DE102021101516B4 - microphone setup - Google Patents

Abstract

Microphone device, with at least one membrane (3, 4) and a capacitor unit (5, 6) assigned to the membrane (3, 4) for scanning vibrations of the membrane (3, 4), and with an additional plunger coil unit (7, 8) for additional scanning of vibrations of the diaphragm (3, 4), with a condenser diaphragm (3) interacting with the condenser unit (5, 6) and a coil diaphragm (4) which is locally and functionally separate therefrom being provided for interaction with the plunger coil unit (7, 8), characterized in that the capacitor unit (5, 6) and the plunger coil unit (7, 8) each have a vent hole (10, 11).

Description

The invention relates to a microphone device, with at least one membrane and a capacitor unit assigned to the membrane for scanning vibrations of the membrane, and with an additional plunger coil unit for additional scanning of vibrations of the membrane, with a capacitor membrane interacting with the capacitor unit and a capacitor membrane that is locally and functionally separate from it Coil membrane are provided for interaction with the plunger coil unit.

Microphones typically work on either the condenser or voice coil principle. In both cases it is an electro-acoustic converter, with the help of which the sound to be recorded is converted into a corresponding electrical signal. With the capacitor principle, the capacitor unit assigned to the membrane ensures that changes in the distance between the movable membrane and a counter-electrode cause changes in capacitance. Depending on the sound pressure, these changes in capacitance are converted into an electrical signal. Due to their design, condenser microphones are usually used where a particularly detailed reproduction is required. However, the range of such condenser microphones is limited, especially with regard to the sound pressure to be reproduced.

For this reason, in addition to condenser microphones, dynamic or moving coil microphones are used, which can process much higher sound pressure levels than condenser microphones. Moving coil microphones are those that work according to the electrodynamic principle. For this purpose, a conductor or plunger coil that moves with the movable membrane is moved in relation to a permanent magnetic field. The movement of the moving coil relative to the permanent magnet ensures that current is induced in the moving coil, which depends on the speed of membrane movement.

For this reason, such dynamic microphones or moving coil microphones are typically used live or for live performances, whereas condenser microphones are mostly used in the studio. In fact, such condenser microphones are rather unsuitable for live performances because, on the one hand, they pick up any background noise due to their high sensitivity and, on the other hand, they are not suitable for the high sound pressure levels that are often generated during live performances. The fact that moving coil microphones generally do not have such a large frequency transmission spectrum as condenser microphones is of lesser importance in this context and in live performances. In addition, moving coil microphones, in contrast to condenser microphones, do not require a power supply, which makes them suitable for use in mobile applications. Its simple design also contributes to this and, in conjunction with the inexpensive production, ensures an almost indestructible character overall.

In the state of the art according to DE 203 01 699 U1 describes a microphone or loudspeaker which consists of at least one CD or DVD disc which has at least one spiral-shaped indentation. The ends of the spiral-shaped coil realized in this way in the disk can be coupled to a power connection. In addition, two disks brought together can also interact in the manner of a coil microphone. In addition, the possibility is raised that the two CD discs act like a capacitor and are placed under an electric field by current connections. Then you can use the discs as a condenser microphone.

The state of the art according to the DE 203 01 699 U1 The combination of a capacitor unit and a plunger coil unit for the respective sampling of vibrations of the associated membrane is already addressed in general. However, the said units are obviously deployed and used alternatively to each other and not simultaneously.

In the generic state of the art according to CN 208798146 U is a waterproof intelligent microphone with the structure described above. The aim is to reduce overall background noise when recording vocals.

The further state of the art after U.S. 2009/0238392 A1 deals with a dynamic microphone of comparable construction. The main concern here is to be able to detect low frequencies.

The CN 109257669A also deals with a microphone comparable to the structure described above, in which a structural unit with two different levels of performance is realized inside.

They are comparable CN 205320229 U , CN 208798146 U , CN 207410477 U and finally CN 205320231 U before.

In practice, however, there are often requirements to the effect that the on When recording music, for example, or in connection with live performances, both a detailed recording with a large frequency range and one with which a large dynamic with regard to the occurring sound pressure is to be displayed is desired. This generally applies to all genres, i.e. classical concerts, rock and pop concerts as well as jazz concerts, but also comedy performances or even theater performances, radio plays, etc. Such requirements arise, for example, if the live performance is to be recorded at the same time. For this reason, in practice and in such a case, condenser microphones and coil microphones or dynamic microphones are often used in parallel. This is particularly complex because, for example, separate microphone stands, electrical power supplies, etc. are required in each case. In addition, mixing the signals is time-consuming because each microphone occupies its own channel on a mixing console. After all, the financial outlay is high, since a music band or an orchestra, for example, has to purchase and store the various types of microphones. This is where the invention aims to remedy the situation overall.

The invention is based on the technical problem of further developing such a microphone device in such a way that it is suitable for both studio and live performances and enables frequency reproduction that is just as rich in detail as it is suitable for high sound pressure levels.

To solve this technical problem, a generic microphone device is characterized within the scope of the invention in that the condenser unit and the voice coil unit each have a vent hole.

Within the scope of the invention, the advantages of the classic condenser microphone on the one hand and of the voice coil microphone on the other hand are combined. Because the condenser membrane interacts with the condenser unit and in this context acts like a condenser microphone. In this case, deformations and movements of the capacitor membrane are converted into electrical signals by the capacitor unit, as described above. For this purpose, the condenser unit is typically composed of an upper condenser plate coupled to the condenser membrane and a lower condenser plate.

As soon as the capacitor membrane vibrates, these correspond to corresponding movements of the upper capacitor plate compared to the lower capacitor plate, which are represented as changes in capacitance of the capacitor formed in this way when electrical voltage is applied. These changes in capacitance are available as an output signal from the microphone device according to the invention.

The additional plunger coil unit for scanning vibrations of the coil membrane is implemented next to it and is locally and functionally independent. Any interactions between the two units can be reduced to a minimum as a result of the spatially and functionally separate design of the coil membrane, including the voice coil unit, from the condenser membrane, including the condenser unit. In fact, the moving coil unit works in such a way that movements of the coil membrane are transmitted to a coil. This coil moves in the field of a stationary permanent magnet, so that depending on the membrane movements, a corresponding current is induced in the coil. The signal from the plunger coil unit is available on the output side of the microphone device and is independent of the signal from the capacitor unit.

In general, both signals can also be mixed with one another. In this case, a common output is then available in addition to the separate outputs of the capacitor unit on the one hand and the voice coil unit on the other hand. A mixing unit is typically connected upstream of this common output. Frequency filters in the form of bandpass filters, for example, can be provided in this mixing unit, with the help of which individual frequency ranges are only used by the capacitor unit and others only by the voice coil unit for the subsequently mixed signal. In addition, the mixing unit can be equipped with an attenuator, with the help of which the dynamics of the signal from the plunger coil unit can be limited as required. Of course, in this context it is possible and conceivable that the bandpass filter in question and also the attenuator can be set from the outside and, if necessary, changed.

According to a further advantageous embodiment, the two membranes are arranged in a common housing. It has proven useful if the two membranes are placed underneath a protective cover on the head side of the housing. The two membranes can be formed concentrically to a common central axis. The invention is based on the finding that the housing enclosing the microphone device in question is typically designed to be rotationally symmetrical to the central axis in question. In addition, the two membranes can be ring-shaped compared to the central axis in question and in common.

In doing so, one will usually proceed in such a way that the condenser membrane is arranged centrally and the coil membrane is arranged peripherally compared to the central axis. This design takes into account the fact that a relatively large area of the capacitor membrane is usually required for the capacitor unit, whereas the plunger coil unit or its associated coil membrane generally does not require such a large surface area. This applies in any case if and when the coil membrane and the associated plunger coil unit are used to reproduce predominantly large volumes and thus sound pressure levels.

For this purpose, the capacitor membrane is generally circular in design, while the coil membrane is designed to enclose the capacitor membrane in the form of a ring. Of course, other embodiments are also conceivable, for example such that the central capacitor membrane is surrounded in the form of a ring by a plurality of coil membranes arranged peripherally.

In addition, it has proven to be particularly advantageous if the capacitor unit and the plunger coil unit are electromagnetically separated from one another. For this purpose and for electromagnetic isolation, a metal shield is usually provided between the capacitor unit and the voice coil unit. With the help of this metal shielding it is ensured that magnetic field lines of the mostly ring-shaped permanent magnet cannot penetrate as far as the capacitor unit and lead to undesirable electromagnetic interference here. In addition, it has proven to be particularly advantageous if both the plunger coil unit and the capacitor unit are each suspended or arranged in the interior of the housing such that they can oscillate. In fact, vibration dampers can be interposed at this point in order to absorb shocks or handling movements acting on the housing in particular and to prevent them from interfering with the electrical signal generated.

Finally, the design according to the invention is such that both the capacitor unit and the plunger coil unit each have a vent hole. This vent hole is necessary to ensure that the respective cone can move freely and follow the impinging sound. Any pressure that builds up inside the housing is diverted to the outside through these ventilation holes and the pressure is relieved.

As a result, a microphone device is made available which combines the advantages of a condenser microphone with those of a coil microphone or moving coil microphone in a surprisingly simple manner. By using a common housing, technological synergies are observed, which at the same time simplify handling with just a single microphone stand. This also applies to the production, so that the price of the microphone device according to the invention is significantly lower than that of the sum of the condenser microphone and the coil microphone. This is where the main advantages can be seen.

• 1 einen schematischen Längsschnitt durch die erfindungsgemäße Mikrofoneinrichtung und
• 2 einen schematischen Querschnitt durch den Gegenstand nach 1.

The invention is explained in more detail below with reference to a drawing that merely represents an exemplary embodiment; show it:

• 1 a schematic longitudinal section through the microphone device according to the invention and
• 2 a schematic cross section through the object 1 .

A microphone device is shown in the figures, which first of all has a ring-shaped pot-like housing 1 . The housing 1 is designed to be rotationally symmetrical in relation to an axis or central axis A. In addition, a protective cover 2 covering the head end of the housing 1 is implemented. The housing 1 may be made of metal. The protective cover 2 is a protective grid or a protective membrane, which is permeable in any case for impinging sound.

The microphone device realized in this way is equipped with at least one membrane 3, 4 and a condenser unit 5, 6 and an additional voice coil unit 7, 8. With the help of the capacitor unit 5, 6, vibrations of the membrane 3, 4 are sampled, specifically a capacitor membrane 3. In contrast, the plunger coil unit ensures the sampling of vibrations of a further and independent membrane 4, namely a coil membrane 4.

According to the invention, the condenser membrane 3 interacting with the condenser unit 5, 6 and the coil membrane 4, which is locally and functionally separate therefrom, are realized and provided for interaction with the plunger coil unit 7, 8. Like the two membranes 3, 4, the capacitor unit 5, 6 and the plunger coil unit 7, 8 are also separated from one another in terms of location and function, as will be explained in more detail below.

It can be seen that the two membranes 3 , 4 are arranged in the common housing 1 . In addition, the two membranes 3, 4 are placed below the head-side protective cover 2 of the housing 1. The two membranes 3, 4 are also formed concentrically to the common axis or central axis A. Consequently, the membranes 3, 4 as well as the housing 1 and the capacitor unit 5, 6 as well as the plunger coil unit 7, 8 are each designed to be rotationally symmetrical to the relevant axis or central axis A.

The two membranes 3, 4 are also concentric to the central axis A in question and are ring-shaped in comparison thereto. In the exemplary embodiment, the capacitor membrane 3 is located in the center or centrally, whereas the coil membrane 4 is arranged peripherally opposite.

In fact, according to the exemplary embodiment, the capacitor membrane 3 is of circular design, whereas the coil membrane 4 encloses the capacitor membrane 3 in the form of a ring. In principle, it is also conceivable that a plurality of different coil membranes 4 are provided, which are designed to surround the circular capacitor membrane 3 on the outer peripheral side thereof. However, this is not shown in detail.

As already explained, the capacitor unit 5, 6 and the plunger coil unit 7, 8 are locally separated from one another. For this purpose, the capacitor unit 5, 6 is arranged centrally in the housing 1 and the plunger coil unit 7, 8, in contrast, is arranged peripherally. There is also a functional separation such that the capacitor unit 5, 6 and the moving coil unit 7, 8 are electromagnetically separated from one another. This is ensured by an interposed metal shield 9.

Based on the sectional view in the 1 one can see that the metal shielding 9 for the electromagnetic separation of the capacitor unit 5, 6 from the voice coil unit 7, 8 encloses the capacitor unit 5, 6 in a ring. As a result, any magnetic field lines or electromagnetic fields emanating from the plunger coil unit 7, 8 cannot adversely affect the functioning of the capacitor unit 5, 6 and the electrical signal generated thereby.

The capacitor unit 5, 6, like the moving coil unit 7, 8, has an associated ventilation hole 10, 11. In fact, a central ventilation hole 10 is provided for the capacitor unit 5, 6 and, in addition, a radial ventilation hole 11 for the moving coil unit 7, 8.

Based on the sectional view in the 1 it can be seen that the capacitor unit 5, 6 is composed in detail of an upper capacitor plate 5 and a lower capacitor plate 6. Both capacitor plates 5, 6 are adapted in size to the diameter of the associated capacitor membrane 3. In this case, the upper capacitor plate 5 is mechanically connected to the capacitor membrane 3 so that vibrations of the capacitor membrane 3 correspond to associated vibrations of the upper capacitor plate 5 . These oscillations or movements of the upper capacitor plate 5 lead to changes in the capacitance of the capacitor 5, 6 formed from the two capacitor plates 5, 6 an electrical energy source integrated into the housing 1, for example a battery or an accumulator.

In contrast, the plunger coil unit 7 has an annular coil 7 that is mechanically connected to the coil membrane 4 . As a result, the ring-shaped coil 7 follows movements of the coil membrane 4 as soon as the coil membrane 4 is hit by sound. The ring-shaped coil 7 is designed concentrically in comparison to the axis or central axis A. This also applies to a permanent magnet 8 surrounding the coil 7 . Since the coil 7 moves relative to the stationary permanent magnet 8 , voltage is induced in the coil 7 , which reflects the movement of the coil 7 in the magnetic field generated by the permanent magnet 8 . The signal resulting in this way is made available via a connection or a further line 13 and can be tapped off.

Since the metal shielding 9 also encloses the capacitor unit 5, 6 in a ring concentrically to the axis or central axis A, electromagnetic interference from the voice coil unit 7, 8 is thereby shielded and the signal made available at the output or the output line 12 of the capacitor unit 5, 6 do not bother. Additional damping elements 14, typically provided radially on the circumference between the housing 1 and the magnet 8, ensure that any impact stresses on the housing 1 are absorbed and do not damage the capacitor unit 5, 6 or the plunger coil unit 7, 8.

The wiring diagram shown makes it clear that both the output line 13 for the plunger coil unit 7, 8 and the output line 12 for the capacitor unit 5, 6 can be used separately and separately from one another. But there is also the possibility to superimpose the signals of both lines 12, 13 in an indicated mixing unit 15. For this purpose, the two signals are mixed or superimposed with one another inside the mixing unit 15 , taking into account one or more bandpass filters 16 and optionally an attenuation element 17 . The design is such that, for example, individual frequency ranges originate predominantly from the signal from the capacitor unit 5, 6 and other frequency ranges predominantly from that of the plunger coil unit 7, 8. With the help of the additional damping unit 17, an adaptation to the different sound pressure or the dynamics can be carried out. As a result of this, another output line 18 is available on the output side of the mixing unit 15, which makes a corresponding and superimposed signal available to the capacitor unit 5, 6 and the voice coil unit 7, 8.

Claims (9)

Microphone device, with at least one membrane (3, 4) and a capacitor unit (5, 6) assigned to the membrane (3, 4) for scanning vibrations of the membrane (3, 4), and with an additional plunger coil unit (7, 8) for additional scanning of vibrations of the diaphragm (3, 4), with a condenser diaphragm (3) interacting with the condenser unit (5, 6) and a coil diaphragm (4) locally and functionally separate therefrom being provided for interaction with the plunger coil unit (7, 8). , characterized in that the capacitor unit (5, 6) and the plunger coil unit (7, 8) each have a vent hole (10, 11). setup after claim 1 , characterized in that the two membranes (3, 4) are arranged in a common housing (1). setup after claim 1 or 2 , characterized in that the two membranes (3, 4) are placed below a head-side protective cover (2) of the housing (1). Setup according to one of Claims 1 until 3 , characterized in that the two membranes (3, 4) are concentric to a common central axis (A). Setup according to one of Claims 1 until 4 , characterized in that the two membranes (3, 4) are annular compared to the common central axis (A). Setup according to one of Claims 1 until 5 , characterized in that the condenser membrane (3) is arranged centrally and the coil membrane (4) is arranged peripherally. Setup according to one of Claims 1 until 6 , characterized in that the capacitor membrane (3) is circular and the coil membrane (4) is designed to enclose the capacitor membrane (3) in the form of a ring. Setup according to one of Claims 1 until 7 , characterized in that the capacitor unit (5, 6) and the plunger coil unit (7, 8) are electromagnetically separated from each other. setup after claim 8 , characterized in that a metal screen (9) is provided for electromagnetic separation.

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