UA32281U - Thermoelectric generator for telemetric systems - Google Patents

Abstract

A thermoelectric generator comprises a body, a gas-fired burner, a thermoelectric module and a heat exchanger for heat supply and rejection. The thermoelectric generator includes a stabilizer of water intake into a combustion chamber. The hot heat exchanger is made as radiator for each module located symmetrically from both sides of the gas-fired burner so that a gill part located in hot gases flow, opposite part has heat contact with the module. The cool heat exchanger has two symmetrically located bases, one side of which has a projection with flats on which modules are located, another side has contact with double gills, each pair has a solid base.

Description

The useful model refers to thermoelectric power sources and will be used to convert the thermal energy of the combustion of organic gas fuel into electrical energy. The thermogenerator is designed to power the telemetry equipment of gas and oil pipelines, drilling rigs, as well as other similar equipment and devices with electrical energy.

The well-known thermogenerator |(1| for powering systems of telemetric monitoring of wells during the drilling process.

The generator contains a case in which an isotopic or chemical heat source is installed and thermoelectric modules that are heated by this heat source. The heat from the modules is removed by the flow of drilling fluid. The disadvantage of such a generator is that it is used only for powering telemetry systems of boreholes and works only when pumping drilling mud, the flow of which removes heat from the cold side of the thermal battery. In the case of using an isotopic heat source, such a generator is environmentally dangerous.

A known thermal generator (2| for powering telemetry equipment containing a hot radiator, which is attached to a heat source in the form of a geothermal hot pipe or a pipe through which hot oil moves, a cold air heat exchanger and thermoelectric modules located between them. The disadvantage of the generator is low power , due to a small temperature difference and significant heat losses due to the difficulty of heat transfer from the pipe to the module.When the power of the generator increases, its overall dimensions increase significantly.

The known thermal generator |Z| for autonomous power supply of electrical and radio equipment in expeditionary conditions.

The generator is placed in the case and consists of a flame-type burner, cold and hot heat exchangers and semiconductor thermocouples located between the heat exchangers. The burner is located in the lower part of the hot radiator. The disadvantage of the generator is the instability of parameters and low reliability when working outdoors. In the presence of wind or precipitation, the stability of the burner is disturbed. And in some cases, the generator stops working due to the burner going out.

The closest to the proposed useful model is a thermal generator |4)|, which contains a burner device on organic fuel, thermoelectric batteries with a hot heat exchanger and a cold radiator, a combustion chamber with an exhaust pipe and a device for regulating fuel heating, which includes bellows with easily boiling liquid. The generator is placed in a housing that has holes for air intake. The disadvantage of the generator is the complex design, the instability of the burner operation, and, accordingly, the initial electrical parameters of the generator during its operation under difficult climatic conditions: wind, precipitation, etc. This is due to the fact that the burner injector, which is located in the housing directly next to the air intake holes, is not protected from uncontrolled forced air intake. This is the reason for the change in the composition of the air-gas mixture during gusts of wind and as a result of the unstable operation of the burner or complete extinction in the case of a significant deviation of the composition of the combustible mixture from the stoichiometric ratio.

Therefore, the task of creating a gas-fueled thermal generator that has stable electrical parameters and high reliability under the condition of autonomous operation both indoors and outdoors is urgent.

This task is solved by the fact that the heat generator, which consists of a body, a gas burner, thermoelectric modules and heat exchangers for supplying and removing heat, which is distinguished by the fact that it contains a stabilizer of the rate of air entering the combustion chamber, while the hot heat exchanger of the generator is made in the form individual radiators for each module, symmetrically located on both sides of the linear burner in such a way that their finned part is in the flow of hot gases, and the opposite side has thermal contact with the module; the cold heat exchanger contains two symmetrically located bases, one side of which has protrusions with planes on which the modules are placed, and the other - a thermal contact with double ribs, each pair of which has a solid base.

Compliance with the "novelty" criterion for the proposed device is ensured by the fact that the declared set of features is not contained in any of the objects of the existing state of the art.

The useful model offers a new solution for a gas-fueled heat generator, which consists of a body, a gas burner, thermoelectric modules and heat exchangers for heat supply and removal, which consists in the fact that the heat generator contains a stabilizer of the air flow rate into the combustion chamber, while the hot heat exchanger generator is made in the form of individual radiators for each module, symmetrically located on both sides of the linear burner in such a way that their finned part is in the flow of hot gases, and the opposite side has thermal contact with the module; the cold heat exchanger contains two symmetrically located bases, one side of which has protrusions with planes on which the modules are placed, and the other - a thermal contact with double ribs, each pair of which has a solid base.

Therefore, a feature that is not found in any of the analogues - it contains a stabilizer of the rate of air entering the combustion chamber, while the hot heat exchanger of the generator is made in the form of separate radiators for each module, symmetrically located on both sides of the linear burner in such a way that their ribbed part is in the flow of hot gases, and the opposite side has thermal contact with the module; the cold heat exchanger contains two symmetrically located bases, one side of which has protrusions with planes on which the modules are placed, and the other - a thermal contact with double ribs, each pair of which has a solid base - provides the claimed device with the necessary "inventive level".

The essence of the proposed useful model is explained by figures.

In fig. 1, 2 shows a vertical section of the thermogenerator in two mutually perpendicular planes, and Fig. C - horizontal section of the generator.

According to the proposed useful model, the heat generator (Fig. 71, Fig. 2) contains hot 1 and cold 2 heat exchangers, between which thermoelectric modules 3 are located. Hot heat exchanger 1 consists of separate radiators for each module, symmetrically located on both sides of the linear burner 4.

The finned part of individual hot radiators is located in the flow of hot gases, and the opposite side has thermal contact with the hot side of the thermoelectric module. The cold heat exchanger (Fig. 3) contains symmetrically located bases, one side of which has protrusions with planes on which thermoelectric modules are placed, and the other is a thermal contact with double ribs 5, each pair of which has a solid base.

The linear gas burner 4 is located in the lower non-finned part of the hot heat exchanger, which is also the combustion chamber. The burner is equipped with a starting device b, which contains a pilot burner, a thermocouple and a piezo ignition electrode.

The stabilizer 7 of the speed of air entering the combustion chamber is adjacent to the lower ends of the hot heat exchanger 1. It contains at least two plates 8 placed horizontally one above the other, each of which has two rows of holes 9 and a separate air duct 10 in the form of a hollow tube of rectangular section. The pipe 10 is located close to the lower plate, and the lower plate with holes is at the same time the upper wall of the pipe 10. The rows of holes 9 are offset relative to each other along the horizontal axis by a distance equal to 2-31, where | - the width of the opening. The ends of the horizontal duct 10 of the air speed stabilizer are open and bent upwards at an angle of 90" (Fig. 2).

In the upper part of the hot heat exchanger 1, there is a smoke pipe 11, which enters the gas collector 12, in the middle of which there is a plate 13 designed to reduce the air flow rate in case of wind blowing into the upper part of the smoke pipe 11.

The free volume between the cold and hot heat exchangers is filled with thermal insulation 14.

The gas linear burner 4 and the starting device are connected by a separate pipeline to the gas automation 15 (Fig. 2), which controls the burning of gas and stops the flow of gas to the linear burner in case of extinguishing of the pilot burner. Gas supply to automation is carried out using a gas pipeline 16, on which a gas tap 17 is installed.

The thermoelectric generator together with automation is located in a continuous housing 18, the lower and upper walls of which have openings 19 (Fig. 1, Fig. 2) for the intake of air for cooling the generator and air necessary for fuel combustion.

The generator works as follows.

Combustible gas through the gas pipeline 16 enters the gas automation 15. With the help of the automation regulator, the gas first enters the starting device 6, and after the ignition of the pilot burner, the gas enters the main linear burner 4, where it is ignited by the pilot burner. The air required for fuel combustion enters through the holes 19 of the housing 18 to the open ends of the pipe 10. Further, the air through the holes 9 enters the injector of the linear burner 4, where a combustible mixture is formed. Hot combustion products pass through the channels of the radiator 1 and are discharged through the smoke pipe 11 into the environment. The heat released during fuel combustion heats the radiator 1, passes through the thermoelectric modules C and is removed by the cold radiator 2 by natural convection of air, which enters through the holes 19 of the lower wall of the housing 18 and leaves through the holes of the upper wall.

Due to the temperature difference between the hot and cold sides, thermoelectric modules generate an electric current.

The electrical power of the generator is 10-12 W at a voltage of 248. The temperature of the hot side is 270-2802C, the cold side is 50-6070.

The thermal generator of the proposed design works reliably outdoors under difficult climatic conditions. Wind and precipitation practically do not affect the stability of fuel combustion, and, accordingly, the output electrical characteristics of the thermoelectric generator. The generator can work for a long time without maintenance because it has no moving parts.

The proposed thermal generator can be used to power telemetry systems of remote objects (gas and oil pipelines, drilling wells, environmental monitoring) or other similar equipment, various electronic equipment, battery charging, etc. with electrical energy.

The increased reliability of the thermogenerator will significantly expand its practical use for solving national economic problems, which will generally improve the quality of production conditions.

Sources of information 1. Pat. VO 2235875 C2, IPC: E21847/12. Thermoelectric autonomous source of power supply / Hrychashkin G.A. (8). - Publ. 10.09.2004. 2. Rai in 14206 IPC: NOTI 35/00, NOTI 35/30. Tnegptoeyesigis rozheg depegayug azzosiaiea m/p oi rireiiipe5z / Spipegu Oauid (SW). - Publ. 21.11.1984.

Z. A.s. 1686984 JSC (50) IPC: NOTI 35/02. Thermoelectric generator /E.G. Pokornyi, O.P. Zherdeva, A.K.

Nikonenok, L.M. Parparov, L.M. Tsipkina, I.L. Shatunov (5). - Publ. 19.02.1990. 4. A.s. 795357 A (50). IPC: NOTI 35/02. Thermoelectric generator /Yuyu.P. Vagulin, Yu.A. Kalinin, N.V.

Kolomoets, V.S. Makarov, V.P. Protsenko (5). - Publ. 21.09.1979.

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Claims (5)

1. A thermoelectric generator consisting of a body, a gas burner, thermoelectric modules and heat exchangers for supplying and removing heat, which is distinguished by the fact that it contains a stabilizer of the air flow rate into the combustion chamber, while the hot heat exchanger of the generator is made in the form of separate radiators for each module , symmetrically located on both sides of the linear burner in such a way that their finned part is in the flow of hot gases, and the opposite side has thermal contact with the module; the cold heat exchanger contains two symmetrically located bases, one side of which has protrusions with planes on which the modules are placed, and the other - a thermal contact with double ribs, each pair of which has a solid base. 2. Thermoelectric generator according to p. plates, and the lower plate with holes is simultaneously the upper wall of the pipe. 3. Thermoelectric generator according to claim 2, which differs in that the rows of holes in the lower and upper plates of the speed stabilizer are offset relative to each other along the horizontal axis by a distance equal to 2-31, where I is the width of the hole. 4. Thermoelectric generator according to paragraphs And, 2, which differs in that the horizontal air duct of the air speed stabilizer contains bent upwards at an angle of 90? open ends. 5. Thermoelectric generator according to item I, which is characterized by the fact that the generator body contains holes for air intake in the lower and upper walls.