DE102016114596B4 - Electro-acoustic transducer - Google Patents

Abstract

Electroacoustic sound transducer (10; 20; 30; 40; 50; 60) with at least one membrane (15) to which at least one voice coil (16; 26; 36; 46; 56; 66) is attached, the voice coil for immersion in a homogeneous magnetic field is provided, characterized in that the voice coil (16; 26; 36; 46; 56; 66) is divided into two parts and an auxiliary coil part (14; 24; 34; 44; 54; 64) and a voice coil part (13; 23 ; 33; 43; 53; 63), the auxiliary coil part (14; 24; 34; 44; 54; 64) being attached to the membrane (15).

Description

The present invention relates to an electroacoustic sound transducer with at least one membrane to which at least one voice coil is attached, the voice coil being provided for immersion in a homogeneous magnetic field, as well as a voice coil itself, a loudspeaker, headphones and a method for producing voice coils.

State of the art

Electroacoustic sound transducers are known, for example for use in a loudspeaker, in which a membrane is provided which is driven by a voice coil. The voice coil vibrates in an air gap of a magnet arrangement, so that the membrane can be moved via an electromagnetic field and the electrical energy is converted into mechanical vibrations of the membrane and thus into sound waves.

The German Offenlegungsschrift DE 10 2009 038 593 A1 shows, for example, a sound transducer magnet system with a ring-shaped magnet that provides a magnetic field for a voice coil in an air gap. This voice coil is attached directly to the diaphragm of the transducer. In the case of sound transducers, this is generally referred to as a two-part membrane. With such an arrangement, only part of the voice coil is located in the homogeneous magnetic field. Therefore, such an arrangement may be problematic in terms of sound quality.

The German Offenlegungsschrift DE 10 2009 011 773 A1 shows a dynamic moving coil loudspeaker in which a voice coil dips into the annular gap of a permanent magnet. The ring coil is attached to the membrane via a coil carrier. In such arrangements, a three-part membrane is used. In general, it has an advantageous effect on the sound quality if the voice coil is attached to the membrane via a coil carrier or a coil collar, since the voice coil then moves completely in the homogeneous magnetic field. However, the production of such a three-part membrane is complex and therefore time-consuming and cost-intensive.

The German Offenlegungsschrift DE 32 41 898 A1 describes an electrodynamic transducer with two voice coils, which are immersed in two separate air gaps of a magnet system. A useful signal is applied to both voice coils. The voice coils are each attached to the membrane via a voice coil former.

The German Offenlegungsschrift DE 26 04 888 A1 discloses a loudspeaker with an inner and an outer voice coil in two separate air gaps, one coil being supplied with a useful signal and the other coil being used to regulate the signal. The bobbins themselves are wound on an inner and an outer sleeve, which are attached directly to the membrane, so that the sleeves act as coil carriers. Such a coil carrier or coil collar produces the required distance between the coil and the membrane.

From the US 2015/0 280 634 A1 discloses an electromagnetic transducer comprising a ring magnet arrangement which generates a magnetic field, a first coil which is arranged in the magnetic field generated by the magnet arrangement so that the first coil moves with respect to the magnet arrangement or vice versa, at least one elastic suspension, which connects the magnet assembly to the first coil to allow reciprocal movement between the first coil and the magnetic assembly, a control coil that is connected to the magnetic assembly via an elastic suspension to reciprocate movement of the control coil with respect to the magnetic Arrangement to allow a vibration surface, which is connected to the first coil or the magnet arrangement or the control coil, and an electronic controller to control an exciting current of the control coil in order to generate a mechanical force which is adapted to the mechanical vibration of the Vibration surface for s expensive.

From the JP 2004-260 348 A shows an electroacoustic transducer in which a first coil and a second coil are provided. These coils are arranged in a non-homogeneous magnetic field.

One method of making coils is in US Pat U.S. 5,937,076 described.

With a two-part diaphragm, only part of the voice coil is located in the homogeneous magnetic field of the air gap, which results in a lower sound quality compared to a three-part diaphragm. With a three-part diaphragm, the voice coil is completely in the homogeneous magnetic field, which means that the sound quality is higher and distortion is lower than with a two-part diaphragm. These advantages in terms of quality are, however, associated with a considerably higher cost in the manufacture of a three-part diaphragm, since a coil collar or a coil carrier is required as an additional component in order to produce the required distance between the voice coil and the diaphragm. The coil collar For example, a separate, time-consuming process has to be carried out by reshaping plastic films under the influence of pressure and temperature, which requires special machines with appropriate operating personnel. Placing the voice coil on the coil collar also requires an additional device with operating personnel and a corresponding expenditure of time.

The invention is based on the object of providing an improved arrangement for an electroacoustic sound transducer which, on the one hand, offers advantages in production and, on the other hand, meets high quality requirements for a sound transducer.

Disclosure of the invention

This object is achieved by an electroacoustic sound transducer with the features of claim 1 and by a voice coil that emerges from claim 11. Advantageous configurations of this sound transducer and the voice coil as well as a loudspeaker, a headphone and a method for producing the voice coil are the subject of the further claims.

The electroacoustic sound transducer according to the invention has at least one membrane to which at least one voice coil is attached. This voice coil is designed to be immersed in a homogeneous magnetic field. The essence of the invention is that the voice coil is divided into two parts and comprises an auxiliary coil part and a voice coil part. This division into two can in particular be implemented essentially as a transverse division of the voice coil, which to a certain extent results in an upper part of the voice coil as an auxiliary coil part and a lower part as a voice coil part. The auxiliary coil part is oriented in the direction of the membrane, the membrane being fastened to the auxiliary coil part. The lower voice coil part is immersed in the homogeneous magnetic field, which is formed, for example, in an air gap of a ring magnet arrangement. Preferably, only the voice coil part is provided for immersion in the magnetic field, so that the auxiliary coil part does not or only partially immerses in the homogeneous magnetic field and is to a certain extent located above the magnetic field. In other words, the auxiliary coil part replaces the coil carrier or the coil collar, which is provided in conventional three-part membranes. The auxiliary coil part is used to mechanically attach the voice coil to the membrane. With particular advantage, the auxiliary coil part simultaneously forms a spacer between the voice coil part and the membrane. The solution according to the invention thus combines the mechanical simplicity of a two-part diaphragm with the special sonic advantages of a three-part diaphragm.

It is particularly advantageous that the voice coil according to the invention with the auxiliary coil part and the voice coil part can be produced in one work process or in one production step. This results in considerable advantages in the manufacture of the sound transducer, in particular in comparison with conventional three-part membranes. The separate production of a coil collar or a coil carrier is completely eliminated. In the case of conventional three-part membranes, it is necessary, for example, to produce an additional component for the coil collar or the coil carrier, which is made in a separate, time-consuming process, for example by reshaping plastic films. The voice coil must then conventionally be applied to the coil collar or the coil carrier. Various special machines are required for the various work steps. In contrast, the voice coil according to the invention can be wound with the auxiliary coil part and the actual voice coil part in one work process on a machine, this process being able to be automated with particular advantage, so that there is a considerable time and cost advantage in the manufacture of the sound transducer according to the invention.

Various advantageous configurations of the sound transducer according to the invention are possible with regard to the special configuration of the two-part voice coil. For example, the auxiliary coil part can essentially only form a spacer between the voice coil part and the membrane, in that the auxiliary coil part is designed as a dummy coil, so to speak, which is located between the voice coil part and the membrane. Furthermore, the auxiliary coil part can simultaneously form a carrier for the voice coil part. In this case, the auxiliary coil part can, for example, comprise only one winding layer which extends over the entire length of the complete voice coil. In the area of the voice coil part, that is to say that part of the voice coil that is immersed in the homogeneous magnetic field, the winding or the windings of the voice coil part are wound on the outside of the auxiliary coil part. In this case, the auxiliary coil part and the voice coil part then differ, for example, by the number of winding layers, the auxiliary coil part preferably having fewer winding layers than the voice coil part.

Another possibility is that the auxiliary coil part comprises one or more winding layers which only extend onto the upper part of the voice coil. In the lower part of the voice coil is the voice coil part, which is immersed in the homogeneous magnetic field. This can also include one or more winding layers. Here, the auxiliary coil part and the voice coil part differ, for example, by the Overall height, the overall height of the auxiliary coil part is preferably designed such that the voice coil part is located in the center of the homogeneous magnetic field.

The electrical contacting of the voice coil according to the invention and in particular the electrical contacting of the voice coil part and optionally the auxiliary coil part can be implemented in different ways. In a preferred embodiment, the auxiliary coil part is not electrically contacted or only partially contacted, so that the auxiliary coil part does not have current flowing through it during operation. For this purpose, for example, the beginning and the end of the auxiliary coil wire can simply be cut off. Another possibility is that the auxiliary coil part is short-circuited with the beginning and the end of the auxiliary coil wire. Furthermore, for an electrical partial contact, for example the start of the auxiliary coil wire can be cut off and the end of the auxiliary coil wire can be contacted together with the start of the voice coil wire. This eliminates the need to differentiate between the end of the auxiliary coil wire and the beginning of the voice coil wire during production, but at the same time the auxiliary coil part is not traversed by current because the start of the auxiliary coil wire is not contacted.

In another embodiment of the sound transducer according to the invention, electrical contact is made with the auxiliary coil part, the auxiliary coil part preferably being connected to an electrical circuit separate from the voice coil part. One possible application of this embodiment of the sound transducer according to the invention is, for example, damping of the sound transducer that can be influenced from the outside and that can be implemented both actively and passively.

Furthermore, it is in principle possible for the auxiliary coil part and the voice coil part to be connected to a common circuit, the connection of the auxiliary coil part preferably being controllable, e.g. B. via a potentiometer. The particular advantage here is that with such an arrangement it is possible to switch between the behavior of a two-part and a three-part membrane or any gradations in between.

In principle, the auxiliary coil part can be made from the same material or from a different material than the voice coil part. The geometry of the auxiliary coil part can be flexibly adapted to the respective requirements. For example, the number of windings of the auxiliary coil part can be smaller or larger or exactly as large as the number of windings of the auxiliary coil part. There are also various options with regard to the number of winding layers. As already mentioned, the number of winding layers of the auxiliary coil part can be smaller than the number of winding layers of the voice coil part, with the advantage that the weight of the entire voice coil is reduced. On the other hand, it is also possible that the number of winding layers of the auxiliary coil part is greater than or exactly as large as the number of winding layers of the voice coil part. Furthermore, the overall height of the auxiliary coil part can be adapted to the respective requirements. For example, it can be smaller or larger or exactly as large as the overall height of the voice coil part. The diameter of the auxiliary coil part can also be adapted, wherein the diameter can be, for example, smaller or larger or exactly as large as the diameter of the voice coil part.

The invention further comprises a voice coil for use in an electroacoustic sound transducer. According to the invention, the voice coil is divided into two parts and comprises an auxiliary coil part and a voice coil part, the auxiliary coil part being provided for attachment to the diaphragm of the sound transducer. With regard to further features of this voice coil, reference is made to the description above.

The invention further comprises a loudspeaker which comprises at least one voice coil or a sound transducer as described above. The invention further comprises headphones with at least one such voice coil or such a sound transducer.

Finally, the invention comprises a method for producing a two-part voice coil according to the above description with an auxiliary coil part and a voice coil part, wherein the auxiliary coil part and the voice coil part can be wound in one and the same work process, in particular on the same winding machine. This possibility of manufacturing the two-part voice coil represents a particular advantage in comparison with conventional three-part diaphragms, since this manufacturing process can be automated particularly well. With conventional three-part membranes, additional materials (e.g. plastic film) and complex production steps (e.g. forming processes) are required for the coil collar or the coil carrier. Such additional processes are completely omitted in the manufacture of the voice coil according to the invention and are replaced by a significantly faster winding process that has to be carried out anyway and which can advantageously also be automated. Personnel-assisted placement of the voice coil on a coil collar or a coil carrier as with conventional three-part diaphragms is also not necessary, since the auxiliary coil part and the voice coil part are already mechanically connected to one another in the winding machine. Attaching the Voice coil according to the invention on a membrane can be carried out in a simple manner without great effort and is also accessible to automated production.

In contrast, for example, to a coil collar or a coil carrier in a three-part membrane, which have a fixed geometry, the geometry of the auxiliary coil part can be easily changed and adapted, for example with regard to the number of winding layers or the overall height. Furthermore, an optimization with regard to a low weight of the voice coil and the required stability is possible, so that overall the production of the voice coil according to the invention can be designed very flexibly. The adaptation of the geometry of the auxiliary coil part is possible at any time, for example by appropriate programming or retrofitting of the winding machine.

With suitable dimensions of the auxiliary coil part, the voice coil part can be positioned in a precise manner in the air gap of a ring magnet or the like. Since voice coils are used at different heights depending on the impedance, appropriate adjustments to the geometries of the auxiliary coil part are advantageous in order to be able to optimally position the voice coil part in the middle of the homogeneous magnetic field, so that, for example, distortions in the sound reproduction are minimized. Since the geometries of the auxiliary coil part according to the invention can be variably adapted in a very simple manner even in automated processes, the invention offers particular advantages, in particular with regard to the production and the high quality of corresponding sound transducers. The sound transducer according to the invention allows a particularly advantageous possibility for flexible optimization of the voice coil position.

The auxiliary coil part, like the voice coil part, is wound from coil wire, but primarily serves as a spacer for positioning the voice coil part in the air gap. The sound transducer according to the invention thus behaves like a sound transducer with a conventional three-part membrane, but the manufacturing effort is significantly lower and comparable to the manufacturing effort for a conventional two-part membrane. In particular, the sound transducer according to the invention can be manufactured using a fully automatic manufacturing process. The sound transducer according to the invention thus optimizes the quality on the one hand and allows significant savings in production on the other.

Further features and advantages of the invention emerge from the following description of exemplary embodiments in conjunction with the drawings. The individual features can be implemented individually and in combination with one another. The configurations of the voice coil according to the invention and the sound transducer explained in more detail in the exemplary embodiments and the drawings are only to be understood as examples. The number of windings, the number of winding layers and the geometries of the voice coil or its auxiliary coil part and its voice coil part can be replaced by other shapes and designs in adaptation to the respective applications.

• 1 - 6 schematische Schnittdarstellungen von verschiedenen Ausführungsformen eines erfindungsgemäßen elektroakustischen Schallwandlers.

In the drawings show:

• 1 - 6th schematic sectional views of various embodiments of an electroacoustic sound transducer according to the invention.

Description of exemplary embodiments

1 shows, as a schematic sectional illustration, a first embodiment of a sound transducer according to the invention 10 . The transducer 10 includes a magnetic assembly 11 with a circular air gap 12th . The magnetic arrangement 11 can be implemented, for example, as a ring magnet or disc magnet or with other magnet designs. The voice coil dips into the air gap 16 a. The voice coil 16 is divided into two parts and comprises a lower voice coil part 13th and an upper auxiliary coil part 14th . Only the voice coil part is immersed in this process 13th in the air gap 12th a. Over the upper end of the auxiliary coil part 14th is the voice coil 16 on the membrane 15th attached. The membrane 15th is with its outer edge on the magnetic ring arrangement 11 attached. In this embodiment, the auxiliary coil part is used 14th primarily as a spacer between the voice coil part 13th and the membrane 15th . The number of turns of the auxiliary coil part 14th and the voice coil part 13th are identical in this example. The voice coil part 13th is through the auxiliary coil part 14th in a comparable position in the air gap 12th held, as is the case with a three-part membrane from the prior art. The sound transducer according to the invention 10 and in particular the voice coil of the present invention 16 with the voice coil part 13th and the auxiliary coil part 14th combines the advantages of a three-part diaphragm with regard to the special tonal qualities with the simple production of a two-part diaphragm. The auxiliary coil part 14th ensures a sufficient distance between the voice coil part 13th and the membrane 15th during operation of the transducer 10 so that the voice coil part 13th located in the homogeneous magnetic field and there is no impairment in the sound quality due to poor positioning of the voice coil part 13th comes in the magnetic field.

The auxiliary coil part 14th and the voice coil part 13th can be manufactured together in the same winding process, so that there is no need for complex assembly of a coil collar or a coil carrier. In addition, the geometries of the auxiliary coil part 14th variably adjustable through simple adjustments during the winding process and adaptable to different applications.

2 shows a further embodiment of a sound transducer according to the invention 20th . Except for the design of the voice coil 26th corresponds to the transducer 20th the in 1 embodiment shown and is provided with the same reference numerals. The same applies to the following figures. The voice coil 26th includes a voice coil part 23 and an auxiliary coil part 24 , in this embodiment the auxiliary coil part 24 only one winding layer and the voice coil part 23 has two winding layers. The number of winding layers is to be understood here only as an example. Due to the lower number of winding layers of the auxiliary coil part 24 compared with the voice coil part 23 becomes the weight of the auxiliary coil part 24 and thus the total weight of the voice coil 26th advantageously reduced, thereby reducing the moving mass in the sound transducer 20th is reduced.

3 shows another embodiment of the voice coil 36 with a transducer 30th . The auxiliary coil part functions in this embodiment 34 on the one hand as a spacer and also as a support for the voice coil part 33 . The auxiliary coil part extends here 34 over the entire length of the voice coil 36 . The voice coil part 33 is on the outside of the auxiliary coil part in the corresponding area 34 wrapped. Here is the diameter of the auxiliary coil part 34 smaller than the diameter of the wound voice coil part 33 . In this embodiment, only the voice coil part located on the outside is preferably used 33 electrically contacted.

4th illustrates another embodiment of a voice coil according to the invention 46 in a transducer 40 . The auxiliary coil part forms here 44 as it were part of the voice coil part 43 , with the auxiliary coil part 44 due to a lower winding height compared to the voice coil part 43 and the voice coil part 43 a higher number of winding layers than the auxiliary coil part 44 owns. The auxiliary coil part 44 and the voice coil part 43 are wound from a continuous wire and thus both make electrical contact. This results in a combined auxiliary and voice coil.

5 illustrates an electrical contact possibility for the voice coil according to the invention 56 a sound transducer 50 . Here is the auxiliary coil part 54 partially contacted. The beginning of the auxiliary coil wire is cut off. The end of the auxiliary coil wire is together with the beginning of the wire of the voice coil part 53 contacted. The voice coil part 53 is doing an electrical circuit 150 connected. The auxiliary coil part 54 However, no current flows through it during operation because the start of the auxiliary coil wire is not contacted. The electric circuit 150 can e.g. B. be an amplifier.

6th shows a further possibility of contacting the voice coil according to the invention 66 at the transducer 60 . This example shows separate contacting of the auxiliary coil part 64 and the voice coil part 63 . The auxiliary coil part 64 and the voice coil part 63 are each on separate electrical circuits 160 or. 170 connected. Here, the auxiliary coil part 64 for example, to control the actual useful signal that is transmitted via the voice coil part 63 running, can be used. For example, via the electrical circuit 160 an externally influenceable damping of the sound transducer 60 (actively or passively).

Claims (14)

Electroacoustic sound transducer (10; 20; 30; 40; 50; 60) with at least one membrane (15) to which at least one voice coil (16; 26; 36; 46; 56; 66) is attached, the voice coil for immersion in a homogeneous magnetic field is provided, characterized in that the voice coil (16; 26; 36; 46; 56; 66) is divided into two parts and an auxiliary coil part (14; 24; 34; 44; 54; 64) and a voice coil part (13; 23 ; 33; 43; 53; 63), the auxiliary coil part (14; 24; 34; 44; 54; 64) being attached to the membrane (15). Sound transducer after Claim 1 , characterized in that the auxiliary coil part (14; 24; 34; 44; 54; 64) is provided at most partially for immersion in the homogeneous magnetic field. Sound transducer after Claim 1 or Claim 2 , characterized in that the auxiliary coil part (14; 24; 34; 44; 54; 64) forms a spacer between the voice coil part (13; 23; 33; 43; 53; 63) and the membrane (15). Sound transducer according to one of the preceding claims, characterized in that the voice coil (16; 26; 36; 46; 56; 66) with the auxiliary coil part (14; 24; 34; 44; 54; 64) and the voice coil part (13; 23; 33; 43; 53; 63) can be produced in one work process. Sound transducer according to one of the preceding claims, characterized in that the Auxiliary coil part (34) forms a carrier for the voice coil part (33). Sound transducer according to one of the preceding claims, characterized in that the auxiliary coil part (24; 34; 44; 54; 64) has fewer winding layers than the voice coil part (23; 33; 43; 53; 63). Sound transducer according to one of the preceding claims, characterized in that the auxiliary coil part (54) is electrically short-circuited or electrically not contacted or electrically partially contacted. Sound transducer according to one of the Claims 1 to 6th , characterized in that the auxiliary coil part (64) is electrically contacted. Sound transducer after Claim 8 , characterized in that the auxiliary coil part (64) is connected to a separate electrical circuit (160). Voice coil (16; 26; 36; 46; 56; 66) for use in an electroacoustic sound transducer with at least one membrane (15), characterized in that the voice coil is divided into two parts and an auxiliary coil part (14; 24; 34; 44; 54; 64) and a voice coil part (13; 23; 33; 43; 53; 63), the auxiliary coil part (14; 24; 34; 44; 54; 64) being provided for attachment to the membrane (15). Voice coil after Claim 10 , characterized in that the voice coil has at least one of the features according to one of the Claims 2 to 9 having. Loudspeaker with at least one voice coil (16; 26; 36; 46; 56; 66) according to Claim 10 or Claim 11 . Headphones with at least one voice coil (16; 26; 36; 46; 56; 66) according to Claim 10 or Claim 11 . Method for producing a voice coil (16; 26; 36; 46; 56; 66) according to Claim 10 or Claim 11 , characterized in that the auxiliary coil part (14; 24; 34; 44; 54; 64) and the voice coil part (13; 23; 33; 43; 53; 63) are wound in one work process.

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