SU1321993A1 - Deaeration unit for hot water supply system - Google Patents

Abstract

The invention relates to a power system and industrial heat engineering. The invention makes it possible to increase the efficiency of operation by stabilizing the direct network water supply system (TL). In the heater (P) 5, through a three-way valve 9, deaerated water enters through line 4 and reverse CB through line 6. Next, heated water through line 7 direct CB enters the consumer. The t-ra of water in line 7 is adjusted to a predetermined value by cooling the mixture in P 5 with make-up cold water from line 3 by changing the ratio of the quantity of water taken from lines 4 and 6. The required ratio of the number of deaerated water from line 4 and the return CB from line 6 is automatically selected by valve 9 by means of actuator 10, controlled by controller 11 according to the signal from sensor 12. The latter is installed in line 7 of direct CB after П 5. 1 Il. sl with yu; 0 O CO

Description

The invention relates to a power system and industrial heat engineering and can be used in the preparation of network water in hot water systems.

The purpose of the invention is to increase the work efficiency by stabilizing the temperature of the direct supply water.

The drawing schematically shows a deaeration plant.

The proposed plant contains a deaerator 1, to which lines 2-4 are connected, respectively, of supplying steam and deaerated water and discharging deaerated water, make-up water heater 5, lines 6 and 7, respectively, of return and outlet of direct supply water. Line 7 is equipped with a circulation pump 8. The unit is equipped with a three-way control valve 9 installed on line 7 of the supply system water to preheater 5. The inlets of valve 9 are connected to lines 4 and 6, respectively, of deaerated water and supply the return network water. The actuator 10 of the valve 9 is connected to the temperature controller 11, the sensor 12 of which is installed in line 7 of the direct supply water behind the heater 5. Line 6 of the return network water is connected by a recirculation line 13 to the deaerator column 1. On line 13 there is a control valve 14, the actuator 15 of which is connected to the pressure regulator 16, the sensor 17 of which is installed in line 6. On

In the mixture, the fraction of deaerated water decreases and the fraction of colder return water decreases, while the temperature of water in line 7 increases, on the contrary, the fraction of hot deaerated water decreases in the mixture and the fraction of colder return water increases.

The mixture of deaerated water from deaerator 1 through line 4 and through line 6 of return network water through a three-way valve 9 and heater 5 is taken up by a circulation pump 8 and supplied through line 7 to hot water consumers. The temperature of the water in line 7 is regulated to a predetermined value by cooling the mixture in the preheater 5 make-up cold

 water from line 3 by changing the ratio of the amount of water withdrawn from line 4 and 6. The necessary ratio of the quantity of hotter deaerated water and return network water from

20, line 6 is automatically selected by a three-way valve 9 by means of an actuator 10 controlled by a controller 11 according to a signal from a sensor 12 installed in line 7 of direct supply water.

25 Condensation of hot water pumping in consumers is accomplished by replenishing deaerator 1 through line 3 through a preheater 5. Water in the storage tank of deaerator 1 is automatically maintained at a given constant level by

line 3 for supplying deaerated water to -0 control valve 18 controlled by the reheater 5 has a valve 18 with an actuator 19 connected to a level 20 regulator and its sensor 21 in the tank of the deaerator 1 on the heating water supply line 2 22, by the actuator 19 as commanded by the level controller 20 at the signal of the sensor 21 installed in the storage tank.

The temperature of the deaerated water in the storage tank is kept constant

water 23 of which is connected to the regulator to ensure complete degassing due to 24 pressure and its sensor 25 in deaerator 1.

The installation works as follows.

Cold water is deaerated via line 3

maintaining a constant vapor pressure in the column of deaerator 1 by changing the amount of steam entering it through the steam line 2 by means of a control valve 22

enters through the preheater 5 into the column 40 through the actuator 23, controlled by the regulator aerator 1, where it is heated to the pressure sensor 24, the sensor 25 of which

installed in the column deaerator 1.

A change in the consumption of hot water by consumers leads to a change in pressure in line 6, which is maintained

boiling points and gases are completely removed from it. Next, the deaerated water is collected in the deaerator 1 storage tank, from where part of it along line 4 and part

reverse network water through line 6-45 at a given level at the signal of the sensor

17 by the pressure regulator 16 by acting by means of the actuator 15 on the control valve 14 installed on the water recirculation line 13, through which it is redirected to the deaerator column for heating and degassing. Thus, when the demand for hot water decreases, pressure in line 6 rises, and according to a signal from sensor 17, pressure regulator 16 opens actuator 15 by means of actuator 15, bypassing excess water from line 6 through line 13 again for heating and degassing into the deaerator column .

The pump is fed and supplied to the pump inlet, pre-cooled to the preset temperature in the preheater 5, with cold water deaerated with cold water from line 3. By pump 8, the prepared water is supplied to the consumer of hot water, the rest of which returns to line 6 deaerated water of line 4. The temperature of the direct supply water to consumers via line 7 is controlled by changing the ratio in the mixture of the amount of deaerated return supply water: as the water temperature in line 7 decreases elichivaets proportion in the mixture of deaerated water and reduced proportion of a colder return water, when the water temperature in the line 7, on the contrary, is reduced in proportion bitter mixture of deaerated water and increased proportion of a cold water return network.

The mixture of deaerated water from deaerator 1 through line 4 and through line 6 of return network water through a three-way valve 9 and heater 5 is taken up by a circulation pump 8 and fed through line 7 to hot water consumers. The temperature of the water in line 7 is regulated to a predetermined value by cooling the mixture in the preheater 5 make-up cold

 water from line 3 by changing the ratio of the amount of water withdrawn from line 4 and 6. The necessary ratio of the quantity of hotter deaerated water and return network water from

The line 6 is automatically selected by a three-way valve 9 by means of an actuator 10 controlled by a regulator 11 according to a signal from a sensor 12 installed in line 7 of direct supply water.

5 The accumulation of hot water intake in consumers is accomplished by replenishing deaerator 1 through line 3 through heater 5. Water in the accumulator tank of deaerator 1 is automatically maintained at a given constant level by

0 control valve 18 controlled at

the control valve 18 is controlled by

water 19 at the command of the level controller 20 according to the signal of the sensor 21 installed in the storage tank.

The temperature of the deaerated water in the storage tank is kept constant

to ensure complete degassing due to

at a given level by the sensor signal

17 by the pressure regulator 16 by acting by means of the actuator 15 on the control valve 14 installed on the water recirculation line 13, through which it is redirected to the deaerator column for heating and degassing. Thus, when the demand for hot water decreases, pressure in line 6 rises, and according to a signal from sensor 17, pressure regulator 16 opens actuator 15 by means of actuator 15, bypassing excess water from line 6 through line 13 again for heating and degassing into the deaerator column .

With an increase in water intake by consumers, the pressure in line 6 decreases, and, according to a signal from sensor 17, pressure regulator 16 by means of actuator 15 closes valve 14, which reduces water bypass from line 6 through line 13 to deaerator 1 and restores pressure in line 6. Thus In line 6, a constant pressure is always maintained, which eliminates the negative effect of a change in hot water pumping on the temperature of the hot water supplied to the network.

In the complete absence of water pumping by consumers, hot water on line b is through a three-way valve 9 and heater 5 is returned via pump 8 again through line 7 to the consumer. At the same time, there is no water withdrawal from the storage tank via line 4 (until the water temperature in line 7 falls below the setpoint of regulator 24) and therefore valve 18 of line 3 and valve 22 of steam line 2 are closed, since no one enters the deaerator column cold make-up water, no return network water from line 13, since at that time valve 14 was also closed.

At the maximum water consumption by consumers, the return of hot water through line 6 is minimal and through the three-way valve 9 the main mass of water passes through line 4 from the storage tank to which intensive replenishment of one deaerated make-up cold water goes from line 3 passing through the heater 5 in which she, herself, is preheated, simultaneously cools the pick-up to Editor N. Flesh Order 2744/31

VNIIPI USSR State Committee for Inventions and Discoveries

113035, Moscow, Zh-35, Raushsk nab. 4/5 Production and printing company, Uzhgorod, ul. Project, 4

In this case, the water from the preheater 5. The valve 22 of the steam line 2 is open to the value at which the pressure in the deaerator 1 is maintained at a given constant level. The valve 14 is almost completely closed and provides a predetermined pressure in line 6 and, accordingly, in the hot water supply networks of the user.

Thus, the installation provides reliable and stable water treatment both at the maximum and at the minimum water consumption by the consumers and provides temperature stabilization and water pressure in the hot water supply networks.

Claims (1)

Invention Formula A deaerating plant for a hot water supply network containing a deaerator with connected supply and drain lines, respectively, of deaerated and deaerated water, a make-up water heater and supply and discharge lines, respectively, reverse and direct network water, which is designed to increase operating efficiency by stabilizing the temperature of the direct supply water, the installation is additionally equipped with a direct supply water located on the line before the three-way regulator installed on it It has a valve controlled by the temperature of the direct supply water behind the heater, while the valve inlets are connected to the lines of the deaerated and reverse supply water. Compiled by L. Simoi Tehred I. Veres Corrector L. Obruchar Circulation 387 Subscription