DE654087C - Cooling device for electrical machines with winding parts lying on top of one another in grooves - Google Patents

Description

In order to dissipate the heat from winding parts of electrical machines that are located in slots, it is known to arrange cooling channels along both flanks. In doing so, the conductors can face the axial air flow The side must be blank to increase heat dissipation. If it is a single ladder placed upright in the groove the air flowing along its broad sides finds an extensive contact surface. It has also been proposed to support individual conductors in places against the walls of the slot by means of insulation shims and around these supports a zigzag on each broad side of the ladder to create along leading path for the cooling air, so that even then an effective Ventilation was possible. But the situation is different if the head of the slot winding lie flat on top of each other. Then comes the cooling air flowing along the flanks of the layered conductor bundle only with the narrow sides of the conductor in contact, and the heat dissipation from the inside the winding cross-section becomes more unfavorable, the thinner the individual conductors are because the broadsides of the conductors have poor heat conductivity Intermediate insulation does not have good thermal contact with each other and with those surrounding them Metal bodies. It has therefore been suggested that the lateral cooling surfaces should be in such To enlarge cases and to provide the narrow sides of the conductors with cooling fins or Insert ribbed sheets between the insulated flat conductors, which in the axial lateral Air ducts protrude. So that will. the heat dissipation from the inside of the coil cross-section is still not sufficient increased, and with a greater number and strength of such ribs a considerable one becomes Blocked part of the cross-section of the axial cooling channels, which can only be measured closely. The narrow sides of the conductors to form cooling channels with recesses running lengthwise in the conductor material to provide or to make the ladder hollow was also known, but let it be Such measures cannot be carried out with relatively thin flat conductors.

Another suggested way, the inside of the coil cross-section from the axial Detecting air flow forms the division of the cross section into two or more One on top of the other or next to one another groups of conductors, which are supported by additional axial Ventilation ducts are separated from each other. This causes the manufacture, stiffening

*) Your patent seeker has specified as the inventor:

Willibald Rohde in Berlin-Schmargendorf.

and: Significant support of the coils in the groove difficult and also a large part of the usable groove cross-section through the ventilation ducts to achieve the ·. Purpose used.

If you have a good derivation of the heat wj wants to reach from inside the coil cross-section, the cooling air must reach the cross-section penetrate at several altitudes

ίο and you a great one, if possible from isolation Free contact surface with the individual flat conductors can be offered. In particular with long machines, e.g. B. in 'runners of Turbo generators with distributed, in grooves Ia-

15 'straight field winding, it is also desirable distribute the cooling air as required to the individual points of the coil length as required to obtain even cooling, i.e. where there is greater heat dissipation, For example, due to preheating of the cooling air, it is necessary to remove the contact surface of the air with the conductor material or to enlarge the passage cross-section there.

According to the invention, in the case of winding parts lying flat on one another in grooves, on the two flanks of which there are axial air channels, both of which are extensive Ventilation of the winding cross-section achieved in which the cooling air with the broad sides the head comes into contact, as well as the possibility offered within wide limits the To dissect airways within the winding arbitrarily and by their corresponding Distribution, cross-section design and sequence in the longitudinal and vertical directions to create an orderly ventilation compensation of the winding. This is there- _ achieved by that the cooling air from the axial channel on one flank or from a longitudinal section of this channel entirely or at least in part by a number distributed over the length of the axial channel, the Winding transversely to its longitudinal axis

■ 45 setting channels after the axial channel is passed over on the other flank. One can For example, divide the groove length into two halves, each of which according to this Principle is ventilated and one from the left, the other from the right face receives the cooling air supplied. The size, number and location of the cross channels there is a wide margin so that they can be used according to requirements can choose.

Further developments of the invention consist in devices according to which the Cooling air is forced from the axial channel through one flank after the other to overflow the Ouerwege in the winding. For example, the axial channel one side as an inflow channel over its entire length, the other as an outflow channel be used. For this purpose, the former is on the air “inlet side facing end open and -, against the radial louvers of the effective ■ covered with iron, while the second on the the end facing the air inlet side closed, but against the radial outlet air slots in the effective iron is open. Should all the air pass through the transverse ducts the winding, it is advisable to use the axial inlet channel or its longitudinal section at the end facing away from the air inlet side as well to close.

In the drawing, the 'Fig. Ί, 2 and 6 illustrate the principle of the invention, while Figs. 3, 4 and 5 expedient embodiments for the practical training of the cross channels.

For the application of the invention, the field winding k of the rotor of a turbo generator with teeth b inserted into the rotor core α is selected in FIG. Teeth and winding are braced in the usual way by retaining wedges c . Axial cooling channels /! and / ₂ . Distributed over the length of the groove, a larger number of outer channels h is arranged in the winding. From the air flow diagram of Fig. 2 it can be seen that the one axial channel j \ is open at the end facing the face of the rotor, but closed by partition walls g against the radial slots d of the effective iron and at the other end at r . The other axial channel f ₂ is blocked at the end facing the air inlet side at p , but is open to the radial slots d distributed over its length. The first channel Z ₁ thus serves exclusively as an inlet channel, the other, f ₂ , as an outlet channel. All of the air flowing into the channel f _x is thus forced through the number of outer channels h distributed over the height and length of the winding to flow over to the axial channel / _{2 of} the other flank, from where it is distributed to the individual radial slots. n ₀ The total length of the groove is divided into two equally ventilated sections. The number * of Ouerkannels h, the density of their succession and their width can be adapted as desired to the desired cooling conditions via these distances.

The transverse channels h at different heights of the winding cross-section can lie directly one above the other or be axially displaced from one another. They are preferably oblique to the longitudinal axis of the groove and at an acute angle to the

Direction of the air flowing towards them in the axial channels. The insertion of the Ouerkanal in the winding allows manifold embodiments. If the leader has sufficient strength, so. the transverse channels h, as illustrated in Fig. 3, can be incorporated as cross grooves in the conductor material itself. The recesses of two directly superimposed conductors are combined here to form a common Ouerkanal. It is known per se, opposite to the formation of axial air channels. to supplement lying recesses of two adjacent conductors to form a common cooling channel. The boundary surfaces of the outer channels are advantageously to be left free of insulation so that the air brushes the bare conductor metal. Such coils can be baked under pressure, without the intermediate insulating m is endangered by sharp edges themselves.

If the strength of the ladder is not sufficient to incorporate cross grooves, it is advisable to carry out the cross channels as shown in Fig. Ι and 4. Here the conductors or entire groups of conductors are bent into another layer in places and the junctions y of conductors or groups of conductors lying directly on top of one another are axially displaced with respect to one another, so that a cavity remains between them. If a special stiffening of the structure is necessary, it can be achieved by inserting hollow bodies η (Fig. 4), which are made of a highly conductive material, e.g. B. made of aluminum and optionally have an external insulation, such as an oxide skin.

Fig. 5 illustrates another possible embodiment for the formation of cross channels, which can be used in all cases. “According to this, strips are looped around individual conductors ί or around individual groups of conductors in a spiral shape, with a determining the width of the obliquely directed cross channels h between the turns of the spiral t The distance is maintained, while the wall thickness of the spiral is decisive for the height of these outer channels. The tape can be multilayered to increase flexibility, made of metal and used to conduct electricity.

While the air flow scheme according to Fig. 2 has the feature that the axial channels of both flanks or the longitudinal sections of these two channels are tangentially flowed through by the air, the parallel connection principle for two axial airways can also be carried out according to the invention. This happens according to the system shown in Fig. 6. Each of the axial channels of both flanks is open at the end facing the air inlet side and divided into a number of longitudinal sections fi, f " ... or f ₂ ', / 2" ... separated from one another by walls. The sections of one flank are cross-connected to those of the other by a number of Ouerkanäle in the winding, the crossing groups h ' and h "of the Ouerkanal are arranged at different heights of the winding cross-section.

In some cases it can be useful to only allow the air to flow in The axial channel used should be made wider than the one used for the outflow Axial channel of the other flank. The invention can also be used with equal success Use stator windings.

Claims (10)

Patent claims: 1. Cooling device for electrical machines with winding parts lying one on top of the other in grooves,. Axial air ducts run along both flanks, characterized in that the cooling air from the axial duct (Z ₁ ) on one flank or from a longitudinal section of this duct is wholly or partially distributed over the length of the axial duct by a number of the winding (k) transversely to its longitudinal axis penetrating channels (h) is transferred to the axial channel (/ ₃ ) on the other flank. 2. Cooling device according to claim 1, characterized in that the axial channel (Z ₁ ) running along one flank or a longitudinal section of this channel at the end facing the air inlet side is open and preferably against the radial air slots (d) of the effective iron, possibly also at the other end (at r), is blocked so that it serves the entry of the cooling air, while the axial channel (Z ₂ ) along the other flank at the end facing the air inlet side (at p) is closed, but against the radial, over its length distributed outlet air slots (d) in the effective iron is open (Fig. 2). 3. Cooling device according to claim r, characterized in that the axial channels (/ 1 and / V) open at the ends facing the air inlet side and in a number of separate longitudinal sections (Z ₁ ', Z ₁ ", Zi'" ... or . fi, fi ', f% "· ..) are subdivided, and that these sections of one flank are arranged crosswise by two at different heights of the winding cross-section. nete groups of outer channels Qi and h ") of the winding (t) are connected to the longitudinal sections of the other flank, so that two parallel airways are formed in the course of the winding (Fig. 6). 4. Cooling device according to claims ι to 3, characterized in that the winding in the groove or its conductor penetrating Qüerkanäle Qi) extend at an acute angle to the direction of them in the axial channels (/) flowing cooling air. 5. Cooling device according to claims 1 to 4 for electrical machines, in which the conductors of the winding have recesses to form cooling channels and, if necessary, these recesses of two adjacent conductors complement each other to form a common channel, characterized in that with a stronger conductor profile of the winding Transverse channels Qi) are formed in the groove by recesses in the conductor material that are transversely guided over the conductors, the boundary surfaces of which can remain blank in a manner known per se, whereby the transverse recesses of two conductors lying one above the other are preferably combined to form a common transverse channel ( Fig. 3). 6. Cooling device according to claims ι to 4, characterized in that with a thinner conductor profile, the conductor or conductor groups are bent in places in another layer and the junctions (y) directly superimposed conductors or conductor groups are axially displaced against each other, so that in between a transverse to the longitudinal axis the conductor running cavity Qi) remains, which to stiffen the structure, if necessary with a hollow body («), preferably made of a highly conductive material, e.g. B. made of aluminum, can be filled (Fig. 1 and 4). 7. Cooling device, in particular according to claims 1 to 4, characterized in that individual conductors (s) or groups of conductors of the grooves winding of band-shaped strips (t) are wrapped in a spiral with a spacing between the turns of the spiral ¹ , so that between the turns of the Spiral passages Qi) for the cooling air that cross the entire cross-section of the conductor bundle at an angle, the height of which is determined by the wall thickness of the band-shaped strips Qs) (Fig. 5). 8. Cooling device according to claim 7, characterized in that the spiral (f) consists of an optionally multilayered metal strip which can also be used for the current conduction. 9. Cooling device according to claims ι to 8, characterized in that the Qüerkanäle Qi) are axially offset from one another at different heights of the winding cross-section. 10. Cooling device according to claims ι to 9, characterized in that the cross section of the transverse channels (Ji) or their number is different over the length of the groove. 1 sheet of drawings