DE4225156A1 - Magnet system for electro-acoustic transducers - Google Patents

Description

Technical field

The invention is concerned with magnet systems of electroacoustic transducers, especially with the Increase in the magnetic flux density in the air gap simultaneous reduction in the size of such systems.

State of the art

Magnetic systems of electroacoustic transducers are generally constructed so that in a magnetic pot Pole core inserted centrally to the central axis of the system is. The free one, not with the bottom of the magnetic pot connected end of the pole core is with the so-called Pole plate connected. The pole plate has opposite Pole core a larger diameter. Depending on the dimension of the Magnetic pot is the upper edge of the magnetic pot with a protruding into the inner diameter of the magnetic pot Disc connected or in one piece in the above Trained way. The parallel to the central axis running edge areas of the pole plate and the part, which in the inner diameter of the magnetic pot  protrudes, face each other at a distance and thus form the system's air gap.

Conventionally, such magnet systems are largely made Ferrite material formed. To be big enough It is to achieve magnetic flux density in the air gap in the arrangements formed from ferrite material required, the magnet system related to the rest Mass of the loudspeaker arrangement is large and therefore heavy to train.

It is also known that the pole core is made of one material form, which is in the field of transducer technology the name neodymium is known. The use of this magnetically high-energy material compared to the transducers created in ferrite technology have the advantage that the transducers trained in neodymium technology same induction in the air gap compared to in Ferrite technology formed transducers significantly can be reduced. Another episode of Converters in neodymium education is possible downsizing, the one associated with the downsizing Weight reduction of the magnet system.

Those with the use of neodymium as material for the Benefits associated with polar core are not so too understand that starting from a predetermined size of the pole core formed from neodymium induction in the air gap by simply increasing the dimensions of the neodymium existing part of the pole core can be increased as desired can. Rather, it is also when using neodymium as material for part of the pole core so that with increasing magnification of the mass of the neodymium part achievable induction increase only disproportionately  can be increased. To illustrate this with an example clarify, it should be noted that with a mass of the neodymium part in the pole core of x an induction (BL) in Air gap of about 0.6 Tesla can be achieved while at an increase in the mass of the neodymium part in the pole core to 2x the induction achievable in the air gap is only about 0.645 Tesla can be increased.

The invention is therefore based on the object Magnet system with neodymium pole core to specify achievable induction in the air gap compared to the known Orders is increased.

Presentation of the invention

This object is achieved in that according to claim 1 the side facing away from the bottom of the magnetic pot Another neodymium plate is arranged.

With this arrangement it is possible to achieve the achievable Induction in the air gap compared to the conventional one Increase training by up to 50%.

Because of the achievable with this arrangement It is further possible to increase the mass of the induction To reduce the total magnet system. For example an induction of 0.65 Tesla in the air gap is required and was previously using a neodymium disc in the pole core the mass of 2x used, so can the same induction can be achieved in the air gap in that the mass of the Neodymium disc in the pole core is reduced to 0.6x and this arrangement with another on the pole plate attached neodymium disc with a mass of about 0.6x is combined.  

A particularly even field line course in the air gap is achieved when according to claim 2, the diameter of both neodymium discs is the same.

Since according to claim 3, the masses of the two neodymium discs does not necessarily have to be the same size, this has the Advantage that the neodymium disc with the larger of the two Masses can be arranged on the pole plate. this has as a result that the height of the magnet system between the Bottom and the pole plate or the top of the Magnet pot can be reduced. Through the Possibility of different sizes or weights Can arrange neodymium discs on both sides of the pole plate by simply changing the mass of one of the two Neodymium discs the required induction in the air gap can be set very easily. In particular is it thereby possible to get one out of the first neodymium disc Pole plate and the magnet pot formed unit for one Prefabricate a variety of speaker types and through that Attach the additional neodymium disc the required Induction for the different types of speakers adjust.

Brief presentation of the figures

Fig. 1 A magnet system for an electroacoustic transducer in the side section; and

FIG. 2a, b show two further magnet systems in lateral cross section.

Ways of Carrying Out the Invention

The invention will now be explained in more detail with reference to the figures become.

Fig. 1 shows a magnet system 10 for an electroacoustic transducer. This magnet system 10 is essentially formed by that on the magnet pot 11 and the pole core 12 . The upper edge of the magnetic pot 10 has a circumferential, unshaped flange 13 which points to the central axis of the system. The pole core 12 is formed from a round disk 14 formed from neodymium and a likewise round pole plate 15 , the upper end of the neodymium disk 14 being connected to the pole plate 15 . Since the diameter of the pole plate 15 is larger than the diameter of the neodymium disc 14 , the upper edge of the pole core 12 is also flange-shaped. The pole core 12 is placed and connected with its end facing away from the pole plate 15 centrally to the central axis on the bottom 16 of the magnet pot 11 . Since the height level of the magnetic pot 11 and the height level of the pole core 12 connected to the base 16 are the same and the outer diameter of the pole plate 15 is smaller than the inner diameter of the flange 13 , the air gap 17 of the magnet system 10 is formed between the flange 13 and the pole plate 15 . The voice coil (not shown) is later inserted into this air gap 17 to complete the electromagnetic transducer. On the side of the pole plate 15 facing away from the first neodymium disc 14, the further neodymium disc 18 is also placed and connected centrally to the central axis in such a way that the similar poles (here the two north poles; N / N) of the two neodymium discs 14 , 18 directly and only through one another the pole plate 15 are separately opposite. The diameter of the further neodymium disk 18 corresponds to the diameter of the neodymium disk 14 arranged in the pole core 12 . This equality in the diameter of both neodymium disks 14 , 18 ensures that the field line course in the air gap 17 has a particularly uniform course.

In order to clarify the increase in induction that can be achieved by this arrangement of the further neodymium disc 18 , the following should be pointed out: If an arrangement according to FIG. 1, in which only the further neodymium disc 18 is omitted, an induction of, for example, 0.6 Tesla could be achieved and one would increase it If the induction in the air gap 17 increases the mass of the neodymium disk 14 in the pole core 12 by the mass of the further neodymium disk 18 , only an increase in induction of between 5 and 8% could be achieved because of the enlargement of the magnetic pot 11 associated therewith. However, if the magnetic pot 11 is designed as illustrated in FIG. 1, an increase in the induction in the air gap 17 of up to 50% can be achieved compared to a magnet system 10 which only has the neodymium disk 14 in the pole core. The advantages achievable according to the invention, which are associated with the arrangement of the second neodymium disc 18 , can also be used to minimize the use of neodymium. If a given induction in the air gap 17 is required and this induction can be achieved by means of a neodymium disk 14 of mass 2x arranged in the pole core 12 , the same induction can be achieved by using two neodymium disks 14 , 18 with a total mass of approximately 1.2x, if this mass is divided on both sides of the pole plate 15 on two neodymium discs 14 , 18 . A further weight saving through the use of two neodymium discs 14 , 18 on both sides of the pole plate 15 resulted from the fact that because of the reduced mass for the first neodymium disc 14 arranged in the pole core 12 , the design of the magnet pot 11 can also be reduced.

As shown in FIGS. 2a, b, it is not necessary that the masses and thus also the designs of the two neodymium disks 14 , 18 on both sides of the pole plate 15 must be chosen to be the same size. Rather, in deviation from the illustration in FIG. 1, the neodymium disc 14 arranged in the pole core 15 can also be made smaller or larger than the other neodymium disc 18 . This combination possibility makes it possible to prefabricate the magnet pot 11 together with the pole core 12 for a large number of loudspeaker types and to adjust the final setting of the induction in the air gap 17 required for the different types by arranging different sized additional neodymium discs 18 on the pole plate 15 .

Reference numerals

10 magnet system
11 magnetic pot
12 pole core
13 flange
14 neodymium disc (1.)
15 pole plate
16 bottom
17 air gap
18 neodymium disc (others)

Claims (3)

1. Magnet system for electro-acoustic transducers
with a magnetic pot and
with a pole core which is formed by a neodymium disc ( 14 ) and a pole plate and which is connected to the bottom of the magnetic pot centrally to the loudspeaker center axis,
characterized in that a further neodymium disc ( 18 ) is arranged in the air gap ( 17 ) on the side of the pole plate ( 15 ) facing away from the neodymium disc ( 14 ). 2. Magnet system according to claim 1, characterized in that the diameter of the further neodymium disc ( 18 ) corresponds to the diameter of the neodymium disc ( 14 ) arranged in the pole core ( 12 ). 3. Magnet system according to claim 1 or claim 2, characterized in that the dimensions of the first neodymium disc ( 14 ) from the mass of the other neodymium disc ( 18 ) is different.