably the power source 16, 17, from which the motor 15 is fed, connected.

The motor 15 is also provided with a separately excited shunt field winding 24 provided, which with direct current from a suitable electrical discharge device 25 is fed to the anode circuit 26 and 27 of which it is connected; the electric Discharge device 25 is in turn supplied with alternating current via a transformer 28 fed, which, as in the drawing, a primary winding 29 and three secondary windings 31, 30 and 32 owns. The primary winding 29 of the transformer is means the conductor 33 is connected to a suitable AC power source, shown in the drawing fio is represented in the usual manner by the feed lines 34.

The electrical discharge device 25 consists, as shown, of two separate ones electrical discharge vessels 35 and 36. iThese vessels are, as shown, from the -Three-electrode type; they are both with anoids 37 ·, 38, grid 39, 40 and heating cathodes 41, 42 provided. Although there are some suitable ones for these electrical discharge vessels Types can be used, three-electrode vessels are preferably used for this purpose, with small ones in their casing Quantities of inert gas or steam, e.g. B. mercury vapor, were introduced after the vessels have been evacuated; the presence of the inert gas or vapor within the vessel serves to create an arc discharge come about, and the discharge vessels are set up in this way, like the electrostatic or grid-controlled arc rectifiers. A well-known one The property of vapor discharge vessels of this type is that the expenditure of a small amount of energy in the grid circle is sufficient, a very large amount of energy in the anode or output circuit of the apparatus to control. The cathodes 41 and 42 are through to the required degree of glow Alternating current is heated to this cathode by the secondary winding 30 of the transfermator is supplied, at the terminals of which are connected in parallel by the conductors 43 and 44 Cathodes 41 and 42 are connected. As shown in the drawing are the electrical discharge vessels 35 and 36 for full-wave rectification of the power source 34 supplied voltage is switched, i.e. the anodes 37 and 38 of the devices are with connected to the outer ends of the secondary winding 31 of the transformer, during the Center of this secondary winding via the conductors 26 and 27 of the anode circuit is connected to a common conductor 45 which, as shown, is connected to the midpoints of cathodes 41 and 42 through conductors 46 and 47 in communication.

The alternating voltages are fed to the grids 39 and 40 by means of a grid feed resistor 48, with the outer ends of which the grids are connected in a corresponding manner by conductors 49 and 50; the grid circuits also contain suitable protective resistors 51 and 52. The voltage ; s, which are fed to the grid supply resistor 48, are a local circuit taken from the secondary winding 32 of the transformer of the (variable) Choke coil 53 and a resistor 54, all through the conductors 55 and are connected in series; one terminal of the iao grid feed resistor 48 is centered the secondary winding 32 of the

formatorSi iduxch. connected a conductor 57, and the other terminal of resistor 48 is with a common point between Choke coil 53 and resistor 54 connected by conductor 58.

As is known to those skilled in the art, the current in the anode circuit 26, 27 of the electrical discharge vessels 35, 36 can be changed as desired by changing the phase position between the alternating voltages that are fed to the corresponding grids and anodes of the electrical discharge vessels 35 and 36. For this purpose, in order to change the reactance of the choke coil 53, a movable soft iron core 59 is introduced into the coil 53, the position of which _{depends on the pull of the weight tray 70, the weights 70 a} and the current strength in the coil 53. The reactance of the choke coil 53 is variable between a maximum when the core 59 is in the lower position and a minimum when the core is in the upper position. The change in the position of the core 59 in the coil 53 is used in this way to change the phase position between the currents of the secondary windings 31 and 32 of the transformer and consequently also the phase position between the voltages that the anodes 37 and 38 and the Grids 39, 40 of the electrical discharge vessels 35, 36 are fed in a corresponding manner. As a result of this, there is a change in the current in the anode circuit 26, 27, and since the field winding 24 of the motor 15 is connected to the anode circuit 26, 27, the speed of the motor 15 is likewise changed in direct proportion to it.

A suitable contact device 60 is with its contacts 63 in the anode circuit 26, 27 of the electrical discharge vessels and is used to control the circuit for to close the field winding 24 of the motor.

The armature of the contact device 19 is actuated by a control relay 61, the actuating winding of which 62 into the anode circuit 26, 27 in series with the field winding 24 the auxiliary contacts 63 is connected when the contact device 60 is in its upper or closed position Position is.

A starter switch shown schematically in the drawing as a push button 64 causes when pressed, it closes a circuit - for the actuation winding 65 of the field switch; this circuit is completed by · one pole of the supply line 34 via the hold push button 66, the movable and fixed contacts 64, the conductor 67, Winding 65 and from there on conductor 68 to the other pole of the feed line 34. The Field switch 65 is also provided with an auxiliary contact 69 ,, - which in the upper or closed position of the switch the associated stationary contacts - bridged and a holding circuit for energizing the winding 65 of the switch, independently 'from the start button 64, closes.

When executing certain processes in a shaft furnace, the z. B. can be fed by the common conveyor belt (conveyor) 10, it is desirable that the relative percentage of the materials making up the mixture supplied remains substantially constant, ie the ratio between the relative proportions in which the separated materials or components of the mixture are fed to the common conveyor belt 10 must remain essentially solid. It can be seen immediately that the weight of the material on the conveyor belt 10 ^{1 will be} unevenly distributed if the conveyor belt 14, which operates at essentially constant speed, feeds a material such as limestone, the pieces of which are usually a fraction of a minute in size and that weigh a fraction of a kilogram to several kilograms for large lumps and that, as a result, the amount in which this material is fed changes in substantially the same proportion as the weight of the successive pieces or lumps. Accordingly, the weight of material on any portion of the belt 10 is a measure of the instantaneous amount in which the material is being fed.

On the other hand, when the conveyor belt 13 feeds material such as coke, its lump size is small and essentially uniform, the proportion in which this Material is fed to the common conveyor belt 10, depending on the speed, with which the conveyor belt 13 is driven by the drive motor 15. So that Ratio between the proportions in which the various materials make up the conveyor belt 10 remains fixed, it is therefore necessary to increase the speed of the Motor 15 according to the proportion in which the first material, that is the limestone, is fed to the conveyor belt 10, d. H. the speed of the motor 15 must be according to the successive instantaneous weights of the limestone a given section of the conveyor belt. For this purpose there is one Weighing pan 70 under the section 73, 74 of the conveyor belt 10 between the transport rollers 75 and 76 arranged; the weighing bowl, which is placed on the movable core 59 of the throttle

coil, as previously stated, is attached, is used to change the Speed of the motor 15 in accordance with the position of the core within the spool 53.

After understanding the elements and the

Apparatus from which the present invention is constructed is based on its mode of operation easy to understand from the following description.

When the various control switches are in the open position in which they are drawn, all apparatus will be in the idle state. The electrical discharge device 25 is only fed when the switch 33 _{a has been brought} into the closed position and the primary winding 29 of the transformer 28 is connected to the current source 34. After the heating cathodes 41 and 42 have been heated to the required degree of glow, the electrical discharge vessels 25 are ready to feed a rectified current through the anode circuit 26, 27 into the field winding 24 of the electric motor 15.

By pressing the start button 64, the field switch 60 is actuated and brought into its upper or closed position, thereby connecting the field winding 24 to the anode circuit 26, 27 of the electrical discharge device; This circuit closes from one of the cathodes 41 or 42 to the conductor 27 via the field winding 24 of the motor 15, the actuating winding 62 of the control relay 61, the main contact 63 of the field switch 60, the conductor 26 to the center of the secondary winding 31 and from there either to the anode 37 or to the anode 38. The current flow in the winding 62 causes the actuation of the control relay 61 in its upper position, in which it closes a circuit for the excitation winding of the main switch 19; This circuit closes from the positive pole 16 of the direct current source via conductor 7i to the lower auxiliary contact of the field switch 60, the contacts of the control relay 61, conductor 72, the coil of the main switch 19 and from there to the negative pole 17 of the direct current source. Switch 19 moves as a result of the excitation of its coil in its upper or closed position, in which it closes the armature circuit of the motor 15; this circuit closes from the positive pole of the conduit 16 through the lower contact of the main switch, the automatic starter device 22, the conductor i8 _a, the armature of the motor 15, the main excitation field winding 20 and the commutating winding 21, the conductor i8, of about the upper contact Main switch to the negative pole 17 of the feed line.

The supply of the armature and the field windings of the motor 15 cause this to circulate and cause the conveyor belt 13 to be driven at a speed which depends on the excitation of the field winding 24 in a known manner. The movable one Core 59 will assume a position dictated by the weight of the material on the section 73, 74 of the conveyor belt 10 and on the amount of current in the winding 53 depends.

As long as the quantities in which the limestone or other material is carried by the Conveyor belt 14 are fed to the conveyor belt 10, remain essentially constant, the movable core 59, which supports the weighing pan 70, is in the position assumed by the current weight of the material on the weighing pan, the weights 7o "and given by the current of the coil 53 is to remain in equilibrium, and the control apparatus will remain inactive. However, if the portion of material that is fed to the conveyor belt 10, as a result of fed piece size or by some other cause changes, the weighing pan 70 the core 59 upwards or move downwards, as may be the case when the weight of the, pieces becomes greater or less than the weight, which is just sufficient to keep the movable core 59 in the aforementioned position. For example, if a large lump of limestone gets onto the conveyor belt 10, the weighing pan 70 depress the core 59 within the coil 53 and thereby becomes the Reactance of the circuit to which the grid feed resistor 48 is connected, and change the phase position between the voltages at the anodes 37, 38 and the Grids 39, 40 move so that the current in the anode circuit 26, 27 and in the Field winding 24 reduced, whereby the speed of the motor 15 is increased, so that the conveyor belt 13 is caused to feed a larger amount of coke to the conveyor belt 10, and in this way the percentage of coke and limestone is essentially kept constant. in the

On the other hand, when the amount of limestone supplied to the conveyor belt 14 is below the required Amount to increase the core 59 in its central position within the coil 53 hold, decreased, the weighing pan will move up and the phase position between the grid and anode voltages in the opposite sense, as above wrote, shift and in this way the current in the anode circuit 26, 27 and increase in the field winding 24 and thereby reduce the speed of the motor 15

so that the proportion of coke that is fed to the conveyor belt 10 by the conveyor belt 13 is, is reduced and thereby the ratio of the material proportions in the mixture on conveyor belt 10 is kept essentially constant.

The relative proportions in which the two materials are fed to the common conveyor belt 10 can be _{adjusted as desired by changing the weights 7O 0} on the balance beam, since a change in the weights jo _{a changes} the position of the core 59 in the coil 53 and thereby the The speed of the motor 15 and consequently the amount of material fed to the conveyor belt 10 by the conveyor belt 13 is varied in the manner described above. It can therefore be seen that any change in the proportions in which material is fed to the conveyor belt 10 by the conveyor belt 14, a change in the reactance of the choke coil 53 and a change in the phase position between grid and anode voltage of the electrical discharge vessels and, consequently, the currents, applied to field winding 24 of motor 15 will cause the speed of the motor to be varied to maintain the percentage of materials at the desired level.

In the event of the absence of the alternating voltage 34, the actuation winding 65 of the Field switch. emitregen, and the switch falls in its lower position, in which it interrupts the circuit for the main switch 19 and the opening of the latter and thus the interruption of the armature circuit of the Motors ι S causes. Similarly, will when an error occurs in an or

<μ> two electrical discharge vessels 35, 36 the anode circuit 26, 27, in which the actuation winding of the control relay is switched is de-energized and therefore causes this, the feed current circuit for the main switch to interrupt, which in turn interrupts the armature circuit of the motor 15 will. It can be seen from this that the main switch is dependent on the AC power source 34 and the field circuit of the engine and that as a result, the engine against starting with open field winding and the same, at any time is protected against errors in the field excitation.

Claims (3)

Patent claims: 1. Device for mixing different materials in the specified mixing ratio, in which the different materials through different conveying devices (Belts) are fed to a third conveyor device, and in which the weight of the one Amount of material supplied at a constant speed driven conveyor using the speed of the drive motor of the other infeed conveyor a balance lever, characterized in that the anode current is grid-controlled, discharge vessels (35, 36) fed from an alternating current network (34) via a suitable transformer (28), preferably with hot cathode and gas tube vapor filling, 'used for control, the control grid voltages with respect to their phase position by means of a solenoid (59) can be influenced by the balance lever. 2. Device according to claim 1, characterized in that for the control the speed of the electric motor (15), preferably a DC motor, the Change of his field excitation (24) with- . means of the control device (discharge vessels 35, 36) is used. 3. Device according to claim 1 and 2, characterized in that the balance lever depending on the weight of the material lying on the collecting conveyor belt to change the inductive Resistance of the solenoid (59) lying in the grid circuit in this the adjustment of an iron core. For this purpose ι sheet of drawings