RU2057442C1 - Fishing tackle float - Google Patents

Abstract

FIELD: fishing industry. SUBSTANCE: float has semi-submersible vertical cylinder of total length equal to 2.2-2.4 of designed amplitude of wave and three-dimensional lens-shaped or cylindrical damper whose volume is equal to 1,8-2.2 of cylinder submerged portion. Float is made of light material with specific buoyancy of 10-12, for instance of polystyrene foam, and is coated with tight protective film. It is expedient to place metal members inside float to impart rigidity, ballasting and attachment of fishing tackle members. EFFECT: reduced rocking of nets and fish boxes in rough sea, prevention of net breaking. 2 cl, 3 dwg

Description

 The invention relates to fishing and marine biotechnology, in particular to the accessories of the networks. It significantly reduces the pitching of the nets supported by the swam, in waves, protects them from tearing, and can also be used to suspend nets for growing mussels and support the bearing seine line.

 Known floats are either glass hollow balls braided by a net and having a special loop for tying a net leash or oval-shaped rotation body with a through hole in the middle, made of light material with specific buoyancy of 10-12. The surface of such a melt is usually covered with a wear-resistant polymer material with a thickness of 1-3 mm. Such, for example, is the melt for fishing gear equipment adopted for the prototype (V.N. Melnikov, A.V. Melnikov and V.N. Fomenko, a / c 1792602 A1 in class A 1 K 73/05 B.I. N 5 1993). Such floats with a horizontally oriented major axis along which a hole is drilled are strung on a supporting cable to which the leashes of the nets are tied. From below, weights are tied to the nets, and as a result, the network appears to be stretched from above by semi-immersed flats, and from below from weights.

 The disadvantage of existing forms of floats is that they practically track the wave, and the network with sinkers does not have time for their fluctuations. As a result, leashes and nets are overloaded, leading to damage on waves of more than 3-4 points. Therefore, stabilization of networks on a wave is an urgent task.

 The purpose of the invention is to reduce the pitching of swims on a wave, to expand the sea’s diabolity, in which the safe use of fishing nets is possible.

The goal is achieved in that a melt made of light material with a specific buoyancy of 10-12 and covered with a dense protective film is given a special wave-resistant shape, including a vertical cylinder with a total length l _p (2.2-2.4) A _p , where A _{p is} calculated the amplitude of the waves, for reliable operation in which it is designed, half immersed in water and a passively active damper of a cylindrical or lenticular shape with a volume of V _d (1.8-2.2) V _c , where V _{c is the} volume of the immersed part of the vertical cylinder equal to V _q (1,1-1,2) S _p · a _p, a base area vertically th cylinder S _n is determined from the melt of required duty m _rn and conditions of equilibrium at the design waterline _n + m m _zn ρV ρ (2,8-3,2) V _p ρ (3,1-3,8) S _i · A _p , where m _{p is the} mass of the melt itself, and V
its displacement, ρ is the density of water, and in addition, the melt has metal fittings inside it to give it rigidity and fasten network elements.

 The invention is illustrated in FIG. 13.

 The shapes of the melt used are shown in FIG. 1.

 In FIG. 3 shows the design of the proposed melt. It includes a vertical cylinder 1 and a damper 2 made of light material, for example, polystyrene foam. Reinforcement 3 is inserted inside the melt in the form of a metal rod passing inside the cylinder and rigidly welded to the disk rod inside the damper. From the bottom and top of the melt, as well as in the area of the working waterline, rings 4, 5, 6 are welded to the rod, which serve to attach the snap-in nets.

 The proposed technical solution is quite technologically possible. At first, the reinforcement is made, it is inserted into a folding form, which is closed with expanded polystyrene or other light material. Then, a surface film is sprayed onto the formed form.

 The proposal meets the criterion of "positive effect", since the melt of the claimed form has the ability to withstand the wave and has a very small vertical pitching. Therefore, nets, nets, or hangings suspended on such a melt will not experience dangerous jerks, at least until a wave of 4-5 points. Floats of a traditional form track the wave and tear the network. The proposed technical solution also meets the criterion of "significant differences", since the proposed wave-resistant form is fundamentally different from the existing ones. A preliminary patent search did not reveal solutions in the field of fisheries, even remotely resembling the one proposed. Therefore, the proposal meets the criterion of novelty.

We show how the cross-sectional area of the vertical cylinder and the size of the damper should be selected. Let, for example, design a melt to protect networks on waves up to 4 points. The height of such waves 2A _r is on average ≈ 1.2 m, length ≈ 25 m and a period of ≈ 4 s. In this case, the required cylinder length is l _p 2.3 A _p 2.3 x x 0.6 ≈ 1.4 m. It should be half immersed in water, therefore l _ps 0.7 m.

1

С учетом V(3,1-3,8)S_ц А_р величина S_ц m_гр/( ρ 4ρ_м) х х А_р (3,1-3,8).Let it be given that the melt payload should be 10 kg. The melt is made of lightweight material with a density ρ _m << ρ. The mass of this material in the melt is m ρ _m V. Assume that the mass of the reinforcement is three times the mass of expanded polystyrene. This ratio can be further refined in the process of manufacturing the floats. Then m _p 4ρ _m x x V and m _gr = ρV

1

Given the V (3.1-3.8) S _c A _{p the} value of S _c m _g / (ρ 4ρ _m ) x x A _p (3.1-3.8).

=(1-1,05)дм Тогда V_ц (5,53-6,02) дм³ и V_д 2 V_ц 11-12 дм³. Если принять для демпфера среднюю толщину t_ср 0,6 дм (с учетом ее уменьшения к внешнему контуру), то площадь соответствующего диска будет S_д

(18,3-20) дм², а его диаметр d_д

= (4,8-5) дм.With ρ _m 0.1 kg / dm ³ , A _p 7 dm and ρ 1.02 kg / dm ³ and m _gr 10 kg, S _c 0.86-0.79 dm, this area corresponds to the diameters d _c =

= (1-1.05) dm Then V _c (5.53-6.02) dm ³ and V _d 2 V _c 11-12 dm ³ . If we take for the damper the average thickness t _cf 0.6 dm (taking into account its decrease to the external contour), then the area of the corresponding disk will be S _d

(18.3-20) dm ² and its diameter d _d

= (4.8-5) dm.

So, the wave-resistant melt, designed for a wave of 4 points and a load capacity of 10 kg, should have the following characteristics:
The total length of the vertical cylinder is 1.4 m,
cylinder diameter d _c 10 10.5 cm,
damper volume V _d 11 12 dm ³ ,
damper diameter d _d 48 50 cm,
total displacement of the melt V _about (16.5-18) dm ³ ,
total mass of melt m (6.6 7.2) kg.

Specific figures on the size of the melt will depend on the density of the material of the melt and the proportion of reinforcement in the mass of the melt. If this fraction can be reduced, then it will be less than S _c and, accordingly, V _d , S _d and d _d . But the methodology for their selection will continue.

 Model tests of pitching buoys of the architecture of FIG. 3 showed that such buoys behave well on steep short waves (the damper in this case works more efficiently) and somewhat worse on slow long waves, but these long waves do not tear networks, it is short cool waves that tear networks. And the proposed wave-resistant melt is here and is opposed to unrest.

Claims (2)

1. FLOAT FOR EQUIPMENT OF FISHING GOODS, which is a body made of material with a specific buoyancy of 10 12 and covered with a dense protective film, characterized in that the body consists of a vertical cylinder with a total length l _p (2,2 2,4) A _p , where A _{p is the} calculated wave amplitude in the working state of a cylindrical or lenticular shape half immersed in water and a passively active damper with a volume of V _d (1.8 2.2) V _c , where V _{c is the} volume of the immersed part of the cylinder equal to (1.1 1 2) S _i • A _p, wherein _p S cylinder base area is determined from the need GRU opodemnosti melt _g m _n, and the conditions of its equilibrium at the design waterline _g m _n + m _n ρV, where ρ density of water, and VV + V _{d p} ≈ (3,1 3,8) S _i • A _p needful melt displacement, and m _{p the} mass of the melt.  2. The melt according to claim 1, characterized in that metal reinforcement is placed inside the cylinder and damper to give it the necessary rigidity, ballasting and fastening of network elements.

Images