DE102008025702A1 - Asynchronous machine, has short circuit element for electrically hot-wiring bar-shaped elements of rotor winding, where winding is made of material comprising carbon nano tubes or material comprising composite of nano tubes and copper - Google Patents

Abstract

The machine has a rotor (14) rotationally and movably supported at a stator, where the rotor has a winding (22) with a set of bar-shaped elements (23). A short circuit element (24) i.e. short circuit ring, electrically hot-wires the set of bar-shaped elements with each other at end areas of the rotor. The winding is made of a material comprising carbon nano tubes or a material comprising a composite of nano tubes and copper. The stator has a winding made of the material comprising the nano tubes. An independent claim is also included for a method for manufacturing a rotor of an asynchronous machine.

Description

The The present invention relates to an asynchronous machine having a Stator and a rotatably mounted on the stator rotor, which a rotor winding (also cage winding called) comprising a plurality of rod-shaped elements each having two end portions, wherein the rod-shaped Elements at the end regions by means of one short-circuit element each (eg a short circuit ring) are electrically shorted together are. The present invention also relates to a method of manufacturing a rotor for an asynchronous machine.

present The interest is directed in particular to a fast-moving Asynchronous machine of the type mentioned above with a so-called Cage induction motors.

The construction of high-speed asynchronous machines of higher performance finds its limits through the mechanical strength of the rotor winding, especially the cage winding. As the diameter of the rotor increases, the cage winding, which is usually made of copper, in particular the short-circuit rings, is subject to increasing stresses due to centrifugal forces. In order to take this problem into account, so-called polar caps are pulled over the short-circuit rings for mechanical fixation of the cage winding. A known from the prior art cage winding is in a schematic sectional view in 1 played. The squirrel cage comprises a laminated core 1 into which a copper rod 2 installed or embedded. The in 1 illustrated copper rod 2 is with other copper rods (not shown) of the cage winding by means of a short-circuit ring 3 shorted. At high speeds of the asynchronous machine is subject to the short-circuit ring 3 , And in particular a connec tion point between the copper rod 2 and the shorting ring 3 , high mechanical stresses. The copper rod 2 and also made of copper short-circuit ring 3 namely have a low mechanical strength. To the on the copper rod 2 and the shorting ring 3 To reduce forces acting at high speeds of the asynchronous machine, is via the Kurschlussring 3 a polar cap 4 drawn. The polar cap 4 is formed in the form of a high-strength, non-magnetic steel ring, which radially to the short-circuit ring 3 is shrunk. For this purpose, a complex, high-precision manufacturing process is required. In addition, there are the polar caps 4 a disadvantage in that due to the different thermal expansion coefficients of copper and steel, the risk of loosening the polar caps 4 with frequent thermal load changes.

Of the The present invention is based on the object, an asynchronous machine and a method of manufacturing a rotor for to propose an asynchronous machine in which and which measures are taken, which increased mechanical strength the rotor winding at higher speeds of Ensure asynchronous machine.

These The object is achieved by an asynchronous machine with the features of claim 1 and by a method for producing a rotor for an asynchronous machine solved with the features according to claim 8.

Of the Basic idea in the asynchronous machine according to the invention is thus that the rotor winding (in particular the rod-shaped elements as well as each one short-circuit element) at least partially (eg, in certain areas) from a nanotube comprehensive material, that is, has a nanostructure.

Under The term nanotubes is known to mean tubes, whose diameter is less than 100 nanometers. A nanotube Comprehensive material indicates increased density a relatively high mechanical Strength up, so that acting at high speeds and with increasing Diameter of the rotor increasing centrifugal forces is maintained, so that the use of polar caps with the This disadvantage is unnecessary.

It has proven to be particularly advantageous if the nanotubes comprise carbon nanotubes or if the rotor winding consists at least partially of a material comprising carbon nanotubes. The term carbon nanotubes (CNT, Carbon Nano Tubes) refers to tubular structures formed of carbon. By using the material comprising carbon nanotubes, a rotor winding is created, which has a significantly higher conductivity compared to a copper winding. Furthermore, a material comprising carbon nanotubes is characterized by a density of 1.3 to 1.4 g / cm ³ and a tensile strength of 45 GPa, resulting in a significantly improved ratio of the tensile strength to the density than, for example, in the case of steel. Moreover, the current carrying capacity and the thermal conductivity is significantly higher than in copper, so that the rotor winding can be designed with lower cross sections and thus a more compact asynchronous machine can be created.

In one embodiment, it is provided that the material consists entirely of nanotubes, before preferably made of carbon nanotubes is formed. If the entire rotor winding, that is to say both the rod-shaped elements and the one short-circuit element in each case, are formed entirely from nanotubes, preferably carbon nanotubes, the advantages of such a material are fully realized.

at an alternative embodiment, the material is made formed a composite of nanotubes and copper. Here through can a cost-reduced asynchronous machine with yet one increased conductivity and mechanical strength exhibiting rotor winding to be created.

Preferably it is provided that at least one short-circuit element is designed as a short-circuit ring is. Alternatively, each one short-circuit element or at least be formed a short-circuit element in the form of a polygon.

Prefers the stator comprises a stator winding, which at least partially from a nanotube, and preferably carbon nanotubes Material exists. In a further embodiment provided that the stator winding at least three coil strands includes and is designed for operation with three-phase current. Because the Current carrying capacity of a nanotube, and specifically Carbon nanotubes, comprehensive material significantly higher is that of copper, is formed by the formation of the stator winding made of such a material that the stator winding be carried out with much lower cross-sections can. This allows a compact design of the asynchronous machine be achieved.

One inventive method is used for manufacturing a runner for an asynchronous machine Providing a rotor core and placing a Rotor winding in and / or on the rotor core, wherein for forming the rotor winding, a plurality of used rod-shaped elements, each with two end portions and the rod-shaped members at the end portions by means, respectively a shorting element electrically shorted together become. An essential idea in the invention Method is that the rotor winding at least partly from a nanotube, preferably carbon nanotubes, comprehensive material is formed.

Further Advantages, features and details of the invention will become apparent the following description of a Favor th embodiment as well as from the drawings. Showing:

1 in a schematic sectional view of a rotor of an asynchronous machine according to the prior art;

2 a schematic representation of a longitudinal section through an asynchronous machine according to an embodiment of the invention; and

3 in a schematic sectional view of a rotor of the asynchronous machine according to 2 ,

The Below detailed embodiment represents a preferred embodiment of the present invention Invention.

An in 2 illustrated asynchronous machine 10 has a stator 11 on which a stator lamination stack 12 and a stator laminated core 12 surrounding stator housing 13 includes. The asynchronous machine 10 also has a runner 14 including a rotor core 15 and a rotor shaft 16 on. Here is the rotor shaft 16 and thus the entire runner 14 each with a ball bearing 17 . 18 on two opposite sides 19 . 20 of the stator housing 13 mounted rotatably movable. Thus, the runner 14 relative to the stator 11 one by an orientation of the rotor shaft 16 defined axis of rotation A rotatable.

The stator core 12 is a stator winding 21 assigned, which has three coil strands in the present example and is thus designed to operate with three-phase current. Furthermore, the runner includes 14 a rotor winding 22 , which is designed in the form of a cage winding.

In 3 is the runner 14 the asynchronous machine 10 according to 2 shown in a schematic sectional view. The rotor winding 22 comprises a plurality of conductive rod-shaped elements 23 (in 3 is just a rod-shaped ele ment 23 shown). The rod-shaped elements 23 are in the rotor sheet package 15 embedded or incorporated. Further, the rod-shaped elements 23 at their ends by means of a respective shorting element 24 , in this case a short-circuit ring, electrically shorted together. Thus represent the rod-shaped elements 23 together with one short-circuit ring each 24 a cage winding of the runner 14 represents.

To a high mechanical strength and electrical conductivity or current carrying capacity of the rotor winding 22 to achieve are the rod-shaped elements 23 as well as each a short-circuit ring 24 formed in the present example of a material comprising carbon nanotubes. Because the carbon nanotubes have much higher mechanical strength than copper, they can be applied to the rod-shaped elements 23 and each a short-circuit ring 24 at high speeds of the rotor 14 withstanding centrifugal forces. Thus, the use of polar caps is unnecessary 4 , which in the prior art (see 1 ) are used to reduce the amount of mechanical stress on the cage winding. Another advantage of the trained from the carbon nanotubes rotor winding 22 is that this can be carried out because of the increased current carrying capacity of the carbon nanotubes with much lower cross-sections.

In the present example, the rod-shaped elements 23 as well as each a short-circuit ring 24 by an electrical conductor according to the document EP 1 275 118 B1 educated. Accordingly, the nanostructure include rod-shaped elements 23 as well as each a short-circuit ring 24 a conductive matrix in which the carbon nanotubes are arranged. In this case, the matrix contains nanostructures in less than 98% by volume. It is also possible to use the rod-shaped elements 23 as well as each a short-circuit ring 24 in a manner deviating from the manner shown here form.

QUOTES INCLUDE IN THE DESCRIPTION

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Cited patent literature

• - EP 1275118 B1 [0023]

Claims (8)

Asynchronous machine ( 10 ) with a stator ( 11 ) and one on the stator ( 11 ) rotatably movably mounted rotor ( 14 ), which has a rotor winding ( 22 ) comprising a plurality of rod-shaped elements ( 23 ), each having two end regions, the rod-shaped elements ( 23 ) at the end regions by means of a short-circuit element ( 24 ) are electrically short-circuited with each other, characterized in that the rotor winding ( 22 ) consists at least partially of a material comprising nanotubes. Asynchronous machine ( 10 ) according to claim 1, characterized in that the nanotubes comprise carbon nanotubes. Asynchronous machine ( 10 ) according to claim 1 or 2, characterized in that the material is formed entirely from nanotubes. Asynchronous machine ( 10 ) according to claim 1 or 2, characterized in that the material is formed of a composite of nanotubes and copper. Asynchronous machine ( 10 ) according to one of the preceding claims, characterized in that at least one short-circuit element ( 24 ) is designed as a short-circuit ring. Asynchronous machine ( 10 ) according to one of the preceding claims, characterized in that the stator ( 11 ) a stator winding ( 21 ), which consists at least partially of the nanotube material. Asynchronous machine ( 10 ) according to claim 6, characterized in that the stator winding ( 21 ) comprises at least three coil strands and is designed for operation with three-phase current. Method for producing a runner ( 14 ) for an asynchronous machine ( 10 ), comprising the steps of: providing a rotor core ( 15 ), - arranging a rotor winding ( 22 ) in and / or on the rotor laminations ( 15 ), wherein to form the rotor winding ( 22 ) a plurality of rod-shaped elements ( 23 ) are each used with two end regions and the rod-shaped elements ( 23 ) at the end regions by means of a short-circuit element ( 24 ) are electrically short-circuited to each other, characterized in that the rotor winding ( 22 ) is formed at least partially from a material comprising nanotubes.