DE624204C - Electrodynamic device for converting sound vibrations - Google Patents

Description

GERMAN EMPIRE

ISSUED ON JANUARY 15, 1936

REICH PATENT OFFICE

PATENT LETTERING

CLASS 21a ² GROUP 2oi

Patented in the German Empire on January 17, 1932

It has already been proposed to improve the frequency characteristic the electrodynamic Design device so that a rigid central part of the membrane carries a coil at its edge, which in an air gap between a central pole piece and an annular pole piece protrudes and that the membrane by means of a ring surrounding it is clamped and a plate located behind the air gap, the two pole pieces connects and therefore delimits an air chamber behind the membrane, from which the air at the membrane vibrations through throttle openings provided in the plate behind the air gap is alternately pushed out and sucked in again.

The alternating flow of air in both directions through the throttle openings through it seeks to dampen the vibrations of the membrane, and by appropriate dimensioning of the throttle openings the effect of this attenuation can extend over the entire range of audible frequencies will. At the same time, the natural frequency of the membrane is increased and this further improves the frequency characteristic of the device.

However, this design has the disadvantage that in the upper range of the frequency characteristic an undesirable peak is created. As has been determined, this is determined by the effect the- mass of the diaphragm in conjunction with the resilience of the air in the chamber under the Membrane caused. According to the invention, this shortcoming becomes apparent in the above Device avoided by having a special air chamber in the middle pole piece of the device is provided that is tuned to the same frequency as the unwanted peak is and through throttle openings with the one located under the rigid part of the membrane Airspace.

Some exemplary embodiments of the invention are shown schematically in the drawings.

Fig. Ι shows an electrodynamic sound conversion device in front view. Some parts of the device have been removed or shown in section for the sake of clarity.

Fig. 2 is a section along line 2-2 in Fig. I. This figure shows the assembly of the various parts of the apparatus.

Fig. 3 shows the most important of the parts shown in Fig. 2 on a larger scale.

Fig. 3 a shows the damping plate that is used in the devices shown in Figs: 2, -3 · and -8- is used.

Fig. 4 shows the central pole piece on a larger scale.

Fig. 5 is a section along the line 5-5 in Fig. 4.

Fig. 6 shows another in sectional view

Embodiment of the invention.

Fig. 7 shows a further embodiment of the invention.

Fig. 8 shows a modified one in sectional view Embodiment of the electrodynamic device of Fig. 2. Fig. 9 shows spacers used in the Figs. 7 and 8 are shown.

The electrodynamic microphone shown in Figs. 1 and 2 is mushroom-shaped Housing, which consists of the part 10, which is preferably made of cobalt steel, and a middle pole 11 consists. As can be seen from the figures, the parts form 10 and 11 a coherent body. The pole 11 carries a, extension 12, which in turn as Carrier for a flanged ring 13 made of non-magnetic material (e.g. Phosphor bronze) is used. The ring 13 is mounted in such a way that it is conical against the inner one Section of extension 12 creates. A central pole piece 14 is such on the Extension 12 attached so that it holds the ring 13 immovable. Coaxial to the middle one Pole piece 14, an annular pole piece 15 is attached to the capsule part 10. The connection between the part iq and the pole piece 15. is made by means of pins or pins. 16 ■ produced, which are stored in soft metal inserts 17. The pole piece 15 is so in Relation · to the pole piece 14 arranged that between the two elements an annular There is space ■; On one side of the annular pole piece 15 is an annular damping plate 18 made of non-magnetic inside the housing Material attached. This plate made of brass, aluminum or the like. Made . can be, preferably has the shape shown in Fig. 3a. The plate is by means of three Screws 19 held in place by the lugs 20 are screwed into the annular pole piece at the periphery of the plate. The plate 18 is provided on one side with a recess and has an annular shape Rib which narrows the annular space between the pole piece 15 and the plate. Between the damping plate 18 and the non-magnetic ring 13 is a packing 21 made of flexible material, e.g. B. Paper, arranged which seals the gap "between these two, so that the air in. the chamber between the pole pieces through the narrow space between the parts 15 and 18 (see Fig. 3) can get to the outside. The ring 13 is preferably made of non-magnetic Material made to prevent magnetic flux in the gap is lost between the pole pieces.

On the opposite side of the annular pole piece 15, a membrane is attached, that of a flat outer part 22, a central expanded, rigid piston part 23 and a central, fluted or flexible part 24 consists. As shown in Fig. 2 3 and 3, the middle part of the diaphragm working as a piston is according to the contour of the Pole piece 14 shaped. Between the membrane sections 24 and 23 is a movable one Coil 25 attached, which move freely in the space between the two P.olstücks can to change the constant magnetic flux between the pole pieces. the Coil 25 can consist of an edgewise wound band-shaped conductor, its, turns Are isolated from one another by means of insulating varnish or the like.

A number of paper disks 26 or the like are arranged between the membrane and the pole piece 15, so that an air gap is created between the membrane and the pole pieces, the dampens the movements of the membrane. The go connection between the membrane and the annular pole piece is made by means of screws inserted into an annular body 27 are screwed, the surface of which is inclined inward. The ring 27 is from one appropriately shaped piece of wire mesh 28 covered, which is held in place by a cover part. The middle part 29 of this. Lid is provided with symmetrically arranged recesses 30 through which the sound waves have access to the membrane surface. The lid also has an annular one Flange 31, which is in a further flange-shaped Part 32 ends. The outer edge of the flange 32 is shaped so that it over can grip an approach on the housing 10 and thus a connection between the cover and the housing of the device. As shown in Fig 1, the pole case is carried by a lower part 34, in which a serving to accommodate the terminals Block 35 is arranged. One of those related to the moving coil Head is visible at 36. The opening in the lower part 34 is closed by a cover 37.

In electrodynamic devices that: have a moving coil and its membrane have such masses and stiffnesses that they act like pistons caused the mechanical movement of the diaphragm and the coil distortions within a co-determined Section of the speech frequency control

rich. The emergence of this distortion is due to the fact that the natural oscillation frequency the membrane lies in this part of the frequency range. The distortions cause a change in the shape of the characteristic curve, which at higher frequencies one shows clear inclination. By making appropriate use of the mass, the rigidity and the Resistance one on one side of the

The amount of air trapped in the membrane and the fact that the air is forced to leave the cavity or chamber in which it is located through a narrowed channel, the mechanical movement of the membrane can be regulated so that the distortion for the entire frequency range is decreased. In the arrangement shown in FIGS. 1 to 3, the required regulation is brought about in a known manner by means of the damper plate 18, which gives the amount of air present in a chamber under the membrane the mass, rigidity and resistance required to eliminate the distortion.
The acoustic chamber formed below the diaphragm by the damper plate 18 gives the diaphragm an increased rigidity, as a result of which the frequency of the diaphragm is increased. Because of the narrowed channel between the large cavity in the magnet capsule and the chamber under the membrane, air is drawn in through the channel when the membrane moves away from the pole pieces. As the membrane approaches the magnets, air is similarly forced out of the channel.

By appropriately dimensioning the cross-section of the channel, it is possible to use the Chamber entering or exiting the chamber air such an acoustic Impedance to oppose that the mechanical movement of the membrane within the essential part of the entire work area, which is between 60 and 10,000 periods is dampened. In certain acoustic devices, e.g. B. electromagnetic or Electrostatic receivers, carbon grain microphones or the like, this impedance must be change opposite to the frequency. In electrodynamic sound conversion devices, such as microphones here treated species, for most of the frequency range in question, the Ratio between the acoustic impedance and the frequency can be kept constant.

It has now been shown that the mass of the membrane and the stiffness of the air there is also a distortion in the characteristic curve in the air chamber below the membrane for that part of the frequency range which occurs between 2,000 and 6,000 periods lies. The curve here initially shows a slight slope and then rises above the desired flat characteristic. This state is created by the fact that the The acoustic impedance acting on the membrane is too high for the mass of the membrane,

According to the invention, this distortion is eliminated in that a special air chamber is placed under the membrane that cooperates with the main air chamber. This interaction creates the characteristic smoothed. An embodiment of the additional damping means is shown in FIG. As can be seen from this figure, the central pole piece 14 is hollowed out so that a chamber 38 is formed between this pole piece and the part 12. In one wall of this one Chamber there are small openings 39, the connections between the chamber 38 and form the cavity on the outside of the palpiece 14. The openings 39 can for example, as indicated in Fig. 4, in a circular shape around the center of the pole piece be arranged. The size of the openings is such that that of the membrane generated air flow is opposed to the necessary resistance. The openings 39 As already mentioned, also form connecting channels between the chamber 38 and the lying under the membrane, with the narrow channel in the main damping element 18 in connection standing chamber.

At low frequencies, i. H. at frequencies up to about 2000 periods, the air causes in the special air chamber only an increase in the stiffness of the membrane. By doing around 5000 periods in which the membrane mass distorts the characteristic curve, the acoustic compensation means act mainly as a resistor. At still In turn, the effect of the compensation means changes by using higher frequencies here counteract the mass reactance of the membrane. The resistance of the air in the main air chamber is constant for most of the frequency range and the increased resistance generated by the additional air chamber neutralizes the mass reactance of the membrane, whereby the irregularities in the characteristic of the device are eliminated and the curve expressing the efficiency of the membrane for the entire frequency range has the form of a flat characteristic curve.

In the modified embodiment of the particular air chamber shown in Fig. 6 the middle pole 40 is provided with an opening, which contains a bridge-shaped part 41. The opening is dome-shaped Cover part 42 is provided, the stem 43 of which penetrates the bridge part 41 and by means of a Mother 44 is being held. The edge 45 of the cover 42 is tapered and conical adapted to the edge of the opening. Between the

Pole piece 40 and the cover part 42 can be arranged appropriate spacers, so that the lid can be centered exactly. Once the lid is properly adjusted, the spacers can be removed again, whereupon the cover cannot be moved by means of the nut 44 is screwed tight. The size of the annular slot between the parts 42 and 40 is decisive for the resistance that the air exiting the chamber to has overcome. This resistance as well as the steepness and the mass of the air are the factors which regulate the operation of the device. Fig. 7 shows another embodiment the special air chamber. According to Fig. 7, a cover part 46 is used, the one larger diameter than the opening in the central pole piece. Between part 46 and a spacer or separating disk 47 is arranged at the edges of the opening in the pole piece 40, which is provided with projections 48. By means of the projections 48, the distance between the pole piece 40 and the cover part 46 can be precisely adjusted. After hiring this distance remains constant and narrow slots of constant are created Size between adjacent protrusions 48 on separating body 47.

Each membrane arrangement has certain S ° parameters that differ from the parameters of other membranes of a similar type. It is therefore advisable to use auxiliary air chambers and the like, which consist of a few individual parts and can easily be connected to the Magnetan arrangement. It is also desirable to have air chambers that are easy to attach and detach, and which can be measured and adjusted prior to insertion into the device. Such a device is shown in Fig. 8. The electromagnetic device shown here has a magnet housing or a pot-shaped magnet 50 to which a pole piece 51 is attached. As can be seen from the figure, the pole piece 51 is held in place by means of a centering pin 52 or the like. An annular pole piece 53 is arranged coaxially to the pole piece 51 and is carried by the magnet 50 by means of zajpies 54. There is an annular air gap between the central pole piece 51 and the annular pole piece 53. An annular damping plate 55, which corresponds to the ring 18 in FIGS. 1 and 2, is attached to the lower edge of the annular poI piece 53. As indicated in Fig. 8, an intermediate washer 55 ° is arranged between extensions on the ring 55 and the annular pole piece 53, and several narrow slots 56 are provided between the damping plate and the annular pole piece. The damping plate is mounted on a soft rubber ring 57, which is carried by the central pole piece 51 and hermetically seals the space between the damping plate and the surface of the pole piece 51, so that the air in the chamber under the membrane only through the narrow slots 56 can get outside. A membrane 58 is arranged between spacer disks 59 and 60 and is held in connection with the annular pole piece 53 by means of screws 61. The screws 61 engage in a retaining ring 62 which is mounted on the outer surface of the membrane. The membrane carries an annular movable coil 63 which can move freely in the annular space between the pole pieces 51 and 53.

The center pole piece 51 has a recess, which is threaded at 64 is. The special air chamber can easily be attached in this cavity. These consists mainly of a pot-shaped body 65, which has a flange 66 is provided. The outer surface of the body 65 is threaded and the body becomes screwed into the cavity in the pole piece 51 until the flange 66 lies against the pole piece. In the bottom of the body 65 several holes 67 are provided, which are removable by means of a Plate 68 can be closed. At the open end of the part 65 is a dome-shaped Lid 69 arranged and between the edge of this Lidelteües and the body 65 a cutting disk 47 is arranged. All belonging to the cup-shaped body 65 Parts are held together by means of a screw 70.

Before the air chamber unit is inserted into the magnet structure, it is without the Plate 68 temporarily connected to the device, so that the values for the spring constant and the mass of the air in the cavity of the pot and the Value of the air resistance in the narrow slots between the plate 69 and the wall of the part 65 can be measured. As soon as the correct values are determined, the Plate 68 .attached to the bottom of the damping element, and the entire device is screwed into the pole piece 51. The magnet arrangement is made of a metal housing 71 surround. The connection between the housing 71 and the magnet arrangement is by means of a ring 72 which is screwed onto the housing 71. This ring carries a perforated screen 73 o. The like. That the membrane against damage and protects against the ingress of dust.

Claims (1)

Claim: Electrodynamic device for the implementation of sound vibrations, in which a rigid The middle part of the membrane carries a coil at its edge, which is inserted into the air gap protrudes between a central and an annular pole piece, and in which the membrane is clamped by means of a ring surrounding it and a plate behind the air gap the two pole shoes to limit one under the membrane located air chamber connects from which the air during the membrane vibrations is alternately pushed out and sucked in through throttle openings of the plate, characterized in that to the Purpose of compensating for one in the frequency characteristic of the device between 2000 and 6000 Hz distortion caused by the mass of the diaphragm and the suspension the air is caused in the chamber behind the membrane, in the middle pole piece a special air chamber is arranged, which through throttle openings with the under the rigid part of the membrane located air space is in communication and their Air content is tuned to the same frequency as the distortion frequency, which is caused by the mass of the membrane and the suspension of the air in the chamber behind the membrane is caused. For this 1 sheet of drawing