DE1018527B - Eddy current brake - Google Patents

Description

Eddy current brake The invention relates to an eddy current brake, their rotating armature to be braked by two on the shaft of the device in a certain mutual distance from each other fastened disks from one ferromagnetic material is formed while the fixed inductor in the room is arranged between the two rotating discs of the armature and a certain amount Includes number of circularly arranged around the shaft electromagnets, the Axes run parallel to the shaft of the device and the pole streams at both ends have which are parallel to the side surfaces of the armature plates and at a low level Distance from them.

Eddy current brakes of this type are known per se. With the known Brakes, the electromagnets are made of cast iron or cast steel, and at their ends pole pieces are attached, the diameter of which is larger than the actual core and which limit the space in which the one used to generate the magnetic flux Coil is attached. - In contrast, according to the invention, the cores of each electromagnet including the pole faces from a single, drawn or rolled, cylindrical A piece of iron is formed, and these cores are made up of two perpendicular to the shaft Discs or plates made of non-magnetizable material and held against axial Shift secured, the plates from the core ends forming the pole faces be enforced.

The formation of each electromagnet core including its pole faces from a single, drawn or rolled piece of iron has the following advantages: On the one hand a drawn or rolled piece of iron has a magnetic flux favorable Texture and excellent permeability, and on the other hand is manufacturing these cores, which do not require any special pole pieces, are extremely cheap, as they are made simply by cutting up rolled or drawn bar stock can be. The formation of the retaining washers penetrated by the core ends a non-magnetizable material prevents these discs from the magnetic Short-circuit the river before it enters the surrounding anchor on both sides of the Inductors arranged disks passes, in which the generating the braking effect Eddy currents are caused.

Furthermore, the structure of the eddy current brake is characterized by the fact that special, Pole shoes attached to the magnetic cores and their fastening means are no longer applicable and that the retaining washers themselves are used at the same time to fix the magnetic coil axially serve, much simplified, and it is also the weakening of the magnetic flux avoided previously by the connection joints between the cores and the associated Pole pieces was caused. Finally, in the construction of the device according to Invention, the cooling conditions, which are particularly important in an eddy current brake have extremely good ones.

It should also be noted that electromagnetic clutches it is known to arrange pole pieces of the inductor on both sides of the rotating rotor, which in turn are connected to each other by iron bolts on which the winding for magnetic excitation is appropriate. However, this is a fundamentally different design than the one used for the subject of the invention, and the working conditions for clutches are also significantly different from those of Eddy current brakes.

It should also be noted that when identifying the subject matter of the invention The used expression "cylindrical" has a general meaning. The cylindrical The surface of the core pieces can be described by any generating line, which moves parallel to a given direction along a closed guideline will.

The invention is shown in the drawing on the basis of several exemplary embodiments explained in more detail. Fig. 1 is an axial section through the upper half an eddy current brake designed according to the invention; Fig. 2 is a front view a core of the electromagnet; Fig. 3 is a partial view showing a modification the device of Figure 1 shows; Fig. 4 shows another embodiment of a eddy current brake according to the invention; Fig.5 is a partial view showing the change shows a detail of the device according to Figure 4. The device of FIGS. 1 to 4 contains an armature, which by two discs 1 and 2 made of a magnetizable material is formed, which is coaxial with the shaft 7 and firmly connected to it and are arranged on either side of a fixed inductor system 18-34.

The disks 1 and 2 are on the shaft by radial arms 3 and 4 7 keyed hubs 5 and 6 connected. The radial arms 3 and 4 are shaped so that they form fan blades. The shaft to be braked is firmly connected to shaft 7.

The inductor system contains a certain number of electromagnets, whose cores, which consist of a magnetizable material, are generally cylindrical Have a shape with their generatrixes being parallel to the axis of the shaft 7. These Cores are supported by two disks made of a non-magnetizable material, which form a right angle with this axis and penetrated by the cores for which they are each provided with a circular row of holes in which the nuclei enter.

The cores consist of rods made of drawn soft steel, which z. B. by cutting a drawn rod of mild steel into sections can be obtained. Such cores have a very regular structure and excellent Permeability to the magnetic flux.

In the example shown in the drawing, the cores are with 34 and the disks with 32a and 32b. These discs have a circular shape or polygonal outline.

Each disc has two concentric circular rows of Make holes. The holes in the outer row (33 a on the disc 32 a. And 33 b for the disk 32 b) take the ends of the cores 34 on. The holes of the inner Row (35 a for the disk 32a and 35b for the disk 32b) form passages for Air currents, which through the space between the discs 32a and 32b radially inward and after flow through the holes 35 a, 35 b in the by the arrow F for airflow to flow outward on the outside of the discs as shown.

The discs 32a and 32b are through between the holes 35a and 35b provided radial ribs 36a and 36b reinforced. The disks 32a and 32b are made preferably made of cast metal.

The ends of the cores 34, which are in the shape of cylinders of suitable cross-section have a smaller cross-section, so that they are inserted into the holes 33a, 33b can be and shoulders 37 a, 37 b form, which will be explained in the below Way with the interposition of parts 41 and 42 against the inner surfaces of the discs 32a, 32b are placed.

The cores 34 can be combined with the disks 32 a, 32 b in any suitable manner, for. B. as follows: In the embodiment shown in FIG. The cores 34 provided with their windings 18 are then inserted into the holes 33 a. The disk 32b placed on the sleeve 43 is then pushed against the disk 32a in such a way that the cores also enter the holes 33b of the disk 32b. The shoulders 37a and 37b of the cores form stops which limit the movement of the disks 32a and 32b with respect to one another. The disks are then joined together by bolts 45 and then attached to the frame of the assembly to be fitted with the brake, e.g. ß: a vehicle attached.

In the arrangement according to FIG. 3, the assembly takes place in a similar manner Way, the disc 32a is, however, attached to the sleeve 43 by being turned around this is poured around.

The shaft 7 is more precise in the sleeve 43 with the help of below bearings described. The cores 34 preferably have that shown in FIG Cross section showing the shape of an isosceles triangle with arcuate Has sides and corners. Two of these sides are formed by arcs with the radius R and one formed with the radius R1, which are connected to each other in the drawing are connected by arcs with the radii r and r1. Around R1 are relatively large compared to the dimensions of the core, while r and r1 are relatively small compared to these. The arches are of course not essential exact circular arcs. The X-Y plane of symmetry of each core is radial; H., it goes through the axis of the shaft 7.

An interesting advantage of such a design of the cores is that it ensures a large magnetic flux and at the same time the circulation of the air on the path shown by the arrow F and also along the path shown by the arrows f, through the holes 38 in the disks 1 and 2 paths made possible by the rotor. The side plates 39 carried by the radial arms 3 and 4 serve to guide the air currents against the outer periphery of the rotor. These plates 39 extend almost to the outer periphery of the disks 1 and 2. Another advantage of these plates 39 is that they protect the radial arms 3 and 4 against falling rocks caused by the wheels of the vehicle.

Another advantage of the cores shaped as shown in FIG in that they have a round surface with no edges or flat faces, so that the wires forming the windings 18 are wound directly onto them can, preferably with the interposition of an asbestos intermediate layer 40. There is no risk of the wires chafing during winding or during operation. The windings 18 are laterally through plates 41 and between These plates and the windings arranged insulating rings 42 held.

The shaft 7 is mounted in the sleeve 43 by two opposing thrust bearing 50a, 50b, each of which is between a shoulder of the shaft 7 and an inserted into one end of the sleeve 43 annular tightening nut 51 a, 51 disposed b. These nuts are provided with sealants for the lubricating oil.

The part of the shaft 7 lying between the shoulders heats up relatively little, so that he be stored between thrust bearings can. The shaft sections that are heated are those that are radial Wear arms 3 and 4. However, since the device is symmetrical, the air gaps remain e equal to each other on both sides of the anchor.

In the modified embodiment of FIGS. 4 and 5, the the armature forming discs 1 and 2 slide in the axial direction, whereby they through elastic means are pressed apart and their movement against each other by suitable stops is limited.

Such as B. shown on the left side of Fig. 4 (the arrangement on the other side is the same, since the device is symmetrical), the hub 5 is placed with the help of grooves on the end of the shaft 7 so that they on this can slide between two limit positions. The inner limit position is determined by the abutment of a sleeve 52 against a ring 51 a, while the other limit position is determined by the abutment of the inner end of a coupling member 53 attached to the shaft by a nut 54. Resilient rings 55 a, 55 b are intended to mitigate the impact of the hub 5 against its stops. A spring 56 is arranged between the hub 5 and the sleeve 52 and drives the hub outward. In the arrangement shown in FIG. 4, this spring 56 lies within the hub 5, while in the embodiment of FIG. 5 it lies outside the hub.

The same result can thereby be achieved in the embodiment according to FIG be obtained that arms 3 and 4 are given sufficient flexibility, while the hubs 5 and 6 are attached in the extension of the shaft 7 on this.

If in this training the brakes are not working and there is no electricity flows through the windings 18, the disks forming the rotor are through the Spring 56 is kept away from the inductor, eliminating any risk of friction between the fixed and rotating parts is excluded. If on the other hand a stream flows through the windings 18, the armature plates 1 and 2 are against the inductor part pulled, and the air gap e becomes very small, creating high electromagnetic forces develop.

Claims (1)

PATENT CLAIMS: 1. Eddy current brake, the rotatable armature of which is formed by two disks of a ferromagnetic material fastened on the shaft of the device at a certain mutual distance from one another, while the fixed inductor is arranged in the space between the two rotating disks of the armature and one comprises a certain number of electromagnets arranged in a circle around the shaft, the axes of which run parallel to the shaft of the device and which have pole faces at both ends which are parallel to the side faces of the armature plates and at a small distance therefrom, characterized in that the The core (34) of each electromagnet, including its pole faces, is formed by a single, drawn or rolled, cylindrical piece of iron and is held by two disks or plates (32a, 32b) made of non-magnetizable material and secured against axial displacement, perpendicular to the shaft (7), where the plates v are penetrated by the core ends forming the pole faces. z. Brake according to Claim 1, characterized in that the two discs or plates (32 a, 32 b) carrying the electromagnets also hold a central sleeve (43) in which the shaft (7) of the brake is mounted. 3. Brake according to claim 1 or 2, characterized in that each fixed disc or plate (32a, 32b) with a certain number of in the vicinity of the shaft (7) of the brake lying openings (35 a, 35 b) for the passage the cooling air is provided. 4. Brake according to one of claims 1 to 3, characterized in that the cores (34) have a smaller cross-section at their end, whereby shoulders are formed at a small distance from these ends, which with the edges of in the fixed disks or Plates (32 a, 32 b) formed holes (33 a, 33 b) cooperate so that they determine the mutual spacing of these fixed disks or plates, the windings (18) being applied to the part of the cores lying between the disks or plates are. 5. Brake according to one of claims 1 to 4, characterized in that the cross section of the cores (34) has the shape of an isosceles triangle (Fig.2) with arcuate sides and corners, the axis of symmetry (XY) of the triangle through the axis the shaft (7) and the tip of the triangle lying on this axis of symmetry faces the shaft. 6. Brake according to one of claims 1 to 5, characterized in that the rotating armature discs (1, 2) are provided with through holes (38) and that fan blades are provided on the outside of the discs, which radial, each disc with the Shaft (7) connecting arms (3, 4) form and generate a flow of cooling air through the holes (38). 7. Brake according to claim 6, characterized in that on the outside of the arms (3, 4) forming the fan blades, an annular cover plate (39) is attached, the outer diameter of which is at least approximately equal to the outer diameter of the rotating armature disks (1, 2). B. Brake according to claim 1, characterized in that the rotating disks (1, 2) can slide axially on the shaft (7), stops on the shaft to limit the displacement of the disks in the direction of the ends of the cores (34 ) to maintain a minimal air gap between the disks and cores and springs (56) which seek to axially remove the disks from the cores, are provided.