SE524605C2 - Air-driven low frequency sound generator and method of controlling the resting position of a piston included in such - Google Patents

Abstract

The invention relates to an air-driven, low frequency sound generator comprising an open resonator (2) working as a sound emitter and also comprising a feeder unit, for the generation of standing, gas-borne sound waves, which sound waves produce a varying sound pressure inside said resonator. The feeder unit includes a cylinder (5) with one open end facing said open resonator and communicating therewith, further including a piston (4) performing a reciprocating movement inside said cylinder, and also including a surge tank (7), at least partly surrounding said cylinder and connected to a first pressure gas source (9), for feeding pressure gas into the surge tank and further into said cylinder via at least one connection opening (10) arranged in a wall of said cylinder. The sound generator further comprises means (14, 15) for bringing said piston (4) to a stand-still position, in which said connection opening is blocked by the piston, by exerting an additional pressure on the upper end of said piston. The invention also relates to a corresponding method.

Description

25 30 524 605 Ü, x S ~ J = ~: - v - - i _ ~. - 1 1 J t ß f, ~ J l - - ~ _ ~ -; = ~ f f, ~. - - _. =. 1 ~ 'i! _,, _. , ~. , ~. ~. ~ .- w »this is that the gas can cause corrosion on the sliding surfaces between the piston and the cylinder in connection with it flowing from the resonant tube via the cylinder into the container.

Since there is a very small play between the outer surface of the piston and the inner surface of the cylinder, corrosion attack on the inside of the cylinder can be devastating to the function of the feed unit. If there is too much corrosion, there is even a risk that the piston will not be able to move.

Another disadvantage of this mentioned type of sound generator is that when the feed unit is started up, the piston does not immediately begin to move with the amplitude of motion it has in the steady state. It is a progressive start of the piston, which can take approximately up to half a second before it has reached the range of motion it has in duration.

The purpose of the present invention is primarily to solve the problems described above. This is achieved in accordance with this invention by means of an air-powered low-frequency sound generator being provided with the new device as they are defined in the characterizing part of claim 1 and with a method which they are characterized in the characterizing part of claim 6.

Thus, by using a method and apparatus for bringing said piston into a rest position, where said connection opening is blocked by the piston, by said spring-loaded end of said piston being actuated by an additional pressure, the great advantage is obtained that corrosion on the inner surface of the cylinder caused by reverse gas flow from the resonant tube is prevented.

Another significant advantage of the present invention is that there is a much faster start-up of the piston movement. In accordance with the present invention, the spring-actuated part of the piston is actuated by an additional pressure, which results in the connection opening between the container and the cylinder being completely closed, which in turn means that the pressurized gas to the feed unit is closed. When this additional pressure ceases, the said connection opening is suddenly opened completely and a strong gas pulse is supplied to the resonator, the generator starting immediately. Tests have shown that the sound pressure amplitude prevailing in duration can be achieved in as short a time as 1/10 second.

In most cases, the present invention results in a rest position, where the other lower end of the piston is located in the vicinity of the open part of the cylinder, close to the resonator. Additional devices and advantages of this invention are set forth in the other dependent claims.

The term "low-frequency sound" means sound with frequencies below 38 Hz. A suitable usable frequency range is 15-35 Hz.

The present invention will now be described by means of an exemplary embodiment only, and with reference to the accompanying schematic diagrams in which: Fig. 1 is a schematic diagram of a sound generator according to the present invention in operation with the piston in its upper turning position; Fig. 2 is a schematic diagram of a sound generator according to the present invention in operation with the piston in its lower turning position, and Fig. 3 is a schematic diagram of a sound generator according to the present invention when in an intermittent standstill. Reference is initially made to Fig. 1 and Fig. 2. The sound generator shown comprises a supply unit 1 mounted on a resonator, which is illustrated here as a resonant tube 2 of the quartz wave type. The feed unit comprises a piston 4, which is mounted so that it can move back and forth inside a cylinder 5, between an upper turning position 3, as shown in Fig. 1, and a lower turning position 8, as shown in Fig. 2. The piston is spring-actuated by means of the spring 6, which is attached to the closed end of the cylinder. The cylinder and piston are mounted in a container or housing 7. A first compressed gas source 9, with a constant gas pressure P01. preferably compressed air, is connected to the container 7. The cylinder has an open end 11, which faces the resonant tube and is connected thereto. The cylinder also has one or more connection openings or ports 10 in the jacket surface through which the pressurized gas in the container can pass into the cylinder and continue downwards into the resonant tube. At the upper closed end of the cylinder, above the piston, there is a connection opening 18 pre-pressure equalization which either communicates with the atmosphere or with a space at the open end of the resonant tube.

When the sound generator is in operation, the gas pressure pg varies at the rear end of the resonant tube, i.e. the end which communicates with the cylinder and the feed unit under the piston according to the formula pg = p1 + po sin 2nft 10 15 20 25 30 524 605 4 Where p1 = the constant air pressure in the rear part of the resonant tube po = the sound pressure amplitude in the rear part of the resonant tube f = the frequency of the standing sound wave t = time If the constant air pressure above the piston, pg, is equal to the constant pressure in the rear end of the resonant tube, p1, the pressure difference sin 21rft.

The piston is pushed up to the upper turning position shown in Fig. 1 when the pressure difference is (+ p0). In that position the ports 10 in the cylinder 5 are open and an air pulse 12 is fed into the cylinder.

The piston is sucked down to the lower turning position shown in Fig. 2 when the pressure difference is (-p0), the ports being closed. In accordance with the present invention, a second pressurized gas source 14 is connected to the other end of the cylinder, i.e. the end which does not face the resonant tube and where the spring of the piston is connected. This second pressure source 14 provides a constant gas pressure, pcz, preferably compressed air, which is regulated by a control valve 15. The pressure, pcz, of this compressed air is much higher than the gas pressure pg. As long as the control valve 15 is in the position shown in Fig. 1 and Fig. 2, i.e. when the supply from the pressurized gas source is closed, the piston moves between the upper and the lower turning position with the same frequency, f, as the standing sound wave in the resonant tube.

When the valve 15 is opened as shown in Fig. 3, the high compressed air pressure, pcz, generated by the second compressed gas source 14 acts on the upper end of the piston and thereby presses the piston downwards. The gas pressure, P02, must be so high in relation to the gas pressure pg, that the piston is pressed downwards to a position, so that the upper turning position will be below the ports 10. Thereby said ports are blocked by the piston and the gas pressure pm from the first gas source 9 is closed. In this condition, the sound generator stops because the piston movement ceases when the compressed air from the first compressed gas source 9 cannot enter the resonant tube 2. In the embodiment H 5 H »: Z s«. ~. -1 w fl f; ,,. s. .i. «t» <1 i 1 ~ a 'i w a w. fl - V71 "2 ___ _ _, -,., U-, _. the shape shown in Fig. 3, the piston is pressed down against a seat 16, which is located at the lower end 5 of the cylinder.

The sound generator is started again by changing the position of the valve 15 from the position shown in Fig. 3 to the position shown in Fig. 1. The spring then pulls the piston to a position above the ports and the piston can again move between its upper and lower turning position. The pressurized gas from the first pressurized gas source can then again pass into the cylinder and further down to the resonant tube.

To control the position of the valve 15, some type of control equipment is suitably used; This control equipment can be manual or any known automatic equipment.

The present invention is not limited to the embodiment shown, which serves only as an example, but can be modified and varied to the extent that they are claimed by the appended claims.

Claims (10)

10 15 20 25 30 524 6056 PATENT REQUIREMENTS An air-powered low-frequency sound generator, comprising on the one hand an open resonator (2), which acts as a sound transmitter and in addition a feed unit (1), which generates standing gas-borne sound waves which produce varying sound pressures inside said resonator (2), said feed unit (1) comprising a cylinder (5) with an open end (11) facing said open resonator (2) and communicating therewith, further comprising a piston (4) performing a reciprocating movement within said cylinder (5) and having a first spring-actuated end and a second opposite end facing said resonator, also comprising an air container (7), which at least partially encloses said cylinder and is connected to a first source of compressed air (9) for supplying compressed air to the air container (7). ) and further into said cylinder (5) via at least one connection opening (10) in the cylinder wall with said piston (4) acting as a valve for regulating said connection opening (10), characterized by that it comprises means (14) for bringing said piston (4) to a rest position where said connection opening (10) is blocked by the piston by applying an additional pressure on said first spring-actuated end of said piston (4). Low frequency sound generator according to claim 1, characterized in that it comprises a second pressurized gas source (14) connected to said cylinder (5) for supplying pressurized gas to a space inside said cylinder and behind said piston (4) for exposing said pressure to the spring-actuated piston fi. End. Low-frequency sound generator according to claim 2, characterized in that it comprises a control valve (15) for regulating the connection to said second pressurized gas source (14). Low-frequency sound generator according to claim 3, characterized in that it comprises means for opening said control valve (15) when the sound generator is to be temporarily switched off and for closing said valve when the sound generator is to be restarted. 10 15 20 25 30 524 605 7 Low frequency sound generator according to any one of claims 2-4, characterized in that there is a seat (16) at the open end (11) of said cylinders (5) and that said other end of said piston (4) is pressed down against this seat (16). ) when it is at rest. A method for regulating the rest position of a piston included in a low frequency sound generator, comprising on the one hand an open resonator (2), which acts as a sound transmitter and also a feed unit (1), which generates standing gas-borne sound waves which produce varying sound pressures inside said resonator (2), said feed unit (1) comprising a cylinder (5) with an open end (11) facing said open resonator (2) and communicating therewith, further comprising a piston (4), which performs a forward and reciprocating movement within said cylinder (5) and having a first spring-actuated end and a second opposite end facing said resonator, also comprising an air container (7), which at least partially encloses said cylinder and is connected to a first source of compressed air (9) for supplying compressed air to the air container (7) and further into said cylinder (5) via at least one connection opening (10) in the wall of said cylinder (5) with said piston (4) acting as a valve f to regulate said connecting opening (10), characterized in that said piston (4) is brought to a rest position, where said connecting opening (10) is blocked by the piston by applying an additional pressure on said first spring-actuated end of said piston (4). A method according to claim 6, characterized in that said additional pressure is provided by a gas pressure supplied to said cylinder (5) from a second pressurized gas source (14) to said cylinder. A method according to claim 7, characterized in that the connection to said pressurized gas source (14) is regulated with a control valve (15). A method according to claim 8, characterized in that said control valve (15) is opened when the low frequency sound generator is to be temporarily stopped by being closed when the sound generator is to be started again. 524 eos 8 A method according to any one of claims 6-9, characterized in that said other end of said piston (4) is pressed down against a seat (16) at the open end (11) of said cylinders (5) by means of said additional pressure.