JP2013182911A - Transformer for microphone - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a transformer for a microphone that has an improved structure effectively reducing stress applied to a core to eliminate the deterioration of magnetic characteristics of the core and increasing the shield effect against induction field even when a mechanical impact force resulting from falling etc. is applied.SOLUTION: A transformer for a microphone includes: a transformer 20 having a core 21 made of a high permeable magnetic material and a coil 22 wound around the core 21; a shield case 50 incorporating the transformer 20 and enclosing a periphery of the transformer 20; and conductive clothes 62, 64 that are disposed between an inner surface of the shield case 50 and the core 21, contacts with the inner surface of the shield case 50 and the core 21, and electrically connects the shield case 50 with the core 21.

Description

  The present invention relates to a microphone transformer capable of obtaining an excellent shielding effect.

  Since the output signal of the microphone is weak, an output transformer may be used for boosting and outputting, or for converting the impedance to an appropriate value and outputting it. In particular, it can be said that it is essential to use a transformer for boosting in a ribbon microphone.

  Since it is desirable that the microphone transformer is as small as possible, a high-permeability permalloy or the like is used as the core material. A high permeability material such as Permalloy has a difficulty in deteriorating magnetic properties when mechanical stress is applied due to impact caused by dropping. In addition, there is a problem that the magnetic characteristics are deteriorated by applying a thermal stress by soldering or the like.

  When a microphone transformer is used, hum noise is mixed in the output signal of the microphone by applying an induction magnetic field from a commercial AC power supply or the like from the outside. Noise is also mixed in the output signal by an induced magnetic field from other than a commercial AC power source. Therefore, the microphone transformer is incorporated in the shield case. As the material of the shield case, a high permeability material such as permalloy having a high shielding effect against the induction magnetic field is used.

  3 and 4 show an example of a conventional microphone transformer incorporated in a shield case. 3 and 4, the microphone transformer 20 includes a core 21 and a coil 22 wound around the core 21. The core 21 is made of a high magnetic permeability material such as permalloy. The coil 22 includes a primary coil and a secondary coil, but the primary coil and the secondary coil are not distinguished in the drawing. As shown in FIG. 3, two terminals 23 connected to both ends of the primary coil extend from the transformer 20, and three terminals 25 connected to both ends of the secondary coil and the center tap as shown in FIG. Is extended. Balance output is possible by providing the secondary coil with a center tap.

  The transformer 20 is incorporated in the shield case 30 and surrounded by the shield case 30. The shield case 30 includes an upper shield case and a lower shield case. The upper shield case is composed of an outer case 31 and an inner case 32 with the cup turned down, and the lower shield case is composed of a cup-shaped outer case 33 and an inner case 34. The upper and lower outer cases 31 and 33 have an open end fitted together to form a sealed space, and the upper and lower inner cases 32 and 34 also have an open end fitted together to form a sealed space. The transformer 20 is disposed in a space formed by the upper and lower inner cases 32 and 34. Spaces are formed at predetermined intervals between the upper and lower outer cases 31 and 33 and between the upper and lower inner cases 32 and 34, respectively. The upper and lower inner and outer cases 31, 32, 33, and 34 are integrally coupled electrically and mechanically.

  The shield case 30 is placed on the circuit board 40 in such a posture that the outer case 33 constituting the lower shield case becomes a bottom plate. A part of the open end of the outer case 31 constituting the upper shield case extends to the circuit board 40 and is connected to the ground pattern of the circuit board 40 by soldering or the like. The two terminals 23 on the primary coil side and the three terminals 25 on the secondary coil side penetrate through the holes of the inner and outer cases 34 and 33 without contacting the cases 34 and 33, and further, the circuit. It penetrates the substrate 40 and is connected to a predetermined circuit pattern of the circuit substrate 40 by soldering or the like.

  As described above, since the microphone transformer 20 is double-shielded by the inner and outer shield cases, the shielding effect against the external induced magnetic field is enhanced. Further, when the core 21 of the transformer 20 is grounded together with the shield case, the shielding effect is further enhanced, and noise generated due to the induced magnetic field can be suppressed to a low level. Therefore, the core 21 and the shield case constituent member, for example, the lower inner case 34 are connected by the conductive wire 24 so that the core 21 and the shield case have the same potential. Both ends of the conducting wire 24 are connected to the core 21 and the inner case 34 by soldering. In order to ensure the shielding effect against the external induction magnetic field, it is desirable that the inner and outer shield cases are electrically connected securely.

  As described above, the core 21 made of a high magnetic permeability material such as permalloy has a problem in that the magnetic properties are deteriorated when mechanical stress such as impact caused by dropping is applied. In the conventional microphone transformer shown in FIGS. 3 and 4, no countermeasure is taken when mechanical stress is applied. Further, as described above, the core 21 made of a high permeability material such as permalloy has a problem that the magnetic characteristics are deteriorated even when a thermal stress is applied. When soldering, thermal stress is applied, and there is a problem that the magnetic properties deteriorate.

  Even when the shield case is made of a high magnetic permeability material such as permalloy, if a mechanical stress such as an impact due to dropping is applied to the shield case, the magnetic properties of the shield case are deteriorated and the shielding effect is also lowered. However, according to the conventional microphone transformer, no countermeasure is taken against the deterioration of magnetic characteristics when mechanical stress is applied to the shield case.

  As a prior art related to the invention of the present application, a conductive cloth is placed on a ground pattern of a circuit board built in a microphone, and a core of an output transformer is arranged on the conductive cloth, and the output transformer is interposed through the conductive cloth. A microphone having a grounded core is known (see Patent Document 1). Patent Document 1 also describes providing a second conductive cloth that covers the output transformer and is in contact with the inner peripheral surface of the microphone case.

Japanese Patent No. 4711768

  According to the microphone described in Patent Document 1, a core caused by mechanical stress when an impact or the like is applied due to a buffering effect of a conductive cloth interposed between a ground pattern of a circuit board and a core of a transformer. This has the effect of reducing the deterioration of the magnetic characteristics. However, if the conductive cloth is interposed between the ground pattern of the circuit board and the core of the transformer, the buffering effect is limited, and the effect of reducing the deterioration of the magnetic properties of the core due to mechanical stress such as impact is not sufficient. I found that there was no. Furthermore, just covering the output transformer with the second conductive cloth in contact with the inner peripheral surface of the microphone case has a limited shielding effect against the induced magnetic field, and it is found that the structure needs to be devised to further enhance the shielding effect. It was.

  The present invention solves the above-mentioned problems of the prior art, that is, even when a mechanical impact force is applied due to dropping or the like, the stress applied to the core is effectively reduced and the magnetic characteristics of the core are not deteriorated. Another object of the present invention is to provide a microphone transformer whose structure is devised so as to increase the shielding effect against the induction magnetic field.

A microphone transformer according to the present invention includes:
A transformer having a core made of a high magnetic permeability material and a coil wound around the core;
A shield case containing the transformer and surrounding the transformer;
A conductive cloth interposed between the inner surface of the shield case and the core and electrically connecting the shield case and the core in contact with the inner surface of the shield case and the core;
It has the most important feature.

  Since the conductive cloth is interposed between the inner surface of the shield case and the core, even if mechanical stress is applied to the core due to dropping of the microphone, etc., the conductive cloth acts as a cushioning material, and the mechanical stress applied to the core is reduced. It is reduced. Since the shield case and the core are electrically connected by the conductive cloth, and there is no need to solder when the shield case and the core are electrically connected, no thermal stress is applied to the core, and the magnetic characteristics of the core are reduced. Deterioration can be eliminated. The transformer is surrounded by a shield case, a conductive cloth is interposed between the inner surface of the shield case and the core, and the conductive cloth electrically connects the shield case and the core. In combination with this, it is possible to obtain a large shielding effect against the induced magnetic field.

It is a partial cross section front view which shows the Example of the transformer for microphones which concerns on this invention. It is a partial cross section side view of the said Example. It is a partial cross section front view which shows the example of the conventional transformer for microphones. It is a partial cross section left view of the said prior art example.

  Embodiments of a microphone transformer according to the present invention will be described below with reference to FIGS. In addition, the same code | symbol is attached | subjected to the same component as the structure of the prior art example shown in FIG. 3, FIG.

  1 and 2, the microphone transformer 20 includes a core 21 and a coil 22 wound around the core 21. The core 21 is made of a high magnetic permeability material such as permalloy. The coil 22 includes a primary coil and a secondary coil, but the primary coil and the secondary coil are not distinguished in the drawing. As shown in FIG. 1, two terminals 23 connected to both ends of the primary coil extend from the transformer 20, and three terminals 25 connected to both ends of the secondary coil and the center tap as shown in FIG. Is extended. Balance output is possible by providing the secondary coil with a center tap.

  The transformer 20 is incorporated in the shield case 50 and surrounded by the shield case 50. The shield case 50 includes an upper shield case and a lower shield case. The upper shield case is composed of an outer case 31 and an inner case 32 having a rectangular cup face down, and the lower shield case is composed of a rectangular cup-shaped outer case 33 and an inner case 34. The upper and lower outer cases 31 and 33 constitute an outer shield case 51 having a rectangular parallelepiped shape with the opening ends fitted together. The upper and lower inner cases 32, 34 also constitute an inner shield case 52 made of a rectangular parallelepiped with the opening ends fitted together.

  In the inner shield case 52, the front and rear of the lower inner case 34 and the inner surfaces of the left and right peripheral walls are fitted to the front and rear and left and right peripheral wall outer surfaces of the upper inner case 32 at appropriate intervals, so The conductive cloth 72, 74 (see FIG. 2), and the conductive cloth 66, 68 (see FIG. 1) is interposed in the space between the left and right. Each of the above-mentioned conductive cloths is, for example, woven or entangled in a cloth-like shape obtained by conducting conductive plating on the surface of fine-line polyethylene terephthalate (PET), and has a certain thickness. The thickness of each of the conductive cloths 72, 74, 66, 68 in a natural state where no external force is applied is thicker than the distance between the inner cases 32, 43 at the positions where these conductive cloths are disposed, Due to the elasticity of the cloth, the inner cases 32 and 34 are electrically connected by being pressed against each other between the peripheral walls of the inner cases 32 and 34.

  The outer shield case 51 and the inner shield case 52 constitute a sealed space inside. The transformer 20 is disposed in the inner space of the inner shield case 52 constituted by the upper and lower inner cases 32 and 34.

  A space is formed between the outer shield case 51 and the inner shield case 52 at a predetermined interval. More specifically, each of the inner surfaces of the upper, lower, front, back, left and right six surfaces of the outer shield case 51 constituting the rectangular parallelepiped, and the upper, lower, front, rear, and left and right six surfaces of the inner shield case 52 constituting the rectangular parallelepiped. A space is formed between the outer side surfaces at a predetermined interval.

  A conductive cloth 61 is interposed between the upper inner surface of the outer shield case 51 and the upper outer surface of the inner shield case 52. The conductive cloth 61 has a thickness dimension in a natural state in which no external force is applied, and is larger than the distance between the upper inner surface of the outer shield case 51 and the upper outer surface of the inner shield case 52, and the conductive cloth 61 has. It is compressed to the above-mentioned distance by elasticity and arranged within the above-mentioned distance. Therefore, the conductive cloth 61 is in pressure contact with the upper inner surface of the outer shield case 51 and the upper outer surface of the inner shield case 52 by its elasticity, and electrically connects the outer shield case 51 and the inner shield case 52.

In the same manner as the conductive cloth 61,
A conductive cloth 63 is provided between the lower inner surface of the outer shield case 51 and the lower outer surface of the inner shield case 52.
A conductive cloth 65 is provided between the right inner surface of the outer shield case 51 and the right outer surface of the inner shield case 52.
A conductive cloth 67 is provided between the left inner surface of the outer shield case 51 and the left outer surface of the inner shield case 52.
A conductive cloth 71 is provided between the front inner surface of the outer shield case 51 and the front outer surface of the inner shield case 52.
Conductive cloth 73 is interposed between the rear inner surface of the outer shield case 51 and the rear outer surface of the inner shield case 52.

  Each of the conductive cloths 63, 65, 67, 71, 73 has a thickness in a natural state in which an external force is not applied, rather than a distance between the outer shield case 51 and the inner shield case 52 at a position where these conductive cloths are disposed. The size is large, and the respective conductive cloths are compressed to the interval by the elasticity of the conductive cloths and are arranged within the interval. Therefore, each of the conductive cloths is pressed against the inner side surfaces of the outer shield case 51 and the outer side surfaces of the inner shield case 52 by its elasticity to electrically connect the outer shield case 51 and the inner shield case 52. .

  A conductive cloth 62 is attached to the upper inner surface of the upper inner case 32 constituting the inner shield case 52, that is, the ceiling surface. The conductive cloth 62 is brought into pressure contact with the upper inner surface of the inner case 32 and the upper end surface of the core 21 of the transformer 20 by elasticity in the thickness direction, thereby electrically connecting the inner case 32 and the core 21. A conductive cloth 64 is attached to the lower inner surface, that is, the inner bottom surface of the lower inner case 34 constituting the inner shield case 52. The conductive cloth 64 is in pressure contact with the lower inner surface of the inner case 34 and the lower end surface of the core 21 of the transformer 20 by elasticity in the thickness direction, thereby electrically connecting the inner case 32 and the core 21.

  In the shield case 50, the outer case 33 is placed on the circuit board 40 so that the outer case 33 constituting the outer shield case 51 becomes a bottom plate. The two terminals 23 on the primary coil side and the three terminals 25 on the secondary coil side penetrate through the holes of the inner and outer cases 34 and 33 without contacting the cases 34 and 33, and the circuit board. 40 is connected to a predetermined circuit pattern of the circuit board 40 by soldering or the like. A part of the open end of the outer case 31 constituting the outer shield case 51 reaches the circuit board 40 and is connected to a ground pattern formed on the circuit board 40 by soldering or other appropriate means.

  Since the shield case 50 is configured as described above, the upper and lower inner and outer cases 31, 32, 33, and 34 are integrated electrically and mechanically by fitting the cases together and interposing a conductive cloth. Is bound to.

  According to the embodiment described above, the conductive cloth is provided between the inner surface of the shield case 50 in which the transformer 20 is built and surrounds the transformer 20, specifically, the inner surface of the inner shield case 52 and the core 21 of the transformer 20. 62 is interposed, and the conductive cloth 62 is in contact with the inner surface of the inner shield case 52 and the core 21 to electrically connect the inner shield case 52 and the core 21. Therefore, it is not necessary to solder the shield case and the core 21 of the transformer 20 to have the same potential to provide a shielding effect, and the problem of deteriorating the magnetic characteristics of the core 21 made of a high permeability material due to thermal stress is eliminated. can do.

  The conductive cloth 62 is interposed between the inner case 32 constituting the inner shield case 52 and the core 21 of the transformer 20, and the lower conductive cloth 64 constitutes the inner shield case 52 and the transformer 20. Therefore, when an impact or the like is applied, the cushioning effect of the conductive cloths 62 and 64 has an effect of reducing the deterioration of the magnetic properties of the core 21 due to mechanical stress. .

  The shield case 50 has a double structure of an outer shield case 51 and an inner shield case 52. Further, the outer shield case 51 and the inner shield case 52 formed of a hexahedron have almost all the six surfaces inward and outward except for corner portions and limited portions such as escape holes for the terminals 23 and 25 of the transformer 20. Since it is shielded by the conductive cloth arranged heavy, the shielding effect with respect to the transformer 20 arranged in the shield case 50 is enhanced. Furthermore, since the outer shield case 51 and the inner shield case 52, the core 21 of the transformer 20, and the ground pattern of the circuit board 40 have the same potential through each conductive cloth, the shielding effect can be enhanced from this point.

  In the embodiment shown in FIGS. 1 and 2, the periphery of the inner cases 32 and 34 are mechanically and electrically coupled together via conductive cloths 72, 74, 66 and 68. By doing so, the area of the conductive cloth 72, 74, 66, 68 can be increased. However, the opening end surfaces of the inner cases 32 and 34 are directly fitted together to form the inner shield case 52, and the conductive cloth 72, 74, 66, and 68 are pasted on the front, rear, left and right inner surfaces of the inner shield case 52. There may be. In addition, the design can be arbitrarily changed without departing from the technical scope described in the claims.

  The microphone transformer according to the present invention is applicable to any type of microphone such as a ribbon type, a condenser type, and a dynamic type, regardless of the type of the microphone.

20 transformer 21 core 22 coil 31 outer case 32 inner case 33 outer case 34 inner case 40 circuit board 50 shield case 51 outer shield case 52 inner shield case 61 conductive cloth 62 conductive cloth

Claims (7)

A transformer having a core made of a high magnetic permeability material and a coil wound around the core;
A shield case containing the transformer and surrounding the transformer;
A microphone transformer comprising: an inner surface of the shield case and a core; and a conductive cloth that is in contact with the inner surface of the shield case and electrically connects the shield case and the core. .   The microphone transformer according to claim 1, wherein the shield case has a double structure including an outer shield case and an inner shield case.   3. The microphone transformer according to claim 1, wherein the shield case is a rectangular parallelepiped, and conductive cloths are arranged on six inner surfaces forming the rectangular parallelepiped.   A conductive cloth is interposed between the outer shield case and the inner shield case, and the conductive cloth is in contact with the outer shield case and the inner shield case to electrically connect the outer shield case and the inner shield case. Item 4. The microphone transformer according to Item 2 or 3.   Both the outer shield case and the inner shield case form a rectangular parallelepiped, and conductive cloths are interposed between the inner six surfaces of the outer shield case and the outer six surfaces of the inner shield case, respectively, The microphone transformer according to claim 2, 3 or 4, wherein a conductive cloth is also disposed on an inner surface of the inner shield case.   6. The microphone transformer according to claim 2, wherein each of the outer shield case and the inner shield case includes two cup-shaped cases in which opening end portions are fitted together. 7. The microphone transformer according to claim 3, wherein one surface of the outer shield case made of a rectangular parallelepiped is disposed on the circuit board in contact with the ground pattern of the circuit board.

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