RU2185727C1 - Food-fish water area monitoring method - Google Patents

Abstract

FIELD: commercial fishing method. SUBSTANCE: method involves selecting area and time of setting catching equipment; setting catching device providing for passage of fish through predetermined section; hauling catching device in predetermined time and determining amount of fish yield. Catching device comprises catches of cascade order adapted for catching objects moving in concrete direction. Predetermined section is effective area of catches of cascade order in catching object movement zone. Catching device is set between fattening and wintering zones so that catches of cascade order intersect supposed site of migrating flows of objects of catching at predetermined period. Method further involves determining path of flows of objects of catching by comparing catching results obtained from virtual setting of catches of cascade order and results obtained from real setting of catches of cascade order in food-fish water area coinciding with place where real catches are set; providing three-staged setting of catches of cascade order: first stage involves sequentially arranging catches of cascade order in "catch-guiding wing-catch" pattern in single line at an angle equal to marine course angle establishing catches of cascade order; second stage involves setting catches of cascade order in direction coinciding with that of arrangement of the most effective catches of cascade order revealed at first stage; third stage involves setting catches of cascade order while taking into account the extent of filling catches of cascade order within each cascade order revealed at second stage. EFFECT: reduced cost of forecasting fish yield at predetermined time and in predetermined area by avoiding the procedure of collecting additional information. 4 dwg

Description

 The invention relates to the field of industrial fisheries, and in particular to methods for monitoring fishing areas.

Closest to the claimed method should include a method of monitoring the object of fishing, based on taking into account the number of herds of migratory and semi-migratory fish that passed over a certain time through the cross section of the river. The method includes the following steps: setting a fishing gear, in particular a cast seine across the river cross section, sampling a cast seine after a certain time, counting the number of caught individuals and determining the size of the whole herd. The total number of fish passing through the harvested section of the river is calculated by the formula:
P = nvVT,
P is the total number of fish passing through the harvested section of the river;
n is the number of fish per unit area;
v is the speed of the fish;
V is the width of the river at the place of fishing;
T is the time elapsed between successive notes.

 This method allows using casting net to determine the number of the fishing object in a certain place and at a certain time and calculate the total number of moving fish (Baranov F.I., Technique of industrial fishing. All-Union Cooperative Publishing House, M.-L., 1933 p. 199-201).

 However, the use of offshore seine to record moving fish in the marine area is ineffective due to its large size and lack of knowledge about the trajectory of the fishing object, since blocking the stream ("river") in the marine area along which the fish goes to the place of seasonal concentration, it is difficult, in addition, when casting a net, a fish moving in both forward and backward directions will be caught, which will ultimately lead to a significant error in calculating the number of herds and to incorrect moni Oring fishing waters. The disadvantages of this method should also be considered the following: the work of the overhead net is cyclical and short-term, which greatly complicates the monitoring, and due to the limited size and tight binding of the net net to the coastline, it is almost impossible to track the deep movements of the fishing object.

 The movement of fish from the place of seasonal concentration (wintering place - feeding place) in the sea occurs along underwater trenches, which can conditionally be taken for many rivers, each of which moves the fish in one direction or another, so you can use to monitor the fishing area method of accounting the number of migratory fish proposed by F. Baranov (Technique of industrial fishing. All-Union Cooperative United Publishing House, M.-L., 1933, p. 199-201). The flow of fish between places of seasonal concentration is carried out according to the "hourglass principle", while the bases of the clocks are places of seasonal accumulations of fish, and the flows of seasonal migration of fish pass through a lot of sandglass necklets, which can conditionally be taken as "small rivers".

 Monitoring of the fishing area will make it possible to find the location and trajectories of the "rivers", to track the movements of fish flows at a certain time and in a certain place, while ensuring the solution of the main problem - determining the most rational quantitative and qualitative location of the fishing fleet in the fishing area.

 The solution of this problem will allow a more rational use of material resources, namely, to determine exactly how many vessels need to be used in the fishing area, what tonnage and what fishing gear should be on these vessels. This will avoid the cost of maintaining the excess fleet and at the same time ensure the maximum possible catch.

 The problem is solved in that in the known method of monitoring the fishing area, including the choice of place and time of installation of the fishing gear, setting the fishing gear, ensuring the passage of the fish through a certain section, its selection after a certain time and determining the size of the fishing object, in accordance with the invention, as fishing gear, cascading order traps are used, which ensure the catch of objects moving in a specific direction, and the area of the catch of the helmet traps is taken as a specific section bottom order, which appears in the zone of movement of the fishing object and is determined by the product of the length of the guide wing and the speed and time of movement of the fishing object, the fishing gear is set between the places of feeding and wintering of the fishing object by crossing orders of cascading traps of the estimated location of the migration flows of the fishing object in a certain period of time, the trajectory of the flows is determined by comparing the results of the catch obtained by virtual setting the orders of cascading traps and real setting the order Of cascade traps in the fishing area, which coincides in location with the actual setting, the ordering of cascade traps is carried out in three stages: at the first stage, cascade traps are arranged sequentially in the trap-guiding wing-trap system in one line at an angle equal to the ship's heading , which establishes the order of cascade traps, and the degree of filling of the cascade order traps determines the direction of movement of the fishing object, at the second stage, cascade traps are placed in the direction At the third stage, the cascade order traps are located taking into account the degree of filling of the cascade order traps inside each order determined at the second stage, the fishing results obtained by real setting the orders of cascade traps, plotted on the map of the fishing area, while automatically using the resolver, the results of the virtual setting of the orders of cascading traps obtained on Based on the processing of known information, the comparison results characterizing the trajectory of the actual migration flows of the fishing object at a specific time for a specific period are displayed on the monitor screen.

 Using for calculating the total number of fish passing through a certain section, the area located in the zone of movement of the fishing object and determined by the product of the length of the guiding wing and the speed and time of movement of the fishing object, allows for the most correct calculation of the fishing object in extensive fishing areas, catching individuals moving in only one direction, while the guiding wings do not allow the fishing object to jump over the fishing gear.

 The inventive method of monitoring fishing areas is applicable for counting the number of flocks of bottom aquatic organisms, in particular flatfish, halibut, rasp, perch, cod, arthropod.

 The use of a cascade trap that catches objects moving in a specific direction for monitoring the fishing area allows one to obtain more reliable results on the movement of the fishing object, which ultimately helps to obtain the most realistic monitoring picture of the fishing area, which allows predicting the actual catch of the object with a high degree of certainty. fishing.

 Setting fishing gear between the places of feeding and wintering of the fishing object by crossing traps of the cascade order of the estimated location of migration flows of the fishing object in a certain period of time allows not only monitoring the fishing area, but also providing fishermen with reliable information about the most rational place for fishing at a certain time. It is known from the prior art that fish, depending on the time of the season, is constantly mixed from the feeding place to the wintering place, in particular, the peak of seasonal migrations of flounder is observed in spring and autumn, and in spring, flounder moves intensively from the wintering place, located at a depth of 200-250 m, to the place of feeding and spawning, located at depths of 20-50 m, and in the fall - vice versa. A similar pattern of movements is observed for halibut, rasp, perch, cod, arthropod and other hydrobionts.

 The choice of the installation site, based on the calculation of the number of caught individuals, makes it possible to quickly determine the density of the gathering of a fishing object in a certain period of time in different areas of the fishing area, while simultaneously fishing and quantifying the number of fishing object in the fishing area, which is called scientific practice "shooting" with a control fishing gear. Surveying is an integral part of fishing area monitoring.

 Determining the flow path of the estimated seasonal migration in three stages using data from long-term studies used for virtual cascading trap orders on the monitor screen using parameters that match the real one, provides the most reliable results of monitoring the fishing area and helps to obtain a real picture of how to move the fishing object so and its about stocks.

 The arrangement of traps of the cascade order sequentially "trap - guiding wing - trap" contributes to the correct calculation of the number of individuals caught by this fishing gear, excluding the accidental entry of fish into the range of the order, since it is limited by end traps that do not have end guiding wings that can introduce an unpredictable variable component of the number of fish caught, because depending on the angle of the meeting with the direction of the fishing object, the end guide wing can affect positively and negatively on the total catch.

 The sequential arrangement of the traps at an angle equal to the heading of the vessel, establishing the order of cascading traps, helps to determine the true path of the stream, resembling a river basin, which varies both in intensity and direction depending on changes in the distance from the feeding place to the wintering place.

 Since the end result of monitoring is to obtain a map of the fishing area with the main and peripheral flows of the fishing object indicated on it, the degree of filling of the orders of cascade traps and traps of the cascade order in it allows you to determine the intersection of the control orders of cascade traps with "rivers" and their branches.

 Placing traps of the cascade order in the places where the most catchy orders were located makes it possible, under the conditions of a limited number of orders and traps, to obtain the most correct results of the fishing area.

 Monitoring using traps of cascade order and comparing with the results obtained both from long-term fishing and predictive research using a decisive device, helps to preserve raw materials through the use of a gentle fishing gear, and also allows you to track direction and speed with minimal cost changes in the actual trajectory of the stream of the fishing object in the fishing area. Using the monitoring results allows you to determine the concentration of the fishing object at a certain time and in a certain place and rationally position both the fishing fleet and the number of fishing gear to ensure predicted catch.

 The method is as follows.

 Using previously published short-term forecasts compiled on the basis of the well-known patterns of the formation of commercial clusters of marine biological resources under the influence of biotic and abiotic environmental factors, information about the ways of seasonal migration of fishing objects, in particular flounder, is entered into the decider, after calculating the entered information on the monitor screen, estimated flow paths of estimated seasonal migration. In FIG. Figure 1 presents graphs compiled on the basis of short-term forecasts and characterizing the activity of the fishing object based on the catch: A) the increase in catch in traps depending on the time of year; C) increase in catch in traps depending on depth; C) the weight size of the fish from the depth of change in the catch of traps. Figure 2 shows the daily change in activity of the fishing object.

 When implementing the inventive method of monitoring the fishing area, the virtual ordering is first performed on the screen of the monitors, then the real ordering is carried out in the fishing area according to the parameters that completely coincide with the parameters of the virtual setting. The results of virtual and real catch in order and trap are compared and the quantitative parameters of the program are adjusted.

Example 1. First, virtual cascading traps are set on the monitor screen. The fishing area is the shelf part of Peter the Great Bay, in the region of 100 m isobaths. Given the dependencies that characterize the activity of catching the fishing object shown in figure 1, and the daily activity shown in figure 2, the orders of cascading traps are set so that they cross the flows of the estimated migration of the fishing object in a certain period of time, produce five orders, in each of which there are ten traps connected to the "trap - guiding wing - trap" system (the order includes nine guiding wings and ten traps of cascade order), for a specific date, per hour NOSTA May 8, 2000, 8 hours, 29 minutes, setting a course produce 67 ^o, orders set at 0.5 miles (926 m), the inclination of the wing on the course in a direction opposite the movement of flounder, towards greater depth, and in the area of prishvorivaniya guiding wings to the entrance mouths of traps in cascade orders of 60 ^° , and in the center of the guiding wings at an equal distance from the traps - 70-80 ^° due to equipping the guiding wing with surfacings and tensioning the order of cascade traps with anchors. After the completion of the ordering, after a certain time, in particular, after 24 hours, an imitation of a sample of orders of cascade traps is started. Figure 3 and 4 presents a diagram of the virtual setting of orders and the results of the catch in orders and traps of the cascade order. According to the results of catching the number of flounders, it is determined that the second order is the most catchy - 2346 kg. Within this order, the second, third and fourth traps have maximum catch - 345, 295 and 393 kg, respectively. There is also an increase in catch in the eighth, ninth and tenth traps - 254, 250, 233 kg, respectively. Taking into account the results of the catch, we can assume that the order in question indicates the location and width of the two streams of movement of the fishing object, and knowing that the length of the guide wings is 50 m and the length of each of the traps is 10 m, we can determine the width of the detected branches - the width of both streams approximately 200 m, and the distance between the centers of the flows is 250 m. Based on the results obtained, we assume that the conditional center of the stream is in the coordinates:
42 ^o 36 'N. (north latitude)
132 ^o 33 'about. (east longitude).

On the same date, a ship enters the sea, which also has five orders on board, ten cascading traps in each. Actual ordering of cascade traps in the fishing area is carried out in the same coordinates with the same parameters as in the virtual setting, simulating fishing. After setting the orders after 24 hours, they begin the sampling of the orders of cascade traps; after calculating the actual catch in the traps of the cascade order, it turned out that the most catchy order was in the coordinate region:
42 ^o 35 'N. (north latitude)
132 ^o 35 'about. (east longitude).

 The maximum catch shifted one mile (1852 m) to the east and this catch fell in the third and fourth trapping area, the fish activation actually comes in the center of the order, in one channel, the catch of the order was 2500 kg, which roughly corresponds to the data of the virtual setting .

 According to the results of the actual statement, the data embedded in the decisive device are corrected only by the location of the maximum catch, since the mass of the catch was close to virtual.

Using the data of the real catch of the most catchy order and formula 1, we calculate the total number of flounder in the fishing area:
1 - the length of the guide wing of the trap in cascade order of 50 m;
m is the number of guide wings in the order of 9 pieces;
P - the number of fish caught in second-order traps - 2500: 0.3 = 8333 individuals; while the average weight of one individual is taken equal to 0.3 kg;
V - width of the order of 50 • 9 = 450 m
v - fish speed 77 m / h.

 T - time between setting and sampling - 24 hours.

n = P: (vVT) = 8333: (77 • 450 • 24) = 8333: 831600 = 0.01 pcs / m ² .

 Consequently, the density of flounder in this area of the fishing area is 0.01 individuals per square meter.

 By determining the density of individuals in other areas, the average density and number of individuals in the entire water area can be calculated using the same principle. In the process of monitoring by comparing previous and subsequent catches, we conclude that the number of the fishing object in the fishing area is increased or decreased, which is the basis for adjusting the fishing pressure (increase or decrease the number of fishing vessels and their duration for the fishing season).

Example 2
To determine the number of flounders after feeding on the same control plot, we set the same number of orders as in example 1, only on the reverse course. In this case, the first order will take the place of the fifth, and the guide wing is inclined in the opposite direction, since the direction of migration of the flounder has changed by 180 ^o .

First, virtual cascading traps are set on the monitor screen. The fishing area is the shelf part of Peter the Great Bay, in the region of 100 m isobaths. The orders of cascading traps are set in such a way that they cross the flows of the alleged migration of the fishing object in a certain period of time, five different arrays are set up, each of which has ten traps connected to the trap-guiding wing-trap system (the order includes nine wings and ten traps) for a specific date, in particular on 20 October 2000, at time of 8 hours 30 minutes, setting a course produce 243 ^o, orders set at 0.5 miles (926 m), the inclination of the wing on the course in the opposite direction of movement flounder, toward the bar and in the vicinity of the guide wings to prishvorivaniya inlet mouths traps cascade orders 65 ^o, and the center of guide wings equidistant from traps - 75-85 ^o by equipping the guide wings overlap and tension anchors order. After the completion of the ordering process after a certain time, in particular after 24 hours, they begin to simulate fishing and, based on the results of catching the number of flounders, determine that the most catchy order is the fifth order, located in the coordinates:
42 ^o 35 'N. (north latitude)
132 ^o 31 'about. (east longitude)
while the maximum catch was trapped from the first (343 kg) to the second (205 kg), as well as from the seventh (318 kg) to the eighth (318 kg). The total catch amounted to 2182 kg, therefore, as in the first example, the flow is divided into branches, but narrower than the first example, they approximately pass along the same coordinates as in the virtual setting on May 8, 2000. This confirms that the opposite the migration of flounder from the feeding ground to the wintering site follows the same path.

 On the same date, a ship enters the sea, which also has five orders on board, ten cascading traps in each. Actual ordering of cascade traps in the fishing area is carried out in the same coordinates with the same parameters as in the virtual setting, simulating fishing. After setting the orders after 24 hours, they begin sorting the orders of the cascade traps, after calculating the actual catch in the traps of the cascade order, it turned out that the fifth order was also the most catchy order, which is located in the same coordinates as in the virtual setting of orders, since they were previously adjusted data entered in the decider. However, the catch amounted to 4256 kg, which is significantly higher than the result obtained in the virtual setting.

Hence, we adjust the catch by weight and by the above formula, determine the actual density of flounder in the control area, taking into account the data of the actual setting:
1 - the length of the guide wing of the trap in cascade order of 50 m;
m is the number of guide wings in the order of 9 pieces;
P - the number of fish caught in second-order traps 4256: 0.5 = 8512 pieces; while the average weight of one individual is taken equal to 0.5 kg;
V - width of the order of 50 • 9 = 450 m;
v - fish speed 77 m / h.

 T is the time between setting and sampling 24 hours

n = P: (vVT) = 8512: (77 • 450 • 24) = 8512: 831600 = 0.01 pcs / m ² .

 From this we draw a preliminary conclusion that the density was preserved, and the mass of individuals increased due to feeding. This may indicate that the flow on the reverse migration decreased in width at a constant density, therefore, it can be assumed that the rate of migration of flounder for wintering is slightly less than the speed of the flounder to the feeding ground. This is the basis for the shipowner to maintain the previous catch quota and forecasting the period of stay of vessels for fishing in this fishing area, which coincides with schedule C in figure 2.

 The inventive method of monitoring fishing areas allows you to predict the catch at a certain time and at a certain place, without the need to collect additional information using airborne reconnaissance, hydrometeorological data, space and fax information.

Claims (1)

 A method for monitoring the fishing area, including selecting the place and time of installation of the fishing gear, setting the fishing gear that allows the fish to pass through a certain section, selecting it after a certain time and determining the size of the fishing target, characterized in that cascading traps are used as fishing gear to ensure catch of objects moving in a specific direction, and as a certain section take the area of the catch of traps of cascade order, which appears in the zone of movement of the object of fishing , the setting of the fishing gear is carried out between the places of feeding and wintering of the fishing object by crossing the cascading trap orders of the proposed field of migration flows of the fishing object in a certain period of time, the flow path is determined by comparing the results of the catch obtained by virtual setting the cascading trap orders and real setting the cascading trap orders on the fishing water area, coinciding in location with the actual setting, the ordering of cascading traps is carried out in three stages apa: at the first stage, cascade traps are arranged sequentially in the "trap - guiding wing - trap" system in one line at an angle equal to the heading of the vessel that sets the order of cascade traps, and the direction of movement of the fishing object is determined by the degree of filling of the traps; at the second stage - cascade order traps are located in the direction in which the most catchy orders located at the first stage were located; at the third stage — cascade order traps are arranged taking into account the degree of their filling inside each order determined at the second stage; the fishing results obtained by actually setting the order of cascade traps are put on the map of the fishing area, while the results of virtual setting are automatically corrected using a resolver orders of cascading traps obtained on the basis of processing known information, while simultaneously displaying on the monitor screen the trajectories of actual migration flows about fishing facility.

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