RU38894U1 - DEVICE FOR REMOVING OXYGEN FROM MAIN WATER OF HEAT SUPPLY SYSTEMS - Google Patents

Abstract

The utility model relates to hot water systems for heating and technical needs and can be used mainly in systems that produce hot water using hot water boilers. The problem to be solved is to prevent the loss of purified water while improving the reliability of the device. The essence of the utility model is that in the device for removing oxygen from the make-up water of heating systems, containing a deaeration column connected through a drain pipe to the storage tank, a coil installed in the boiler, the main pipe of the make-up water is connected to its input, and to the output - the heated water pipeline connected to the inlet of the deaeration column, a water level meter and a set point for the maximum allowable water level are added, the outputs of which are connected inenes with corresponding inputs of the first comparison unit connected to the input of the first alarm unit, a pressure sensor and a setpoint of the minimum allowable pressure value, the outputs of which are connected to the corresponding inputs of the second comparison unit connected to the input of the second alarm unit and the input of the control unit, to the outputs of which the control inputs of the first and second electromagnetic valves are connected, as well as a three-way valve with electric drive installed in the heated water pipeline, ravlyaetsya input of which is connected to the output of the first alarm unit, and the second outlet is connected to a crosspiece which is connected to the main feed water conduit, the Dutch

Description

The utility model relates to hot water systems for heating and technical needs and can be used mainly in systems that produce hot water using hot water boilers.

When generating and entering hot water into the heating system, water losses occur due to leaks, accidents. To compensate for the loss of hot water in closed heat supply systems, devices are used to generate make-up water purified from oxygen and carbon dioxide that enters the heating network.

In accordance with current standards [1, 2] on the quality of make-up water of heating networks, it must contain a strictly limited amount of oxygen - not more than 50 μg / l. In raw (untreated) water entering the treatment system, oxygen is one hundred times higher than normal. Even a slight excess of the norm leads to a significant contamination of the network water with iron oxides, as well as to intensive corrosion of the metal of hot water boilers and pipelines of the heating network.

As a prototype of the proposed utility model, a device has been adopted for removing oxygen from makeup water of heating systems [3], which provides high-quality purification from makeup water oxygen.

The prototype device comprises a hot water boiler, a deaeration column, an accumulator tank and an additional coil installed at a distance of 0.1-0.2 m from the rear wall of the boiler. The coil inlet is connected to the pumping station via a main pipeline. In the coil, water is heated, which is fed through the pipeline of heated water to the deaeration column, where the water is purified from oxygen.

The disadvantage of the device according to the prototype is the fact that in the absence or reduction of losses of network water, an overflow of the battery tank occurs, the purified make-up water is discharged into the sewer. These unjustified losses increase the operating costs of the heating system.

It is impossible to avoid the loss of make-up water by reducing or cutting off the water supply to the coil in the known device, because in this case, the coil is heated by the heat of the gas burner of the boiler, and when the water supply is resumed, it breaks.

The problem to be solved is to prevent the loss of purified water while improving the reliability of the device.

To solve this problem, when the battery tank is full, the device ensures the return of untreated water from the coil output through a jumper to its input. In addition, the device monitors the pressure in the make-up water main pipeline, and when accidents occur at the pumping station or in the water supply network, the main pipeline is automatically connected to the reserve water supply source.

The essence of the utility model lies in the fact that the device for removing oxygen from the make-up water of heating systems contains a deaeration column connected through a drain pipe to the storage tank and a coil installed in the hot water boiler, to the input of which a main pipe of make-up water is connected, and to the outlet - a heated water pipeline connected to the inlet of the deaeration column; a water level meter in the battery tank and a setpoint for the maximum permissible level in odes, the outputs of which are connected to the corresponding inputs of the first comparison unit connected to the input of the first alarm unit, the pressure sensor and the setpoint of the minimum allowable pressure value, the outputs of which are connected to the corresponding inputs of the second comparison unit, connected to the input of the second alarm unit and the input of the control unit , the outputs of which are connected to the control inputs of the first and second electromagnetic valves, as well as a three-input valve installed in the heated water pipeline an electric control input of which is connected to the output of the first alarm unit, and the second outlet is connected to a crosspiece which is connected to the main feed water conduit, wherein the pressure sensor and the first solenoid

the valve is sequentially installed in the section of the make-up water main pipeline between the inlet from the pump station and the jumper, and the second electromagnetic valve is installed in the connecting pipe from the reserve water supply source, which is connected to the make-up water main pipe between the jumper and the coil inlet.

The essence of the utility model is illustrated by a drawing of a device for removing oxygen from make-up water.

The device comprises a water boiler 1, made in the form of a thick-walled reservoir of insulating material. A gas burner, heating elements of a hot water supply system (not shown for simplicity) and a coil 2 for heating make-up water installed at a distance of 0.1-0.2 m from the rear wall of the boiler are installed inside the boiler.

The main pipe 3 of make-up water is connected to the input of the coil 2, connected to the central water supply system from the pump station and equipped with two tees for connecting the connecting pipe 4 from the reserve water supply source and jumper 5.

A heated water pipe 6 connected to the inlet of the deaeration column 7 and equipped with a three-way valve 8 with an electric actuator is connected to the output of the coil 2, the second output pipe of which is connected to the jumper 5.

The deaeration column 7 can be performed according to one of the known schemes, for example, shown in the prototype [3], according to which it contains a rigidly fixed swirler, which provides a decrease in the pressure of the water flow and the formation of bubbles filled with oxygen, which are separated from the water by the action of the centrifugal force field and form a stable vapor-gas vortex along the column axis. Evacuation of gas into the atmosphere is carried out through a gas pipe.

The drain pipe of the deaeration column 7 is connected to the inlet fitting of the battery tank 9, through the outlet fitting 10 of which purified and settled water enters the return pipe of the hot water supply system.

The battery tank 9 is equipped with a water level meter 11, the inlet tube of which is installed in the bottom of the tank. As a meter 11 in the device

a differential pressure gauge can be used that measures the pressure of the water column, the value of which is proportional to the level of the tank.

The output of the meter 11 is connected to the first input of the first comparison unit 12, to the second input of which the output of the setter 13 of the maximum allowable water level is connected. In the simplest case, block 12 can be made in the form of a level switch, the output of which, when the signal exceeds the measured value of the signal level of the set value, a control signal is generated. The output of the comparison unit 12 is connected to the input of the first alarm unit 14, which is, for example, an electric bell, and the control input of a three-way valve 8 with an electric actuator.

In the main pipeline 3, in its section between the inlet from the pump station and the tee for connecting the jumper 5, a pressure sensor 15 and a first solenoid valve 16 are installed in series, and a second solenoid valve 17 is installed in the connecting pipe 4 from the backup water supply source.

The output of the pressure sensor 15 is connected to the first input of the second comparison unit 18, the second input of which is connected to the output of the setter 19 of the minimum allowable pressure value. The output of the second comparison unit 18 is connected to the input of the second alarm unit 20 and the input of the control unit 21, to the corresponding outputs of which are connected the control inputs of the first and second electromagnetic valves 16 and 17.

The device operates as follows.

In the initial state of the device, the first solenoid valve 16 is open, the second solenoid valve 17 is closed, and in the three-way valve 8, the first output is open and the second is closed.

Chemically purified water from the water supply network enters the make-up water pipe 3 to the coil 2 located in the boiler 1 and, passing through it, is heated to a temperature of 90-95 °, which is necessary for the effective operation of the deaeration column 7, into which the heated water from the outlet the coil is fed through line 6 through the open first output of the three-way valve 8.

In the deaeration column 7, the make-up water is purified from gas impurities, discharged into the battery tank, where it settles, finally freed from oxygen and fed through the outlet nozzle 10 of the battery tank to the return pipe of the hot water supply network to compensate for losses due to leaks and other network failures.

The filling level of the battery tank 9 is controlled by a water level meter 11, the readings of which are compared in the comparison unit 12 with the maximum permissible value of the water level in the tank from the setpoint 13.

If this value is exceeded, the control signal from the output of block 12 includes an alarm block 14, which notifies the operator on duty and simultaneously enters the control input of the three-way valve 8, in which the first output is closed and the second is opened. At the same time, water from the outlet of the coil 2 returns through the jumper 5 to the main pipeline 3 and, mixed with cold water, enters the coil. This prevents the loss of purified water and reduces operating costs in the hot water supply system.

The pressure sensor 15 measures the pressure of the water in the main pipe 3. The readings of the sensor 15 are compared in block 18 of the comparison with the minimum allowable pressure value from the setter 19.

With a sharp decrease in pressure, the cause of which may be a rupture of the piping of the water supply system, failure of pumps, and other malfunctions, a control signal is generated at the output of block 18, including a second alarm block 20 and fed to the input of the control block 21.

The control unit 21 can be made, for example, in the form of an electromagnetic relay with a group of normally closed and normally open contacts. In the initial state of the device, through normally closed contacts forming the first output of the control unit 21, a supply voltage is supplied to the winding of the electromagnetic valve 16, ensuring its open state. At the same time, at the second output of block 21, formed by normally open contacts, there is no voltage, the coil of the electromagnetic valve 17 is de-energized, and it is closed.

Upon receipt of the input of the control signal unit 21, the normally closed relay contacts open and the normally open contacts close. The winding of the valve 16 is de-energized, and it closes, and the winding of the valve 17 is energized, opening the valve, and water from the backup water supply flows through the connecting pipe 4 to the main pipe 3 and then to the inlet of the coil 2, preventing the possibility of emptying the battery tank.

Alarm blocks 14, 20 allow in case of emergency to attract the attention of the operator on duty and timely eliminate the malfunction in the hot water system

Thus, by introducing control over the water level in the storage tank and the pressure in the make-up water main pipeline, the device allows providing the necessary supply of purified water and preventing its loss, as well as the possibility of water circulation from the coil inlet to avoid its emptying and destruction in emergency situations .

The industrial applicability of the utility model is determined by the possibility of manufacturing the device according to the above description from known materials and components and the possibility of use in hot water systems to remove oxygen from make-up water.

List of references

1. Rules for the design and safety of operation of steam and hot water boilers. - M.: NGO OBT. - 1993 - Table 9. Norms of quality of network and make-up water of boilers.

2. RD 24.031.120-91. The quality standards of the network and make-up water of boilers, the organization of the introduction of chemical regime and chemical control.

3. RF certificate No. 14999 for utility model, IPC F 22 D 1/00, publication of September 10, 2000, prototype.

Claims (1)

A device for removing oxygen from the make-up water of heating systems, containing a deaeration column connected through a drain pipe to the battery tank, a coil installed in the boiler, the main pipe of the make-up water connected to its inlet, and the heated water pipeline connected to the inlet of the deaeration column to the outlet , characterized in that it includes a water level meter and a dial for the maximum permissible value of the water level, the outputs of which are connected to the corresponding inputs of the first comparison unit connected to the input of the first alarm unit, a pressure sensor and a setpoint of the minimum allowable pressure value, the outputs of which are connected to the corresponding inputs of the second comparison unit connected to the input of the second alarm unit and the input of the control unit, to the outputs of which the control inputs of the first and the second solenoid valve, as well as a three-way valve with electric drive installed in the heated water pipeline, the control input of which is connected the output of the first alarm unit, and the second output pipe is connected to a jumper that is connected to the make-up water main pipe, while the pressure sensor and the first solenoid valve are installed in series on the make-up water main pipe section between the inlet from the pump station and the jumper, and the second solenoid valve installed in the connecting pipe from the backup water supply source, which is connected to the main makeup water pipe between do jumper and coil input.