RU2725303C1 - Thermoelectric power supply for self-contained heat generator - Google Patents

Abstract

FIELD: heat exchange.SUBSTANCE: invention relates to heat engineering, namely, to systems of apartment heating and power supply of residential buildings. Disclosed is a thermoelectric power supply source for an autonomous heat generator (TPSS), comprising heat generator (1), equipped with a gas branch pipe (2) connected to a main pipe of flue gases (3), section of which at the heat generator outlet is coated with a cylindrical air casing (4) consisting of two half-shells (5), equipped with fastening holes (6), into which through fastening bolts (7) are inserted, which are plugged from the internal end face and form a circular intake slot (8). Casing is connected by air duct (9) equipped with blowing fan (10) to the heat generator furnace. Thermoelectric unit (TEU) (11) is arranged inside the casing around the external surface of the gas branch pipe section. TEU consists of N thermoelectric sections (TEP) (13) located on pipeline surface, each of which is longitudinal frame (14) installed with a gap Δ from the outer surface of the gas branch pipe and consisting of n cells (15), on the ends of which there are one fastening threaded hole (16), in which through fastening bolts are screwed, and on the cell edges are laid with their lower edges n flat thermoelectric transducers (17) connected by current collectors (18, 19) to collectors of similar charges (20, 21), on which in each thermal power plant there are radiators (22) equipped with through holes (23) at the ends and pressed by clamping nuts (24) to the external surface of TIC on through fixing bolts.EFFECT: technical result is higher power and efficiency of TPSS.1 cl, 5 dwg

Description

The present invention relates to a power system, and in particular, to apartment heating and power supply systems of residential buildings.

A heat generator is known for autonomous power supply containing external and internal vertical rectangular boxes, a universal firebox with a gas duct, a gas pipe, primary and secondary circuits, walls of the external and internal boxes, covers, bottoms and vertical partitions in contact with heated water are made with longitudinal vertical and horizontal gear grooves facing the hot side, into which gear ribs are inserted, consisting of series-connected thermionic (thermoelectric) transducers made of a pair of segments of different metals M1 and M2, the ends of which are interconnected by contact junctions, the pairs of which are interconnected in the cooling zone through capacitors and jumpers, forming thermoelectric sections and thermoelectric blocks that are connected to collectors with the same charges connected to current leads [RF Patent No. 2599087, IPC F24 H1 / 00, 2016].

The main disadvantages of the known thermoelectric generator for stand-alone power supply are the complexity and bulkiness of its design, the inability to use the heat of the exhaust flue gases to generate thermoelectricity, which reduces its reliability and efficiency.

Closer to the proposed invention is an autonomous thermoelectric generator on the pipeline, containing a portion of the pipeline on which circumferential thermoelectric sections are provided along their entire length, equipped with electric capacitors and connected by jumpers, forming a thermoelectric block equipped with current leads with the same charges, and the thermoelectric sections are located zigzag sequentially one after another of thermionic (thermoelectric) transducers, each of which consists of a pair of segments made of different metals M1 and M2, the ends of which are interconnected, forming upper and lower junctions, and a section of the pipeline on which the circumferential thermoelectric sections are located closed by a casing made of a corrosion-resistant material with high thermal conductivity. [RF patent No. 2614349, C23 F13 / 00, 2019].

The main disadvantages of the known autonomous thermoelectric generator in the pipeline are the complexity of manufacture and insufficient power for servicing the heat generator, due to the design of the thermoelectric sections, which reduces its reliability and efficiency.

The technical result of the invention is to increase the reliability and efficiency of a thermoelectric power source for an autonomous heat generator.

The technical result is achieved by a thermoelectric power source for an autonomous heat generator, comprising a heat generator, a gas pipe connected to a flue gas pipe, a portion of which at the outlet of the heat generator is covered with a cylindrical air casing made of a corrosion-resistant material and composed of two half-casings equipped with fixing holes, into which inserted fastening bolts are inserted, plugged from the inner end and forming an annular intake slit from the outer end, the casing being connected by an air duct provided with a blower fan, and a heat generator furnace, a thermoelectric unit connected by electrical wiring to the inner surface of the aforementioned section of the gas pipe is located in this case, the fan motor, inverter and battery, the thermoelectric unit consists of N thermoelectric sections located on the pipeline surface, each of which represents a longitudinal frame installed with a gap Δ from the outer surface of the gas pipeline and consisting of n cells, at the ends of which are arranged one fastening screw hole in which through fastening bolts are screwed, and n flat thermoelectric transducers connected to the cell edges by their lower edges connected with current outputs with collectors of the same name, radiators are made on the upper outer surface of the thermoelectric transducers of each thermoelectric section, made of a hydrostatic material with high thermal conductivity, equipped with bore holes at the ends and pressed to the outer surface of the thermoelectric transducers by clamping nuts on the through mounting bolts.

In FIG. 1 shows a diagram of a thermoelectric power source for an autonomous heat generator (TEES), FIG. 2, 3 - general view and section of a thermoelectric block (TEB), in FIG. 4, 5 - node connection elements of flat thermoelectric converters (PTEC) of the thermoelectric section (TPP).

The proposed TEES comprises a heat generator 1 equipped with a gas pipe 2 connected to a flue gas pipe 3, a portion of the gas pipe 2 at the outlet of the heat generator 1 is covered with a cylindrical air casing 4, consisting of two half-shells 5, provided with fixing holes 6 into which through fastening holes are inserted bolts 7, muffled from the inner end and forming an annular intake slit from the outer end 8. The casing 4 is connected by an air duct 9 provided with a blower fan 10 to the furnace of the heat generator 1, a thermoelectric block (TEB) 11 is arranged inside it around the outer surface of the aforementioned section of the gas pipe 2; connected by wiring to the electric motor 12 of the fan 10, the inverter and the battery (not shown in Fig. 1-5). In this case, the thermopile 11 consists of thermoelectric sections (TPPs) 13 located on the surface of the pipeline 13, each of which is a longitudinal frame 14, installed with a gap Δ from the outer surface of the gas pipe 2 and consisting of n cells 15, at the ends of which are arranged one mounting threaded hole 16, into which the through fixing bolts 7 are screwed, and n flat thermoelectric converters (PTEC) 17 are placed on the edges of the cells 15 (for example, Peltier elements connected by current leads 18, 19 can be used as PTEC) with collectors of the same charges 20 and 21, and on the upper outer surface of the PTEC 17 of each frame 14 of the TPP 13, radiators 22 are made of a hydrostatic material with high thermal conductivity, provided with bore holes 23 at the ends and pressed to the outer surface of the PTEP with clamping nuts 24 on the through fastening bolted 7.

TEIES is installed during the installation or reconstruction of the apartment heating system, for which the pre-assembled TPPs 13, complete with radiators 22, are attached to the inner surface of the half-casings 5 with fixing bolts 6 and clamping nuts 24, after which the half-casings 5 are longitudinally superimposed on the gas pipe 2 section and fixed between themselves (attachment points in Fig. 1-5 are not shown). During the installation, the gap ∆ must be observed (the gap size ∆ is selected from the condition that there is no contact of the bottom surface of the PTEP 17 with the outer surface of the gas pipe 2 and the temperature of the air gap is not higher than 100 ° C to avoid overheating). After the installation of the TPP 13 and the entire thermopile 11, the current leads 18 and 19 of all the PTEC 17 are connected by electrical wiring through the collectors of the same charges 20 and 21 with the electric motor 12 of the fan 10 and other consumers of electricity (not shown in Figs. 1–5).

TEES presented in FIG. 1–5, works as follows. After starting the heat generator 1 and the blower fan 10 during the movement of hot flue gases in the gas pipe 2 with a temperature t _G indoors or outdoors with an air temperature t _C , a significant temperature difference is created between the temperature of the outer surface of the pipe 2 t _P and the air temperature (t _GP -t _C ) entering the annular cavity 8 through the intake cavity into the cavity of the casing 4, as a result of which a heat exchange process takes place between them. In this case, heating occurs through an air gap of thickness Δ from the wall of the pipe 2 of the lower surface of the PTEC 17 and the simultaneous rapid cooling of their upper zone due to the contact of radiators 22 made of material with high thermal conductivity, the flow of fresh air entering through the annular gap 8 of the casing 5. The created temperature difference between the heating and cooling zones of the PTEC 17 causes electron emission in them and the appearance of thermoelectricity in TPP 13 [S.G. Kalashnikov. Electricity. - M: "Science", 1970, p. 502-506]. The obtained thermoelectricity of each TPP 13 is summed up in the TEB 11 and fed through the collectors 20, 21 to the inverter (not shown in Figs. 1–5), where the required voltage and current are generated and supplied to the electric motor 12 of the fan 10, the battery, and other consumers ( Fig. 1-5 are not shown).

The magnitude of the difference in electric potential and current strength at current leads 18, 19 depends on the temperature difference on the junctions of metals M1 and M2, their characteristics, the number and characteristics of PTEC elements 17 in TPP 13, their number in TEB 11, the thermal characteristics of radiators 22, and the gap Δ which is installed during installation. If necessary, several thermopiles are installed 11. The required voltage U and current I depending on the load of the heat generator 1 and the temperature difference (t _P –t _C ) are regulated in the inverter (not shown in Fig. 1-5). The resulting electricity is used to operate the fan 10 and, for example, to automate the operation of the heat generator.

Thus, the design of the proposed TEES due to the increase in power provides the possibility of autonomous operation of the heat generator of the apartment heating system without connecting to the electric network, and the design of the fuel and energy complex 11 (EMF source) allows you to replace failed PTES and TPPs with the existing heating system, which increases its reliability and efficiency.

Claims (1)

A thermoelectric power source for an autonomous heat generator, comprising a heat generator equipped with a gas pipe in which a blower fan is placed, a thermoelectric unit covered with a cylindrical casing made of a corrosion-resistant material, consisting of thermoelectric sections assembled from thermoelectric converters connected in series to collectors with charges of the same name connected to current outputs, characterized in that the gas pipe portion at the outlet of the heat generator is covered with a cylindrical air casing composed of two half-shells equipped with fixing holes, through which fixing bolts are inserted, plugged from the inner end and forming an annular from the outer end intake slit, thermoelectric block consists of N thermoelectric sections located on the surface of the gas pipe N, each of which is a longitudinal frame installed with a gap Δ from its outer surface, consisting of n cells, at the ends of which are arranged one fixing threaded hole into which through fastening bolts are screwed, and n flat thermoelectric converters are laid on the edges of the cells with their lower edges, on the upper outer surface of the flat thermoelectric converters of each thermoelectric sections superimposed radiators made of a hydrostatic material with high thermal conductivity, equipped with bore holes at the ends and pressed against the outer surface of the flat thermoelectric converters by clamping nuts on the through fixing bolts.

Images