RU102760U1 - HEAT ITEM - Google Patents

Abstract

 A heating unit, containing the supply and return pipelines of the heating network with inlet and outlet valves, respectively, and installed on the pipelines after the inlet and in front of the outlet valves, by dirt collectors, pressure gauges, thermometers and pressure regulators, the supply and return pipelines of the heat consumption system with the outlet and inlet valves and installed on these pipelines after the inlet and before the outlet valves with manometers and thermometers, a mixing pipeline between the supply and return pipelines of the heat network, characterized in that it is additionally equipped with a self-excited hydraulic shock generator, a check valve, a hydraulic accumulator and a thermal expansion valve with a thermosensitive element, while a self-excited hydraulic shock generator is installed in the return pipe of the heating network in the area after the mixing pipeline, in which the check valve, the hydraulic accumulator are sequentially connected and a thermal expansion valve with a heat-sensitive element located in one of the supply or return ruboprovodov.

Description

The utility model relates to heat power engineering, and the estate to heat supply, and can be used in heat and water supply systems with a dependent scheme for connecting one or several types of heat load to a consumer's heat source (heating, ventilation, air conditioning, hot water supply system).

Known heat station heating system with a water-jet elevator and branches to ventilation and air conditioning systems, containing supply, return, mixing pipelines, with valves installed on them, thermometers, manometers, a water-jet elevator installed in the piping mixing unit, a pressure regulator and a heat meter on the return the piping of the heat point after the mixing pipeline, the flow regulator on the supply pipe to the mixing unit (Heating and ventilation, a textbook for high schools. In 2- h. Part 1. Heating, 3rd ed., revised and enlarged M., Stroyizdat, 1975. 483 s, PN Kamenev, AN Skanavi et al., pp. 168-172, fig. Iv.10).

Among the disadvantages of the known device, it should be noted low efficiency, not exceeding 10-15%, increased consumption of fuel and energy resources spent on heating, a small range of regulation of the mixing coefficient and the fact that the circulation pressure at the input of the heating unit should be at least 10 times exceed circulating pressure in the local heating system.

The technical result consists in increasing the efficiency of the operation of a heat point by providing automatic control of the mixing coefficient, as well as in increasing the heat transfer coefficient of heat-using equipment.

The technical result is achieved by the fact that the heat point contains the supply and return pipelines of the heat network with inlet and outlet valves, respectively, and installed on the pipelines after the inlet and in front of the outlet valves with dirt collectors, manometers, thermometers and pressure regulators, the supply and return pipelines of the heat consumption system with the outlet and inlet valves and installed on these pipelines after the inlet and before the outlet valves, manometers and thermometers, a mixing pipeline between yuschim heat and reflux piping network. In addition, the heat station is equipped with a self-excited hydraulic shock generator, a check valve, a hydraulic accumulator and a thermal expansion valve with a heat-sensitive element, while a self-excited hydraulic shock generator is installed in the return pipe of the heating network in the area after the mixing pipeline, which includes a check valve, a hydraulic accumulator and a thermal expansion valve with heat-sensitive element located in one of the supply or return piping x

The heat point contains (Fig. 1) supply 1 and return 2 pipelines of the heating network with inlet 3 and outlet 4 valves, respectively, and installed on pipelines 1,2 after the inlet 3 and in front of the outlet 4 valves with sump 5, manometers 6, thermometers 7 and pressure regulators 8, supplying 9 and return 10 pipelines of the heat consumption system (not shown in the diagram) with output 11 and input 12 valves, respectively, and installed on pipelines 9, 10 after input 12 and before the output 11 valves with pressure gauges 6 and thermometers 7, mixing a piping 13 between the supply 1 and the return 2 pipelines of the heating network (pipelines 9, 10 of the heat consumption system), a self-excited hydraulic shock generator 14 installed in the return pipe 2 of the heating network in the area after the mixing pipe 13, in which the check valve 15, the accumulator 16 are connected in series and a thermal expansion valve 17 with a heat-sensitive element 18 located in the return pipe 2 of the heating network.

The heat point works as follows. The high-temperature coolant T ₁ enters the heat point through the supply pipe 1 of the heating network through the inlet valve 3, passes the mud collector 5, cleaning itself of mechanical impurities, and the pressure regulator 8, where the pressure of the high-temperature coolant T ₁ stabilizes to the required value, then bypassing the mixing unit in the connection point of the mixing pipe 13, enters the supply pipe 9 of the heat consumption system (not shown in the diagram) and leaves the heat point through the outlet valve 11 with a temperature of T ₃ .

The cooled coolant T ₂ through the inlet valve 12 of the return pipe 10 of the heat consumption system (not shown in the diagram), enters the heat center, passes the self-excited hydraulic shock generator 14, pressure regulator 8, sump 5 and through the outlet valve 4 of the return pipe 2 of the heating network leaves the heat point. When the cooled coolant T ₂ moves through a self-excited hydraulic shock generator 14, a series of periodic hydraulic shocks occurs, the positive propagation wave of which ensures the arrival of the cooled coolant T ₂ into the mixing pipe 13 sequentially through a non-return valve 15, a hydraulic accumulator 16 and a thermal expansion valve 17 into the supply pipe 1 of the heating network . The amount of cooled coolant T ₂ supplied through the mixing conduit 13 depends on the frequency and amplitude of the generation of hydraulic shocks at the self-excited hydraulic shock generator 14 and the degree of opening of the expansion valve 17, which is automatically (mechanically or hydraulically) supplied from the heat-sensitive element 18 mounted on the return pipe 10 heat consumption systems. To monitor the parameters of the coolant in the heat point at each of the pipelines, measuring equipment is installed: manometers 6 and thermometers 7. A feature of this heat point is that the self-excited hydraulic shock generator 14 provides pulsed circulation of coolants in each of the pipelines, which increases the heat transfer coefficient of the coolant.

Compared with the known solution, the proposed device allows for automatic regulation of the mixing coefficient due to the pulsed circulation of the coolant, to increase the heat transfer coefficient by 1.5-2.5 times. In addition, the self-cleaning effect of heat-using equipment is realized, which ultimately increases the efficiency of the use of fuel and energy resources and the energy efficiency of the heat supply system as a whole.

Claims (1)

A heating unit, containing the supply and return pipelines of the heating network with inlet and outlet valves, respectively, and installed on the pipelines after the inlet and in front of the outlet valves, by dirt collectors, pressure gauges, thermometers and pressure regulators, the supply and return pipelines of the heat consumption system with the outlet and inlet valves and installed on these pipelines after the inlet and in front of the outlet valves with manometers and thermometers, a mixing pipeline between the supply and return pipelines of the heat network, characterized in that it is additionally equipped with a self-excited hydraulic shock generator, a non-return valve, a hydraulic accumulator and a thermal expansion valve with a heat-sensitive element, while a self-excited hydraulic shock generator is installed in the return pipe of the heat network in the area after the mixing pipeline, in which the non-return valve and the hydraulic accumulator are connected and a thermal expansion valve with a heat-sensitive element located in one of the supply or return ruboprovodov.