ES2257695T3 - A LOW FREQUENCY SOUND GENERATOR ACTIVATED BY AIR AND A PROCEDURE FOR THE REGULATION OF THE PISTON IN THIS GENERATOR. - 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

A low frequency sound generator activated by air and a procedure for regulating the piston in said generator.

The invention relates to a sound generator of low frequency activated by air, as described in the preamble of claim 1 of the patent. The invention also refers to a procedure for regulating the position of one piston stop included in a low sound generator frequency, as described in the preamble of the patent claim 6.

In particular, the present invention relates to a low frequency sound generator of the type described in the WO-A1-8807894, in which a feeder unit comprising a mobile piston is used to generate a stationary sound wave transmitted by gas. He piston performs an oscillating movement inside a cylinder, which is surrounded by a balance tank connected to a source of gas under pressure The piston regulates a connection opening between the cylinder and balance tank. Since this opening of the cylinder connection is located near an open end of the cylinder, which is opposite and in communication with an open end of the resonator tube, the resonator tube is also in communication with the inside of the balance tank.

The dimensions of the resonator are chosen from so that a standing sound wave can be generated in the resonator using the gas under pressure supplied by the tank Balance. Preferably, the resonator is a room resonator wave, in most cases a quarter resonator tube wave. When a standing sound wave has been generated in the resonator, this standing sound wave has its maximum amplitude of sound pressure at the place where the unit is located feeder This sound pressure works on the surface of the piston end, resulting in an oscillating movement of the piston. The other end of the piston is spring loaded, and the piston can move in phase with variations in the pressure of sound of the standing wave under the condition that the resonance frequency of the mechanical oscillation system be more high than the frequency of the standing sound wave in the resonator. US4359962 describes a sound generator with a resonator tube and a slider which is located in the cylinder.

Sound generators of this type are used, for example, for cleaning large boilers, exchangers of heat and other appliances where it is difficult to get access to surfaces that need to be cleaned.

In many of its applications these generators Sound are used intermittently. When the generator Sound must be turned off for a certain period of time, this is achieved, according to the prior art, cutting off the gas supply to pressure to the balance tank of the feeder unit. In bliss stop position, the piston will normally be located in such way that the opening of the connection between the balance tank and the inside of the cylinder is not completely blocked by the piston and therefore the gas will be flowing back from the resonator tube towards the cylinder and then inside the tank of equilibrium This gas flow has the disadvantage that it can cause corrosion on the sliding surfaces of the piston inside of the cylinder when the gas flows from the resonator tube through of the cylinder and inside the balance tank. Since it exists only a small gap between the outer sides of the piston and the inside of the cylinder, the accumulation of corrosion inside the cylinder can be quite detrimental to the operation of the feeder unit If there is too much corrosion, there is even a risk of that piston movement being inhibited.

Another disadvantage with this sound generator of The prior art is that the starter of the feeder unit does not causes the piston to start moving immediately with its amplitude of work displacement. Instead there is a start progressive movement of the piston that will take approximately half a second before it reaches its displacement amplitude of job.

The object of the present invention is Mainly solve the problems discussed above. This  is achieved, in accordance with the present invention, by means of a air-activated low frequency sound generator provided with the new features defined in the characterizing part of claim 1 of the patent, and by a method as defined in the characterizing part of the claim 6.

Consequently, providing a procedure and a means to bring said piston to a stop position, in the which said connection opening is blocked by the piston, exerting additional pressure on said first driven end by spring of said piston, the important advantage achieved is that corrosion is avoided on the interior surfaces of the cylinder, due to the fact that any return gas flow from the resonator tube to the balance tank is effectively prevented.

Another important advantage that is achieved through the present invention is that a movement starter is obtained of the piston much faster. In accordance with the present invention, an additional pressure is exerted on the end operated by piston spring, which results in the opening of the connection between the balance tank and the cylinder is blocked completely, thereby cutting off the gas supply to pressure towards the feeder unit. When, later, it is done that said additional pressure cease, said connection opening Instantly opens completely, a powerful gas impulse quickly enters the resonator and the resonator will start immediately. Tests have shown that the breadth of the operating sound pressure can be reached in a while as short as in 1/10 of a second.

In most cases, the present invention will result in a stop position where the second end The bottom of the piston will be located near the open end of the cylinder, next to the resonator.

Additional features and advantages of the present invention will be appreciated in the claims remaining dependents.

It should be understood that the expression "sound of low frequency "refers to sound of a frequency of approximately below 38 Hz. A sound frequency of proper operation would be approximately between 15-35 Hz

The present invention will now be described by means of a preferred embodiment, given only as a example, and with reference to the attached schematic drawings, in which:

Fig 1 is a schematic illustration of a Sound generator according to the present invention, during the operation, with the piston located in its neutral position higher,

Fig 2 is a schematic illustration of a Sound generator according to the present invention, during the operation, with the piston located in its bottom dead center, Y

Fig 3 is a schematic illustration of a sound generator according to the present invention when It is in an intermittent stop.

Initially reference is made to Figs. 1 and 2. The illustrated sound generator comprises a unit feeder 1 mounted on a resonator, which in the case illustrated is a quarter wave resonance tube 2. The feeder unit includes a piston 4 that is arranged to perform a movement oscillating inside a cylinder 5, between a top dead center 3, shown in Fig. 1, and a lower dead center 8, shown in the Fig. 2. The piston is spring loaded by means of spring 6, which is attached to the closed end of the cylinder. The cylinder and the pistons are mounted on a balance tank or shell 7. A first source 9 of pressurized gas, providing a gas pressure constant p_ c1, preferably by compressed air, is connected to the balance tank 7. The cylinder has one end open 11 in front of the resonance tube and in communication with East. The cylinder is also provided with one or several openings of connection or holes 10 in the cylinder wall by means of the which the pressurized gas supplied to the equilibrium tank can also enter into the cylinder and continue down towards the resonance tube At the upper closed end of the cylinder, by above the piston, there is a connection opening 18 used for the pressure equalization and provides communication either to atmospheric pressure or to a space at the open end of the tube of the resonator.

When the sound generator is in operation, the gas pressure p_ at the rear end of the resonance tube, that is, that end of the tube resonance that is in communication with the cylinder and the unit feeder, below the piston, varies according to

p_ {g} = p_ {1} + \ hat {p} _ {0} \ sen \ 2 \ pi \ \ cdot \ f \ \ cdot \ t

Where

p_ {1} = constant air pressure in the rear end of the resonance tube.

\ hat {p} 0 = amplitude of the pressure of sound at the rear end of the resonance tube

f = frequency of the sound wave stationary

t = time.

If the constant air pressure above the piston, p2, is equal to the constant pressure at the end back of the resonance tube, p1, the differential pressure above the piston is \ hat {p} 0 {sin} \ pi \ cdot f \ cdot t.

When the differential pressure has its maximum value (+ \ hat {p} 0), the piston is pressed to neutral top, which is illustrated in Fig. 1. In that position, the holes 10 in the cylinder 5 are open and an air pulse 12 It is supplied inside the cylinder.

When the differential pressure has its value minimum (- \ hat {p} 0), the piston is sucked into neutral bottom, as illustrated in Fig. 2, and the holes are closed.

In accordance with the present invention, in the opposite end of the cylinder, that is the end that is not in front of the resonance tube and at whose end the spring is fixed of the piston, there is a second source of pressurized gas 14 connected to the cylinder This second pressure source 14 supplies a constant gas pressure, p2, preferably air compressed, which is regulated by a regulating valve 15. This compressed air pressure, p_ {c2}, is much higher than the gas pressure p_. As the regulating valve 15 is in the position shown in Figs. 1 and 2, that is the supply from the pressurized gas source 14 is cut, the piston will move between the top and bottom dead spots with the frequency f of the standing wave in the resonance tube.

When valve 15 is switched to position open pressure shown in Fig. 3, the compressed air pressure, p_ {c2}, generated by the second source of pressurized gas 14, will act on the upper end of the piston and will serve to press down the piston. This gas pressure p_ {c2} must be so high, compared to the gas pressure p_ {g}, that the piston is pressed down to a position where its point top dead is located below holes 10. In consequently said holes will be blocked by the piston and the gas pressure p_ {c1} of the first source 9 of pressurized gas will be cut. In this position, the sound generator will enter a stop since the piston movement will stop when the air compressed from the first source 9 of pressurized gas cannot enter inside the resonance tube 2. In the embodiment advantageously illustrated in Fig. 3, the piston will be pressed towards down against a seat 16 arranged at the lower end of the cylinder 5.

When you want the sound generator to enter in operation again, the position of the valve 15 changes from the position illustrated in Fig. 3 to the position illustrated in Fig. 1. The spring will then move the piston to a position by above the holes, and the piston will be free to move again between its upper and lower dead spots. Be will allow the pressurized gas from the first gas source 9 to pressure enters the cylinder again and then down to the tube resonance.

In order to control the operation of the regulating valve 15, preferably some type is provided of control medium. This control means can be a manual means or some type of automatic control means known per se.

The inventive concept, in accordance with the present invention should not be limited to the embodiment illustrated here, by way of example only, but can be modified and varied within the scope of the invention as it is defined in the appended claims of the patent.

Claims (10)

1. An air-activated low frequency sound generator comprising an open resonator that works as a sound emitter and also comprising a feeder unit (1), for the generation of gas-borne stationary sound waves, whose sound waves they produce a variable sound pressure within said resonator, said feeder unit (1) including a cylinder (5) with an open end (11) in front of said open resonator and in communication with it, also including a piston (4) which performs an oscillating movement within said cylinder (5) and having a first spring-operated end and a second opposite end in front of said resonator, and also that includes a balancing tank (7), which at least partially surrounds said cylinder ( 5) and connected to a first source of pressurized gas (9), to feed pressurized gas into the equilibrium tank (7) and then into said cylinder (5) through d and a connection opening (10) disposed in a wall of said cylinder, and said piston (4) that functions as a valve for regulating said connection opening, characterized in that it comprises means (14) for bringing said piston (4) to a stop position, in which said connection opening (10) is blocked by the piston (4), exerting additional pressure on said first spring actuated end on said piston. 2. A low frequency sound generator according to claim 1, characterized in that it comprises a second source of pressurized gas connected to said cylinder for supplying pressurized gas to a space within said cylinder and behind said piston to exert said pressure in the spring-loaded end of the piston. 3. A low frequency sound generator according to claim 2, characterized in that it comprises a regulating valve for regulating the connection of said second source of pressurized gas. 4. A low frequency sound generator according to claim 3, characterized in that it comprises a control means for opening said regulating valve when the sound generator must be brought to an intermittent stop or to close said valve when it is intended that the Sound generator comes into operation again. 5. A low frequency sound generator according to any of claims 2-4, characterized in that a seat is provided at the open end of said cylinder and that said second end of said piston is brought to the stop against said seat in its position of stop. 6. A method for regulating the stop position of a piston (4) included in a low frequency sound generator comprising an open resonator that works as a sound emitter and also comprises a feeder unit (1), for the generation of gas-borne stationary sound waves, whose sound waves produce a variable sound pressure within said resonator, said feeder unit (1) including a cylinder (5) with an open end in front of said resonator and in communication with this, further including said piston (4) that makes an oscillating movement within said cylinder (5), said piston (4) having a first spring-operated end and a second opposite end in front of said resonator, also including an equilibrium tank (7), which at least partially surrounds said cylinder (5) and connected to a first source of pressurized gas (9), to feed pressurized gas into the tank of e balancing (7) and additionally within said cylinder (5) through at least one connection opening (10) disposed in a wall of said cylinder (5) and said piston (4) functioning as a valve for regulating said connection opening (10), characterized in that said piston (4) is brought to a stop position in which said connection opening (10) is being blocked by the piston (4), by means (14) of the application of additional pressure at said first spring actuated end of said piston (4). A method according to claim 6, characterized in that said additional pressure is exerted in the form of a gas pressure, whose gas pressure is fed into said cylinder from a second source of pressurized gas connected to said cylinder. A method according to claim 7, characterized in that the connection of said source of pressurized gas is regulated by a regulating valve. 9. A method according to claim 8, characterized in that said regulating valve is open when the low frequency sound generator must be brought to an intermittent stop and because it is closed when it is intended that the sound generator be put into operation again. 10. A method according to any of claims 6-9, characterized in that said second end of said piston is brought to the stop against a seat located at the open end of said cylinder exerting said additional pressure.