RU2078047C1 - Deaerator - Google Patents

Abstract

FIELD: purification of water; power engineering. SUBSTANCE: deaerator has storage tank connected with columns each of which is provided with branch pipes located in tanks. Each branch pipe is provided with gates. Pump delivers contaminated water to tank via pipe line. Purified water is discharged from by means of pump. Storage tank is provided with at least one bin. Column forms bin. Heat exchanger is located in storage tank above bin. Deaerator is also provided with steam ejector, active medium supply branch pipe, flash steam discharge branch pipe, additional compartment and separation compartment with in their lower portions; compartments are located in tanks. Heat exchanger is located in steam space of compartment. EFFECT: enhanced efficiency. 4 cl, 2 dwg

Description

 The invention is intended to purify water from dissolved impurities and may find application in the energy sector.

 Known thermal and vacuum deaerators (Sterman L. S. Pokrovsky V. N. Chemical and thermal methods of water treatment at thermal power plants. M. Energia, 1981, p. 115 122).

 A disadvantage of the known vacuum deaerators is the need to use high pressure steam and the impossibility of lowering the pressure lower than 0.0075 MPa. A known vacuum deaerator (A.S. USSR N 861329), containing a horizontally mounted cylindrical body with nozzles for supplying a heating medium, in the upper part of which there is a collector of deaerated water, separated by a perforated sheet from the downstream mixing chamber and the vaporization compartment adjacent to the side walls of the housing and the camera, in the housing on the other side of the camera, a second vaporization compartment is made adjacent to the side wall of the housing.

 The disadvantage of this deaerator, as well as other similar deaerators, is the high energy costs of creating a vacuum, insufficient removal of dissolved gases and the inability to remove salts dissolved in it from water.

 The closest in essence to the claimed deaerator is a deaerator (AS USSR N 992430) containing cylindrical columns mounted on the storage tank, each of which has a water supply pipe, and equipped with a separation compartment connected to the columns and formed between the columns vertical partitions.

 This deaerator is selected as a prototype. The disadvantages of the prototype is that it does not provide the removal of salts dissolved in water and the deaeration process is associated with high energy costs associated with the need to use a heating medium with a relatively high temperature.

 The purpose of the invention is to eliminate the noted disadvantages.

 The technical result of the invention lies in the fact that the deaerator containing columns installed on the storage tank, each of which has a nozzle, a separation compartment formed by vertical partitions, the outlet pipe of the outlet, according to the invention, is equipped with tanks for untreated and purified water and a condensate collecting tank located below the installation level of the tanks for purified and untreated water, the columns are equipped with valves located below the water level in the tanks, the column for supplying untreated water By hoisting a hopper over which a heat exchanger is placed, the entrance to which is connected to the outlet of the vapor removal system, the storage tank is formed with at least one hopper located in the lower part of the storage tank, a heat exchanger is placed above the hopper, connected with the input of the heating medium, a heat exchanger is placed in the separation compartment, the inlet of which is connected to the raw water pump, and the outlet is located in the raw water tank, the water level in which is 10 m below the water level in the storage tank.

 The technical result also consists in the fact that the deaerator contains an additional compartment formed by vertical partitions, the lower part of the additional compartment is equipped with a valve located below the water level in the additional tank, one of the vertical partitions is equipped with a plate mounted for rotation and with a gap with respect to the side walls , the lower edge which is pivotally connected to the vertical partition, and the upper edge is connected with at least one element with positive buoyancy.

 The technical result also consists in the fact that on the outer surface of the heat exchangers work elements rigidly fixed at one end are made of metal with shape memory.

 The technical result also lies in the fact that the heat exchangers are made of metal with shape memory.

 In FIG. 1 schematically shows the proposed deaerator; in FIG. 2, section AA in FIG. one.

 The deaerator contains (Fig. 1) a storage tank 1 connected to columns 2 and 3. Each of columns 2 and 3 has a nozzle located respectively in tanks 4 and 5, the upper part of which is connected with the atmosphere. Each pipe is equipped with valves (positions 6 and 7 in Fig. 1). The untreated water is supplied to the tank 4, which is received by the pump 8, through the pipeline 9. The direction of the untreated water is shown by arrow 10. The purified water enters the tank 5 and is pumped out of this tank using the pump 11 in the direction of the arrow 12. The battery tank 1 is equipped with at least one hopper 13 located at the bottom of the tank 1. The hopper 13 contains a hermetically sealed lid (not shown). Column 2 is formed with the formation of the hopper 14, also containing a hermetically sealed lid (not shown). A heat exchanger 15 is placed in the volume of the tank 1 above the hopper 13. A heat exchanger 16 is placed in the inner cavity of the column 2 above the hopper 14. The input and output of the heating medium into the heat exchanger 15 are shown by arrows 17 and 18. The storage tank 1 is divided into the first volume 19 and the water volume 20 To remove the vapor in the upper part of the deaerator, a vapor removal system is installed, consisting of a steam element 21 m of nozzles for supplying an active medium 22 (the direction of steam movement is shown by arrow 23) and a vapor outlet pipe 24, the direction of discharge of vapor from the steam volume 19 is shown with arrows 25. After the ejector 21, the mixture of active medium (steam) and vapor through the pipe 26 enters the inlet of the heat exchanger 16. The output of partially condensed water, steam and non-condensable gases is shown by arrow 27.

 The deaerator also contains an additional compartment 28, the upper part of which is formed by an inclined partition 29, the side walls of the storage tank 1 and mounted for rotation and with a gap with respect to the side walls of the tank 1 by a plate 30, the lower part of which is connected, for example, by a hinge 31 with the wall of the additional compartment 28. The upper edge of the plate 30 is connected to the element 32 (Fig. 2), which has positive buoyancy and is made, for example, in the form of a hollow sealed cylinder. The lower part of the additional compartment 28 is equipped with a valve 33 located in the tank 34, containing a pipe outlet 35 of water from the tank.

 The deaerator also contains a separation compartment 36, the lower part of which is provided with a valve 37 and is located in a tank 38 containing a water outlet pipe from the tank 39. The tank 38 is located below the installation level of the tanks 4, 5 and 34. A heat exchanger 40 is placed in the steam volume of the separation compartment 36, the entrance to which is connected with the outlet of the pump 8 for supplying untreated water to the receiving tank 4.

 In the upper part of the tank-accumulator 1 there are pipes 41 and 42 equipped with valves.

 On the outer surface of the heat exchangers 15 and 16, work elements rigidly fixed at one end are made of metal with shape memory (not shown). The elements can be made, for example, in the form of springs, the turns of which are snug against the outer surface of the tubes of the heat exchangers 15 and 16. The working elements can also be made in the form of fins tightly mounted or welded to the outer surface of the tubes of the heat exchanger.

 The heat exchangers 15 and 16 themselves can be made of metals with shape memory, for example, in the form of spiral heat exchangers.

 Deaerator works as follows. Before putting it into operation, the valves 6, 7, 33 and 37 are closed. The pipe 42 is connected to the discharge water line and the valve on the pipe 42 opens. The pipe 41 is in communication with the atmosphere, and the valve on this pipe also opens. Water through the pipe 42 enters the internal volume of the deaerator, fills it, while the air is displaced through the pipe 41 into the atmosphere. As soon as the entire volume of the deaerator is filled with water and water flows through the pipe 41, the valve on the pipe 42 and the valve on the pipe 41 are closed. Then the tanks 4, 5, 34 and 38 are filled with water, after which the valves 6, 7 and 37 open. Since blocks 4, 5 and 38 are in communication with the atmosphere, when the valves 6, 7 and 37 are opened, part of the water from the internal volume of the deaerator enters the tank 4, 5 and 37, and inside the storage tank 1 the water level is set so that a vapor volume of 19 , the difference in water levels in the storage tank 1 and tanks 4, 5 and 38 is approximately but 10 m (corresponding to the atmospheric pressure expressed in meters water column). In the vapor volume 19, the pressure of saturated water vapor is set corresponding to the temperature of the water that has filled the deaerator.

Next, the heating medium is supplied to the heat exchanger 15. The heating medium may be water entering the drains, or vapor from the expander of continuous blowing of the steam boiler, or any medium at a temperature exceeding the saturation temperature of the steam in the steam volume 19. In practice, this can be any coolant at a temperature in excess of 30 40 ^o C.

 Then, steam (active medium) is supplied to the ejector 21, which begins to eject the vapors from the steam volume 19, creating additional rarefaction there. The vapor from the volume 19 enters the ejector through the pipe 24 in the direction of the arrow 25. The mixture of active steam and vapor through the pipe 26 begins to flow into the heat exchanger 16 and gives its heat to the water in the volume of the column 2.

 Next, the pump 8 is turned on, which pumps cold untreated water through the heat exchanger 40 into the tank 4 through the pipe 9. At the same time, the pump 11 is turned on, which pumps the purified water from the tank 5, which after heating can be fed into the steam boiler.

Water purification (deaeration and simultaneous partial removal of salts dissolved in water) occurs as follows. Since the amount of gases dissolved in water (primarily oxygen and carbon dioxide) depends on pressure, when the water moves in column 2, its pressure decreases and in the volume of the storage tank 1 at the interface between steam volume 19 and water volume 20 is equal to pressure saturation at the appropriate water temperature. If, for example, the water temperature is 28.6 ^o C, then the saturation pressure is 0.004 MPa. When the pressure decreases, the gases dissolved in the water are released from the water and enter the steam volume 19, from where they are sucked out with the ejector using an ejector 21. When the water moves in column 2, it washes the outer surface of the heat exchanger 16, which is placed along the height of column 2 in such a way so that water boils on its surface. If, for example, the heat exchanger 16 is located in the upper part of column 2, then the water will boil at temperatures of the order of 30-40 ^o C. The steam formed during boiling sparges through the water column in column 2 and in bank 1, while the release of gases dissolved in water is enhanced . At the same time, with surface boiling of water on the outer surface of the heat exchanger 16, salts dissolved in water in the form of scale begin to be deposited. Similarly, surface boiling of water occurs on the outer surface of the heat exchanger 15 with the release of gases dissolved in the water and deposition in the form of scale of salts on the outer surface of the heat exchanger.

 As a result of such work of the deaerator, deaerated and partially purified from salts water enters the tank 5 through column 3.

 At the same time, condensation of droplet moisture occurs in the separation compartment 36. Since tank 38 is installed at a mark lower than the horizontal mark for tanks 4, 5 and 34, when the valve 37 is opened when the deaerator is put into operation, the water level in the separation compartment 36 has become lower than the water level in the storage tank 1. Vapors of water wash the outer surface of the heat exchanger 40, through which the colder water flows, and partially condense, while drops of condensate drain off the surface of the heat exchanger 40 and accumulate The volume of the separation compartment 36, while the water level in this compartment will rise, but the difference in levels in compartment 36 and tank 38 remains constant and equal to about 10 m. As necessary, the condensate from the tank 38 is pumped to the consumer of pure condensate through the pipe 39 using a pump (not shown).

 The deaerator can also work as follows. When installing an additional compartment 28 in the reaerator (Figs. 1 and 2) with the gate valve 33 open, water is pumped out of the tank 34 using an additional pump (not shown). In this case, water enters compartment 28 from the volume 20 of the storage tank 1. Since the water entering the tank 4 may contain impurities of various oil products, oils, fats, etc., these impurities with a lower density float in a volume of 20 and concentrated in the upper layers of water at the interface between steam 19 and water volumes 20. The plate 30 provides for the entry into the compartment 28 of water from the upper layers. Since atmospheric pressure can change during operation of the deaerator and, as a result, the water level in the storage tank 1 can change, in order to ensure that the upper sufficient thin layer of contaminated water enters the compartment 28, the upper edge of the plate 30 is connected to the elements 32 that have positive buoyancy and provide constant the gap between the surface of the water in the tank 1 and the upper edge of the plate 30. When the level in the tank changes, the plate rotates around the axis of the hinge 31. The contaminated speed accumulated in the tank 34 With concentrated impurities, water is sent for treatment (cleaning systems are not considered in the application materials).

 The deaerator can also work as follows.

 When scale deposits on the outer surfaces of heat exchangers 15 and 16 reach a certain value (this value is established experimentally), increase the temperature of the heat carriers entering the heat exchangers 15 and 16. For example, this can be done by increasing the flow rate of steam supplied to the input of the ejector 21 through the pipe 22 As soon as a result of supplying a heat carrier with a high temperature to the heat exchanger, the temperature of the working elements made of a material with a shape memory and placed on the outer surface is warm exchangers 15 and 16 becomes greater than the temperature of transition metal from one geometric form to another, the elements working "remembers" its original shape, e.g., a spring length increases and its unattached end slides along the outer surface of the tube. This causes the destruction of the scale layer on the surface of the heat exchangers. Solid particles of scale under the influence of gravity fall down and fall into the volumes of the bins 13 and 14. When a certain amount of scale particles accumulate in the bins 13 and 14, the deaerator can be temporarily stopped and the accumulated scale can be removed through the covers placed on the bins.

 Then, the temperature of the heat carriers entering the heat exchangers 15 and 16 is reduced to such a value that the working elements made of metal with shape memory take their initial geometric shape.

 The deaerator can also work as follows. If heat exchangers 15 and 16 are made of metal with shape memory, for example, in the form of spiral heat exchangers, then with surface boiling of water, scale is deposited on the outer surface of these heat exchangers. When the thickness of the scale layer reaches a certain value (established experimentally), increase the temperature of the coolants entering these heat exchangers. As soon as the temperature of the metal from which the heat exchangers are made becomes higher than the temperature of the transition from one geometric shape to another, the heat exchangers “recall” their original shape, while, for example, the distance between the turns of the spiral heat exchanger can change. In this case, the scale layer is destroyed on the outer surface of the heat exchangers, and the solid scale particles fall down and settle in the bins 13 and 14. After the scale layer is destroyed on the surface of the heat exchangers, the temperature of the heat carriers entering the heat exchangers is reduced to such a value that they take their initial geometric shape.

Metals with shape memory are used in technology (A.S. NN 893334, 1100423, 1148678, etc.). The transition temperature of an element made of metal with shape memory depends primarily on the composition of the components included in the alloy. For example, in titanium nickelide T46H54, the onset of shape recovery occurs at a temperature of 75 ^o C, and titanium nickelide T45H55 at 35 ^o C.

 The deaerator provides deep degassing of water at low energy costs, allows you to purify water from organic impurities (primarily from oils) and partially remove salts dissolved in water, due to which a technical and economic effect is achieved.

Claims (4)

 1. A deaerator containing columns installed on the storage tank, each of which has a nozzle, a separation compartment formed by vertical partitions, a vapor outlet pipe, characterized in that the deaerator is equipped with untreated and purified water tanks and a condensate collecting tank located below the level installation of tanks for untreated and purified water, the columns are equipped with valves located below the water level in the tanks, the column for supplying untreated water is formed with the formation of a hopper, above which the heat the exchanger, the entrance to which is connected to the outlet of the vapor removal system, the storage tank is formed with at least one hopper located at the bottom of the storage tank, a heat exchanger is placed above the hopper, connected by a pipe to the heating medium inlet, a heat exchanger is placed in the separation compartment , the entrance to which is connected to the outlet of the pump for supplying untreated water, and the outlet is located in the tank for untreated water, the water level in which is lower than the water level in the storage tank by a linear value expressed in meters, corresponds to guide atmospheric pressure.  2. The deaerator according to claim 1, characterized in that it contains an additional compartment formed by vertical partitions, the lower part of the additional compartment is equipped with a valve located below the water level in the additional tank, one of the vertical partitions is equipped with a rotationally installed and with a gap in relation to to the side walls with a plate, the lower edge of which is pivotally connected to the vertical partition, and the upper edge is connected with at least one element with positive buoyancy.  3. Deaerator according to paragraphs. 1 and 2, characterized in that on the outer surface of the heat exchangers are placed rigidly fixed at one end of the working elements made of metal with shape memory.  4. Deaerator in paragraphs. 1 and 2, characterized in that the heat exchangers are made of metal with shape memory.

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