DE864015C - Device for adjusting the depth of fishing nets - Google Patents

Description

For the creation of networks with variable depth during operation, one has so far been of the Thoughts assumed to train the means for adjusting the network depth so that from their setting even the depth of the network can be seen. However, it has been shown that this only a relatively imprecise depth display and thus also an imprecise depth setting of the Network is to be achieved and that the means for adjusting the network depth serve the purpose of depth measurement are not appropriate.

The essence of the invention is that the depth of the network by changing the on Static or dynamic vertical forces acting from the ship in connection with the network a device for measuring the respective network depth is adjustable. The vertical adjustment forces can be replaced by one or more variable displacement bodies, e.g. B. air-filled Bring out bubbles, the buoyancy of which affects the depth of the network. You can use the adjustment can also be generated dynamically by exposing one or more to the driving pressure and the pitch of the elevator can be adjusted from on board in relation to the direction of travel provides.

By arranging several adjusting forces acting at a horizontal distance from one another, is it is possible to achieve both the depth setting and the correct swimming position of the network.

The displacement bodies or rudders are advantageous for changing the depth of the Lashes attached. In this way, collisions can be avoided, especially when the Avoid the network.

In the drawing, the invention is illustrated by way of example, namely shows

Fig. Ι a network according to the invention in operation, in side view,
Fig. Ι a a modification to Fig. I,

FIG. 2 shows the network according to FIG. I, against the direction of travel seen,

3 shows a partial view of FIG. 2; FIG. 4 shows the measuring arrangement belonging to FIGS in a schematic representation.

The net 2 towed by the ship 1 is opened (cf. the points of attack of the hoisting lines 7, 8 dragging the net are at the same depth. The net is designed so that it sinks to the ground when the ship is at rest, i.e. when there is no dynamic forces, and that the vertical force component ν occurring when the ship is moving through the pulling lines lifts the net off the ground until the depth and inclination of the Kurrleinen decreasing dynamic vertical force ν and the pull of the neti downwards keep the equilibrium.

The depth of the network can be adjusted by changing the dynamic or static buoyancy forces acting on the network. For this purpose, as shown in FIGS. 1 and 2, an air bubble in the form of a hose 9 and 10 is attached to each lifting line at the same distance from the network, the volume of which can be changed by blowing in or letting off air. For this purpose, the bladders 9, 10 are connected by pressure hoses 11, 12 to a compressed air source 13 and air outlets 14, 14 _B located on board. The connection to the compressed air source or the outlet can be established or interrupted by valves 15, 16 and I5 _a and i6 _a.

Fig. Ι a shows an embodiment in which a depth elevator 9 ', 10' is attached to each of the trailing lines 7, 8 for variable depth adjustment. The rudders can be adjusted separately from the ship by lines 11 ', 12'. Depending on their tendency towards the attacking flow force R , a more or less large upward or downward force component r occurs, by which the depth setting of the network is influenced. The depth setting is carried out with the aid of a special measuring device. This measuring device uses the hydrostatic pressure on the network as a measure of the network depth. By means of a pressure hose 21, air is constantly pressed down from the compressed air tank 13 via a throttle resistor 22 to the lower open end of the pressure hose. The throttle resistor 22 is set in such a way that air flows continuously into the pressure hose 21 and escapes at the outlet part 17. One can observe the flow of air at the throttle resistor 22 or the line 21; however, it is generally sufficient if the pressure in the container 13 and the throttle resistor 22 are set so that a low flow is ensured for all depths.

For this purpose, the pressure in the container 13 can through a compressor system not shown in the drawing either constantly kept so high be that there is always a sufficient excess pressure available, or the pressure can in the container 13 by hand or automatically as a function of be regulated by the respective network depth so that it is always a certain amount above the the water pressure corresponding to the depth of the network. If the pressure in the container 13 is kept constant, so the throttle resistor 22 must at all possible network depths the pressure difference between the Pressure in the container and the pressure in line 21, d. H. the respective water pressure on the network or at the exit point 17. With a constant throttle resistance, this can increase Adjust the pressure difference only by means of a correspondingly different flow rate. Man but can also adjust the throttle resistance manually or automatically, depending on the respective Regulate the network depth so that the flow velocity is essentially the same for all network depths remain.

The pressure behind the throttle resistor 22 required for this is equal to the pressure of the water column α at the outlet point 17, ie equal to the net depth η reduced by the height (n - a) between the outlet point 17 and the center of the net. The changes in this height (w- a) with the network depth and speed are so small that to determine the network depth η the measured depth α only has to be increased by a constant value k in order to increase from the value α to the desired network depth η reach. The value k can be determined once and for all through experiments, in that the differences (n - d) occurring during operation are measured in a series of experiments by arranging an additional measuring hose to the center of the network.

The pressure of the water column is measured by a manometer 18 which is calibrated in such a way that its pointer 19 directly indicates the respective network depth η on a straight depth scale 20. The air bladder 10 could be brought to the same pressure as the air bubble at the trawling cable 8 but 9. It is possible to set up also, as shown in the example, so form that the air bladder 10 through separate valves i5 _a, i6 _s separately to the pressure vessel 13 and outlet I4 _{a is} connected. Then, by pumping up the second air bubble 10 more or less, it is possible to compensate for incorrect swimming positions of the net, which are noticeable in a different height setting of the two otter boards or rope ends. The prerequisite for such a correction is that one can observe the swimming position of the net. For this purpose, a measuring device is provided through which the difference in the hydrostatic pressures at two points of the Kurr-

line is measured, namely at the point 17 of the hoisting line 7, at which the air hose 21 ends, and at a point 23 of the Kurrleine 8, to which a second measuring hose 24 from the air chamber 13 over a choke resistor 25 is brought down. The throttles 22 and 25 can be set so that that even for the lowest network layer the pressure is sufficient to displace the water column up to the outlet points 17 and 23 of the pressure hoses.

The difference in these pressures is measured by a manometer 26. _{Its pointer 27 actuates the valves I5 a} and i6 _n via contacts 28, 29 and relays 30, 31 as soon as it deviates from its zero position due to different depths (a - b) of the hose openings 17 and 23. The volume of the displacement body 10 is then _{increased or decreased by opening the valve i5 a} or i6 _e until the correct floating position of the network is restored and the measured depths a and b are equal to one another.

The pointer 19 of the pressure gauge 18 is used as a control contact designed for the device for adjusting the depth of the network. This depth setting 'is determined by a pair of contacts 32, 33 which can be adjusted along the scale 20 by hand. So long the depth pointer 19 is in the middle between the two contacts 32 and 33, the remain Valves 15 and 16 closed; if the pointer differs from that determined by the contacts 32, 33 Depth value after smaller depths, the circuit of a current source 34 is via a Relay 35 is closed and the line 11 is thereby connected to the outside air via the valve 16. Air slowly escapes from the hose 9 via the line 11 and the valve 16 until the Network sinks again to greater depth as a result of the shrinkage of the bubble 9, the circuit of the Relay 35 is opened again by moving back the pointer 19 and the valve 16 is closed.

Conversely, if the network migrates from the given depth to greater depths, then through the pointer 19 via the contact 13 of the circuit a relay 36 closed and thus the bladder 9 via the line 11 and the valve 15 with the Pressure vessel 13 connected. The volume of the displacer 9 is then increased by blowing in air and thus its buoyancy is increased, and the net returns to its intended position.

Under the manometer pointer 19 and the control contacts 32, 33, the writing strip 37 of an echograph, which is connected to an acoustic echo sounder apparatus 38 with a transmitter 39 and a receiver 40, moves transversely. The echoes received by the echo sounder device from the sea floor and from the school of fish S are recorded on this writing strip by a pen (not shown in the drawing). The sea depth t and depth s of the schools of fish are displayed over the width of the writing strip, in such a way that the depth scale of the manometer and the echograph coincide.

For the correct setting of the network, it is only necessary to set the expensive contacts 32, 33 to the depth J of the school of fish indicated by the echograph. The net is then brought completely automatically to the depth specified by the control contacts 32, 33, namely the depth j of the school of fish, and is held at this depth. Through the contacts 32, 33 in connection with the net depth pointer 19, the valve 15 or 16 is opened until the net has reached the predetermined depth and the pointer 19 is out of contact with the contacts 32, 33. The proper network location is given by the differential pressure gauge 26, the pointer 27 through the relays 30, 31, the valves i5 _a, i6 controls _a for the second pressure bladder 10, and in such a way that occurring pressure differences as a result of different depth settings of the two pressure bubbles 9 and 10 are automatically compensated.

The invention is not restricted to the examples shown; Changes and other designs possible.

When setting the depth using variable displacement bodies, it must be ensured that the impulse to change the depth, a pressure change initially in the opposite direction. Senses requires. the An increase in volume caused by an increase in air pressure causes a shift in the Network to shallower depths, d. H. in the sense of a reduced water pressure, and vice versa. As soon as the network is relocated, the air pressure must be readjusted accordingly so that the change in water pressure does not change the volume if possible of the displacer. So you have to lower the air pressure to move it down To achieve lows, first increase, and after this movement occurs, decrease again. It would also be possible to provide displacement bodies whose volume is independent of the water pressure and can only be changed from board.

In order to determine and control the swimming position of the network, other or more than can also be used two points of the lifting lines or the net are measured. The depth measurement can of course also in other ways, e.g. B. done by pressure cans with electrical transmission of the measured values. To establish the correct swimming position, the measured values are not reported on board required if the device to compensate for wrong swimming positions is completely on the Attaches network and connects there with the controlling measuring device.

Claims (8)

PATENT CLAIMS: 1. A device for adjusting the depth of fishing nets, characterized in that the Depth of the network by changing the static or dynamic acting on the network Vertical forces from the ship in connection with a device for measuring the respective network depth is adjustable. 2. Apparatus according to claim 1, characterized by one or more in theirs Volume that can be changed on board, preferably air-filled displacement bodies (9, 10), whose buoyancy affects the depth of the network. 3. Apparatus according to claim 1, characterized in that it is provided with a dynamic, Depth control adjustable from board is provided (Fig. ia). 4. Apparatus according to claim 3, characterized in that for dynamic depth control one or more rudders (9 ', io') which are exposed to the travel pressure (R) and are adjustable in their inclination against the direction of travel on board are provided. 5. Apparatus according to claim 1 to 4, characterized characterized that at a horizontal distance from each other several separated from board attack from controllable vertical forces that are used both to control the depth setting as are also suitable for maintaining the correct floating position of the net. 6. Fishnet according to one of the preceding claims, in particular claim 5, characterized characterized in that the device for changing the depth of the Kurrleinen as or attached or to be attached to a lifting line. 7. fishing net according to claim 5 and 6, characterized in that the difference in the depth setting is measured between several points in the network. 8. fishing net according to claim 7, characterized in that the means for changing the floating position of the network is automatically controlled by the measured depth difference will. 1 sheet of drawings 95811.55