DE1286725B - Lifting magnet - Google Patents

Description

1 2

The invention relates to electric lifting magnets in excitation coils made of copper or aluminum wire and has two or more poles. Load lifting - it is not possible to significantly increase the pulling force of a lifting magnet magnets are used to handle ferromagnets. In the right part of FIG. 1 see objects and are known in various such a pole plate 2 α with associated embodiments. They consist of the 5 field diagram shown. The main part of the field lines, borrowed from excitation coils and an open magnet, which enforce this pole plate 2 a , must unmagnetkreis overcome by the ferromagnetic tables to be carried stretches. Fal-load is closed in the pole ring surface. decrease the values of By very quickly.

In principle, there are lifting magnets in the case of lifting magnets. There are also known lifting magnets in which

Task, the arrangement of the individual components io to meet a part of the non-magnetic excitation winding in the Inso that a high load-bearing capacity ensures neren a pole is arranged. Fig. 2 shows one. The tensile force of a lifting magnet is a section through a lifting magnet of this type with function of the normal component of induction (By) a magnet yoke 8, a center pole 9 with a pole plate in the pole face and its size for each point of the 9 a, a pole web 10, an inner one Coil 11, the same: 15 pole face annulus 12 and a center pole face 14

, 1 By \ ² and a load 13. In the left part of the figure is the

ρ = 0.04056 y ₁₀₀₀ J. Course of the field lines indicated. This execution

tion form has a considerably enlarged

The disadvantages of the known electric load lifting center pole surface 14, but has the following disadvantages magnets are based on FIGS. 1 and 2 of the ao. The center pole 9 with the center pole face 14 is explained as a drawing. Fig. 1 shows a section through the generator of the maximum induction must be smaller and keep its known pot lifting magnet than the lifting magnet according to FIG. 1. Load. The lifting magnet shown has a magnet on their way from the magnet yoke 8 to the pole plate 9 a gnetjoch 1, a center pole 2, an outer pole 3, a partially penetrate the field lines through the inner coil magnetically non-conductive exciter winding 4 and pole as 11 made of non-magnetic material. In addition, surfaces 6, 7, one of which a load 5 is applied, forces. In the pole web 10 the pole face annulus 12 its left part of the FIG. 1 is a highly simplified figure based on the value of the magnetic potential. The values of the internal magnetic field are shown. By in the circular pole face ring 12 are constant,

It can be clearly seen that not all field lines only reach about 55% of the values of By in the pole face 14 on their way from the magnet yoke 1 to the load 5. Another serious disadvantage is the use of the center pole 2 and the outer pole 3. A part of all electric lifting magnets is penetrated by the high inductive field lines, under high magnetic vity of the excitation winding. It is true that these losses are caused by the non-magnetic excitation winding 4. The normal component of induction By is only assigned to switching voltage peaks.

10 CkG) < Bv <20 CkG) limitation is more present. Lead breaks

almost always to the destruction of the lifting magnet.

In all points of the annular surface between the invention, the object is to provide a

Mittelpolfläche 6 and 7 is Außenpolfläche By small, to create electric lifting magnet in which the

0 < By <L 1 (kG) ⁴ ° load capacity is significantly increased. Through the invention

^ - a lifting magnet is created, which is in the

and goes through zero at some point that. in F i g, 1 area between the ferromagnetic poles one is indicated by a dashed line Ll. has high induction, low magnetic coupling Exceptions are the edge surfaces of this circular loss at the critical points of the magnetic circuit ring, because there the influence of the pole edges has been recorded and in its excitation winding one

makes noticeable. has effective overvoltage protection.

In the case of well-dimensioned round lifting magnets, the invention is characterized in that

the proportion of ferromagnetic surfaces in the parts of the excitation winding consisting of electrically isolated, total pole surface is rarely greater than 35%. The proportion of ferromagnetic conductors are carried out, which in the circular ring area (about 65% of the total pole area) 50 winding space of the lifting magnet so arranged in the total tensile force is very low and is that these magnetically conductive parts of the maximum 10%. Excitation winding as an amplifier of the iron cross-section If a significant increase in the tensile force of at least part of the magnetic circuit is to be achieved, By must act especially in this pole or magnetic yoke, but no magnetic surface is to be strengthened. Furthermore, from Fig. 1 55 table bridge between two magnetic counterparts can be seen that form in the magnetic circuit at different poles, and that it occurs together with the unma points, a strong saturation. These critical magnetic parts of the excitation winding from the excitation points are indicated by the dashed lines Ll and current flowing through them and when L 2 is excited. This high level of saturation increases the amount of magnetic circuit involved.

magnetic losses in the lifting magnet and 60 It is already known that in a lifting magnet, the induction weakens in the entire pole face. the excitation winding with the mediation of electrical A reinforcement of the point of insulating filling compound lying in the line L 2 , the metal particles are contained in all known lifting magnet designs. Due to these metal particles, the magnerization is significantly increased, taking into account the magnitude of the excitation-electrical conductivity of the filling compound, development is not possible. 65 so that the relatively small space between the exciter

There are also known electro-lifting magnets development and magnetic circuit lower magnetic losses with more or less protruding pole plates. At generated. The problem of magnetic conductivity the use of pole plates in connection with the field winding, which have a considerably larger

3 4

Takes up space than the filling compound, in the case of the coil 18 designed according to the invention, high inductance fastening of the field winding does not play a role. functions in the edge surface of the center pole plate ISa.

According to the invention, parts of the exciter winding are A conical design of the coil 18 is

ment made of ferromagnetic conductors, so appropriate to the corner scattering at the approach of a that these parts of the excitation winding reduce a double 5 magnetic yoke 16, but it is not Fulfill function. They are part of the magnet condition.

circle, which you strengthen considerably, and at the same time a in F i g. 4 shown according to the invention

Carrier of an electrical current, the lifting magnet formed for excitation has a magnetic

of the magnetic circuit contributes. In addition, over a circle made of cast dynamo steel with a center pole 21,

Men with a suitable circuit, the magnetically conductive io a magnetic yoke 22, an outer pole 23 and pole

the parts of the excitation winding, as a result of their protruding plates 21 a, 23 a. In the winding space of this lifting device magnetic coupling and sufficient magnets are designed according to the invention

Number of turns, the task of a highly effective part of the excitation winding made of magnetically conductive

Damper winding. Material 24, 25, 26 arranged so that they are all parts

The advantages achieved by the invention are to reinforce the magnetic circuit without, however, a ma-

mainly to be seen in the fact that because of the inventive gnetische bridge between the center pole 21 and the

according to the arrangement of a partial winding from magnetic outer pole 23 to form. The pole plates 21 a, 23 a

tisable material directly around a magnetic cover at the same time the poles 21, 23 and the associated

pol this part of the field winding has a low hearing parts 24, 25, 26 of the field winding according to

Has magnetic resistance. This is how the invention works. This lifting magnet execution

this winding part as part of the magnetic pole and is form has very high load-bearing capacities. The rest

interspersed with field lines in the same direction. Part 27 of the excitation winding is a coil made of aluminum

The pole plate can be kept so large that minium or copper wire.

it completely covers this part of the winding, and one in FIG. 5 illustrated two-pole load lifting

has high adhesive forces right up to its edges. The as magnet according to the invention consists of a U-shaped

By values of By drop only slowly to the pole edges of the magnetic circuit 28, an inventive

down. As a result, this load-lifting coil 29 and a second coil 30 are distinguished

magnet is characterized by greater load-bearing capacities than non-magnetic material,

similar to Fig. 2. A shown in FIG. 6 shown vertical partial section

The advantages achieved by the invention are the winding 26 according to FIG. 4 shows one particular

however, are not limited to the mentioned advantageous embodiment of the partial winding

improvement, rather, at the same time, simpler magnetically conductive material according to the invention.

Construction and easy assembly achieved. As the figure shows, this coil is made of one

In the drawing, embodiments of tape 31 and a film 32 (which are wound up at the same time)

Lifting magnets according to the invention shown, 35 celts are produced),

namely illustrated The band 31 is made of non-insulated sheet steel

F i g. 3 a vertical section through an invented and forms an excitation current conductor made of magnetizing

proper lifting magnet and its load; in the hard material, and its width corresponds to the

the left-hand part of the figure shows the course of the field lines. The film 32 serves as intermediate layers

indicates 40 aluminum with a thickness of about 20 μ and with

F i g. 4, in a highly schematic manner, a vertical half of an electrolytically applied oxide insulation 33

cut through another embodiment one about 5μ thick. This highly heat-resistant insulation

Lifting magnet according to the invention, lationsschicht has a dielectric strength that

5 shows a vertical section through one which is sufficient to show the turns of the band 31

inventive two-pole lifting magnet to isolate 45 from each other. The steel belt 31 and the

F i g. 6 a vertical partial section through an aluminum foil 32 can also be specified electrically in parallel Embodiment of a coil can be switched on, so that an improvement in the master exciter winding achieved according to the invention and value of the part 26 of the excitation winding

F i g. 7 shows an electrical circuit of both parts of the FIG.

Excitation winding, which is a use of the ferro- 50 Die F i g. 7 shows that a simultaneous

Magnetic conductors wound coil as a damper use according to the invention as a magnetic

development made possible. Conductive coil 35 of an excitation winding

The magnetic circuit of one in Fig. 3 pot shown with a further magnetically non-conductive coil

The lifting magnet consists of the following dynamo 34 as a damper winding is possible. The coil 35

cast steel parts: a center pole 15, a magnet 55 made of ferromagnetic material, connected in parallel

yoke 16 and an outer pole 17. As an exciter winding with a voltage-variable resistor 36,

treatment are a coil 18 made of magnetically conductive is hereby almost short at high voltages.

Material and a coil 19 made of aluminum or closed. The coil 34 made of non-ferrous metal

Copper wire attached concentrically around the center pole, there is no protective element against overvoltages. Will

arranges. A center pole plate 15 ″ covers both the 60 and the two coils 34, 35 with the aid of switching devices 37,

Center pole 15 as well as the 38 arranged according to the invention are connected to a DC voltage source, see above

Nete coil 18 made of magnetically conductive material. work together as an excitation winding, and the

The magnetic circuit of the lifting magnet is cross-current through the resistor 36 is very low.

short-circuited by a load 20. When the lifting magnet is switched off, the one in the left opens

Part of the figure shown, greatly simplified field 65 switching device 37 first, and the resistor 36 attenuates

Line image shows that the magnetically conductive that occurs in the magnetically conductive coil 35

Coil 18 acts as a reinforcement for the center pole 15. In overvoltage. When switching off the magnetic

Connection with the center pole plate 15 ″ produces the non-conductive coil 34 which works magnetically conductive

tend coil 35, which remains closed via the resistor 36, as a strong damper winding and avoids the creation of dangerous overvoltages at the ends of the magnetically non-conductive coil 34.

Claims (5)

Patent claims: 1. Lifting magnet with at least one pot-, E-, U-shaped or similarly designed magnetic circuit and at least one excitation winding with one or more coils made of insulated copper or aluminum wires, marked thereby t that parts (coils 18, 24, 25, 26, 29) of the excitation winding made of electrically isolated, ferromagnetic conductors are designed, which are arranged in the winding space of the lifting magnet are that these magnetically conductive parts (coils 18, 24, 25, 26, 29) of the excitation winding as reinforcement of the iron cross-section of at least part of the magnetic circuit, such as poles (15, 21, 23) or magnetic yoke (24, 28) work, but no magnetic bridge between two magnetic opposing poles, and that they together with the non-magnetic parts (coils 19, 27, 30) of the excitation winding are traversed by the excitation current and during excitation of the magnetic circuit. 2. Lifting magnet according to claim 1, characterized in that the parts consisting of ferromagnetic conductors (coils 18, 24, 26) of the excitation winding, which are assigned to a pole (15, 21, 23), through a pole (15, 21, 23) final pole plate (15 a, 21a, 23 a) are completely or partially covered. 3. Lifting magnet according to claim 1 and 2, characterized in that the ferromagnetic Part (coils 18, 24, 25, 26, 29) of the excitation winding made of a ferromagnetic tape (31) and at least one aluminum foil (32) as a carrier in an insulating layer (oxide insulation 33) are wound from aluminum oxide in such a way that this insulating layer (oxide insulation 33) the adjacent Windings made of ferromagnetic tape (31) electrically separates from each other. 4. Lifting magnet according to claim 1, 2 and 3, characterized in that the aluminum foil (32) is connected electrically in parallel with the ferromagnetic band (31). 5. Lifting magnet according to claim 1 and 2, characterized in that the ferromagnetic Parts (coils 18, 24, 25, 26, 29) of the excitation winding individually or together, with the help of a voltage-variable resistor (36) connected in parallel when the excitation current is switched off act as a damper winding. 1 sheet of drawings