NL9400923A - Transducer of an electrostatic loudspeaker and method for the production of an insulated stator plate of a transducer of this type - Google Patents

Abstract

Transducer for an electrostatic loudspeaker, comprising a stator and an electrically charged membrane, which is clamped over a circumference with the aid of tensioning means. The stator comprises at least one electrically charged stator plate which is positioned opposite the membrane. The stator plates are connected to a variable voltage source and have a smaller surface than the membrane. The part of the membrane which is located directly opposite the stator plates is positioned at a distance from the circumference of the clamp. The surface of the conducting stator plates amounts to between 70 and 80% of the surface enclosed by the circumference of the clamp. Method for the production of stator plates for a transducer of this type, a plate being made with the aid of multi-layer technology and being built up from different layers of insulating material and at least one layer of conducting material which is completely enclosed by the layers of insulating material and which is provided with a pattern of holes. Material of the plate is removed until the layer of conducting material is enclosed by a layer of insulating material with a required thickness. Smaller holes are then disposed in the insulating layer at the location of the holes in the layer of conducting material. A raised edge is disposed on one side on the edge of the plate.

Description

Short Title: Transducer of an electrostatic loudspeaker and method of manufacturing an insulated stator plate from such a transducer

The invention relates to a transducer for an electrostatic loudspeaker, consisting of a stator and an electrically charged or chargeable foil or membrane, which membrane is clamped circumferentially by means of clamping means, which stator consists of at least one electrically conductive stator plate, which is spaced opposite the membrane and parallel to the membrane, which stator plate or plates are connected to a variable voltage source.

Such transducers have been known for a long time and are used in sound equipment for sound reproduction, as well as in equipment for medical and material research using, for example, ultrasound. The membrane has a constant charge Q with respect to the stator. A voltage is applied to the stator plate, upon which a signal voltage is superimposed. The ratio between the charge Q and the voltage U is the capacitance C of the capacitor, which is expressed in the formula Q = U x C. The charge Q is kept constant. If the voltage U is changed, the capacitance C will therefore have to increase or decrease inversely. Capacity C is inversely proportional to the distance between the membrane and the stator plate and is changed by increasing or decreasing the distance between the stator and the membrane. With varying tension, the membrane will therefore vibrate and generate sound.

In order to obtain a wide frequency range and a linear transfer, the stator is generally constructed as an assembly of two stator plates placed on either side of the membrane. These stator plates are then provided with openings or perforations to attenuate the noise produced by the membrane as little as possible. These stator plates are provided with an insulating layer to prevent breakdown. A signal voltage is superimposed on each of the stator plates, the superposition of the signal voltage on the stator plates taking place opposite to each other, so that the membrane moves alternately from both stator plates. Such a construction is also called a push-pull configuration.

In order to obtain a large acoustic output with a high efficiency, the capacity C and thus the ratio between the bias voltage U and the charge Q must be high, while in order to prevent distortion of the sound the transducer itself must be made relatively small. As a result, such a loudspeaker can only function at extremely high voltages of approximately 10,000 volts. Since the distance between the diaphragm and the stator plates is usually only about one millimeter for proper operation, the risk of breakdown is high. The membrane and the conductive layers in the stator plates must therefore be very well insulated. However, with the usual insulating materials, material aging eventually occurs, causing the risk of breakdown to increase significantly with the age of the loudspeaker.

In the current electrostatic loudspeakers, the membrane is often made of a film of High Density Polyethylene, HDPE, which is covered on one side with a layer of conductive material, such as carbon or gold.

Because the membrane is clamped at the edges and the distance between the membrane and the stator cannot be changed there, the charge on the membrane will shift on the membrane to the clamped edge in accordance with the formula Q = U x C. Because more cargo is present near the clamped edges, there is a great risk of breakdown near the edges.

Load shifts on the membrane cause distortion of the sound to be reproduced and are therefore undesirable. Because of this, the electrical conductivity of the membrane is usually kept low, so that the charge shifts are kept to a minimum. However, at the clamped edges of the membrane, this means, in accordance with the formula Q = C x C, that with constant C and Q and an increased voltage U the chance of breakdown on site is further increased. Also, a great tensile force will be exerted on the membrane at the edges, whereby tensile stresses in the material will increase considerably.

The object of the invention is a transducer of the above-described electrostatic type, in which the risk of breakdown is greatly reduced.

This object is achieved with the invention in that the conductive stator plate or plates has or have a smaller surface area than the membrane and that the portion of the membrane which is directly opposite the conductive stator plate or plates is at a distance from the circumference of the clamping. There is then no danger near the clamping means that, due to a constant load and a constant capacity, breakdown could occur with increased tension. The membrane can adjust the distance over the entire surface of the stator plate or plates to the changed voltage, so that the above-described problems will hardly occur, if at all. It has been found that with a transducer thus constructed it is possible to achieve a breakdown strength of approximately 20,000 volts at a distance of 1 mm between the membrane and the stator.

Because the diaphragm deviates with the same amplitude with a smaller capacitor surface, this intervention reduces the total capacity of the loudspeaker as a whole with the same acoustic output. The speaker is therefore easier to control and associated amplifiers are less loaded.

Preferably, the area of each conductive stator plate is between 70 and 80% of the area enclosed by the periphery of the clamping. It has been found that the above-mentioned advantages are then optimally expressed. The capacity reduction of the speaker is then approx. 30% with the same acoustic output. If the surface of the conductive stator plate is kept even smaller in relation to the membrane, the membrane can no longer be optimally controlled and sound distortions can occur.

Preferably, the transducer is configured such that one or more spacers are positioned approximately midway between the stator and the membrane and the conductive stator plate around the spacers includes an interruption. These spacers serve to prevent the diaphragm from bending too far and sticking to one of the stator plates. Because this greatly reduces the risk of sticking, it is possible to apply a higher electrical charge to the membrane.

The conductive stator plate around the spacer is designed with an interruption to prevent the diaphragm from decreasing the capacity at these points by changing the voltage. The insulating layer encasing the conductive stator plate can continue through this interruption.

The invention also relates to a method of manufacturing insulated stator plates for a transducer described above. It is customary to provide two conductive stator plates with an insulating layer. As already stated, material aging occurs over time, which greatly increases the risk of breakdown.

In accordance with the invention, the risk of breakdown is greatly reduced by the fact that, by means of multi-layer technique, a plate is made, which is composed of several layers of insulating material and at least one layer of conductive material, which is completely enveloped by the layers of insulating material and which is patterned with holes, and then material is removed from the sheet until the layer of conductive material is enveloped by a layer of insulating material of a desired thickness, and then holes are formed at the holes in the layer of conductive material applied in the insulating layer with a diameter smaller than the diameter of the holes in the conductive layer, which is then applied on one side to the edge of the plate with a raised edge.

This pre-existing multi-layer technology was initially developed with a view to obtain printed circuit boards with an extremely high density of circuits. The printed circuit boards consist of layers of conductive material, in which a pattern of connections has been etched. The conductive layers are covered by insulating material, usually glass fiber reinforced epoxy resin.

By first starting from a multi-layer plate in the manufacture of the stator plate, a relatively thick and thus rigid plate can be assembled, which will not warp during the production process. The raised edges on both stator plates of a stator thus manufactured in cooperation with each other form the spacer ring and clamp the membrane together. By using epoxy resin with glass fiber reinforcement, an extremely good insulation is obtained, whereby the glass fibers contribute to a very high breakdown voltage. This method makes it possible to produce a very well insulated stator plate in an inexpensive and controllable manner, the conductive stator plate having a smaller circumference than the clamping means, which are arranged as a spacer on the outer edges of the insulating layer of the stator plate. Also, the inner circumference of each of the holes in the conductive layer is completely enveloped by the insulating material.

The invention will now be explained in more detail with reference to the drawings. Show in this:

Figure 1 Schematic cross section of a loudspeaker according to the invention;

Figure 2 Front view of a speaker stator plate in accordance with Figure 1;

Figure 3 Partial cross section of a transducer with a spacer.

Figure 1 shows in cross-section a transducer 1 of an electrostatic type loudspeaker, which is built up from a first stator part 2 and a second stator part 3. The two stator parts 2, 3 are each made up of a conducting stator plate 4, which is completely enclosed by a layer of insulating material 5. The two stator parts 2, 3 are further provided with openings 6 for a minimal damping of the sound by both stator parts 2, 3. The openings 6 in the stator parts 2, 3 run concentrically through openings 7 in the conductive stator plates 4. The openings 7 have a larger diameter than the openings 6 in the stator parts 2, 3, so that the periphery of the openings 7 in the conductive stator plates 4 is completely covered by insulating material. The two stator parts 2, 3 are arranged on top of each other and are kept at a distance from each other by clamping means in the form of a spacer ring 8. The spacer ring 8 is built up from an elevated edge 9 of the first stator part 2 and an elevated edge 10 of the second stator part 3. The height of the edges 9, 10 is of the order of approximately one millimeter. The two edges 9, 10 are attached to each other. A foil or membrane 11 is stretched between the edges 9, 10. The distance between the inner circumference of the edges 9, 10 and the outer circumference of the conductive stator plates 4 is between 5 and 30 mm. At these distances, a capacity reduction of approximately 30% is achieved with the same acoustic output.

An electrical charge is applied to the membrane 11, which remains constant. The conductive stator plates 4 are each connected to a voltage source. The membrane 11 forms a capacitor with both conductive stator plates 4. If the voltage is increased on one of the two stator plates 4, the capacity will have to be lowered under the formula Q = U x C with the charge remaining the same, so that the membrane 11 will move away from that stator plate. Because the tension on both stator plates 4 is always increased opposite to each other, the membrane 11 will move back and forth. This will produce sound at the correct frequencies.

The extreme edges 12 of the conductive stator plates 4 are located at a large distance from the spacer ring 8. This prevents the membrane 11 locally from increasing the distance to the conductive stator plate 4, so that the risk of breakdown is considerably reduced.

Figure 2 shows a front view of a stator part 2 or 3 in accordance with figure 1. In the center, the stator part 2 comprises a conductive stator plate 4 completely embedded in insulating material, which connection point can be connected to a voltage source via terminals 13. At a certain distance from the extreme edges 12 of the conductive stator plate 4, the stator part 2 comprises a raised edge 9. Approximately in the center, the conductive stator plate 4 comprises gaps 14, on which spacers can be applied which are approximately the same height as the raised edge 9 and which prevent the membrane from bending too far and sticking to the stator part 2. The second stator part to be arranged on the stator part 2 must then also be provided with such spacers at a corresponding place. The membrane is then clamped locally by the spacers. According to the invention, the periphery of the spacers is spaced from the periphery of the break 14 in the conductive stator plate 4.

Figure 3 shows a partial cross-section of a transducer 1, provided with two opposite spacers 15. These spacers are made of a good insulating material and locally clamp the membrane 11. The spacers 15 are provided at breaks 14 in the conductive stator plates 4. The circumference 16 of the breaks 4 is spaced from spacers 15, so that the risk of breakdown at the location of the wedging blocks 15 is small. is.

Claims (4)

1. Transducer for an electrostatic loudspeaker, consisting of a stator and an electrically charged foil or membrane to be charged, which membrane is clamped circumferentially by means of clamping means, which stator consists of at least one electrically conductive stator plate, which is mounted on a spaced opposite the membrane and parallel to the membrane, which stator plate or plates is connected to a variable voltage source, characterized in that the conductive stator plate or plates have a smaller surface area than the membrane and that the portion of the membrane which is directly opposite the conductive stator plate or plates, at a distance from the periphery of the clamping. Transducer according to claim 1, characterized in that the area of each conductive stator plate is between 70 and 80% of the area enclosed by the periphery of the clamping. Transducer according to any one of the preceding claims, characterized in that one or more spacers are placed approximately in the middle between the stator and the membrane and that the conductive stator plate around the βίε toothpieces comprises an interruption. Method for the manufacture of stator plates for a transducer according to one of the preceding claims, characterized in that a plate is made using multi-layer technique, which is composed of several layers of insulating material and at least one layer of conductive material, which completely enveloped by the layers of insulating material and provided with a pattern of holes, and then material is removed from the plate until the layer of conductive material is enveloped by a layer of insulating material of a desired thickness, and then at the location of the holes in the layer of conductive material holes are provided in the insulating layer with a diameter which is smaller than the diameter of the holes in the conductive layer, which is then provided on one side on the edge of the plate with a raised edge.