SE452541B - SOUND TRANSMITTER, INCLUDING ONE OF A MAGNETODYNAMIC DRIVE SYSTEM PAVERABLE MEMBRANE - Google Patents

Description

45 30 452 541 movable forward and eats in a cylinder connected to a resonant horn, achieve a high degree of action because the magnitude of the piston movement is completely impedance dependent. However, a disadvantage of this known type of sound transmitter is above all that one has to expect a certain wear between piston and cylinder, where sealing problems can also occur, and that a crank-driven oscillation movement is not very advantageous from a mechanical and dynamic point of view.

The present invention relates to a sound transmitter of the pressure chamber type, comprising a diaphragm which can be actuated by a magnetodynamic drive system, which forms a limiting wall in a pressure chamber connected to an acoustic horn.

In order to thereby achieve high efficiency at high acoustic power while utilizing an advantageously simple drive system, such a sound transmitter according to the invention has obtained the features according to claim 1.

For a more detailed explanation of the invention, reference is made to the accompanying drawing, in which Fig. 1 is an axial sectional view of a sound transmitter according to the invention in a first embodiment, Fig. 2 is a fragmentary cross-sectional view of the sound transmitter of Fig. 1, and Fig. 3 is an axial sectional view of a second design of the sound transmitter according to the invention.

Referring to FIGS. 1 and 2, the sound transmitter shown therein comprises a cylindrical housing 10, inside which an elastic contraction drum 11 formed as a cylinder is attached at its ends. Inside the contraction drum a central cylindrical rigid sleeve 12 of non-magnetic material is arranged in the housing, an annular space 13 being formed between the contraction drum 11 and the sleeve 12, which forms a pressure chamber. Connected to one end of the housing is a conical end piece 14, which together with a conical end piece l5 connected to the sleeve 12 or associated therewith delimits an annular channel 16 communicating with the pressure chamber 13, which connects pressure pressure. 451 452 541 chamber with a partially shown resonant horn 17.

Mounted on the other end of the housing 10 is an electric motor 18, the shaft 19 of which projects into the housing 12 coaxially therewith. Attached to the shaft 19 is a rotor 20 enclosed by the sleeve 12 inside at least partially magnetic material, which has a number of permanently distributed pairs of permanent magnets 21 evenly distributed around the rotor, the magnets in each pair being directed radially outwards and having opposite polarity, such as marked in the drawing, so that the magnetic grease is passed through the rotor between the inner ends of the magnets, while a strong magnetic grease is present between the outer ends of the magnets. Inside the contraction drum 11 are inserted axes 1 in continuous ferromagnetic flexible rods 22, FIG. 2, the number and division corresponding to the number and the division of the magnetic pairs 21, respectively. To avoid electromagnetically induced eddy currents, these rods 22 are formed as bundles 22. iron wires, which are insulated from each other. When the rotor 20 is rotated, the magnets 21 actuate the wire bundles 22 inserted in the contraction drum 11, so that there is a substantially radial contraction movement of the elastic drum consisting of elastic material each time a magnetic pair 21 magnetically passes a wire bundle 22 thereon and . This takes place at the same time for the a11a bundles of threads. The sleeve 12 thereby prevents the contraction drum 11 from coming into contact with the rotor 20. The described radial contraction tubes and the accompanying expansion tubes, due to the elasticity of the contraction drum, provide the volume changes necessary for the pressure wave with the magnetic changes in the pressure modification. the structure of the system (number of poles) and the corresponding structure of the contraction drum with rods (bundles) 22. The frequency of the sound is a direct function of the rotational speed and the number of poles. Preferably, the contraction drum 11 abuts the sleeve 12 at each contraction movement, so that the volume change in the pressure chamber should be almost independent of the sound pressure level in the pressure chamber, which is a marked advantage over conventional conventional electromagnetic comparisons. of speaker type.

It will be appreciated that with sound transmitters according to the invention, relatively high tone frequencies can be generated even at moderate rotational speeds. Electric motor operation, which is proven and simple, can be used without the need for a gearbox. For example, about 300 Hz can be generated with a 12-pole rotor in normal asynchronous motor operation.

The rotationally symmetrical pressure chamber 13 enables relatively large pressure chamber volumes and large motion amplitudes without any unbalanced forces. In principle, the contraction drum ll is the only worn part in the sound transmitter.

When using a resonant horn with high acoustic impedance, the tone shocks can become distinct despite the electric motor's acceleration and deceleration moments.

In the embodiment according to FIG. 3, the rotor 20 'is arranged on the outside of the contraction drum 11 and the sleeve 12 is replaced by a central body 12'. The permanent magnets 21 in each pair in this case have the same polarity and repel the rods inserted in the contraction drum against the body 12 'each time they pass the rods. Otherwise, the function is as previously described.

Alternatively, the permanent magnets, especially with very high-power sound transmitters, can be replaced with direct-current electromagnets, which receive current over slip rings, or the magnets can be replaced with a stationary coil system with basically one coil for each rod (bundle) in the contraction drum, for generating an alternating magnetic field.

If the coil system is designed as a three-phase winding, a rotating magnetic field can be provided with a stationary stator winding, which can be advantageous at low frequencies and high effects.

In the embodiments shown, the contraction drum 11 is cylindrical but can also be conical.

Claims (10)

10 15 20 25 30 35 452 541 PATENT REQUIREMENTS A sound transmitter, comprising a diaphragm which can be actuated by a magnetodynamic drive system, a magnetic field being rotatable relative to the diaphragm by means of the drive system to produce a periodic oscillation thereof, characterized in that the diaphragm is arranged as a limiting wall ; arranged peripherally relative to the drive system for effecting periodic contraction and expansion of the pressure chamber (13) through the boundary wall radially acting on the magnetic field. A sound transmitter according to claim 1, characterized in that the diaphragm (II) has a number of circumferentially evenly distributed axially extending portions (22) of ferromagnetic material, separated by non-magnetic material. 3. An audio transmitter according to claim 2, characterized in that each portion of ferromagnetic material is constituted by a flexible rod (22) of ferromagnetic material arranged in or on the membrane (II). An audio transmitter according to claim 3, characterized in that each rod (22) consists of a number of thin wires insulated from each other. 5. A sound transmitter according to any one of claims 1 - 4, characterized in that the pressure chamber (l3) is delimited between the diaphragm (ll) and a coaxial wall (l2) therewith. Audio transmitter according to one of Claims 1 to 5, n e t e c'k n a d conical. 7. An audio transmitter according to any one of claims 1 - 6, characterized in that magnets (2l) on a rotor (20) are rotatable relative to the diaphragm (11) on its inside or outside. feel - that the membrane (ll) is cylindrical or feel - that the membrane (ll) is arranged on the outside of a A sound transmitter according to claims 6 and 7, n a d sleeve (12) of non-magnetic material, which together with the diaphragm delimits the pressure chamber (13), and that the rotor (20) 10 452 541 is arranged inside the sleeve. Q Audio transmitter according to claims 6 and 7, characterized in that the rotor (20 ') is arranged on the outside of the diaphragm (11), which together with a body (12') arranged inside the same delimits the pressure chamber (13). 10. l0. Sound transmitter according to one of Claims 1 to 6, characterized in that a stationary winding for generating an alternating magnetic field is arranged on the inside or outside of the diaphragm.