SU921483A1 - Lamp for determining reaction of fishes and non-fish objects to light of different spectral composition - Google Patents

Description

(54) LAMP FOR DETERMINATION OF REACTIONS OF FISH AND NON-FISHING OBJECTS ON ELECTRIC LIGHT OF VARIOUS SPECTRAL COMPOSITION

The invention relates to industrial fishing and is intended to determine the reactions of fish and non-fish objects to electric light of different spectral composition.

A lamp is known for determining reactions, fish and non-fish objects, which contains a reflector, emitters of individual parts of the spectrum of light, starting-regulating equipment with a cable, and hermetic connection 11}.

The disadvantages of the known luminaire are the insignificant accuracy of determining the reactions of fish and non-fish objects to electric light of different spectral composition and a small amount of optical radiation to be studied. This is based on the identification by many researchers of the perception of light exposure through the eyes of man and animals living in the air; a transparent medium, and the eyes of aquatic animals, including fish, constantly being in an optically turbid aqueous medium.

The purpose of the invention is to improve the accuracy in determining the reactions of fish and non-fish objects to electric light differently.

personal spectrum and expansion of the range of research.

The objective is achieved by the fact that the lamp for determining the reactions of fish and non-fish objects to the electric light of a different spectral composition, containing a reflector, emitters of individual parts of the spectrum of the BCi-o radiation, start-regulating equipment with a cable and a tight connection, It has at least 17 emitters, one of which is a white emitter,

15 together with the seven emitters of the primary colors of the visible part of the spectrum are fixed, circumferentially centered, in the center of which there are five emitters, cyMiiia radiation spectra

20 of which covers the ultraviolet region, while the extreme ultraviolet emitters are located on the sides of the square, in the tops of which there are emitters, the sum

Claims (5)

25 radiation spectra which cover the infrared region, and every two emitters installed around the circumference and one extreme ultraviolet lie at the vertices of an equilateral triangle. And the starting-regulating apparatus contains an electronic-automatic programmer, and the radiators are connected to the programmer via re-rheostats. In addition, the tight connection L contains three bushings, the inner of which is made with a channel for placing the cable and is equipped with a ball retainer, and the two outer ones are made with cutting and have seals. The starting and adjusting equipment is located on the back side of the luminaire. The lamp is equipped with a reflector with a lens mounted on it. FIG. 1 shows a lamp for determining the reactions of fish and non-fish objects to electric light of different spectral composition, side view in section; in fig. 2 - the same, view sperd; in fig. 3 - wiring diagram for remote control of the lamp. The luminaire contains a reflector 1 emitters of individual parts of the spectrum, such as multicolored incandescent lamps 2, a switchgear and control device containing a block 3 and a block with a board 4 with cable 5 and a hermetic connection containing sleeves 6-8. White emitter 9, along with seven emitters of 10–16 primary colors of the visible part of the spectrum, are fixed around a circle, in the center of which five emitters 17–21 ultraviolet and four infrared 22–25 are located, along with extreme ultraviolet and radiators 17–20 located on the sides of the square 26, infrared radiators 22-25 are placed at the tops of the cotr, and every two radiators, for example 14 and 15, circumferentially installed, and one extreme ultraviolet, for example 17, lie in the vertices of an equilateral triangle 27. The regulating equipment contains an electronic automatic programmer from the board 4, and the radiators 9, 10-16, 17-21 and 22-25 are connected to it via variable resistors 28. The hermetic connection contains three bushes 6-8, 7 inside the outer The threaded part of the body is made with a channel 29 for placement of the cable 5 and is equipped with a ball Clamp 30, and the two outer 6 and 8 are made with an internal thread and have seals, for example, in a new .31 and electrowelded 32 thread. from block 3 to accommodate the rheostats 28 / the board 4, when manually operating the lamp, is placed on its back side (not shown). The lamp is equipped with a reflector 1 with a lens 33 mounted on it mounted in the frame 34. The lamp consists of two parts, a protective hermetic housingZZ, which is pasted over with a gap (it is not) , and the reflector 1, which are interconnected by means of twelve anchor bolts 36, and also are geometized circumferentially with a pad of raw rubber 37. Bolts 36 go into the luminaire from the side of the body 35 and sealed with it would be with rubber. gasket 38. The bolts 36 are wrapped in threaded holes 39 on the metal sheeting 40 at the bottom of the bowl of the cutter 1. The emitters, in this case in the form of incandescent lamps 9, 10-16, 17-21, 22-25, are screwed into hermetic cartridges 41 and together with them, rigidly 42 are fixed to the reflector 1. A lens 33, designed to add optical radiation, is enclosed in a frame 34. The radiators above the water surface are cooled by fresh air inflow, and at deep water with outboard water that penetrates freely into the hole 43; on the ends of the rim 34 of the lens 33. To manually control the luminaire without an automatic programmer, use the knobs 43 with electrical .1 rubber layer 44, and the emitters 9, 10-16, 17-21 and 22-25 are used through switches 45. For remote control the luminaire uses a multicore cable 5 placed inside the cargo cable braid 46. The tight connection bb, before using the luminaire, is poured from all sides by the boil. Keyboard pointers (spectral components) 47, as well as level 48 and level divisors 49 for individual bands of the continuous spectrum, which are tared in advance on the photometric bench (not shown), are shown on board 4. FIG. 3 shows three mounting blocks: block 3 for rheostats 28 and switches 45, block 4 for the programmer cG of the display 4 and the main unit 50 for accommodating radiators 9 1p-16, 17-21, 22-25, which are shared with manual and separately with remote control of the lamp. With the remote control, the luminaire unit 50 is mounted inside the housing 35, and the blocks 3 and 4, if used for the craft, in the navigational cabin. Between them, blocks 50.3 and 4 are connected by cable 5, while blocks 3 and 4 are combined. With the manual use of the luminaire, blocks 50 and 3 are connected as one unit in the housing 34, with Lpoc from the scoreboard 4 and the power multicore cable 5 are missing. The wiring in the electrical circuits is carried out with the usual cable 51, and the separating hermetic strips 52 and 53 are mounted, respectively, inside the blocks 50 and 3 The luminaire operates remotely and the luminaire prepared for operation (Fig. 1-3) is lifted overboard with a cargo boom. and lowered on cable 5 in the outer cable braid 46 to a predetermined, where there is a cluster of fish, during the period of the experiments, monitoring of the performance is carried out using sonar devices (not shown). The work is carried out in two steps. Initially, the total optical spectrum of electromagnetic waves from 10 to 1,000,000 MMK is roughly examined, and certain areas and groups of areas (spectra) are identified in it, which are especially perceived by fish both in the direction of attraction and scaring. For this, without the progrmmator from the board 4, unit 3, in manual mode, all radiators 9,10-t6, 17-21 and 22-25 are connected in series one after another and manipulated with rheostats 28 to achieve maximum effect. If a . the radiation range of the source is small, alternately in power, selecting the necessary set of reference and emitters. For example. To emit reproduction stocks of fish and non-fish objects at a specific power of a series of reference optical radiation, the detected wavelengths in the range from 10 to 1,000,000 mmk use three interchangeable sets of radiation — v telvey 50-500, 500-1000 and more than ilOOO W . When combined, two and several emitters (in the visible spectrum) 9-17 are analyzed together with 17–21 and 22–25 infrared emitters with ultraviolet radiation. If necessary, those of the lamps that are not used are disconnected from the mains through the switches 45. With surface use, the luminaire observing the fish is carried out visually and with the help of sonar devices. Accurate determination of the spectral i line intervals and their characteristics is carried out by a haunting experiment in the natural habitats of the objects studied during all the major seasons of the year. To create an accurate linear spectrum or group of spectral lines, in those parts of the general scale of electromagnetic waves, where the concentrating or scaring effect of the applied emitters 9, 10-16, 1721 and 22-25 is observed, on fish or non-fish objects with all closed off { Phone x 45 uses a programmer from the board 4. On the board 4 programmers horizontally placed five or more rows of keys 47 corresponding to certain spectral ranges (lines 48) and level dividers 49 for the used emitters 9,10-16, 17- 21 and 22-25. Each horizontal row 48 is divided into levels 49, corresponding to .175 the width of the radiation range of all emitters. For example, the red emitter 10 has a continuous emission range of 760-620 microns, which is 140 microns in length on a common scale of electromagnetic waves. Each horizontal row of 48 keys 47 corresponds to 1/5 of 140 mmk, i.e. 28 MMK. So vertically against the emitter 10 on the board 4 numbers will be put: the first row of keys. 47: 760-632 MMK, second p d 732-.;. 704 t / iMK, third p. 704-676 M1ld, fourth 676-648 MMK. and fifth row 648-620 tlk. If, during the experiments, it is required to have narrower wavelength intervals from higher than the specified intervals, press the level divider key 49, which corresponds to half the width of dj; the wavelength range is 760-732 mmk,:, 732-704 mmk, 704-676 mmk, 676- 648 MMK, 6.48-620 MMK. While the dividers. Levels 49 may be several, in this case (fig.Z) placed one. After pressing the corresponding keys 47, opposite the set of emitters, the electronic plexus in the programmer moves the levers of the variable rheostats to a predetermined scale division and supplies current to these emitters (not shown). If during the experiments it will be noticed that with increasing or decreasing the Power of the used emitters, the effect of attraction or. scaring off fish in any one of the cases increases, it is necessary isg. alternately use three sets of reference emitters. For coarse manual tuning at a given wavelength of optical radiation, without lens 33, the programmers from board 4 use a table previously pre-tinted by the light-measuring table, in which spectral lines and individual line spectrums are applied horizontally, and vertically when two are added and. several adjacent: optical areas of the optical spectrum, graduated 1No readings on the variating scales of devices for adjusting rik brightness rheostats 28 (not shown) Other luminaire use patterns are also possible. After experiments with sources of electroluminescent and control catches of a given fish species for all seasons of the year — at specified intervals of wavelengths and their chapels — the power characteristics made specific industry recommendations for making special attracting or concentrating emitters. Anshocogic studies can be carried out in air through non-fish objects that live both in the sea and on land. The proposed lamp allows you to quickly determine the reaction of fish and non-fish objects to complex emitters of various modifications in the visible, ultraviolet and infrared spectra and effectively control their behavior with the maximum approximation to the natural environment of these objects. Claim 1. A luminaire for determining the reactions of fish and non-fish objects to an electric light of different spectral composition, comprising a reflector, radiators of separate parts of the spectrum of light radiation, control equipment with a cable and a sealed connection, characterized in that fish and non-finded objects for electrolight of various spectral composition and expansion of the range of investigation, the lamp contains at least 17 radiators, one of which is radiator b This color, along with the seven emitters of the primary colors of the visible spectrum, is fixed around a circle in the center of which there are five emitters crosswise, the sum of their emission spectra covers the ultraviolet region, while the extreme ultraviolet emitters are located on the sides of the square, at the vertices of which , the sum of the emission spectra of which covers the infrared region, every two emitters installed by the circumference and one extreme ultraviolet lie in the vertices Orono triangle. 2. The lamp according to claim 1, in connection with the fact that the starting-regulating equipment contains an electronic-automatic programmer, and the radiators are connected to the programmer through variable resistors. 3. The luminaire is pop.1, in contrast to the fact that the tight Sbe combination contains three bushings, the inside of which is made with a channel for placing the cable and is equipped with a ball retainer, and the two outer ones are made with cutting and have seals. 4. The luminaire according to claim 1, characterized in that the start-up control equipment is located on the back side of the luminaire. 5. The lamp according to claim 1, about tl and h ay u and with the fact that it is equipped with a reflector with a lens mounted on it. Sources of information accepted by you during the examination 1. USSR author's certificate No. 230988 Cl. 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