RU2041515C1 - Electromagnetic device - Google Patents

Abstract

FIELD: electrical engineering. SUBSTANCE: electromagnetic device has its spatial magnetic system built up of magnetically isolated and joined together members 1,2 provided with yokes and rods carrying coils of primary and secondary windings. Each coil embraces two adjacent rods. EFFECT: improved design. 11 cl, 9 dwg

Description

 The invention relates to electrical engineering, namely to the section of single-phase and three-phase transformers.

 As is known [1], electromagnetic devices, in particular low power transformers, operate with a load close to the nominal, therefore it does not matter what losses prevail in steel or copper. In laboratory equipment, especially designed for traveling work (tests and adjustments), the main requirement is to reduce the volume and weight, i.e. weight and size parameters. Moreover, the decrease in volume is usually more significant, since in some cases this allows to reduce the size and weight of the entire device: the efficiency for these devices, as a rule, does not matter. It is also known that as a magnetic circuit in low-power transformers, plates of the U-shaped form from electrical steel of various grades are used. Coils with primary and secondary windings are mainly located on the middle core of the magnetic circuit. However, for economic reasons, the dimensions of the magnetic cores are limited to sizes 2525-3232: the bulkiness and high cost of the stamp make large sizes economically disadvantageous. In addition, in some properties, transformers on W-shaped magnetic cores are inferior to transformers with magnetic cores from U-shaped plates, for example, in the case when it is necessary to arrange the primary and secondary windings on both rods to reduce magnetic flux scattering.

 The closest in technical essence to the proposed device is the electromagnetic apparatus of A. M. Repin [2] in which the magnetic system is made in the form of a multi-core core with closed yokes of a polygonal or loop shape with a multiple of three or four or with an odd number of rods with polyhedral or round coils . Such a device has several disadvantages. The Repin apparatus [2] involves its use in a multiphase network. Multiphase systems (more than three) take place in special systems where economic and mass-dimensional indicators are pushed to the next plan. In addition, the use of transformers in multiphase systems automatically assumes the presence of both a source and a consumer of multiphase current. And the implementation of such systems requires special development, and most importantly, significant material costs. Thus, even if it is possible to somehow somehow reduce the overall dimensions of the transformers "with an odd (more than three) number of rods with polyhedral or round coils" [2] then the overall dimensions of the source and consumer of alternating current significantly overlap the effect achieved.

 It should also be noted that the use of three-phase current is economically feasible where the consumer power is more than three kVA. At lower consumer capacities, in order to reduce the overall dimensions of the transformer, inverter converters are used, which are currently widely used in radio and electronic equipment.

 In principle, it is possible to use the electromagnetic apparatus of A.M. Repin with an odd number of rods, i.e., in multiphase systems (more than three), using design features to create a compact transformer shape and improve overall dimensions. But this goal is more easily achieved by increasing the frequency of the supply current, and this situation is widely used in technology, in particular, in the production of welding equipment, in electrolysis, etc.

 In the prototype [2] the magnetic system is made in the form of a multi-core core with closed yokes. The device is extremely unreliable in operation. If insulation is broken in at least one of the split parts of the winding, the magnetic flux closes in a rod with a damaged winding due to the closed yoke, which leads to a sharp change in the EMF at the ends of the winding, its overheating and to a breakdown of insulation, short circuit and, as a result, burning of all windings . A device with a magnetic system made in the form of a multi-core core with closed yokes can be used in a limited area of electrical engineering. So, for example, there is no way to make a controlled transformer: use such a device as an adder, modulator, generator, etc.

 The invention is aimed at solving problems of improving the reliability and expanding the functionality of an electromagnetic device.

 The problem is solved in that the spatial magnetic system is made of separate magnetically insulated and composed of elements having yokes and rods with coils of primary and secondary windings, at least one winding covers two rods: primary and secondary windings are made in sections, forming coils, moreover, at least one of the sections of the secondary windings covers the section of the primary winding; having two yokes and a rod, the elements of the magnetic system with coils form a system in the form of a prism of 2n (where n 2,3,4.), elements sequentially connected by rods, each coil covering two adjacent rods having two yokes and rods with coils, the elements of the magnetic system form a system of n (where n 2,3,4.) elements, in which the (n + 1) -th coil covers the first rods, and each n-th coil covers the second rods. The device forms a magnetic system of n (where n 5,6,7.) Elements, with two elements having 2 (n-3) yokes and (n-2) rods with coils parallel to each other, and (n- 2) elements having two yokes and two rods each, with their ends of the rods docked to the rods between the other two elements, while 2 (n-2) coils span two docked rods; having three yokes and three rods of n (where n 3,4,5.) elements of the magnetic system with coils form a system of n elements, in which the first half of 2n coils covers two rods, and each of the second half of coils covers one rod. The magnetic core of the elements is made in the form of a quadrangular frame by winding from a ferromagnetic tape. The magnetic core of the elements is made in the form of a quadrangular frame by blending from ferromagnetic plates. The magnetic core of the elements is made in the form of a triangular frame by winding from a ferromagnetic tape. The magnetic core of the elements is made in the form of a triangular frame by blending from ferromagnetic plates. The magnetic circuits of the elements are tightened around the outer perimeter with nuts on the studs of the hard strips, on one end of which there is a hole, and on the other a stud, which enters the hole of the subsequent strap, and stops are installed along the inner perimeter.

 Thanks to this embodiment of the electromagnetic device, it becomes possible to increase reliability and expand the scope of the device. Consider two schemes for the construction of four-coil transformers. Suppose that under some operating conditions of the transformer in one of the coils 1 or 4 there is an interturn circuit. Then, in the case of Fig. 1a in coil 1 or 4, the inductive resistance decreases and the magnetic flux penetrating before the closure of coil 2 and 3 will pass mainly through coil 1 or 4 and, as a result of large magnetic fluxes in the coils, heating of the windings and insulation burnout.

 In the proposed device, the picture is different. In the same situation, the interturn circuit in coils 1 or 4, due to the fact that the magnetic circuits are magnetically insulated, the magnetic fluxes through the other coils will be limited by the inductive resistance of these coils. This eliminates the emergency.

 The proposed device allows its use in a wide variety of devices. Consider the work of some of them. In practice, certain difficulties arise when implementing the inclusion of a single-phase transformer of medium power (5-20 kVA) in a three-phase network (in this case one of the phases is overloaded), which is extremely undesirable. And if it is necessary to use a three-phase transformer in a single-phase network, certain difficulties arise (reduction in efficiency, the need to increase overall dimensions). In the proposed device with an n-multiple of six, this situation is quite simple: it is enough to connect the coils to a star in pairs, and the inputs to be connected to a three-phase network. If the coils are paired in parallel, then the inputs can be supplied with a voltage of a single-phase AC network. Such methods of incorporating the device both into a three-phase current network and into a single-phase current network are possible due to the presence of magnetic isolation between the elements of the system.

 It is well known that for smooth regulation of the voltage at the input of the transformer use magnetic amplifiers or autotransformers [3] including them in series in the primary circuit of the transformer. However, it should be noted that the power of these two devices are approximately equal. This means that the weight and size parameters of the entire device doubles, the number of working elements increases, and as a result, the reliability of the device decreases. In the proposed device, coils that span one rod can be used as elements of a magnetic amplifier. And after putting the transformer into operation, these coils are used as transformer elements. Thus, a part of the transformer is used as a magnetic amplifier, and when the transformer enters the operating mode, the same part supplements the transformer. The combination of a magnetic amplifier and a transformer in one device is possible in the presence of magnetic isolation between the elements of the system.

 The proposed device allows you to perform the so-called controlled transformer. The design of the magnetic circuit is such that the central coil, having a part of the primary and secondary windings, covers the rods of the "elementary" magnetic circuits, in which the magnetic flux does not overlap. On the second rods are coils with the remainder of the primary winding. They are interconnected in parallel, and all together with the second part of the primary winding, located on the central coil, in series. Thus, magnetic fluxes in each "elementary" magnetic circuit circulate independently, but are inductively combined by a secondary winding. The primary circuit is powered by control keys. Programmatically, you can change both the current value and its direction. Thus, it is possible, without changing the amplitude of the input voltage, to stepwise control the amplitude of the voltage in the secondary circuit. Keys are controlled at the moment the current passes through zero and, as a result, the shape of the output voltage is not distorted, there are no conditions for the appearance of higher-order harmonics.

 Now we dwell on the design features of the transformer magnetic circuits, in particular, pay attention to the node where the yoke and the rod are joined, and determine the essential features of the proposed devices. In known devices [1-3], the yoke is made inextricably and the rods and yokes are butt-welded. This design of the magnetic circuit does not allow with great accuracy to combine the ends of the yoke plates and rods. This is illustrated in FIG. 2, which shows the projections of the ends of the plates and the yoke at the joints: a straight section of the yoke and a rectangular rod: b case of an oval yoke and a round rod: in the case of an oval section of the yoke and a rectangular rod. And as a result of the mismatch of the ends of the plates of the rods and the yoke at the junction leads to a significant increase in the loss of electromagnetic energy and its transformation into thermal energy, which directly proportionally affects the overall dimensions of the transformer. In the proposed constructions of the magnetic core of the transformer, the yokes are continuous and the lamination of the plates is carried out overlap. This design of the magnetic circuit is technologically advanced and has low losses.

 In FIG. 3 shows the projection of the magnetic circuit of a four-coil transformer, where 1 yoke; 2 rod; 3 gasket of insulation; a top view; b, c, d side views during batching with plates of a certain type.

 In this design, the transformer magnetic circuit consists of four magnetic circuits, isolated from each other by spacers, i.e. the magnetic circuit of such a transformer consists of four "elementary" magnetic circuits, consisting of two yokes and two rods. The magnetic flux of each individual of the four magnetic cores penetrates two adjacent coils. Two magnetic fluxes circulate in each coil, thus, by means of electromagnetic induction in the coils, the magnetic fluxes are interconnected among all four “elementary” magnetic circuits. This ensures, firstly, the closure of magnetic fluxes and, secondly, the absence of counter magnetic fluxes anywhere in the cross section in each of the four "elementary" magnetic circuits.

 The design of the coupler of such a transformer is also simple. It is carried out from above and from below, four levels cover yokes along the outer perimeter. A stud is welded at the end of the strip, and there is a hole at the second end. Each pin enters the hole of the subsequent strip, the transformer coupler is made with nuts.

 Consider the design of the magnetic circuit of a six-coil transformer. The magnetic circuit of such transformers (figure 4) consists of six "elementary" magnetic circuits, similar in design to a four-coil transformer. The plates of the magnetic cores on the inner side are held by wedges driven into the gap between the magnetic circuit and the inner side of the coil or in any other way, the consideration of which is not essential.

 In FIG. 1 shows the device (and according to [2] b, the proposed one; in Fig. 2 projections of the ends of the plates and the yoke at the junction: a straight section of the yoke and a rectangular rod: b case of an oval yoke and a round rod: in the case of an oval section of the yoke and a rectangular rod; in Fig. 3 shows the projection of the magnetic circuit of a four-coil transformer: a top view; b, c, d side views when batching with plates of certain types; in Fig. 4 a, b, c, d of a projection (top view) of magnetic circuits of different layouts of a six-coil transformer; Fig. 5 a, b, c, d plate options and methods of laminating an six-coil transformer overhead; in Fig. 6 a, b, c, d, plate options and methods of laminating an eight-coil transformer; in Fig. 7, a transformer in the form of a tetrahedral pyramid; in Fig. 8, a transformer in the form of a hexagonal pyramid; in Fig. 9 a , b, possible types of transformers are schematically shown.

 Industrial application of the invention can be carried out by a device that contains coils 1, a magnetic system 2, formed from magnetically insulated elements in the form of spatial geometric shapes.

 The electromagnetic system operates as follows.

 The primary windings in the coils 1 (Fig. 2-9) are supplied with voltage, and the windings between the coils are connected so that there are no counter flows in the cross section of the magnetic circuits. Since magnetic fluxes are interconnected through coils through inductive coupling, and coils are interconnected through magnetic fluxes, the structural design of the magnetic circuit is single and indivisible. Magnetic fluxes penetrating the secondary windings cause EMF induction in them.

 The calculation of the main parameters of the transformer of all types is as follows.

/3,04, где S_o, см²; Р, Вт.For a given power P (industrial current frequency), the cross section S _{o of the} magnetic circuit (a set of plates of electrical steel) is calculated by the formula
S _o =

/ 3.04, where S _o , cm ² ; R, Tue

From the operating conditions of the transformer, its type and the number of coils n are selected. Then from the relation
W x S _o U 37.5, where W is the number of turns; U voltage across the winding in each coil, determined by the number of turns in the windings. From the conditions of current flow in the windings, according to well-known formulas, the cross section of the wire is calculated.

As an example of a specific implementation of the proposed transformer, we consider a four-coil transformer, the magnetic core of which forms the shape of a tetrahedral prism. Coils are located on the side ribs. The transformer was calculated for a welding machine with a power of P 3 kVA at U 220 V. The cross section of the magnetic circuit on the side rib was selected 18 cm ² . The window has a size of 50 x 100. The primary winding in each coil contains W 110 turns, the secondary W 120 with taps at 12 and 36 turns. The primary and secondary windings were wound with a copper wire in enamel insulation with a diameter of 2, 44. The primary windings were connected in series, and the secondary ones in parallel.

Claims (11)

 1. An electromagnetic device containing a spatial magnetic system with coils of primary and secondary windings, characterized in that the spatial magnetic system is made of separate magnetically insulated and composed of elements having yokes and rods with coils of primary and secondary windings, at least one winding covers at least two rods.  2. The device according to p. 1, characterized in that the primary and secondary windings are made in sections, forming coils, and at least one of the sections of the secondary windings covers a section of the primary winding.  3. The device according to paragraphs. 1 and 2, characterized in that the elements of the magnetic system have two yokes and rods with coils and form a system in the form of a prism of 2 n (where n = 2,3,4.) Elements, sequentially joined by rods, each coil covering two adjacent rods.  4. The device according to paragraphs. 1 and 2, characterized in that the elements of the magnetic system have two yokes and rods with coils and form a system of n (where n 2,3,4.) Elements, in which the (n + 1) th coil covers the first rods, and each nth coil spans the second rods.  5. The device according to paragraphs. 1 and 2, characterized in that it forms a magnetic system of n (where n 5,6,7.) Elements, and two elements having 2 (n-3) yokes and n-2 rods with coils are parallel between by itself, and n-2 elements, each with two yokes and two rods, with their ends of the rods are docked to the rods between the other two elements, while each of the 2 (n-2) coils encompasses two docked rods.  6. The device according to paragraphs. 1 and 2, characterized in that having three yokes and three rods n (where n 3,4,5.) The elements of the magnetic system with coils form a system of n elements, in which the first half of 2n coils covers two rods, and from the second half of the coils, each of them covers one rod.  7. The device according to paragraphs. 1-4, characterized in that the magnetic circuit of the elements is made in the form of a quadrangular frame by winding from a ferromagnetic tape.  8. The device according to paragraphs. 1-5, characterized in that the magnetic circuit of the elements is made by blending of ferromagnetic plates.  9. The device according to paragraphs. 1,2 and 6, characterized in that the magnetic circuit of the elements is made in the form of a triangular frame by winding from a ferromagnetic tape.  10. The device according to paragraphs. 1,2 and 6, characterized in that the magnetic circuit of the elements is made by blending of ferromagnetic plates.  11. The device according to paragraphs. 7 and 8, characterized in that the magnetic circuits of the elements are tightened around the outer perimeter by nuts on the studs of the hard strips, on one end of which there is a hole and on the other a stud that enters the hole of the subsequent strap, and stops are installed along the inner perimeter.

Images