SU1216573A1 - Heat supply system - Google Patents

Description

1216573

The invention relates to heat power engineering and can be used for heat supply systems equipped with battery tanks.

The aim of the invention is to expand the range of regulation with the constant flow of coolant

re

70

on a

9

in a ku e by nor acra J5 nude nor in with

Sh

20

through the heating surface of the boiler.

The drawing shows a schematic of the heat supply system.

The heat supply system contains the heating surface 1 of the boiler, installed in its duct 2 and communicated by its entrance through the valve 3 with the outlet section 4 of the lower perforated tube 5 of the storage tank 6, and the return pipe 7. The heating surface 1 is connected with the outlet to the direct pipeline 8 and through the valve 9 with the inlet section 10 of the upper perforated tube 11 of the storage tank 6. The heat supply system further comprises an elevator with an active nozzle 12 and a receiving chamber 13. The heating surface 1 of the boiler is connected to the inlet section the flow 10 of the upper perforated pipe 11 through the active nozzle 12 of the elevator, the receiving chamber 13 of which is connected to the outlet section 4 of the lower perforated pipe 5 through its flow regulator 14 to its valve 3. The output section 15 connects the upper perforated pipe 11 through the regulator 16 to the jumper 17 in the zone between the pump 18 installed on it and the valve 19. The jumper 17 is connected at one end to the direct pipe 8 and the other to the return pipe 7. At the entrance to the heating surface 1, the return pipe 7 is installed pump 20.

The heat supply system works as follows.

The boiler operates during the calculated period at a constant nominal load Q, 45 with a constant flow rate of heated water G. through the heating surface 1

 Ll

thirty

35

and heating water from 70 C to 150 ° C. At the same time, in the forward and return pipelines 8 and 7, the flow rate of water Gj is also constant, but greater than G, (G, 7G,). In this case, the heat supply to the consumer by the scheme is provided according to the temperature schedule, for example, 70-130 ° C in an amount from O to Qj, and moreover. Water temperature in the storage tank VNIISH Order 988/48

water with a temperature of 150 of surface 1 of heating 9 enters the active elevator, where, by mixing the feed to the lower perforated battery 6, it reduces the service to 95 ° C and the input of J5 perforated layers of the water storage tank surface exit 1 mom pipeline 8 in to

necessary to maintain perurature according to tempe fic. Circulation of the main water in the direct piping is carried out from the return 25 to water 7 through the valve 1 and to the inlet of the surface 1 of the boiler the main flow in the lower perforated valve 3 from the storage tank 1.

As the load to the consumer grows, the temperature of the pipeline 8 by increasing the valve 9 and the regulator begin to close, valves 3 and 19 are attached. Valves 3 and 9 and the controller are fully closed, the araskho valve is equal to 19

four

Gi

With further p loading, Q 2 opens the reagent 16 for taking water at 95 ° C and the valve 3 of water from the return pipe 7 to the storage tank 6 ku 19 is closed. When the dos in the direct pipeline 8 130 ° С

50 ka 19 - in the closed.

Thus, the heat supply system was proposed to use the accumulation of 95 ° C with the release

55 it to the consumer with more temperature.

Circulation 650. Subscription

Branch ShSh 11ATent, g, Uzhgo1H d, st. Project, 4

about

process of discharging it -o.

at the end, and the charge temperature,

When the regulator 16 is in the closed state, and the regulator 14 of the flow and the valve 3,

9 and 19 - in the open. In this mode

about.

water with a temperature of 150 ° C from the exit of the heating surface 1 through the valve 9 enters the active nozzle 12 of the elevator, where, mixing with water supplied to the receiving chamber 13 from the lower perforated tube 5 of the storage tank 6, reduces its temperature to 95 ° C and It enters through the upper perforated pipe 11 into the upper layers of the storage tank 6. A part of the water enters with a temperature of 150 C from the outlet of the heating surface 1 through the direct pipeline 8 in quantity.

necessary to maintain the temperature in it according to the temperature schedule. In this case, the main flow of water in the direct pipeline 8 is circulated from the return pipe 7 through the valve 19 by the pump 18, and to the inlet of the heating surface 1 of the boiler the main water flow is carried out from the storage tank 6 through the lower perforated pipe 5 and gate valve 3.

As the load Q (consumer leave) increases, the temperature in the direct pipeline 8 increases, for which the valve 9 and the flow regulator 14 begin to close, and the valves 3 and 19 close. At. Zi 9i valves and flow regulator 14 are completely closed, and flowrate through the valve 19 is equal to the difference in flow rates.

As the load Q 2 continues to grow, regulator 16 is opened to take in water with a temperature of 95 ° C and valve 3 to pass water from the return pipe 7 to the storage tank 6, and valve 19 closes. When the temperature in the forward pipeline 8 reaches 130 ° C, the regulator 16 is in the open position and the valve 19 is in the closed position.

Thus, the proposed heat supply system will allow the use of teapa accumulation with a temperature of 95 ° C when the latter is dispensed to a consumer with a higher temperature.

Circulation 650. Subscription

Claims (1)

HEAT SUPPLY SYSTEM, containing the heating surface of the boiler, communicated by its entrance through the valve with the outlet section of the lower perforated pipe of the storage tank and the return pipe, and by the exit - with the direct pipeline and through the valve with the entrance section of the upper perforated pipe of the battery tank, the outlet section of which is connected through the regulatory body to the jumper in the area between the pump and the valve installed on it, and the jumper at one end is connected to a direct pipeline, characterized in that, for the purpose of extension control range at a constant flow rate through the boiler heating surface, further comprising a silo with active nozzle and a receiving chamber, the jumper is connected to the other end of the return pipe, and the surface _of the heating boiler NOSTA · © connected to the input of the upper perforated tube through the active nozzle elevato -, pa, the receiving chamber of which through the flow regulator is connected to the output section of the lower perforated pipe to its valve. δΖ ^ 9ίΖΓ ^{π ,,} · Π§