SU937902A1 - Equipment for replenishment of heating system - Google Patents

Description

(54) INSTALLATION FOR FILLING HEATING NETWORK

The invention relates to a centralized heat supply for consumers, namely to central water heating systems. A known installation for feeding a heat network with water, containing a vacuum de-aerator and a water storage tank with a make-up pump, connects the heat supply network l. A disadvantage of the known device is the need to take a steam turbine vapor to the vacuum deaerator. The closest in terms of technical dryness to the proposed is a unit for feeding the heat network, containing supply and return lines, a hot-water boiler with a main additional heat exchanger, a tank-pump with a booster pump, a deaerator and an overflow pipe L2. The disadvantage of this installation is increased power consumption for the drive of the network pump and its overload. The purpose of the invention is to increase the efficiency of the equipment. Delivered ael is achieved in that the installation foai heating network feeding, comprising flow and return, vodogreyiu boiler with main and dopopnite vym m tloobmennnkami, tank accumulator with poschtitochnym pump, the deaerator and a bypass pipeline provided dopopnitelg w 1m bypass pipe "mtrovoiom, connecting the tank to the battery with the return line, and the additional heat exchanger is connected to the battery tank after the feed pump. The drawing shows the scheme of the proposed install. Ustanatsa contains deaerator G, piping 2 deaerated water, piping 3 deaerated water, storage tank 4, make-up pump 5, make-up regulator 6, return line 7, network pump 8, direct line 9 of heat network, main heat exchanger

10, a boiler 11, an additional heat exchanger 12, a pipeline 13, a heating water pipeline 14, a bypass conduit 15, an additional pipeline 16, regulators 17-19.

The installation works as follows.

At the same time, the water to be deaerated through the pipeline 2 and the water overheated through the pipeline 14 is supplied to the vacuum ajvar & mountains 1. The deaerated; I get the water through the pipeline 3 to the tank accumulator 4, which is pumped into the feed pump 5, is pumped to c, blunt through the feed regulator 6 to the reverse mains line 7, from where under the pressure of the network pump 8 is fed to the forward network 9 of the heating network, while heating in the main boiler 10 of the boiler 11, and the other part of the water is discharged Before the regulator, the feeds through the conduit 13 are heated in an additional heat sinter 12 of the boiler 11 as a heating agent through pipe 14 to the vacuum deaerator 1. In the heat exchanger 12, the water is heated to an effective temperature that ensures effective deaerator of the make-up water. The water pressure at the outlet of the heat exchanger 12 is provided by a booster pump 5, taking into account the required underheating of it up to the saturation temperature c. The flow of superheated water to the vacuum deaerator 1 is varied by a regulator 18, depending on the load of the EPH deaerator. To ensure a stable ogazation mode, the temperature of the heat exchanger water 12 is kept constant by bypassing part of the superheated water through conduit 15 using controller 17 to the return line 7. In the same way, overburning is prevented

heat exchanger 12 in case of significant reduction or full preheating of the supply of superheated water to the vacuum deaerator 1. Pressure in the reverse network mains: 7 is maintained by regulator 6 of the make-up. In the absence of a water flow, the heating network is fed into the sysfon operation with the regulator 17 of the regulator 19 and the water is supplied

from the return mains 7 to the tank-pump 4 via pipeline 16 in an amount equal to its flow in the bypass pipeline 15.

In the proposed installation, the increase in the thermal impurity of the heat exchanger 12 is increased by decreasing the main heat exchanger 1O of the boiler 11.

Claims (2)

1.Sokolov E.Ya. Heat certification and heating networks. M., Energie, 1975, p. 220, p. 7.7. 2. Izvesti VUZov, series Energhegika, 1979, No. 11, p. 116-117. -o d