SU1166219A1 - Power supply system for magnetodynamic installation - Google Patents

Abstract

1. POWER SUPPLY SYSTEM OF MAGNETODYNAMIC INSTALLATION, having two inductors and at least one electromagnet, containing the first autotransformer connected to one line voltage of a three-phase network, the second autotransformer connected to another line voltage of this network, ahead of the first phase, and an adjustable capacitor for balancing the currents of the network, with both autotransformers being made with leads to receive on the inductors, electromagnets and a partial or full voltage capacitor created by In the winding of the corresponding autotransformer, one inductor is connected to the first autotransformer, one voltage of the adjustable capacitor is connected to one of the windings of the second autotransformer, and the electromagnet outputs are connected via keys to the windings of both autotransformers, characterized in that performance of the magnetodynamic installation, reducing the installed capacity and higher- (L nor the reliability of the power supply system, the third autotransformer connected to third linear voltage network voltage, adapted to produce on the terminals connecting to it a second inductor partial or full voltage generated in the winding of the autotransformer ;. 2. A power supply system according to claim 1, characterized in that additionally introduced compensating adjustable capacitors are connected in parallel with the first inductor and in parallel with one of the electromagnets.

Description

The invention relates to electrical engineering and can be used in the development of means for electromagnetic heating and transferring molten metal using power sources, available means for converting metal, and more specifically concerns the magician. The invention can be most effectively used for heating and metered casting of metals into casting molds in accordance with the requirements of the technological process while simultaneously ensuring the symmetry of the currents in the supply network. Various casting devices and molten metal dispensers (mechanical, pneumatic and electromagnetic) are widely used to automate the foundry industry. The production units of the magnetodynamic type or magnetodynamic plants (VDU), whose operation is based on the interaction of current and magnetic flux in the active zone of these plants, most fully meet production requirements. When fed with alternating current, the performance of the MRL in the metal casting process depends not only on the effective values of current and magnetic flux, but also on their initial phases, which imposes specific requirements on the parameters of the power supply and, accordingly, on the power supply circuitry. . In addition to the noted features, MRLs are characterized by the fact that for a multiphase network they are unbalanced loads causing asymmetry of currents and voltages negatively affecting the operation of all network elements, including the devices themselves in which the power supply unit contains transformers. or autotransformers to which an adjustable capacitor and two loads are connected, which, in particular, can be an inductor and an electromagnet VDU fl J and C2 J. In these devices, the ratio of the initial phases of the voltage to the load It is chosen from the condition of minimization of the installed power, which requires the inclusion of an inductor with a higher power factor from the mains voltage that is lagging in phase (approximately 110), while to ensure efficient operation of the VDU, the phase angle between the voltages supplying The electromagnetic systems of the installation must be in the range of 120 ° with the advance voltage on the inductor system. Therefore, such devices cannot ensure the achievement of the necessary technological parameters, for example, a given level of electromagnetic pressure. A VDU power supply system is known, in which the inductor and electromagnet systems can be connected to a three-phase network directly or with the help of a power supply unit. In this case, the power supply unit contains the first autotransformer connected to one line voltage of a multiphase network, the second autotransformer connected to another voltage of this network, which is ahead of the first one in phase, and an adjustable capacitor for balancing network currents. The power supply also includes a third autotransformer, designed to power the electromagnet. All autotransformers have a lot of output to obtain partial or full voltage on the connected loads, while the load for the first autotransformer is an inductor, one pin of which is operatively connected to one of the winding pins of this autotransformer, and one pin is adjustable. capacitor - with one of the winding leads of the second autotransformer, while the second lead of this capacitor is connected to the corresponding phase of the network. In this design of the MDU power supply system, the second autotransformer performs the functions of a phase-shifting element (electromagnetic voltage divider), providing an adjustable voltage capacitor having an optimal (from the point of current current balancing) initial phase, defined by. under the conditions of balancing Cz. The first and third autotransformers provide power to the inductor and the electromagnet, respectively, and the autotransformer that supplies the electromagnet has a low utilization factor, since the time it takes to pour the metal into the mold in the process cycle of the installation is usually 10-30%.

311662

Thus, in the well-known setting, the tasks of power and optimization of balancing are solved separately. In addition, the initial phases of the input voltage of such MRLs are determined by the capabilities of the three-phase electrical network and are not always optimal, which degrades the efficiency of the use of electrical energy, ultimately leading to low efficiency of the installation as a whole. Moreover, the separate use of autotransformers for power supply and balancing of currents of a three-phase network also leads to an increase in the installed power of the device.

The power ratio of the inductor, electromagnet and adjustable capacitor are such that almost all three autotransformers have 20

dinink power, therefore, when feeding MRLs containing more than one inductor and an electromagnet, it is necessary either to increase the number of feeding autotransformers or, correspondingly, their power. This in turn will lead to an additional increase in the installed power of the power supply unit.

The closest to the technical essence of the invention is an MDU power supply system having two inductors and at least one electromagnet containing a first auto-recorder connected to one line voltage of a three-phase network, the second is an autotransformer connected to another line voltage of this network , leading the first in phase, and an adjustable capacitor for the symmetry of the mains currents, with both autotransformers being made with electrodes to receive partial or complete the voltage generated in the j-coil of the corresponding autotransformer, with one inductor being connected -. A first autotransformer, one output of a regulated capacitor is connected to one of the outputs of the 5Q winding of the second autotransformer, and the outputs of the electromagnets through the keys are connected to the outputs of the windings of both autotransformers L4 J.

The use of the known power supply system - 55 NIN-for MDU, having two inductors and one or two electromagnets, intended for pouring metal od19

currently in two or one form, requires an increase in the installed power of autotransformers twice, or a corresponding increase in the number of these autotransformers, which in turn will lead to an additional increase in the installed power of the power supply system.

The purpose of the invention is to improve the performance of the MDU, reducing the installed capacity and increasing the reliability of the power supply system.

The goal is achieved by the fact that in the power supply system of SchU, which has two inductors and at least one electromagnet, contains the first autotransformer connected to one line voltage of a three-phase network, the second autotransformer connected to another line voltage of this network containing the first in phase, and an adjustable capacitor, for balancing the currents of the network, while both autotransformers are terminated with leads for obtaining, on an inductor, electromagnets and a capacitor, a partial or total voltage, given in the winding of the corresponding autotransformer, with one inductor connected to the first autotransformer, one output of the adjustable capacitor connected to one of the windings of the second autotransformer, and the outputs of the electromagnets connected to the windings of both autotransformers through the keys of the third autotransformer connected to the third linear the voltage of the network, made with the conclusions to obtain on the second inductor connected to its second inductor partial or full voltage generated in the winding is about autotransformer.

At the same time, additionally introduced compensating adjustable capacitors are connected parallel to the first inductor and parallel to one of the electromagnets.

Figure 1 is a schematic diagram of an IMU power supply system; Fig. 2 is a topographic voltage chart on the elements of an installation diagram illustrating its principle of operation.

The MRL power supply system contains three autotransformers 1-3, adjustable capacitors 4-6, inductors 7 and 8, electromagnets 9 and 10. Autotransformers 1-3 and adjustable capacitors 4-6 form an IMU power supply system, and inductors 7 and 8 and electromagnets 9 and 10 are the load of this power supply. The proposed VDU power supply system is connected to a three-phase network shown as A, B, and C buses. At the same time, the winding 11 of the autotransformer is connected to the linear voltage of the VCA, the winding 12 of the transformer 2, to the linear voltage of the VDP and the leading voltage of the Urd, and the winding 13 autotransformers 3 - to the linear voltage, which is lagging from the voltage V. The windings 11-13 have, besides the linear B, desoldering shots, which are the terminals of the winding parts, which ensures operative connection of the loads to any winding leads, including inverse leads. Adjustable capacitor 4 is connected to one linear output of winding 11 and to one of the taps of winding 12 for balancing network currents. Balancing is carried out in a known manner. The inductor 7 and the electromagnet 9 are turned on in the same way as in the known device. In series About electromagnets 9 and 10, keys 14 and 15, respectively, are turned on, and inductor B is connected to the common section of autotransformers 1 and 3 and to one of the windings 13 taps. Operative -; R; The electrical connection of the inductor 8 with the autotransformer 3 is carried out in the same way as the connection of the inductor 7 with the autotransformer 1, i.e. switchable from one tap to another. The ratio of the initial-phase voltages on the inductors 7 and 8, and, accordingly, the electromagnets 9 and 10 must be established quite clearly. Therefore, the selection of autotransformers 1-3 for connecting the loads is carried out according to the technology requirements, and the asymmetry of the currents in the network arising from this is eliminated by connecting an adjustable capacitor 4 to the corresponding tap-off windings of the autotransformer 2. According to the invention (FIG. 1) parallel to the inductor 7 and the electrical equipment compensating adjustable capacitors 5 and 6 are connected. The role of these capacitors is that they compensate for the reactive power of the respective loads, which helps to reduce Becoming as a power autotransformers, and adjustable capacitor. When the MDU operates in the metal heating mode, only inductors 7 and 8 are included. The magnitudes and phases of the voltages supplying these inductors are chosen based on the condition that the metal is heated in the MRL, which is provided by selecting the magnitude and initial phases of the voltages on the inductors. Therefore, the beginnings of the windings of the inductors 7 and 8 must be coordinated so that the difference between the initial phases of the supply voltages is 60. This sufficiently ensures an intensive heat and mass transfer between the channels I; MRL, and, consequently, the rate of heating of the metal in the installation. The resulting vector of pulsating power of a three-phase network in this case is determined by the sum of the vectors of pulsating powers of inductors 7 and 8 N2.N7 + Ns U7i7 + Uflia N5; e:, (О The value of the capacitor 4 () and its initial phase can be be calculated using expressions (1) and (2). it and the required value of the transformation ratio of the autotransformer 2 in accordance with the topographic diagram of FIG. 2 is determined by the expression 2 2 UBC / U6C (Iff where the transformation ratio means the linear stress ratio inlet av of the transformer to the voltage between the tap to which the circuit element is connected and the linear output of the autotransformer corresponding to the beginning of the linear voltage vector to which this autotransformer is connected.When the MDU operates in the mode of casting metal in accordance with the requirements of the technological mode, electromagnets 9 and 10 are keys 14 and 15 are connected to the corresponding outputs (including linear ones) of autotransformers 1 and 2. In this case, the resulting 11662 pulsating power vector is equal to the sum of the pulsating vectors power inductors 7 and 8 and electromagnets 9 and 10 N2.N, + Nj + N5 + N o% e This vector can be compensated by using a capacitor 4. The initial phase of the voltage –– capacitor 4 is determined by the expression (2), and transformation of the autotransformer 2 - expression (3). Depending on the ratio of the powers of the inductors 7 and 8 and electromagnets 9 and 10, the N vector varies in size and phase, which may lead to the need to switch the output of the capacitor from the linear output of autotransformers 1 and 3 to the corresponding intermediate taps of the autotransformer 1. At Thereby the magnitude and phase of the voltage on the electromagnets and the capacitor is determined by the expressions / u ,,,,) 44; x- i: -, j., Vj., g, o (rcigv it) where K, UcVUcA; K2 U8c / UBc; id - linear network voltage. The necessary K2 value for known values of K-, and ((-i -) (4Ve-) Eliminate the need for switching capacitors 4, reduce its power and increase the power factor at the input of the NDU power supply unit with the help of adjustable capacitors 5 and 6 The power of these capacitors is chosen from the condition of compensation of the pulsating powers of inductors 7 and 8, electromagnets 9 and 10 and is determined by the relations N, + N3. + N4 Ni5 :; ,,.; NI If it becomes necessary to wash down the metal with only one casting mold, in MDU of FIG. 1, it is more profitable to do this with Using the electromagnet 10, Tajc reduces the installed capacity of capacitors in this case. The use of the proposed invention for power supply provides, compared to known devices that do not provide for balancing network currents and optimize the conditions for the process of heating and pouring molten metals into molds, the following advantages: allows to simplify the power supply circuit of an MRL with two inductors and electromagnets, reduce the number of autotransformers and installed capacity of power capacitors, increase its reliability; the presence of three autotransformers in the scheme of the power supply unit SCHU expands the functionality of the circuit in comparison with the known device; Combining in the device the functions of balancing the currents of the three-phase network and regulating the magnitude and phase of the voltages on the electromagnetic systems of the installation and on the adjustable capacitors increases the ratio of using the electrical equipment of the circuit.

f-l

FIG 2

Claims (2)

1. POWER SYSTEM OF A MAGNETO-DYNAMIC INSTALLATION having two inductors and at least one electromagnet containing a first autotransformer connected to one line voltage of a three-phase network, a second autotransformer connected to another line voltage of this network, ahead of the first phase, and an adjustable capacitor for balancing network currents, while both autotransformers are made with leads for receiving partial or full voltage on inductors, electromagnets and capacitors; the current generated in the winding of the corresponding autotransformer, moreover, one inductor is connected to the first autotransformer, one output of the adjustable capacitor is connected to one of the terminals of the winding of the second autotransformer, and the conclusions of the electromagnets are connected via keys to the terminals of the windings of both autotransformers, characterized in that, for the purpose increasing the productivity of the magnetodynamic installation, decreasing the installed capacity and increasing the reliability of the power system, a third autotransformer was introduced in C //. <system, connected to the third linear * mains voltage, made with leads to obtain, on the second inductor connected to it, the partial or full voltage generated in the winding of this autotransformer. 2. The power system according to claim 1, characterized in that parallel to the first inductor and parallel to one of the electromagnets are connected additionally introduced compensating adjustable capacitors. 0¾ KZ ς ©