JP2017200142A - Microphone frequency filter device and microphone - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a microphone frequency filter device and a microphone which can easily and continuously change a cutoff frequency with a simple configuration.SOLUTION: A frequency filter device (F) is for filtering a signal output from a microphone unit (50) of a microphone (1). A transformer (90), and a magnetic field applying section (102) for applying a magnetic field to the magnetic path of the transformer are included. The transformer includes a coil (96), a first core (93a), and a second core (93b). A magnetic flux of a first magnetic path (M1) formed by the first core is larger than a magnetic flux of a second magnetic path (M2) formed by the second core. The magnetic field applying section applies a magnetic field to the second magnetic path.SELECTED DRAWING: Figure 2

Description

  The present invention relates to a microphone frequency filter device and a microphone.

  The microphone generates noise (vibration noise) when vibration is applied, and generates noise (wind noise) when wind is applied. Among microphones, dynamic microphones are easily affected by vibration and wind, and are susceptible to vibration noise and wind noise. In general, vibration noise and wind noise appear on the low frequency side of the frequency response. Therefore, in the microphone, a low cut is performed to remove a low frequency response with a filter or the like.

  A dynamic microphone usually does not contain an electronic circuit. Therefore, the low cut is performed, for example, by a system in which a passive element such as a capacitor that cuts a low band is connected in series to the signal path. However, with this method, the output impedance of the microphone increases at a low frequency response.

  As a low-cut method that does not use a capacitor, there is a method in which an inductor is connected in parallel to a signal path. However, in this method, since a large inductor is used, it is difficult to reduce the size of the microphone. In this method, the cut-off frequency of the low cut cannot be continuously varied.

  In the past, a technology has been proposed in which a low-cut cutoff frequency is continuously varied by adjusting the degree of magnetic coupling of the core of the step-up transformer in a ribbon microphone that is a kind of dynamic microphone (for example, , See Patent Document 1).

JP 2009-267539 A

  However, in the technique disclosed in Patent Document 1, a core, an adjusting screw, an elastic material, and the like divided into a step-up transformer that performs low cut are used. Therefore, the structure of the step-up transformer is complicated. Further, since the cut-off frequency is adjusted depending on the size of the small gap between the divided cores, it is difficult to finely adjust the cut-off frequency.

  The present invention has been made to solve the above-mentioned problems of the prior art, and has a simple configuration, a microphone frequency filter device and a microphone, which can easily and continuously vary the cutoff frequency. The purpose is to provide.

  The present invention is a frequency filter device that filters a signal output from a microphone unit of a microphone, and includes a transformer and a magnetic field applying unit that applies a magnetic field to a magnetic path of the transformer. The first magnetic path formed by the first core is larger than the second magnetic path formed by the second core, and the magnetic field application unit includes the second magnetic path. A magnetic field is applied to the path.

  According to the present invention, the cut-off frequency can be changed easily and continuously with a simple configuration.

It is a front view which shows embodiment of the microphone concerning this invention. FIG. 2 is a cross-sectional view of the microphone of FIG. 1 taken along line AA. FIG. 3 is an exploded cross-sectional view of the microphone of FIG. 2. It is a front view of the transformer with which the microphone of Drawing 1 is provided. FIG. 5 is a bottom view of the transformer of FIG. It is a front view of the coil with which the transformer of FIG. 4 is provided. It is a bottom view of the coil of FIG. It is a front view of the 1st magnetic material with which the transformer of Drawing 4 is provided. It is a bottom view of the first magnetic material of FIG. It is a front view of the 2nd magnetic material with which the transformer of Drawing 4 is provided. It is a bottom view of the 2nd magnetic material of FIG. It is a schematic diagram of the frequency filter apparatus for microphones concerning the present invention when the switch with which the microphone of Drawing 1 is provided is ON. It is a schematic diagram of the frequency filter apparatus for microphones concerning this invention when the switch of FIG. 12 is OFF. It is a graph of the frequency response of a microphone when the switch of FIG. 12 is moved from ON to OFF.

  Hereinafter, embodiments of a microphone frequency filter device and a microphone according to the present invention will be described with reference to the drawings.

● Microphone ●
First, an embodiment of a microphone according to the present invention will be described.

Microphone Configuration FIG. 1 is a front view showing an embodiment of a microphone according to the present invention.
The microphone 1 collects sound waves from a sound source (not shown). The microphone 1 is a handheld microphone.

FIG. 2 is a cross-sectional view of the microphone 1 of FIG.
FIG. 3 is an exploded sectional view of the microphone 1.
The microphone 1 includes a grip housing 10, a head case 20, a head case mounting member 30, a mounting screw 40, a microphone unit (hereinafter referred to as “unit”) 50, a unit holder 60, and a first elastic body 70. And a second elastic body 80, a transformer 90, a switch 100, an output connector 110, and a name ring 120.

  In the following description, the forward direction is the direction on the side (upper side in FIG. 2) where the microphone 1 is directed to the sound source during sound collection. The rear direction is the direction opposite to the front side (the lower side in the drawing of FIG. 2).

  The grip housing 10 functions as a grip for the microphone 1. The grip housing 10 is made of metal such as brass, for example. The grip housing 10 is manufactured by die casting, for example. The grip housing 10 is cylindrical. The grip housing 10 includes a fixed portion 11, a connector storage portion 12, and a switch mounting portion 13.

  The fixing part 11 fixes the head case mounting member 30. The fixing portion 11 is disposed on the front end side of the grip housing 10. The fixing portion 11 includes a screw insertion hole 11h. The screw insertion hole 11h is a hole through which the attachment screw 40 is inserted.

  The connector storage unit 12 stores the output connector 110. The connector storage portion 12 is disposed on the rear end side of the grip housing 10. The inner diameter of the connector housing 12 is smaller than the inner diameter of other parts of the grip housing 10. The connector storage portion 12 includes a tool insertion hole 12h. The tool insertion hole 12h will be described later.

  The switch mounting portion 13 supports the switch 100 so as to be slidable in the front-rear direction (the vertical direction in FIG. 2). The switch mounting portion 13 is disposed at a substantially central portion in the front-rear direction of the grip housing 10.

  The head case 20 houses the unit 50 and protects the unit 50 from dust and wind. The head case 20 includes a case portion 21 and a case fixing portion 22.

  The case part 21 protects the unit 50 from dust and wind. The case portion 21 has, for example, a three-layer structure of a steel outer grill, a metal mesh (not shown), and a urethane foam (not shown). The case portion 21 has a barrel shape having an opening at the rear end. The case fixing part 22 fixes the case part 21 to the head case mounting member 30. The case fixing part 22 has a ring shape. The case fixing part 22 is attached to the rear end (opening end) of the case part 21. The case fixing portion 22 includes a female screw portion 22a. The female screw portion 22 a is disposed on the inner peripheral surface of the case fixing portion 22.

  The head case attachment member 30 attaches the head case 20 to the grip housing 10. The head case mounting member 30 is made of metal such as brass, for example. The head case mounting member 30 has a bottomed cylindrical shape. The head case mounting member 30 includes a male screw portion 30a and a female screw hole 30h. The male screw portion 30 a is disposed on the outer peripheral surface of the front end of the head case mounting member 30. The female screw hole 30 h is disposed on the peripheral wall at the center of the head case mounting member 30. The bottom surface 31 of the head case mounting member 30 includes a support hole 31 h in the center of the bottom surface 31. The support hole 31 h supports the unit holder 60.

  The mounting screw 40 fixes the head case mounting member 30 to the grip housing 10. The mounting screw 40 is, for example, a countersunk screw.

  The unit 50 collects sound waves from the sound source and outputs an electrical signal corresponding to the collected sound waves. The unit 50 is, for example, a unidirectional dynamic microphone unit.

  The directivity of the unit 50 is not limited to unidirectionality. Further, the type of the unit 50 is not limited to the dynamic type.

  The unit holder 60 holds the unit 50 and forms an air chamber A described later in the unit holder 60. The unit holder 60 is made of metal such as brass. The unit holder 60 has a substantially bottomed cylindrical shape with an open front end. The unit holder 60 includes an elastic body support portion 61.

  The elastic body support portion 61 supports the second elastic body 80. The elastic body support 61 is cylindrical. The elastic body support portion 61 is integral with the unit holder 60. The elastic body support portion 61 protrudes rearward from the bottom surface of the unit holder 60. The elastic body support portion 61 includes a cable insertion hole 61h. The cable insertion hole 61h is a hole through which a cable (not shown) that electrically connects the unit 50 and the transformer 90 is inserted.

  The first elastic body 70 suppresses the propagation of vibration from the grip housing 10 (head case mounting member 30) to the unit holder 60. The first elastic body 70 is made of, for example, a synthetic resin having elasticity such as rubber. The first elastic body 70 has a ring shape.

  The second elastic body 80 suppresses propagation of vibration from the grip housing 10 (head case mounting member 30) to the unit holder 60. The second elastic body 80 is made of, for example, a synthetic resin having elasticity such as rubber. The second elastic body 80 is substantially ring-shaped.

  The transformer 90, together with the switch 100, constitutes a microphone frequency filter device (hereinafter referred to as “frequency filter device”) F, which is a filter for filtering an electric signal from the unit 50. Filtering is, for example, a process for degrading a frequency component of a predetermined band (for example, a low band) of an electric signal. The configuration and operation of the frequency filter device F will be described later.

  The output connector 110 is an output connector defined in, for example, JEITA RC-5236 “Latch lock type circular connector for audio equipment”. The output connector 110 includes a cylindrical base 111, a first pin (not shown) for grounding, a second pin 112 on the signal hot side, a third pin 113 on the signal cold side, and a male screw 114. .

  The base 111 includes a screw hole 111h. The screw hole 111 h is disposed on the outer peripheral surface of the base 111. The male screw 114 is fitted into the screw hole 111h. The first pin, the second pin 112, and the third pin 113 penetrate the base 111 in the front-rear direction.

  The name ring 120 covers the fixing portion 11 of the grip housing 10 and the mounting screw 40 to enhance the aesthetic appearance of the microphone 1. The material of the name ring 120 is, for example, metal. The name ring 120 has a substantially cylindrical shape.

Configuration of Frequency Filter Device Next, an embodiment of the frequency filter device according to the present invention will be described.

  The frequency filter device F performs filtering of the electrical signal output from the unit 50. For example, the frequency filter device F functions as a high-pass filter that degrades a frequency component lower than a predetermined frequency (cutoff frequency) of the input signal and passes a frequency component higher than the predetermined frequency. The frequency filter device F includes the transformer 90 and the switch 100 as described above.

FIG. 4 is a front view of the transformer 90.
FIG. 5 is a bottom view of the transformer 90 in FIG.
A two-dot chain line in FIG. 4 indicates a magnetic path M of the core 93 to be described later.

  The transformer 90 boosts the electrical signal from the unit 50 and outputs it to the output connector 110. The transformer 90 includes a coil bobbin 91, a primary winding (not shown), a secondary winding 92, and a core 93. The coil bobbin 91, the primary winding, and the secondary winding 92 constitute a coil 96 of the transformer 90.

FIG. 6 is a front view of the coil 96.
FIG. 7 is a bottom view of the coil 96 of FIG.
The coil bobbin 91 is a core material around which the primary winding and the secondary winding 92 are wound. The coil bobbin 91 is made of, for example, an insulating synthetic resin. The coil bobbin 91 is, for example, a rectangular cylinder. The coil bobbin 91 includes a hole (hereinafter referred to as “hollow part”) 91h.

  The hollow portion 91h is disposed at the center of the coil bobbin 91 along the axial direction of the coil bobbin 91 (the vertical direction in the drawing of FIG. 6). The hollow portion 91h is rectangular when viewed from the bottom.

  The primary winding and the core 93 constitute an input side coil of the transformer 90. The secondary winding 92 and the core 93 constitute an output side coil of the transformer 90. The primary winding and the secondary winding 92 are, for example, copper wires.

  The core 93 constitutes a path (hereinafter referred to as “magnetic path”) M of a magnetic flux generated by an electric signal input to the input side coil. As shown in FIG. 4, the core 93 includes a first core 93 a and a second core 93 b. The first core 93a and the second core 93b have the same rectangular frame shape in plan view. One side of the frame of the first core 93a is common to one side of the frame of the second core 93b in plan view. As shown in FIG. 5, the core 93 includes a plurality of first magnetic members 94 and a plurality of second magnetic members 95.

FIG. 8 is a front view of the first magnetic material 94.
FIG. 9 is a bottom view of the first magnetic material 94 of FIG.

  The first magnetic material 94 constitutes a first core 93a and a second core 93b. The first magnetic material 94 is made of a metal having a high magnetic permeability, for example. The first magnetic material 94 has a plate shape. The first magnetic material 94 has an E shape when viewed from the front. The first magnetic material 94 includes a base portion 94a, and three first leg portions 94b, second leg portions 94c, and third leg portions 94d that extend in the same direction from the base portion 94a. The length of the first leg portion 94b is the same as the length of the second leg portion 94c and the length of the third leg portion 94d.

  The first leg portion 94b is arranged at the center of the base portion 94a in the longitudinal direction (left and right direction in FIG. 8). The second leg portion 94c is disposed at one end in the longitudinal direction of the base portion 94a. The third leg portion 94d is disposed at the other end in the longitudinal direction of the base portion 94a. The first leg portion 94b is a first central portion in the present invention. The second leg portion 94c is an eleventh core portion in the present invention. The third leg portion 94d is a twelfth core portion in the present invention.

FIG. 10 is a front view of the second magnetic material 95.
FIG. 11 is a bottom view of the second magnetic member 95 in FIG.

  The second magnetic material 95 constitutes the first core 93a and a part of the second core 93b. The second magnetic material 95 is made of a metal having a high magnetic permeability, for example. The second magnetic material 95 has a plate shape. The second magnetic material 95 has a U shape in front view. The second magnetic material 95 includes a base portion 95a, and first and second leg portions 95b and 95c that are two leg portions extending in the same direction from the base portion 95a. The length of the first leg portion 95b is the same as the length of the second leg portion 95c.

  The first leg portion 95b is disposed at one end of the base portion 95a in the longitudinal direction (left and right direction in FIG. 10). The second leg portion 95c is disposed at the other end in the longitudinal direction of the base portion 95a. The 1st leg part 95b is the 2nd center part in this invention. The 2nd leg part 95c is a 21st core part in this invention.

  The distance L1 between the first leg 94b and the second leg 94c of the first magnetic material 94 is a distance L2 between the first leg 94b and the third leg 94d of the first magnetic material 94, and The distance L3 between the first leg portion 95b and the second leg portion 95c of the second magnetic material 95 is the same.

  The switch 100 is a slide type switch as shown in FIG. The switch 100 includes a main body 101 and a magnet 102. The positional relationship between the transformer 90 and the switch 100 will be described later.

  The main body 101 is made of metal such as brass. The main body unit 101 includes a storage unit 101 a that stores the magnet 102.

  The magnet 102 applies a magnetic field (DC magnetic field) to the magnetic path M of the core 93. The magnet 102 is an example of a magnetic field application unit in the present invention. The magnet 102 is a permanent magnet, for example. The magnet 102 is stored in the storage unit 101 a of the main body unit 101.

  In addition, a magnet should just generate | occur | produce a magnetic field in the magnetic path M of the core 93, and is not limited to a permanent magnet.

Transformer assembly method Next, the assembly method of the transformer 90 will be described with reference to FIGS.

  The coil 96 is assembled by winding the primary winding and the secondary winding 92 around the coil bobbin 91. The coil 96 includes a hollow portion 91 h of the coil bobbin 91. The primary winding is disposed so as to surround the outer peripheral surface of the coil bobbin 91. The secondary winding 92 is disposed so as to surround the outside of the primary winding.

  The core 93 is configured, for example, by stacking eight first magnetic materials 941-948 and six second magnetic materials 951-958.

  The first magnetic material 941-948 and the second magnetic material 951-956 are attached to the coil 96. First leg portions 941b-948b (even numbers are not shown) of the first magnetic material 941-948 are alternately inserted into the hollow portion 91h of the coil 96 from both ends of the hollow portion 91h. The first legs 951b-956b (even numbers are not shown) of the second magnetic material 951-956 are alternately inserted into the hollow portion 91h of the coil 96 from both ends of the hollow portion 91h.

  The first magnetic members 941-948 are stacked in pairs, with the two pieces serving as a pair. The first magnetic members 941-948 form two rectangular closed magnetic paths arranged in parallel in a front view.

  The second magnetic members 951-956 are stacked with a pair of two sheets, the directions of which are changed. The second magnetic members 951-956 form a rectangular closed magnetic path in front view. In front view, the shape of the closed magnetic circuit formed by the second magnetic material 951-956 is the same as the shape of any closed magnetic circuit formed by the first magnetic material 941-948.

  The pair of first magnetic members 94 are alternately stacked with the pair of second magnetic members 95.

  The second leg portions 941c-948c (even number is not shown) of the first magnetic material 941-948 and the second leg portions 951c-956c (even number is not shown) of the second magnetic material 951-956 are hollow portions. The coil 96 is arranged on one side (hereinafter referred to as “one side”) in a direction (left and right direction in FIG. 5) orthogonal to the through direction of 91h (perpendicular direction in FIG. 5). On the other hand, the third leg portions 941d-948d of the first magnetic material 941-948 are disposed on the side opposite to one side of the coil 96 (hereinafter referred to as “other side”).

  The base portions 941a-948a, the first leg portions 941b-948b, and the second leg portions 941c-948c of the first magnetic material 941-948 are the base portions 951a-956a and the first leg portions of the second magnetic material 951-956. Together with 951b-956b and second legs 951c-956c, a first core 93a is configured. That is, the first core 93 a is configured by laminating the first magnetic material 94 and the second magnetic material 95.

  The base portions 941a to 948a, the first leg portions 941b to 948b, and the third leg portions 941d to 948d of the first magnetic material 941 to 948 are the base portions 951a to 956a and the first leg portions 951b of the second magnetic material 951 to 956. The second core 93b is configured together with −956b. That is, the second core 93 b is configured by laminating the first magnetic material 94 and a part of the second magnetic material 95.

  The 1st core 93a and the 2nd core 93b are arrange | positioned along with the direction orthogonal to the penetration direction of the hollow part 91h. Compared with the first core 93a, the second core 93b has a gap (toothed shape) in the stacking direction of the first magnetic material 94 and the second magnetic material 95 (the vertical direction in the drawing of FIG. 5). That is, the magnetic path (hereinafter referred to as “first magnetic path”) M1 formed by the first core 93a is compared with the magnetic path (hereinafter referred to as “second magnetic path”) M2 formed by the second core 93b. ,wide. That is, the first magnetic path M1 is asymmetric with the second magnetic path M2 with respect to the hollow portion 91h.

  As described above, the second magnetic path M2 is narrower than the first magnetic path M1. Therefore, the magnetic resistance of the second magnetic path M2 is larger than the magnetic resistance of the first magnetic path M1. That is, the magnetic flux of the first magnetic path M1 is larger than the magnetic flux of the second magnetic path M2.

  Note that the configuration of the first magnetic material 94 and the second magnetic material 95 constituting the core is not limited to the number of layers and the stacking order of the present embodiment as long as the first magnetic path and the second magnetic path are asymmetric. That is, for example, the plurality of first magnetic members 94 and the plurality of second magnetic members 95 may be stacked together without being stacked alternately. Further, the number of the first magnetic material 94 and the second magnetic material 95 is not limited to the number of the present embodiment as long as the first magnetic path and the second magnetic path are asymmetric.

● Manufacturing Method of Microphone Next, a manufacturing method of the microphone 1 will be described with reference to FIGS.

  First, the unit 50, the first elastic body 70, and the second elastic body 80 are attached to the unit holder 60. The rear end of the unit 50 is fitted to the front end of the unit holder 60. Inside the unit holder 60, an air chamber A is formed by the rear end of the unit 50 and the unit holder 60.

  The first elastic body 70 is attached to the outer peripheral surface of the unit holder 60. The second elastic body 80 is attached to the outer peripheral surface of the elastic body support portion 61 of the unit holder 60.

  Next, the unit holder 60 is attached to the head case attachment member 30. The unit holder 60 is inserted into the head case mounting member 30 from the front of the head case mounting member 30. The elastic body support portion 61 of the unit holder 60 is inserted into the support hole 31 h of the head case mounting member 30. A first elastic body 70 is disposed between the inner peripheral surface of the head case mounting member 30 and the outer peripheral surface of the unit holder 60. A second elastic body 80 is arranged between the support hole 31 h and the elastic body support portion 61. That is, the unit holder 60 is supported by the first elastic body 70 and the second elastic body 80 in a vibration-proof manner.

  Next, the transformer 90, the switch 100, and the output connector 110 are attached to the grip housing 10.

  The transformer 90 is housed in the grip housing 10 from the front end side of the grip housing 10. For example, the transformer 90 is fixed to the center of the grip casing 10 in the front-rear direction by a fixing member (not shown) with the first core 93a facing forward (upward in the drawing in FIG. 2).

  The switch 100 is attached to the switch attachment portion 13 of the grip housing 10 so as to be movable in the front-rear direction (the vertical direction in FIG. 2). One magnetic pole of the magnet 102 faces the switch mounting portion 13. The moving direction of the switch 100 is the front-rear direction (vertical direction in FIG. 2), which is a direction orthogonal to the penetration direction of the hollow portion 91h of the transformer 90 (horizontal direction in FIG. 2).

  The distance between the first core 93 a and the magnet 102 is longer than the distance between the second core 93 b and the magnet 102.

  When the switch 100 is located at the front end of the switch mounting portion 13 (when the switch 100 is ON), the magnet 102 is located on the side of the second core 93b in the longitudinal direction of the grip housing 10 (the vertical direction in FIG. 2). Placed in. When the switch 100 is located at the rear end of the switch mounting portion 13 (when the switch 100 is OFF), the magnet 102 is disposed behind the second core 93b in the longitudinal direction of the grip housing 10.

  The distance between the second core 93 b and the magnet 102 varies depending on the position of the switch 100 in the switch mounting portion 13. The distance between the second core 93 b and the magnet 102 increases as the switch 100 moves from the front end (ON) to the rear end (OFF) of the switch mounting portion 13. That is, when the switch 100 is OFF, the magnet 102 is farthest from the second core 93b.

  Thus, the frequency filter device F is configured by the transformer 90 and the switch 100 in which the magnetic paths are formed asymmetrically.

  The output connector 110 is housed in the connector housing portion 12 from the rear end side of the grip housing 10. After the output connector 110 is housed in the connector housing portion 12, the male screw 114 fitted in the screw hole 111h in advance is pulled out of the screw hole 111h by a screwdriver or the like inserted into the tool insertion hole 12h, and the grip housing 10 Abuts on the inner surface. As a result, the output connector 110 is fixed to the grip housing 10.

  Here, the transformer 90 is connected to the unit 50 and the output connector 110 by a cable (not shown).

  Next, the head case attachment member 30 is attached to the grip housing 10. The head case mounting member 30 is inserted into the fixing portion 11 of the grip housing 10 from the front end side of the grip housing 10. The mounting screw 40 is inserted into the screw insertion hole 11 h of the grip housing 10 and is fitted into the female screw hole 30 h of the head case mounting member 30.

  Next, the name ring 120 is attached to the outer peripheral surface of the fixing portion 11 of the grip housing 10. The mounting screw 40 is hidden from the outside by the name ring 120.

  Next, the head case 20 is attached to the head case attachment member 30 from the front of the grip housing 10. The female screw portion 22 a of the case fixing portion 22 of the head case 20 is fitted into the male screw portion 30 a of the head case mounting member 30. The unit 50 is disposed inside the head case 20.

● Operation of Frequency Filter Device Next, the operation of the frequency filter device F will be described.

FIG. 12 is a schematic diagram of the frequency filter device F when the switch 100 is ON.
FIG. 13 is a schematic diagram of the frequency filter device F when the switch 100 is OFF.
In FIG. 12 and FIG. 13, an elliptical arrow indicates a magnetic field (magnetic flux) of the magnet 102 included in the switch 100.

  When the switch 100 is ON, the magnet 102 is disposed on the side of the toothless portion (the narrow portion of the second magnetic path M2) of the second core 93b. One magnetic pole of the magnet 102 faces the tooth-missing portion of the second core 93b through the switch mounting portion 13. At this time, a DC magnetic field from the magnet 102 is applied to the second core 93b (second magnetic path M2). Therefore, the second magnetic path M2 formed by the second core 93b is magnetically saturated by the DC magnetic field applied from the magnet 102 in a narrow portion of the second magnetic path M2. As a result, the low-frequency response of the transformer 90 is degraded.

  When the switch 100 is moved from ON to OFF, that is, when the magnet 102 is moved away from the second core 93b, the DC magnetic field applied from the magnet 102 to the second core 93b according to the distance between the second core 93b and the magnet 102. The magnetic flux density decreases. That is, the deterioration of the low-frequency response of the transformer 90 recovers as the distance between the magnet 102 and the second core 93b increases.

  When the switch 100 is OFF, the DC magnetic field from the magnet 102 is hardly applied to the second magnetic path M2. That is, when the switch 100 is OFF, the low frequency response of the transformer 90 is hardly degraded.

  As described above, the magnetic flux density of the DC magnetic field applied from the magnet 102 to the second core 93 b is adjusted by adjusting the distance between the second core 93 b and the magnet 102.

  The electrical signal output from the unit 50 is output from the output connector 110 to an external device such as an amplifier via the transformer 90. When the frequency response of the low frequency range of the transformer 90 deteriorates, the frequency response of the electric signal output from the unit 50 deteriorates at a frequency lower than a predetermined frequency in the transformer 90. The low cut-off frequency (hereinafter referred to as “low cut frequency”) at which the deterioration of the frequency response of the electric signal begins depends on the distance between the second core 93 b and the magnet 102. That is, the low cut frequency becomes higher as the distance between the second core 93b and the magnet 102 becomes shorter.

  As described above, the switch 100 is movable in the front-rear direction. That is, the distance between the second core 93b and the magnet 102 can be changed continuously. That is, the frequency filter device F continuously varies the low cut frequency.

  FIG. 14 is a graph of the frequency response of the microphone 1 when the switch 100 is moved from ON to OFF. The figure shows the frequency response of the microphone 1 when the switch 100 is changed in four stages from OFF to ON. The symbol “a” indicates the frequency response of the microphone 1 when the switch 100 is OFF. Symbols “b”, “c”, and “d” indicate the frequency response of the microphone 1 when the switch 100 moves from OFF to ON stepwise. The magnetic flux density of the DC magnetic field applied from the magnet 102 to the second core 93b increases in the order of the symbols “b”, “c”, and “d”.

  The low cut frequency varies according to the magnetic flux density of the DC magnetic field applied from the magnet 102 to the second core 93b. When the magnetic flux density of the DC magnetic field applied from the magnet 102 to the second core 93b is high (when the code is “d”), the low cut frequency is, for example, 350 Hz. When the magnetic flux density of the DC magnetic field applied from the magnet 102 to the second core 93b is low (when the code is “b”), the low cut frequency is, for example, 45 Hz.

Summary According to the embodiment described above, the frequency filter device F includes two cores 93a and 93b having different magnetic fluxes (the magnetic paths M1 and M2 are configured asymmetrically), and a direct current is applied to the transformer 90. And a magnet 102 for applying a magnetic field. Therefore, the second magnetic path M <b> 2 formed by the second core 93 b on the side where the magnetic flux of the transformer 90 is small is saturated by the DC magnetic field applied from the magnet 102. As a result, the low-frequency response of the transformer 90 is degraded.

  The magnet 102 is movable in the direction in which the first core 93a and the second core 93b are arranged side by side. Therefore, the adjustment of the distance between the second core 93b and the magnet 102 is easy.

  Further, by moving the position of the switch 100 in the switch mounting portion 13, the distance between the second core 93b and the magnet 102 changes continuously. That is, the low cut frequency of the transformer 90 changes continuously.

  Furthermore, the core 93 of the transformer 90 is configured by laminating two types of magnetic materials, an E-shaped first magnetic material 94 and a U-shaped second magnetic material 95. The core 93 includes a first core 93 a configured by the first magnetic material 94 and the second magnetic material 95, and a second core 93 b configured by a part of the first magnetic material 94 and the second magnetic material 95. Is composed of. Therefore, the frequency filter device according to the present invention can narrow a part of the magnetic path M with a simple configuration in which a part of the configuration of the conventional EX-type laminated core is changed.

  Furthermore, the distance between the first core 93a and the magnet 102 is longer (far) than the distance between the second core 93b and the magnet 102. Therefore, the magnet 102 can efficiently apply a DC magnetic field to the second magnetic path M2 that is narrower than the first magnetic path M1.

  Thus, the frequency filter device according to the present invention can easily and continuously change the low cut frequency with a simple configuration.

  The microphone according to the present invention includes the frequency filter device according to the present invention. Therefore, the microphone according to the present invention can easily and continuously change the low cut frequency with a simple configuration.

F frequency filter device 1 microphone 10 grip housing 20 head case 30 head case mounting member 40 mounting screw 50 unit 60 unit holder 70 first elastic body 80 second elastic body 90 transformer 91 coil bobbin 91h hole (hollow part)
92 Secondary winding 93 Core 93a First core 93b Second core 94 First magnetic material 94a Base portion 94b First leg (first central portion)
94c 2nd leg (11th core)
94d 3rd leg (12th core)
95 Second magnetic material 95a Base portion 95b First leg (second central portion)
95c 2nd leg (21st core)
96 Coil 100 Switch 101 Main unit 102 Magnet (electric field applying unit)
110 Output connector 120 Name ring

Claims (7)

A frequency filter device for filtering a signal output from a microphone unit of a microphone,
With a transformer,
A magnetic field application unit for applying a magnetic field to the magnetic path of the transformer;
With
The transformer is
Coils,
A first core;
A second core;
With
The magnetic flux of the first magnetic path formed by the first core is larger than the magnetic flux of the second magnetic path formed by the second core,
The magnetic field application unit applies a magnetic field to the second magnetic path;
The frequency filter apparatus characterized by the above-mentioned. The distance between the magnetic field application unit and the transformer is variable.
The frequency filter device according to claim 1. The first core and the second core are configured by laminating a plurality of magnetic materials,
The number of the magnetic materials constituting the first core is greater than the number of the magnetic materials constituting the second core.
The frequency filter device according to claim 1. The plurality of magnetic materials are:
A first magnetic material;
A second magnetic material having a shape different from the shape of the first magnetic material;
With
The coil is
Hollow part,
With
The first magnetic material is
A first central portion disposed in the hollow portion;
An eleventh core part constituting the first core;
A twelfth core part constituting the second core;
With
The second magnetic material is
A second central portion disposed in the hollow portion;
21 core parts constituting the first core;
With
The first central portion and the second central portion are stacked in the hollow portion to constitute the first core and the second core.
The frequency filter device according to claim 3. The first core and the second core are arranged side by side in a direction orthogonal to the penetration direction of the hollow portion,
The frequency filter device according to claim 4. The magnetic field application unit is movable in a direction perpendicular to the penetration direction of the hollow portion.
The frequency filter device according to claim 5. A microphone unit,
A frequency filter for filtering a signal output from the microphone unit;
Having
The frequency filter is the frequency filter device according to any one of claims 1 to 6.
A microphone characterized by that.

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