DE1728983U - PIEZOELECTRIC TUBE SWINGER. - Google Patents

Description

s RA35782W56.E6-

SIEMENS

SIEMENS-SCHUCKERTWERKE p _A: 54/1943

AKTIENGESELLSCHAFT ',

Act.z .: g. 14 954 / 42S Gm

Piezoelectric tube chimney

The invention relates to a tubular piezoelectric oscillator, in particular made of ceramic material, e.g.

^ sintered barium titanate. The invention has the task asked to create such a transducer, which is advantageous for sound radiation in liquids at low ultra-visual frequencies suitable is.

According to the invention, the tubular transducer is closed on one side by a flat radiating plate, the diameter of which is a maximum of 50% larger than that of the tube. The diameter of the radiating plate is advantageous in this way. chosen that their deepest bending resonance is higher than the resonance of the transducer. In this case, the radiating plate will not yet bend at the resonance frequency of the viewer ■. In order to achieve this, it is expedient that the diameter of the pipe is related to its length as about 1:10. The radiation plate is made as light as possible, but without falling below the strength that

t is necessary to ensure the necessary flexural strength. If you also choose the ratio of the diameter to the wall thickness of the

ι tube such as 6: 1, a relative bandwidth of at least 5? o is achieved with sound radiation in common liquids, so that, given the high manufacturing tolerances, no individual tuning of the transducers is required. The electrical resistance of the transducer can also be influenced by the wall thickness. By using many slim transducers, you can achieve a significantly lower electrical resistance than with a few strong transducers with the same radiating surface.

The radiating plate is expediently made of the same material as the transducer and is glazed onto the end of the transducer. A glaze is used that has a coefficient of thermal expansion which corresponds to the material of the transducer.

- 1 - Rei / Oa

PA 2 / H / 90a (amlitogen) 5000 β 55

PA 54/1943

In the figure, an embodiment of the invention is in section shown.

The transducer consists of a drawn, slim tube 1 piezoelectric ceramic, in particular polarized barium titanate ceramic. On one end face of the tube 1 is a radiation plate 2 made of the same ceramic material with an im thermal expansion coefficient glazed on to match the ceramic. The tube 1 carries a burned-in metallic Outer covering 4 and an inner covering 5.

At the junction of the longitudinal oscillation is the mount of the oscillator, which consists of the screw bolt 6, attached. The screw bolt β is at its upper end with a rubber sleeve 7, over which there is a metallization 8, e.g. in the form of wires. The end of the bolt 6 is with this Metallization in contact. Through the rubber sleeve, which has a diameter that is larger than that of the pipe 1, is the attachment of the bracket to the pipe in perfect quiet causes and at the same time the power supply to the inner lining manufactured. The screw bolt 6 is for the purpose of height adjustment of the oscillator, in particular for assembling several oscillators on the support plate 9 by means of the nuts 10 attached. The support plate 9 can be provided with several bores, so that when several transducers are arranged next to one another, the radiation plate 2 lay against one another like the cells of a honeycomb. Ss then becomes one of the shape of the sheet 9 corresponding Hall-radiating surface formed.

The power supply for the external surface is also provided at the junction the longitudinal oscillation through the supply line 11. Between the Radiation plate 2 and the holder forms an air cushion 12 which prevents sound from being radiated downwards. The inventive Holding with the interposition of elastic means at the node of the longitudinal oscillation has the advantage that any Energy radiation via the bracket is prevented.

Claims (6)

Protection claims Ί. Piezoelectric tube oscillator, especially made of ceramic Material, characterized in that the tubular transducer is closed on one side by a flat radiating plate, whose diameter is a maximum of $ 50 larger than that of the pipe. 2. Tube vibrator according to claim 1, characterized in that the diameter of the radiating plate is chosen so that its deepest Bending resonance is higher than the resonance of the transducer. 3. Tube vibrator according to claim 1 and 2, characterized in that the relationship between the diameter of the pipe and its length is about 1:10, 4. Tube vibrator according to claims 1-3, characterized in that the ratio of the diameter of the tube to the wall thickness of the tube is about 6: 1. 5. tube vibrator according to claim 1, characterized in that the Radiating plate is made of the same material as the tube and is preferably glazed onto the end of the transducer. 6. Tube vibrator according to claim 1, characterized in that the vibrator on the inner wall at the node of the longitudinal vibration comprises a holder, which preferably consists of a support bolt which, with the interposition of elastic means, e.g. Rubber sleeves, attached to the inner wall of the transducer.