RU1797584C - Heat generator - Google Patents

Abstract

The invention relates to the field of aeronautics and can be used to equip hot air balloons. An object of the invention is to improve operational performance by increasing performance by increasing power. The heat generator 1 contains a cylinder 2 with liquefied gas, an evaporator 3, the inlet of which is connected to the cylinder 2 through the main valve 7, and the outlet is connected by a pipe 6 to the collector 4. The goal is achieved by the fact that it is equipped with an additional valve 8, a tight cavity is formed around the pipe 6 9. The tight cavity 9 through the additional valve 8 is in communication with the output of the main valve 7, and holes 6 are made on the pipe 6 inside the cavity 9. 1 ill.

Description

The invention relates to the field of aeronautics, and in particular to hot air balloon equipment.

The closest technical solution to the proposed acquisition is a heat generator. containing a cylinder with liquefied gas, an evaporator, the inlet of which is connected to the cylinder through the main valve, and the outlet is connected by a pipe to the collector.

A disadvantage of the known device is its narrow range of applications. For example, if the cross section is unfavorable, under circumstances, the hot air balloon may sink onto the wires of the high voltage transmission. In this case, a short-term sharp increase in the power of the heat generator is necessary. However, a known heat generator operating at maximum power cannot provide a power gain. As a result, disaster is inevitable.

An object of the invention is to improve performance by increasing power.

This goal is achieved by the fact that in a heat generator containing a cylinder with a liquefied gas, the evaporator, the inlet of which is connected through the main valve to the cylinder, and the outlet is connected by a pipe to the manifold, a tight cavity is formed around the pipeline, communicated through the additional valve to the main valve outlet, and holes are made in the pipeline inside the cavity.

The drawing shows a diagram of a heat generator. .

The heat generator 1 contains a container 2 with a liquefied basin, an evaporator 3, a collector 4 with nozzles 5, a pipe 6, a main valve 7, an additional valve 8, cavity 9. The evaporator 3 has an inlet 10 connected through a main valve 7 with a cylinder 2, and an outlet 11 connected by a pipeline 6c with a collector 4. The cavity 9 is sealed and communicated through an additional valve 8 with an outlet 12 of the main valve 7. On the pipeline 6, holes 13 are made in the cavity 9. The heat generator

has an ignition valve 14 with handles 15, 16, a pilot burner 17, a pressure gauge 18, an ignition device 19. The main valve 7 has a control handle 21. The cylinder 2 has a gas cavity 22 and a liquid cavity 23.

The device operates as follows.

Using the handle 15 of the valve 14, the gas supply from the gas cavity 22 of the cylinder 2 to the pilot burner 17 is opened and the ignition device 19 is turned on. Using the handle 16, the size and stability of the torch of the pilot burner 17 are controlled. Then, the handle of the 20-main valve 7 opens the fluid supply from the liquid cavity 23 of the cylinder 2 to the evaporator 3 and then to the manifold 4 and the nozzle 5. The fuel leaving the nozzles 5 is ignited by the pilot burner flare: l 17, the temperature around the evaporator 3 increases, the liquid fuel turns into gaseous in the evaporator 3, and t Generator 1 goes to nominal mode. An increase in the power of the heat generator 1 is ensured by the further opening of the main valve 7. If, when the main valve 7 is fully open, it is still necessary to increase the power of the heat generator (for example, when flying in areas with increased turbulence or to increase the rate of climb ™), handle 2.1 opens the additional valve 8 and serves liquid the fuel into the cavity 9, and from there through the holes of the 13-pipe, through which gaseous fuel flows from the evaporator 3 to

collector 4.

In the pipeline 6 there is a mixture of liquid and gaseous phases of the fuel. Due to the greater heat content in comparison with the liquid phase, the gas phase of the fuel transfers heat to the liquid phase, as a result of which the gasification of the latter takes place. In collector 4 only gasified fuel is obtained with a temperature intermediate between the temperatures of the vaporized and liquid phases of the fuel. The fuel consumption through the nozzles 5 increases, the heat output of the heat generator 1 also increases.,,

.