SU1760539A1 - Acoustic generator - Google Patents

Abstract

Use in the field of technical acoustics and as a source of powerful and super-powerful sound signals in shipbuilding. SUBSTANCE: invention comprises a pipe-shaped body, one of the ends of which is connected to a matching horn and is installed inside the pipe on its axis a working body with a drive, the working body is made in the form of an impeller of a fan with an even number of blades that have opposite angles of attack through one , while the second end of the tube is provided with a bottom, radial partitions are uniformly installed inside the pipe between the bottom and the impeller of the fan, the cavities between which through one are provided with transverse partitions on the side stops, and the cavity between the transverse baffles and the inlet is pneumatically connected to the horn cavities between the impeller and the bottom which are shifted with respect to the cavities open to the horn input, an angle corresponding to the angular size of a single cavity. In the walls of the body of all cavities between the radial partitions, which are not connected to the entrance of the matching horn, through windows are made. 1 hp ff, 2 ill.

Description

The invention relates to technical acoustics and can be used as a source of powerful and super-powerful low-frequency sound signals, in particular as a source of sound signals in navigation.

Known acoustic generators used as a source of powerful low-frequency sound signals.

Emitter of an acoustic signal on an auth. St. No. 720486 is made in the form of a cylindrical resonant chamber with a slotted nozzle located opposite the wedge-shaped notch in the side surface of the chamber, and provided with a cylindrical nozzle and a piston mounted for movement in the nozzle coaxially with the resonant chamber, with the ratio of the nozzle diameter and the resonant chamber 1 / 4-1 /five.

It requires the presence of compressed air, which is not always possible, and in addition, it has a significantly lower efficiency than the in and proposed generator.

Sirens contain a source of gas (air) jet and a Siren flow interrupter, in particular the von Gerke siren, are structurally made similar to the proposed generator, but according to the pattern of acoustic oscillations they have nothing in common with it. Besides the / o, sirens have a significant disadvantage

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compared with the proposed acoustic generator. Due to the fact that the principle of action of sirens is based on the modulation of the gas flow, at least half of the power in them is expended on a constant component, which reduces the efficiency.

Of the known acoustic generators, the closest in technical essence to the proposed device is an electrotophone according to the author. St. No. 357587.

It contains a horn mounted on a cylinder with a piston coupled to a camshaft, kinematically connected with an electric motor, with the s piston filling the window with the rotation bodies inside it that are coupled to the camshaft.

The motor shaft of this electric motor is connected to a gearbox, by means of which the rotational speed is adjusted to the required one, with the help of a camshaft, the rotational movement is converted into reciprocating and transferred to the piston that performs this movement in the cylinder. One cylinder outlet is connected to the horn outlet, and the antiphase generation of the back side of the piston is usually not used (muffled or connected to the atmosphere) or is used in separate circuits using phase inversion special tools.

The presence of the gearbox and cam mechanism complicates and increases the cost of the device. In addition, they reduce the service life of the device, require regular maintenance (lubrication). Another fundamental disadvantage of a piston radiator arises from the fact that the working body in it performs a reciprocating motion. With increasing radiator power, there comes a moment when no known structural materials used in the manufacture of the piston can withstand the load, i.e. the power of such a radiator is limited.

The aim of the invention is to increase the radiated power and simplify the design.

The goal is achieved by the fact that in an acoustic generator containing a body in the form of a pipe, one of whose ends is connected to a matching horn, and a working body with a drive mounted inside the pipe on its axis, the working body is made in the form of an impeller of a fan with an even number of blades that have opposite angles of attack through one, while the second end of the pipe is provided with a bottom, evenly inside the pipe between the bottom and the impeller of the fan

Radial partitions are installed, the number of which is equal to the number of blades of the wheel, the same radial partitions are installed between the impeller and the horn inlet, the cavities between which are equipped with transverse partitions on the horn side and the cavity between the transverse partitions and the horn inlet are pneumatically connected to the cavity between the worker wheel and bottom, shifted with respect to the cavity, open to the entrance of the horn, at an angle corresponding to the angular size of one cavity.

Distinctive features of the proposed acoustic generator, which provide increased radiated power and simplified design, are absent in other objects of the equipment, which allows to conclude that the proposed technical solution complies with the criteria of the invention: novelty and significant differences.

Figure 1 shows a schematic representation of the proposed device in two projections in section (without a cut of the impeller and electric motor); Fig, 2 - the device in isometric projection,

The acoustic generator comprises a housing in the form of a pipe consisting of segments 1 and 2; flange 3 connecting pipe lengths; matching mouthpiece 4; a flange 5 connecting one end of the pipe with a matching horn; the working body in the form of an impeller 6 of a fan with an even number of blades, which through one have opposite angles of attack (in figures 1 and 2 a four-wheel is shown without twisting the blades); the drive in the form of an electric motor 7 located in the inactive central part of the pipe section 2; blades 8 with a positive angle of attack; blades 9 with a negative angle of attack; the bottom of the second end of the pipe 10; uniformly mounted radial partitions

11 between the bottom and the impeller, the number of which is equal to the number of wheel blades; the same radial partitions

12 between the impeller and the entrance of the horn; transverse partitions through one cavity on the side of the horn 13; pipes 14 for pneumatic connection of the cavities between the bottom and the impeller with the input of the horn; windows 15 on the body; working cavity 16 cut 1 pipe; insulated from the mouth of the mouth of the cavity 17 of the pipe section 1; working cavity 18 of the pipe section 2; not connected to the mouth of the mouth of the cavity 19 of the pipe section 2; working cavity 20 at the outlet of the pipe 14,

The device works as follows.

When starting the electric motor 7, the impeller 6 begins to rotate, the blades 8 of the impeller begin to work as pipes forcing in section 1, and as pipes suction from section 2, and the blades of 9 impellers on the contrary as pipes from inlet 1 and forcing into 1 pipe section.

If there were no radial partitions 11 and 12, neither suction nor injection into the 1 m 2 pieces of pipe would exist. Since radial partitions 11 and 12 are installed on both sides of the impeller 6, forming cavities 16-19, the picture changes fundamentally. The partitions in the pipe section 2 do not reach the axis of the pipe and end at the non-working cavity in which the electric motor 7 is installed. The distances between the impeller and the partitions are minimal.

The formed cavities 16-19 begin to work as independent pipes. Partitions prevent the mixing of positive and negative flows from the blades (except for tsgo, as in a conventional axial fan, they work as a spraying apparatus, i.e., reduce the curl of flows). Each blade, work on the cavity, works as if on its pipe, regardless of the work of other blades on other cavities. The volume of the cavity (i.e., its height at a given pipe diameter) is chosen for reasons of allowable pressure fluctuations as the blades of different signs pass in front of it. Almost the height of the cavities is approximately equal to the radius of the pipe.

When a positive blade passes in front of the cavity, injection into the cavity takes place; in the next phase, when the negative blade passes in front of the same cavity, suction takes place, i.e. as a result, alternating pressure is created at the outlet of each cavity. In the adjacent cavities, the processes exchanged at this moment for the opposite.

Thus, each cavity generates an acoustic signal at its output, the signals generated by the adjacent cavities are in opposite phase.

At the same time, in pipe section 2, located on the opposite side of the impeller b, the processes are completely similar to those that occur in pipe section 1, with the only difference being that the cavities of the sections on which the same blade is currently working, t . located on the same straight line, they generate phase-out generation relative to each other, as well as the adjacent cavities in one pipe segment.

Thus, on the one hand, the impeller in-phase generation is carried out by cavities 16, antiphase in the cavity 17, on the other side of the impeller in-phase generation is carried out shifted by one with respect to the first cavity 18, in antiphase - in cavity 19.

The generator (figure 1 m 2) has two positive working blades, two negative. In each section of the pipe at the same time

there are four cavities. Two of them are in-phase, two out of phase. In the first and second sections of the pipe, the in-phase and anti-phase cavities are displaced one relative to each other.

The pattern of the formation of in-phase and out-of-phase radiations resembles the pattern of radiation of a piston generator, although outwardly these structures seem to have nothing in common with each other. therefore

the use of acoustic oscillations from the exit of the cavities can be similar to the way it is done in reciprocating generators. It is possible to drown out antiphase oscillations (to brew the outputs

cavities), you can connect with the atmosphere, mine horn, you can apply special schemes (phase-rendering or summing oscillations in some directions), allowing you to use

exits of all cavities. During the operation of the proposed generator for one horn, all the outlets of the cavities 18 and 19 of section 2 are welded to the bottom (the bottom 10 is put) and its in-phase cavities 18 are supplying

pipes. 14 are connected pneumatically with working cavities 20 located in front of the closed cavities 17 of the pipe section 1 outside their dimensions. The end of pipe section 1 is connected to the inlet of the horn 4 by means of flange 5. Thus, the in-phase cavities 16 of the pipe section 1 and 18 of the pipe section 2 work at the horn inlet. The pipe sections 17 and 19, which are antiphase, are isolated from the horn inlet.

The best result is obtained by combining them with the atmosphere with the help of an ocean of oceans 15, cut through in the hull.

It was expected that the result would be better with windows 15 closed, since in this case, the cavities 17 and 19 begin to work as pneumatic springs. In fact, the height of the cavities was chosen optimal for these springs. In practice, with the windows open, the result is better than with the windows closed. The height of the cavities, i.e.

the length of the entire generator may in this case be somewhat reduced.

In addition to the four-blade impeller of the fan, an impeller with any even number of blades up to reasonable limits can be used - 2,4,6,8,10,12,14,16. The number of cavities in the pipes in this case should be equal to the number of blades of the working track.

From the theory of axial aentstilors known. but that an increase in the number of blades can lead to a decrease in efficiency due to an increase in the swirling flux, but in this case it is about. give does not come, because partitions prevent curling. 8, due to the wide variation in the use of the number of blades, there is no need for a gearbox. The generator with the number of blades 2 emits at a frequency equal to the speed of rotation of the engine (50 Hz at 3000 rpm), with the number of blades 16 at a frequency 8 times higher than the speed of rotation of the engine. The reduction was moved from a mechanical gearbox to an air one.

Special consideration should be given to the issue of choosing the size of the distance between the impeller and partitions, which is important. It is known that in sirens that also have a rotor and a stator (analogs of the impeller and partitions), the distance between them is tenths of a mm. The rotor has a so-called sliding fit inside or in relation to the stator. With increasing power and. Therefore, the diameter of the siren to perform such a landing becomes extremely difficult. With an increase in the gap, the efficiency of the siren begins to fall sharply, since the constant component of the flow increases due to the breakthrough of air when the rotor and stator apertures overlap.

It is the ability to maximize the degree of overlap of the holes in the sirens that makes it possible to bring the variable component of the flow to 50% at best.

In the proposed generator, the size of the gap plays a completely different role. The variable component already at the exit of the rotor (impeller) is 100%, since At the entrance of the cavities 16–19, positive 8 and negative 9 blades work across each other. The minimum clearance is chosen in the sense that there should be no overflow of positive and negative flows and unnecessary directions.

The tests of the manufactured acoustic generator were carried out with a gap of 15 mm. No sliding fit here

this is not the case; in the manufacture of the generator, metal-cutting machines were not used, only a welding machine was used, which significantly reduces the cost

device.

The proposed acoustic generator compared to the prototype has several advantages. The power of the acoustic generator can be significantly increased.

0 due to the absence of complex reciprocating movement of the working organ. It can in principle be brought to the power of axial fans, i.e. 1000 kW and more. The prototype for acoustic power greater than 1.5-2 kW is practically no longer operational.

In the proposed generator, the design is simplified and reliability is increased due to the absence of a mechanical gearbox.

0 and cam or kulisno-connecting rod mechanism.

Experiments were conducted confirming the performance of the proposed acoustic generator.

5 A acoustic generator with a diameter of 600 mm and an impeller rotational speed of about 1500 was tested. providing a peripheral speed of the blades about 50 m / s. Were received

0 125 at the exit of the horn.

With an increase in the peripheral speed of the ends of the generator blades to 100–150 m / s and the selection of the optimal design parameters of the generator, its power increases substantially and the efficiency can reach 70% (in the prototype 40%).

 The economic effect of using the invention in relation to a unit of production may be about 3,500 rubles.

Claims (2)

1. Acoustic generator, comprising a housing in the form of a pipe, one end of which is connected to a matching horn, and installed inside the pipe on its axis 5 with a drive, characterized in that, in order to increase the radiated power and simplify the design, the working member is made in the form of an impeller of a fan with an even number of blades, which have opposite angles of attack through one the bottom, inside the pipe between the bottom and the impeller of the fan, uniformly radial partitions, the number of which is equal to the number of blades of the wheel, between the impeller and the mouth of the horn, the same radial partitions are installed, the cavities between torymi through, at anu provided with transverse perego- oodkami by the speaker, and the cavity between the transverse partitions and the horn inlet are pneumatically connected to the cavities between the impeller and the bottom, which are shifted with respect to the cavities open to the horn inlet, by an angle corresponding to the angular size of one cavity. 2. The generator according to claim 1. characterized in that in the housing walls of all the cavities between the radial partitions that are not connected to the entrance of the matching horn, pass-through windows are made ff fS- C --- H } / 7 6