RU199115U1 - FAIL-SAFE FIVE-PHASE ASYNCHRONOUS MOTOR WITH COMBINATION WINDING - Google Patents

Abstract

The utility model relates to the field of electrical engineering and can be used in the production of fault-tolerant induction motors with improved output characteristics. The declared asynchronous motor containing the housing of the asynchronous motor, the stator magnetic core, made of laminated electrical steel, in the grooves of which there is a five-phase single-layer winding with active conductors in the stator slots, the number of which is a multiple of five, a template winding is located with the possibility of forming ten phases, which are a combination of two winding circuits, one of them is connected in a pentagon in series with a step m, and the second is connected to a star with the possibility of forming the resulting vectors of magnetic fluxes, having 72 electrical degrees between each other, provides an increase in the energy efficiency of a fault-tolerant five-phase induction motor. 2 ill.

Description

The utility model relates to the field of electrical engineering and can be used in the production of fault-tolerant induction motors with improved output characteristics.

Known asynchronous electric machine [patent RU No. 2556075 C1, H2K 3/12, publ. 07/10/2014], which contains a device for creating a magnetic field and a device for converting one type of energy into another form. In this case, a winding in the form of a multicore cable, consisting of two or more insulated, not electrically connected, conductors is placed in the existing grooves of the magnetic circuit of the device to create a magnetic field.

The disadvantage of the analogue is the energy efficiency of an asynchronous machine and a smaller moment, which consists in using a stranded wire in the grooves of the magnetic circuit, with standard connection schemes.

Known winding of an electrical machine [patent RU No. 2275729 C1, N02K 3/04, publ. 04/27/2006], including rods located in the upper part of the core grooves closer to the toothed surface of the core, forming the upper layer of the winding, and the rods located in the lower parts of the core grooves closer to the yoke of the core, forming the lower layer of the winding, conductors of the frontal parts located along the ends of the core, including electrically insulated conductors between the rods of the winding coils and electrically insulated conductors for connecting the coil groups, as well as electrically insulated conductors of the winding phase terminals, in which at least most of the conductors of the frontal parts are made in the form of jumpers, the cross-sectional areas of which at the points of their connection with rods less than the cross-sectional area averaged over the length of the groove of the connecting rods of the winding, and the joints of the coil jumpers with the rods of the upper layer of the winding are located on the side of the toothed surface of the core, and the joints of these jumpers with the rods of the lower layer of the winding are located on the side of the yoke of the core, while the conductors of the winding phase leads also have a cross-sectional area at the points of their connection with the rods less than the cross-sectional area of the rods averaged over the groove length with which they are connected.

The disadvantage of the analogue is the low energy efficiency of the asynchronous machine due to the bridges located in the frontal parts, which create scattering fields near the end and slot planes of the stator.

Known asynchronous machine [patent RU 2240641 C2, N02K 17/14 publ. 20.11.2004], which contains a squirrel-cage annular rotor and an annular stator, consisting of sectors with a different number of direct and opposite turns of the winding. The required number and ratio of the number of direct and opposite turns of the winding is achieved by the number and the corresponding inclusion of sectors. Alternatively, the turns of the stator winding are cast and a mechanism for adjusting the gap between the squirrel cage annular rotor and the stator sectors is used.

The disadvantage of the analogue is low energy efficiency, caused by the fact that cast turns of the stator sector winding are used as a winding.

The closest in technical essence and the achieved result to the claimed utility model is an asynchronous energy efficient machine [RU patent No. 2558672 C2 H2K 3/42 publ. 08/10/2015], including a rotor and a stator with a core, in the grooves of which there are active conductors of a two-layer wave winding with frontal conductors, the cross-sectional area of at least most of which at the points of their connection with the active conductors of the said winding is less than the cross-sectional area averaged over the length of the groove of the connected active conductors, made in the form of flat rings of frontal bridges, is equipped with two additional flat rings with electrically conductive ring-shaped sections along the width of the ring of frontal bridges, fixed coaxially to the rotor in the end parts with a small air gap near the rings of the frontal bridges.

The disadvantage of this machine is the low energy efficiency caused by the use of a double-layer wave winding in the grooves of the stator core, which leads to a decrease in starting characteristics and creates less torque.

The task of the utility model is to improve the starting characteristics of an induction motor and expand the functionality of a fault-tolerant five-phase induction motor with a combined stator winding.

The technical result is to increase the energy efficiency of a fault-tolerant five-phase asynchronous motor.

The problem is solved and the technical result is achieved by the fact that an asynchronous motor, including a rotor and a stator with a core, in the grooves of which there are active conductors of a two-layer wave winding with frontal conductors, the cross-sectional area of at least most of which at the points of their connection with the active conductors of the said winding less than the cross-sectional area averaged over the length of the groove of the active conductors to be connected, made in the form of flat rings of frontal bridges, equipped with two additional flat rings with electrically conductive ring-shaped sections along the width of the ring of frontal bridges, fixed coaxially to the rotor in the end parts with a small air gap near the frontal rings jumpers, according to the utility model, that in the stator slots, the number of which is a multiple of five, there is a template winding with the possibility of forming ten phases, which are a combination of two winding circuits, one of them is connected in a pentagon sequentially with a step m, and the second is connected to a star with the possibility of forming the resulting vectors of magnetic fluxes, having 72 electrical degrees between them.

Template winding refers to the winding of electrical machines, made of coils (sections) of the same size and shape, made on a template and then laid in the grooves.

The essence of the utility model is illustrated by drawings. The figure 1 shows a sketch layout in cross-section of a fault-tolerant five-phase asynchronous squirrel-cage motor. Figure 2 shows a winding diagram of a fail-safe induction motor.

A fault-tolerant five-phase asynchronous motor with a combined winding contains: an asynchronous motor housing 1, a stator magnetic core 2, made of laminated electrical steel, in the grooves of which there is a five-phase single-layer winding 3 with active conductors in the slots of the stator core, consisting of two types of windings connected in series with equal pitch , which is a regular pentagon 4, and the other is connected to a star 5. All coils are connected according to the diagram in figure 1 and have terminals A-B-C-E-D, in addition, a rotor 6 with a core and a short-circuited cast winding 7 is shown, which is fixed on the shaft 8.

The proposed failsafe five-phase induction motor with a combined winding operates as follows.

The input ends of the stator winding are connected to a five-phase AC voltage source. When voltage is applied to a winding consisting of two types of windings, one of which is connected to a pentagon 4, and the other to a star 5. In each phase, a magnetic flux is created, which changes with the frequency of the applied voltage. Their magnetic fluxes are shifted relative to each other by 72 °, both in time and in space.

The resulting magnetic flux of the stator 2 rotates, and thereby creates an EMF in the short-circuited rotor 6. Since the rotor winding has a closed electric circuit, a current arises in it, which in turn, interacting with the stator magnetic flux, creates a starting torque of the motor, which tends to turn the rotor in the direction of rotation of the stator magnetic field. When it reaches the value of the braking torque of the rotor, and then exceeding it, the rotor with shaft 8 begins to rotate.

Thus, the proposed design makes it possible to increase the starting characteristics of an asynchronous motor and expand the functionality of a fail-safe five-phase asynchronous motor with a combined stator winding, increase energy efficiency, and also simplify the design of the asynchronous motor and its manufacturing technology.

Claims (1)

An asynchronous motor, including a rotor and a stator with a core, in the grooves of which there are active conductors of a two-layer wave winding with frontal conductors, the cross-sectional area of at least most of which at the points of their connection with the active conductors of the said winding is less than the cross-sectional area averaged over the length of the slot of the connected active conductors, made in the form of flat rings of frontal jumpers, is equipped with two additional flat rings with electrically conductive ring-shaped sections along the width of the ring of frontal jumpers, fixed coaxially on the rotor in the end parts with a small air gap near the rings of the frontal jumpers, characterized in that in the grooves of the stator, the number of which is a multiple of five, a template winding is located with the possibility of forming ten phases, which are a combination of two winding circuits, one of them is connected in a pentagon in series with a pitch of t, and the second is connected to a star with the possibility of forming in this case, the resulting vectors of magnetic fluxes having 72 electrical degrees between them.

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