NO151358B - PROCEDURE FOR SLAM DRAINAGE - Google Patents

Description

Sonar.

The present invention relates to echo-

lots for sending and receiving pul-

looks for acoustic energy (usually ultrasound)

for locating objects in relation to a ship on which the sonar is mounted,

e.g. for recording the seabed or fish. Especially when the sonar is used for locating fish, it is desirable to be able to receive quantitative echo registers

on the basis of the echoes can give an impression of the size and quantity of the fish as well as the depth the fish is in. There are, however, certain difficulties in

now quantitative recordings due to variations in the coupling between the electroacoustic transducer and the surrounding seawater. Such variations appear on

due to the occurrence of air in the vicinity of the electroacoustic transducer due to the ship's speed and sea: The purpose of the invention is to provide a sonar which is less sensitive

such as for variations in the connection between the electroacoustic converter and the

yielding seawater than with previously known echo sounders.

In the case of a sonar comprising a pre-

stronger and an associated pulse generator

tor for generating electrical pulses at specific intervals, an electroacoustic

ical converter which is supplied to the mentioned pulses for sending out corresponding acoustic pulses, and reception of echo pulses which are converted into electrical pulses which are supplied above the amplifier with an indicator to indicate the time between pulse sending out and reception, this is achieved according to the invention

late in that the electroacoustic transducer consisting of a number of equal units arranged in different places of a ship,

over a faces with a to number of units corresponding positions connect one and one en-

hot with the generator and amplifier on

in such a way that when the electrical pulse appearing at the output of the amplifier does not have a greater amplitude than predetermined, within a certain time after the pulse is emitted from the generator, components ensure that the inverter is brought into a new successive position. Preferably, the predetermined am-

plitude chosen so that it is exceeded by echo pulses from a reference object, e.g. the seabed or a shoal of fish, by normal connection between the generator, the amplifier, the converter units and the seawater.

In this way. will it by performance

of air in the vicinity of a converter unit during operation, insufficient coupling with the water occurs, so that the next pulse emission will take place from the converter unit that is put into operation at the following turning position. Preferably, each converter serves-

hot both for sending and receiving. Preferably, a regulating device is arranged for regulating the amplification

clean gain according to signals received from a reference object, to compensate for variations in the coupling between the generator, amplifier, converter units and the sea water.

The reference object can in this case

be the seabed.

Alternatively and preferably, the reference object can be a body located during operation in a fixed position in relation to the electroacoustic converter.

An embodiment of the invention will be explained in more detail with reference to the drawing. Fig. 1 shows a block diagram for a sonar according to the invention. Fig. 2 shows various diagrams showing the pulse shapes at different locations in the block diagram. Fig. 3 shows a connection diagram for a modified part of the sonar.

The sonar according to the embodiment has a conventional indicator 1 with a pen which is moved at a uniform speed across a strip of suitable recording paper which is moved at a uniform speed perpendicular to the movement of the pen. At a fixed point for each movement of the pen across the paper, an electrical contact is made which provides a trigger pulse shown in fig. 2a.

The trigger pulse controls an ordinary electric pulse generator 2 for the supply of electric pulses with ultra sound frequency, through a rotary vane 3 with three positions, to one of the three electroacoustic converter units 4a, 4b and 4c, depending on the vane's position. The converter units 4a, 4b and 4c are arranged for producing ultrasonic pulses by supplying suitable electrical pulses, and receiving echo pulses and producing corresponding electrical pulses. The converter units 4a, 4b and 4c are placed in different places on the ship's bottom, and the locations have been chosen on the basis of experience, so that the possibility of all three converter units being simultaneously exposed to connection difficulties with the surrounding seawater is minimal. Echo pulses that hit the converter units provide electrical signals which are fed via the inverter 3 to a conventional amplifier 5. The input signals to the amplifier 5 consist of strong signals from the transmitted pulses, followed by signals corresponding to echoes from fish or the seabed, as shown in fig. 2g. These signals are amplified and rectified by the amplifier 5, so that an output signal corresponding to fig. 2b. The signals as shown in fig. 2b is supplied to the printer 1 where the signals are drawn up in a known manner.

The signals are also supplied to an automatic gain control circuit 6 which normally regulates the gain to maintain an amplitude of the received signals from a reference object at an approximately constant level. The reference signals can be echo signals from the seabed. Alternatively and preferably, the reference signals can be signals received from a body, e.g. in the form of a ball suspended at a predetermined distance from the bottom of the ship. The automatic gain regulation preferably works in the same way as described in British patent document No. 808,274.

The signals in fig. 2b is also supplied to a gate circuit 7 which only lets through a signal with an amplitude that exceeds a certain level I in fig. 2b.

The signal from the gate circuit 7 has a form which is shown in fig. 2c, which only contains the transmitted pulse signal and an echo signal representing the seabed. This signal is supplied to a multivibrator 8 which is also supplied with the control signal from the indicator 1, as shown in fig. 2a, in such a way that the multivibrator is started by sending a pulse and is stopped again by the echo signal from the seabed. However, it should be noted that the multivibrator 8 will also stop automatically if no pulse is received from the seabed, before the appearance of a new pulse transmission. The multivibrator 8 is monostable with a period that is slightly shorter than the time interval between the sending of two consecutive pulses.

The multivibrator 8 thus produces an output signal as shown in fig. 2d, i.e.

■ a negative square pulse that starts when a pulse is sent and normally ends when an echo pulse is received from the seabed.

The signal from the multivibrator, as shown in fig. 2d, a conventional Miller integrator 9 is supplied which provides a sawtooth pulse, as shown in fig. 2nd.

The signal as shown in fig. 2e is applied to the input of a further gate circuit 10 which lets through signals with an amplitude that is more negative than a fixed level II in fig. 2nd. Level II has been chosen so that it is not reached until reception of an echo signal from the seabed at the expected depth, but is reached by the signal in fig. 2e if no echo is received from the seabed with an amplitude corresponding to satisfactory coupling between the transducer and the seawater.

The gate circuit 10 provides an output pulse, as shown in fig. 2f, and only if no echo pulse is received from the seabed.

The output signal from the gate circuit 10 is fed to a step mechanism 11 which affects the rotating vane 3.

Provided that an echo is received from the bottom with sufficient amplitude within a period of time when such a signal can be expected and the sonar works satisfactorily, the turner 3 will not be operated. If, however, no echo signal from the bottom is received,

which means that the converter unit in question above inverter 3 is connected

with the pulse generator 2 and the amplifier 5

does not work satisfactorily, the next inverter unit will be connected using

the turner 3; and satisfactory signals will

probably achieved using this converter unit.

The multivibrator 8 can be replaced by a

coupling device as shown in fig. 3. I

this coupling device is a resistor

21 and a capacitor 22 connected in series

across a supply voltage. A coil 23 and a

thyratron 20 is connected in series in parallel

with the capacitor 22. The coil 23 drives

a two-way rotary vane (not shown) which

is connected to the Miller integrator 9.

When no signal is supplied to the grid in the thyratron 20, the capacitor 22 is charged. The waveform shown in fig. 2a is added

the grid in the thyratron and ignites this, like this

that current flows through the coil 23. The capacitor 22 discharges quickly and goes out

the thyratron 20, after which the capacitor

22 is recharged.

The waveform as shown in fig. 2c is supplied to the grid in the thyratron 20 and normally will

an echo signal from the seabed cause a

corresponding discharge of a pulse current

through coil 23. The rotatable faces

is moved to the next position by the pulse current

and its contacts are subjected to voltages,

so that a waveform is provided, which

shown in fig. 2d. If the amplitude of the echo signal from the seabed is below the level

I, the waveform of fig. 2c do not ignite

the thyratron 20 and the waveform as shown in

fig. 2e will be below level II. The waveform in fig. 2f is then provided and drives

the step mechanism 11. The thyratron 20 is fed with a signal from the step mechanism 11

which ensures that the thyratron will always ignite

before the next transmission of a signal with

the waveform in fig. 2a. The three signals which

supplied to the grid in the thyratron 20 is isolated

from each other by resistors or cathode followers. As will be seen, this switching device works in the same way as the multivibrator 8.

Claims (4)

1. Echo sounder comprising an amplifier and a pulse generator connected thereto for producing electrical pulses at specified intervals, an electroacoustic forms which are fed to the mentioned pulses for sending out corresponding acoustic pulses, and receiving echo pulses which are transformed into electric pulses which are fed above the amplifier with an indicator to indicate the time between pulse sending and receiving, characterized in that the electroacoustic converter which consists of a number of equal units (4a, 4b, 4c) arranged in different places of a ship, above a turn (3) with a position corresponding to the number of units connect one and one unit (4a, 4b, 4c) with the generator (2) and the amplifier (5 ) in such a way that when the electrical pulse appearing in the output of the amplifier (5) does not have a larger amplitude than predetermined, within a certain time after a pulse emission from the generator (2), components (7, 8, 9, 10, 11) so that the turner (3) is brought into a new successive position. 2. Sonar according to claim 1, characterized in that the predetermined amplitude is chosen so that it is exceeded by echo pulses from a reference object, e.g. the seabed or a shoal of fish in the case of a normal connection between the generator (2), the amplifier (5), the converter units (4a, 4b, 4c) and the seawater. 3. Sonar according to claim 1 or 2, characterized in that a regulating means (6) for regulating the amplification of the amplifier (5) in accordance with signals received from the reference object. 4. Echo sounder according to one of claims 1-3, characterized in that the said components comprise a sawtooth pulse generator (9) which is triggered by the pulses from the generator (2) to give a control signal, a first gate valve (7) which is fed from the output of the amplifier (5) and only lets through signals above a predetermined amplitude, with signals that have passed the gate circuit (7) being fed to the sawtooth pulse generator (9) to interrupt the control signal, and a second gate circuit (10) which lets through the control signal when this exceeds a predetermined amplitude, to the inverter (3) for its operation.