RU2201379C2 - Aerostatic apparatus - Google Patents

Abstract

FIELD: lighter-than-air flying vehicles. SUBSTANCE: proposed apparatus has case with air and helium ballonets and engine nacelle. Case is made in form of spherical segments. Curvature of upper spherical segment exceeds curvature of lower one. Rigid framework is arranged inside said case. Located along axis of case is framework strut whose one end is engageable with upper part of case and other end is engageable with its lower part; nacelle is mounted on the outside of lower part of case for rotation through 360 deg. Thrust vectors of cruise engines mounted on this nacelle may deflect up and down. Suspended from framework by means of angular brackets is ring-shaped frame. Free ends of bracket carry engines provided with blades. On lower side of brackets, cargo ropes are provided along axis of each engine. Ring-shaped frame is provided with radial diaphragm which is engageable with lower end of vertical strut where access hatch is available. EFFECT: enhanced operational efficiency. 5 cl, 5 dwg

Description

 The invention relates to aerostatic apparatus, carrying out the lifting and transportation of bulky cargo-giants, the transportation of which by traditional methods is not efficient enough.

 Aerostatic devices are known, for example, of the Zeppelin type airship (see "Interesting newspaper" block D, 12 (75), 1999, Kiev).

 These devices have disadvantages. The airship has an increased length in order to have enough volume for light gas. In the form of an airship having a significant elongation, both ascending and descending flows, peculiar “scissors” can act simultaneously on its hull during flight, due to which it is necessary to strengthen the hull shell or the inner frame to prevent shear force and bending moments. This leads to undesirable weighting of the structure. In addition, at near-zero speeds, the aerodynamic rudders of the tail unit are not effective enough and the lateral wind blows the apparatus, affecting the lateral surface of an increased area. To overcome the forces from the wind, it is necessary to apply complex systems of powerful power plants that operate for a limited time, which is not entirely advantageous in terms of weight and value. A significant disadvantage is the use of ballast in the form of water, soil, concrete blocks, etc.

 When transporting giant goods weighing 50, 100, 200 tons or more, the labor costs for loading and unloading ballast are too large in terms of number of employees and duration in time. In addition, difficulties arise with ballast water at low temperatures. The presence of ballast brings significant inconvenience in operation and is not a hopelessness with modern progress.

 A known device of the Skype type is a lenticular shape with horizontal plumage (see. "Modern aerostatic aircraft", G. S. Nesterenko, V. I. Narinsky, 1977.).

 The disadvantage of the apparatus is the lack of control at near-zero speeds in operation, because aerodynamic planes are not effective. And the inner frame, consisting of farms, has an increased weight, because compressive truss bearing elements of large lengths require significant areas in their sections to ensure longitudinal stability. Therefore, these shortcomings lead to insufficient efficiency in operation.

 Known thermal airship (USSR Author's Certificate 1609720, 64 V 1/00).

 The aforementioned flaws of a classic airship are inherent in this airship: weighting of the structure to withstand cutting forces and bending moments, as well as insufficient controllability at low speeds and especially in crosswinds. In addition, significant heat loss in the winter period due to large areas blown by a high-speed stream or wind is a disadvantage. This reduces operational efficiency.

 The aim of the invention is to increase the efficiency of the aerostatic apparatus.

 This goal is achieved by the fact that the proposed aerostatic apparatus has significantly smaller dimensions with the same volume as the classic airship. The smallest dimensions, as you know, the ball, but it has significant aerodynamic drag. Therefore, in the proposed apparatus, the housing is made in the form of a biconvex lens.

 The upper part of the body in shape is a spherical segment of one ball, and the lower part of the body is a spherical segment of another ball. Moreover, the upper spherical segment has a large curvature, i.e. a smaller radius of the sphere, and the lower spherical segment has less curvature, i.e. larger radius of the sphere. This form of the hull gives lift when flying, which saves fuel and increases range. Inside the housing is a frame made in the form of a wheel, the annular rim of which is placed along the line of intersection of the spherical segments.

The rim is connected by radial rigid pipes (wheel spokes) located in a horizontal plane. These spokes are connected to a vertical strut placed along the axis of symmetry of the housing. So that the knitting needles do not interfere with each other, a ring of a larger diameter than the diameter of the rack is installed on a vertical stand. A vertical strut interacts with one end with the upper part of the body, and the other with the lower. In this case, the lower part of the vertical rack extends beyond the outer lower contour of the housing by a significant amount. On the outer lower part of the body of the apparatus there is a cabin (gondola), which is mounted with the possibility of rotation around the vertical axis by 360 ^o . The gondola has marching engines, the thrust vectors of which can deviate up and down. Rotational fastening of the nacelle eliminates the need to rotate the aerostatic apparatus, which has neither front nor rear - it is symmetrical. Only the gondola has a front part where the pilots and a rear streamlined part are located. Therefore, with this concept, aerodynamic rudders are not required to rotate the apparatus. At zero speeds, the wind is parried by installing the gondola in the direction of the wind, creating the necessary parry thrust of the engines.

 The body in the form of a biconvex lens (like a jellyfish in water) easily perceives wind gusts (waves), because The body is symmetrical and streamlined on all sides.

 The upper part of the vertical strut extends beyond the outer upper contour of the housing by an amount sufficient to install the upper motors that can rotate in the horizontal plane. This allows you to stabilize the movement of the aerostatic apparatus in a vertical plane. For lifting and flying at a certain height in the lower part of the hull are balloons with a soft shell, which contains air leaving the balloons when lifting to a height, and filled with air when lowering the apparatus.

 In the upper part of the apparatus are placed balloons (cameras) with helium. When climbing to a height, their volume increases due to a decrease in the volume of air balloons.

 To avoid the use of traditional ballast during operation, an annular frame is fixed to the rigid elements of the frame, for example to radial spokes, by means of angular brackets. Engines equipped with blades are mounted on the free shoulders of the angle brackets on the upper side, providing vertical traction during rotation, and flexible connections (in the form of cables) are attached to the load in the lower part, along the axis of the engine. In the annular frame there is a radially located diaphragm interacting with the lower end of the rack, where there is a hatch with a ladder for the crew to enter the apparatus. For the perception of forces, the ends of the upright are connected by braces with radial spokes.

 The proposed device allows you to use it without ballast both in a single version, and in a coupled form.

 The proposed solution meets the criteria of the invention "significant differences", because not found technical solutions having features similar to the hallmarks of the claimed device.

The invention is illustrated by drawings, where
figure 1 - layout of the aerostatic apparatus in a vertical section;
figure 2 is a view A, a bottom view;
figure 3 - paired apparatus with one load;
figure 4 - arrangement of devices for the rotational interaction of the nacelle with a vertical rack;
figure 5 - arrangement of devices for the rotational interaction of the upper engines with a vertical strut.

 The aerostatic apparatus has a body made in the form of a biconvex lens, the upper part of which is a spherical segment 1 of one ball of a smaller radius, and the lower one - a spherical segment 2 of another ball of a larger radius, rim 3, placed along the line of intersection of the spherical segments, radial spokes 4, located in the horizontal plane and connecting the rim with a vertical strut 5, interacting at one end with the upper part of the casing, and the other with the lower, air balloons 6, located in the lower part of the casing a, helium balloons (chambers) 7, a nacelle 8 having the ability to rotate around the lower end of the strut, engines 9 located on the nacelle and able to rotate the thrust vector in a vertical plane, upper motors 10 mounted rotationally in a horizontal plane at the upper end of the strut, frame 11, made in the form of a ring with a diaphragm 12, interacting with the lower end of the vertical strut, equipped with an access hatch 13 with a ladder. The frame is fixed to the radial spokes with the help of angular brackets 14, on the free shoulders of which from the upper side there are mounted motors 15 with blades 16, and on the lower side along the axis of the engine - flexible connections in the form of cables 17 for suspension of loads. The ends of the upright are connected by braces 18, 19, 20, 21 with radial spokes.

 The aerostatic apparatus operates as follows.

 To transport the cargo after equipping the apparatus to the required range, the crew rises into the nacelle 8 through the hatch 13, which has a ladder, and tests the engines. The mechanic disconnects the cable ties fixed on the chassis racks, fixed on the parking lot. Gondola engines lift the device, overcoming its mass, which is approximately 1% of the carrying capacity, after which the pilot guides the gondola in the desired direction at the required height at the right speed.

 To lift the load, the device hangs above it, cables 17 are fixed on the cargo, descending from the brackets 14. After securing the cargo, the engines 15 are turned on, after which the cargo rises and is transported to the place of its installation. The cables are disconnected and the device flies for a new load or to the place of basing.

 For lifting and transporting cargo, according to the mass of the greater carrying capacity of the apparatus, two apparatuses are used, connected vertically by cables (Fig. 3).

 The use of this invention will significantly reduce costs with traditional methods of transportation of bulky cargo giant.

Claims (5)

1. An aerostatic apparatus comprising a body having segments of the surface of the upper and lower parts, air balloons, balloons for helium, a carcass, a nacelle and mid-flight engines, characterized in that it is equipped with a carcass strut located along the symmetry axis of the body and interacting at one end with the upper part of the hull, the other end with the lower part of the hull, on the outside of which a nacelle is mounted on the strut for rotation 360 ^o , on which the said marching engines are mounted with the possibility of rejection ia thrust vector up and down.  2. The aerostatic apparatus according to claim 1, characterized in that it is equipped with angular brackets, a frame and engines with blades for lifting loads, with each bracket attached to one of the spokes of the frame and designed to install an engine with blades.  3. The aerostatic apparatus according to claim 2, characterized in that the frame is made in the form of a ring with a diaphragm.  4. The aerostatic apparatus according to claim 2, characterized in that it is equipped with flexible connections for suspending the cargo on the one hand, and on the other hand, each flexible connection is fixed to the arm of the bracket on the other hand with respect to the installation site of the engines with blades.  5. The aerostatic apparatus according to claim 1, characterized in that the surfaces of the upper and lower parts of the body are made in the form of ball segments, the upper of which is made of greater curvature than the lower.

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