SU1106729A1 - Model of anchored system - Google Patents

Abstract

A LAYOUT OF AN ANNOUNCED SYSTEM, including a chain, imitating flexible SVYA311 and hanging at one end on a vertical shield at a fixed point corresponding to the position of the core, and at the other end attached to two nitas stored in the blocks installed on the guides of the vertical shield with loads imitating the horizontal and vertical tension forces behind an indigenous object, characterized in that, in order to provide an opportunity to demonstrate the influence of hydrodynamic forces on the position of elements behind the root system and increase the effect of consistency, the chain is supplied with direction indicators of the tension forces applied to the ends of the flexible connection, rods, each of which contains an arrow and a plumb line, indicating respectively the direction of the hydrodynamic force and the weight force applied along the length of the flexible connection, and additional loads imitating hydrodynamic forces and suspended at the ends of additional threads stored in additional blocks, while the indicators are installed at the ends of the chain, the rods are inserted with into the chain and oedineny to its adjacent units m, plumb thread, yarn and additional arrow attached to each shaft at its center of gravity, and the mass of each rod with an arrow S COOT- 1. plumb and level equal to the mass portion or ve.tstvuyuschego chain.

Description

The invention relates to shipbuilding, in particular to models for indigenous systems, for example, to packages that are connected through measles to a flexible coupling ground. The model of the klyuzovy device is known, containing a rigid frame with traction arms, a flexible partition and a block through which the root cable is thrown with a load at one end and a bark at the other. The well-known layout behind the root system includes a chain that simulates a flexible connection and is suspended by one end on a vertical uy-iTe at a fixed point corresponding to the position of the core, and the other end is connected to two threads stored in blocks mounted on the vertical shields with weights imitating the values of the horizontal and vertical tension forces for the indigenous object flj. However, the absence of adaptations in it that demonstrate the direction of the forces applied to the root system under the influence of the deep current and imitating hydrodynamic forces acting on the flexible coupling does not allow p to use a known model for the potent demonstration of the influence of hydrodynamic forces. the position of the elements (of the flexible connection, beyond the main object) behind the root system, and also reduces the effect of implicitness. In addition, the absence in the known layout of these devices does not allow to quickly obtain the parameters for the root system (end angles, angles along the length of the flexible connection, recess, etc.). The aim of the invention is to provide the possibility of demonstrating the influence of hydrodynamic forces on the position of elements behind the core system and enhancing the effect of consistency. The goal is achieved by the fact that, in a known layout, a root system, including a chain, simulates a flexible connection and is suspended by one end on a vertical shield at a fixed point corresponding to the position of the core, and the other end is attached to two threads a vertical shield, blocks with weights imitating the magnitudes of the horizontal and vertical tension forces behind the primary object; the chain is equipped with direction indicators of the tension forces applied to the ends of the flexible zi, rods, each of which contains an arrow and plummet, showing, respectively, the direction of the hydrodynamic force and the weight force applied along the length to the flexible connection and additional weights simulating the hydrodynamic forces and indicated at the ends of the additional threads stored in the additional blocks with This pointers are installed at the ends of the chain, the rods are inserted into the chain and attached to its adjacent links, a plumb line, additional threads and an arrow are attached to each rod in its center of gravity, and the mass each rod with an arrow and a plumb line is equal to the mass of the link or the corresponding part of the chain. FIG. 1 is depicted as a root system under the influence of forces applied to it; in fig. 2 - layout for the root system, general view; FIG. 3, Sterzren with an arrow and a plumb line, attached to chain links; in fig. 4 - rod with an arrow and a plumb, side view. I When setting up as a root system (in the absence of flow) at a depth of H, the paneer under the action of buoyancy T over the indigenous object O (for example, bu), the flexible connection / L (for example, buirep) assumes a vertical position (Fig. 1). At the same time, the root object O is located on the recess H from the sea surface AA, and the akor on the bottom of the sea at point I. Under the action of surface flow, the root object O is in position 0, and the connection L is flexible under the action of weight forces Γ takes position /, (Fig. 1). Under the influence of the deep current 2 / behind the primary object, 0 / J occupies the U position, and the coupling is flexible (vYD by the action of hydrodynamic forces / and the forces of weight T takes the position). (Fig. 1). The forces Г and / J determine the shape of the flexible coupling / о, and taking into account the force To, the distance Hj beyond the indigenous object 0 from the surface of the sea AA. In this case, the forces G along the length of the flexible connection / (, are equal in magnitude and their action is directed vertically downwards, forming hydrodynamic resistance forces C, angles a (. (Three angles,, () are shown in size angles between the flow direction Y and the flexible f bond / J. Hydrodynamic forces (three forces are shown in Fig. 1, and points C, GX and C are directed perpendicularly to the flexible link /.2 and in magnitude per unit length f are equal to RC -0-Si "4, (1) where Cff is the hydrodynamic resistance coefficient j is the mass density of water, is the flow velocity and, m / s is the diameter of a flexible connection, m; is an angle between the flow path and a flexible connection. In accordance with the design rule, to achieve a geometric and force similarity of a flexible connection (for example, burep) and a metal chain is sufficient to their ends apply horizontal forces T and t proportional to their masses Q and L or their weights & .. and BC. Mathematically, this can be expressed as fe-t (2) "2 g Qe. If we denote the mass of the chain, where MC is the linear mass of the chain , - its running BecJ о - acceleration of free fall and the mass of the flexible coupling in water a-MtLr -1-l where - mass per unit length of flexible linkage in water / lineal weight flexible bond in water; free fall acceleration ta a tj Mch. 1% Q Me-f «ft. : J -ffb-f- here is the linear scale. Consequently, if on a vertical shield 1, hang up one end of H with chain 2 of length and weight C, and connect two strands 3 and 4 to the other end of it, thrown over blocks 5 and 6, mounted on the guides 7 of shield 1, s weights (Figs. 1 and 2) ii-T, JT, fi, .. T, | -tiv ", then we obtain a mock-Itz of a flexible connection L t under the action of 4, 2 and 5, imitating the forces T / { Tj. and G. Chain 2 consists of links 8 (Fig. 3) and at its ends I and 0 have rings 9 and 10, which are freely connected to the end links of meters. Arrows 1t are rigidly attached to rings 9 and 10, which show the direction action forces Tjf. and t #. The ring is loosely fitted on the pin (in Fig. 2 it is not encased) mounted on the shield 1. The scales in degrees are set at the points I and 0 (for example, according to the type of conveyor). demonstration of the weight force G in the center of the body of each rod 12 pin 13 loosely fitted ring 14 with a weightless thread 15 attached to it with a load 16 (Fig. 2 and 4). Since during the deep flow If, the flexible coupling Ly is affected by the hydrodynamic resistance forces Q (Fig. 1), to demonstrate them, on each pin 13 rods 12 are rigidly mounted at a right angle to the rod arrow 17. To imitate the forces R to each pin 13 is attached thread 18, transferred through block 19 with a load, the weight of which is determined in accordance with the layout rule (2) according to the formula (Fig. 2 and 3) G, a:.%. 1G About ye In this case, the thread 18 should be located in the direction of the force (Fig. 1), i.e. along arrow 17. A hinge 20 is attached to rod 12 in grads (for example, in the form of a protractor). Work with the layout is carried out as follows. First of all, rods 12 (preferably of light material) are made with pin 13 and scale 20, ring 14 with thread 15 and weight 16, arrow 17. Then, having a total mass of rod 12 (with pin 13, scale 20, ring 14, weight 16, string 15, arrow 17) select chain 2, the mass of each link of which is equal to the total mass of the rod 12, and the dimensions of the link are sized for the rod (you can pick up a chain from smaller links, but in this case the condition of equality of the total mass of the rod and several links and their total length and length of the rod). Based on the convenience of the demonstration, chain 2 is chosen with a length (Z, with a mass o, and a linear scale m, Between the links of chain 2 at equal distances from each other, rod 12 is connected with pin 13 and scale 20, and to ends I and Chain 2 - rings 9 and 10 with arrows 11 fixed on them. Chain 2 is suspended on a vertical shield 1 at one end with a ring 9 on a pin (in Fig. 2 it is not marked located at point I, and at the other end 0 using threads 3 and 4, sorting 5 and 6 with loads loaded through blocks i and b with loads 2 and t./i, the values of which are determined from (4), choosing the values T, 1 and O for any known root system. Blocks 5 and 6 are pre-installed with the ability to move along the guides 7 of the shield 1. Then the rings 14 with the threads 15 and weights 16 are put on the pins 13 of the rods 12, and the arrows are mounted 17, orienting them in the direction of convexity of the chain 2 and positioned perpendicularly to the rod 12. Quick-detachable elements (for example, split into links, rings, carabiners, etc., are used in order to connect the main parts of the layout. In FIG. 2 are not indicated). With the demonstration on the shield 1 punched graph paper. By moving along the guides 7 blocks 5 and 6, the horizontal position of the thread 3 and the vertical position of the thread 4 are achieved. By this case, the chain 2 demonstrates the position behind the root system under the influence of surface current on the root object O, and the heat input weight G flexible communication L-1. In this case, the string 15 with the load 16 and the arrow 11 respectively demonstrate the direction of action of the forces of weight and strength% n T at the points I and 0 behind the root system, the shape of the chain 2 is the form of a flexible connection. and rods 12 are sections of a flexible connection along its length. To demonstrate the position of the elements behind the root system on the deep flow U, the pins 13 of the rods 12 attach the threads 18 thrown through the blocks 19 from the sinker # 1 r,, (Gd, the magnitude of which is determined by (1) and (5). This angle is defined as the average where the angles rf, cc and ts are removed at the position of chain i along the bars 20 of the rods 12 between the threads 15 and arrows 17 (Figs. 1 and 2). By moving along the guides 7 of the blocks 19, threads 18 with arrows 17 (at that, thread 3 is kept horizontal, and thread 4 is vertical, also by moving blocks 5 and 6 in the direction of direction 7), since the weights' efforts, r, r, must be directed in the direction of action applied to the sections of the flexible connection Lj. (Fig. 1 and 2). The position behind the core object 0 and the shape of the flexible connection L2 can be refined by changing the values of the weights, 2. and 1, the values of which are recalculated according to the formula (1) and (5) for the refined angles ot-;), and cCj, taken on scales 20 for the position of the flexible coupling Lg, In this case, the chain 2 of the rod exhibits a flexible connection L2, and its shape is similar to the form of a flexible connection; the weights ir and 2 imitate the magnitude of the vertical force T ; (buoyancy behind the core object) and the magnitude of the horizontal force T (the hydrodynamic resistance forces of the hull behind the indigenous object), which are the tensile forces, arrows 11 show the forces T and their direction attached to the root object and the bark removed on scales set by B points I and 02) / arrows 17 demonstrate the direction (on scales 20) of hydrodynamic resistance forces (J, R; 2. and ъ applied to various parts of the flexible coupling LI J; Iz 3 loads imitate hydrodynamic forces resistances 1.2 applied to the sections of flexible communication L2, plumb line (thread 15 with load 16) demonstrates the direction of action of the forces of weight g, the values of the segments h and the horizontal projection OOj, are characterized by the deepening H H1 distance (horizontal distance from cor.) for the indigenous object. With the help of the proposed layout, it is possible to demonstrate the effect of different flow rates on the position

of the ecore system (by changing the value of the weights d, ifj. P ° of the values of the weights t and the effect of the magnitude of buoyancy for the indigenous object, etc.

The effectiveness of the proposed layout

in comparison with the well-known one, it allows for the inevitable demonstration of the forces applied to the root object, the koryu of the flexible coupling; demonstrate the form of a flexible link; demonstrate the position behind the indigenous object (its deepening and distance) demonstrate the effect

for the fundamental system of changing the magnitude of the flow velocity, buoyancy behind the indigenous object, the diameter of the flexible coupling, etc.

This in turn increases the absorption of material by cadets.

Providing the layout with quick-release elements allows it to be assembled and disassembled in any audience equipped with a blackboard, which reduces the time it takes to prepare the layout for action and simplifies handling. No special materials or specialists with special training are required to make a layout.

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Claims (1)

LAYOUT OF AN ANCHORED SYSTEM, including a circuit simulating a flexible connection and suspended at one end on a vertical shield at a fixed point corresponding to the position of the anchor, and at the other end attached to two threads stored in blocks mounted on the guides of the vertical shield, which simulate horizontal and vertical forces tension of the anchored object, characterized in that, in order to ensure the possibility of demonstrating the influence of hydrodynamic forces on the position of the elements of the anchored system and higher To illustrate the effect of visibility, the chain is equipped with direction indicators for the action of the tension forces applied to the ends of the flexible connection, rods, each of which contains an arrow and a plumb line, respectively showing the direction of action of the hydrodynamic force and the weight force applied along the length of the flexible connection, and additional weights that simulate hydrodynamic forces and suspended at the ends of additional threads stored in additional blocks, while the pointers are installed at the ends of the chain, the rods are inserted into the chain and attached to it hedge links, a plumb line, additional threads and an arrow are attached to each rod at its center of gravity, and the mass of each rod with an arrow and a plumb is equal to the mass of the link or coot - C of the corresponding section of the chain. > 1 1106729