RU120191U1 - DEAERATION UNIT - Google Patents

Abstract

1. Deaeration unit, consisting of a deaeration column, a heating medium supply line, a storage tank, a preheating heat exchanger for deaerated water connected by a supply line to the deaeration column, a drain line from the accumulator tank to a pumping pump connected to the deaeration water supply line to boiler, characterized in that the heat exchanger for preheating the deaerated water is installed on the drain line of the water from the storage tank to the pumping pump. ! 2. The device according to claim 1, characterized in that a preheating heat exchanger for deaerated water is installed on the line for supplying deaerated water to the boiler.

Description

The utility model relates to the field of energy, in particular, to deaeration plants for heating and technological boiler and steam turbine plants as part of a combined cycle.

Known vacuum deaeration plants for hot water boilers, consisting of a deaeration column, a storage tank and an ejector for suction of gases released during deaeration (see the reference book Thermal and Nuclear Power Plants, edited by A.V. Klinenko and V.M. Zorin, Publishing House of MPEI, M. 2003, 321-325).

The main disadvantage of these installations is the need to ensure vacuum density and the complexity of the schemes associated with the installation of the ejector. In addition, the battery tank must be placed at a high altitude to provide pressure to the pumps that pump water from the deaeration plant.

Atmospheric or high pressure deaeration plants are known, consisting of a deaeration column, an accumulator tank, a deaerated water pump and heat exchangers for preheating water or condensate entering the deaerator (see ibid. Pp. 224-230, 321-325, 490- 492). The main disadvantage of these installations is the need to place them at a height of 12 to 26 m in order to provide support to the feed pumps. In addition, the high temperature of the water leaving the deaerator (104 ÷ 158 ° C) raises the temperature of the exhaust gases from the heat recovery boiler and the boiler at the heating and technological boiler houses, which leads to a decrease in their efficiency (hereinafter referred to as efficiency).

These disadvantages can be overcome if heat exchangers for preheating the deaerated water at the inlet to the deaeration column are installed on the drain line of the deaerated water from the storage tank, so that the preheating is carried out by cooling the deaerated water.

In Fig.1, 2 shows a diagram of a dosing unit. The installation consists of a deaeration column 1, a supply line for a heating coolant (steam, hot water) 2, a storage tank 3, a heat exchanger for preheating the deaerated water 4, a drain line from the storage tank 5, a discharge pump (supply, network) 6, a supply line water to the deaeration columns 7 and the supply line of deaerated water 8 to the boiler.

Installation works as follows.

Deaerated water enters the preheater 4 installed on the drain line from the storage tank 5, heats up and through line 7 enters the deaeration column 1, into which the heating medium flows through line 2. Deaerated water enters the storage tank 3, and then through drain lines 5 to heat exchanger 4 and pump 6, and is pumped through line 8 to the boiler.

Preheating the deaerated water in the heat exchanger 4 improves the deaeration and reduces the required flow rate of the heating medium along line 2, cooling the deaerated water in the heat exchanger 4 reduces the temperature of the flue gases from the boiler (or the PTU recovery boiler), which increases their efficiency.

The heat exchanger 4 with a small hydraulic resistance can be located on the drain line of the cooling water 5, in this case it reduces the necessary head-up height of the pump 6, ensuring its cavitation-free operation (Fig. 1).

The heat exchanger 4 can be located on line 8 (mainly for heating boiler rooms, where the pressure behind the pump is not high). In this case, an increase is provided economically by reducing the flow rate of the heating medium along line 2 and increasing the efficiency of the boiler by lowering the temperature of the exhaust gases (Fig. 2).

Thus, the proposed scheme of the deaeration plant allows you to simultaneously increase the efficiency of boiler rooms, increase reliability and reduce the dimensions of the deaeration plant, which fundamentally distinguishes it from other devices of this type.

Claims (2)

1. A deaeration plant, consisting of a deaeration column, a supply line for a heating coolant, a storage tank, a preheater of a deaerated water connected by a line for supplying it to a deaeration column, a drain line from a storage tank to a pump for discharge, connected to a line for supplying deaeration water to a boiler, characterized in that the heat exchanger for preheating the deaerated water is installed on a drain line from the storage tank to the pump. 2. The device according to claim 1, characterized in that the heat exchanger preheating deaerated water is installed on the supply line of deaerated water to the boiler.