RU2242672C1 - Deaeration unit - Google Patents

Abstract

FIELD: power engineering; thermal deaeration of boiler water and heating system makeup water, deaeration of water used in chemical and other technologies.

SUBSTANCE: proposed deaerator unit has deaerated water storage tank, centrifugal-vortex deaerator, droplet deaerator, vented steam contact cooler, deaerated water inlet and outlet pipes, pipes for vented steam outlet from storage tank and centrifugal-vortex deaerator communicating with vented steam contact cooler through pipeline, cooling water pipeline communicating with vented steam contact cooler and through the latter, with centrifugal-vortex deaerator. Inserted in pipeline split joint connecting vented steam contact cooler to centrifugal-vortex deaerator is water-jet or steam-jet injector. Suction pipe of injector is connected to cooling water outlet pipe of vented steam contact cooler. Delivery pipe of injector is connected to centrifugal-vortex deaerator, and injector nozzle communicates with deaerated water pipeline or with steam line. This deaerator unit is characterized in that vented steam contact cooler and centrifugal-vortex deaerator can be installed at slightly different elevations.

EFFECT: facilitated installation, reduced number of connecting pipes.

5 cl, 4 dwg

Description

The invention relates to the field of energy and can be used for thermal deaeration of water from steam boilers and make-up water of heating networks, as well as for deaeration of water used in chemical technology and other technologies.

The most widely used in the energy sector of Russia are atmospheric and vacuum column type deaerators (see L.1, p. 20, 49. II Oliker “Thermal deaeration of water in heating and industrial boiler rooms and heating networks.” Publishing House of Construction Literature. Leningrad , 1972).

Deaeration plants with such deaeration columns have many drawbacks leading to their unsatisfactory operation:

1. They require preliminary heating of deaerated water to a value of only 10 degrees Celsius below the saturation temperature in the deaerator, which is unattainable in most boiler rooms.

2. Have a shallow depth of performance regulation.

3. Have a large metal consumption.

4. The surface evaporator coolers (ORP) quickly fail due to carbon dioxide and oxygen corrosion of the ORP heating surfaces, and deaeration plants operate without ORP, losing a large amount of heat with the vapor.

Most of these drawbacks have been eliminated in two-stage deaeration plants using centrifugal-vortex deaerators as the first stage and drip deaerators (i.e., deaerators, which are a dispersing device operating on the principle of spraying deaerated water in the vapor space of a deaerated water storage tank ( see L. 2. RF Patent No. 1454781 “Deaeration plant”, where a deaerator protected by RF patent No. 2131555 and L.3 - RF Patent No. 2151341 “Deaerator”, in centrifugal vortex deaerator and drip deaerator are combined in one block.Articles in magazines L. 4 “Industrial Energy” No. 11 for 1999, pp. 11-14, L. 5 “News of heat supply” No. 1 for 2001, p. 28).

A deaeration plant protected by RF patent No. 1454781 (it is used only with a contact cooler for vapor, described in Energetik magazine No. 4 for 2000, page 28, only in it as heating steam is selected as a prototype) deaerating medium) is used vapor from the deaerator of high pressure).

The prototype has a centrifugal-vortex deaerator (CVP) as the first stage with the supply pipes of the deaerated water and deaerating medium (steam or superheated water), if necessary (the deaerator can work without supplying a deaerating medium - on the “initial effect” if the deaerated water is overheated higher than the saturation temperature in the deaeration plant), the tank-accumulator of deaerated water, in the upper (steam) part of which the drip deaerator KD (dispersing device) is located, the pipe wires for venting the vapor (vapor-gas mixture) from the tank and from the CVP to the contact cooler for the vapor — HVAC with inlet and outlet cooling water pipelines, the last of which is connected to a centrifugal-vortex deaerator.

In this installation, a two-stage deaeration takes place. In the CVP, water is heated by steam or superheated water from boilers and is partially deaerated due to the formation of vapor and the entrainment of aggressive gases with it (or, for example, when operating in a vacuum mode, the water is heated before entering the deaerator to a temperature higher than the boiling point under steady-state vacuum in a deaeration plant). In the second stage of deaeration, the water is dispersed in the vapor space of the tank, boils with the formation of vapor and is freed from residual aggressive gases. These deaerators work with very high technical characteristics.

The disadvantage of the installation with a surface vapor cooler is its high cost and the fact that it quickly fails due to corrosive gas corrosion and the deaerator, which is forced to work without a vapor cooler, loses a lot of heat to the atmosphere. This disadvantage is eliminated by the use of a contact vapor cooler (HVAC), in which the condensation of the vapor contained in the vapor is carried out by direct contact with cooling water. At the same time, the heat transfer coefficient is 2000 times higher than when steam contacts water through the heating surface (see article L.6, p. 28).

A disadvantage of the installation with a contact cooler for vapor is that it is difficult to supply cooling water heated in a contact cooler to the CVP, because the pressure in the CVP is always higher than in the HVAC. It is necessary to raise it to a height of 6-8 meters above the HPP, which is not always possible, or to drain the cooling water into any intermediate tank and have an additional pump for pumping water from it to the HPP.

The aim of the present invention is to eliminate the drawbacks of the use of HVAC: providing the ability to install HVAC with a small height difference from the CVP (simplifying installation work, reducing the number of connecting pipes), providing the ability to supply cooling water after the HVAC directly to the CVP without an intermediate tank and without installing an additional pump on it tank. As HVAC, you can use the invention, protected by RF patent No. 2131555 “Deaerator (heat and mass transfer)”.

This goal is achieved by the fact that in a known deaeration installation having a storage tank of deaerated water, a centrifugal-vortex deaerator with supply pipes of deaerated water and (if necessary) with nozzles of a deaerated medium (as a first stage), a droplet deaerator in the form of a dispersing device, located in the upper part of the storage tank and acting as a deaerator of the second stage, outlet pipes for water and vapor, contact-type vapor cooler connected to the storage tank and centrifugally - with a vortex deaerator using a vapor pipe and with a centrifugal-vortex deaerator with a cooling water drain pipe, a water-jet or steam-jet injector is installed on this cooling water drain pipe (a centrifugal-vortex type steam jet kinetic pump can be installed instead of the injector - see RF patent №2210043 or a water-jet centrifugal-vortex injector) so that the suction nozzle of the injector is connected to the nozzle for draining the cooling water from the HVAC, the injection nozzle of the injector is connected to CVP, and a nozzle pipe of the ejector is connected to the water supply (e.g., to the pipeline deaeriruemoy water) or to the steam pipe. The drip deaerator is made in the form of a perforated pipe or in the form of a pipe, or with slotted openings located in the vapor space of the storage tank. Centrifugal-vortex deaerator and drip deaerator can be made in the form of a single unit (see RF patent No. 2151341). In case of insufficient preliminary heating of the deaerated water, a pipeline of the deaerating medium (steam or superheated water) can be connected to the centrifugal-vortex deaerator.

Installing a water-jet or steam-jet injector (or steam-jet kinetic pump) in the cut-off of a pipe for draining cooling water from the HVAC to the high-pressure cylinder with its nozzle part connected to a water pipe having sufficient pressure, for example, to one of the inlet pipes of deaerated water, at the site before the flow regulator is installed water to the deaerator or to the steam line, allows you to install the vapor cooler (HVAC) in a convenient place, for example, at the same height as the centrifugal vortex deaerator (do not install the HVAC above the CVP for 6-8 meters, about It appears from the cooling water drain tank), which significantly reduces the metal content of installation and installation costs and eliminates the energy consumption for pumping the cooling water from the intermediate tank to the CVP.

The implementation of a centrifugal-vortex deaerator and drip deaerator in the form of a single unit allows you to better standardize the deaerator and produce it in series. It also simplifies installation.

The connection of a nozzle of a deaerating medium (steam, superheated water) to the CVP makes it possible to operate the deaerator with insufficient preliminary heating of the water in front of the deaerator in both atmospheric and vacuum modes and to heat the deaerated water in the CVP.

The holes in the drip deaerator in the form of slots can reduce the resistance of the CD during a rotating flow of water.

The implementation of the steam injector in the form of a kinetic centrifugal vortex pump allows you to increase the range of adjustable water flow.

The invention is illustrated by drawings.

Figure 1 shows a diagram of a deaeration plant, in which the centrifugal-vortex deaerator, protected by RF patent No. 2131555, serves as the first stage, drip deaerators shown in Fig. 3 placed in the vapor space of the storage tank serve as the second stage.

Figure 2 - diagram of a deaeration plant with a centrifugal-vortex deaerator and with a droplet deaerator, made in the form of a single unit (node) (deaerator is protected by RF patent No. 2151341).

Figure 3 is a longitudinal section of a drip deaerator, schematically shown in figure 1.

In Fig.4 - the same as in Fig.2, only with longitudinal sections of CVP and HVAC.

The deaeration unit has a deaerated water storage tank 1, a centrifugal vortex deaerator 2 (CVP), a drip deaerator 3 (dispersing device) (one or several), a contact cooler for vapor 4 - HVAC, a water-jet or steam-jet ejector (injector) 5. Instead of a steam-jet an ejector, you can install a steam jet kinetic pump (application No. 2001107731, which issued a decision on the grant of the RF Patent dated 10/30/02). Both of these ejectors (injectors) (water-jet and steam-jet) can be installed in parallel and used at different times, depending on the pressure of water and steam and on the load of the installation. The installation has the following pipelines. Pipeline 6 of deaerated chemically cleaned water (HOV) with a regulator 7 of HOV flow rate, branch pipe 8 from pipeline 6 to the nozzle part of the ejector (injector) 5. There is a steam pipeline 9 with a regulator 10 of steam flow (this steam pipeline may not exist if the deaerated water is preheated to a temperature above the saturation temperature corresponding to the pressure in the deaeration plant). A steam line 9a connected to the nozzle portion of the ejector, this steam line may be a branch from the steam line 9 or be independent. Pipeline 11 connects the centrifugal-vortex deaerator 2 with the drip deaerator 3 (in the installation in Figs. 2, 4 this pipeline is not there, there the water from the high-pressure pump passes to the compressor cylinder through the scapular swirl device). The pipeline 12 is a pipeline of cooling chemically purified water supplied to the HVAC (4). The pipeline 13 connects the vapor space of the tank 1 with the HVAC, and the pipeline 14 connects the CVP with the HVAC. Pipeline 15 connects the outlet pipe of the HVAC cooling water to the suction pipe of the ejector (injector) 5. Pipeline 16 connects the HVAC to the atmosphere, and pipe 17 connects to the vacuum system (water-jet or steam ejector or to the vacuum pump) if the deaeration plant is vacuum. Pipeline 18 - bypass in addition to the ejector. Installing it is optional. It serves to drain the cooling water in addition to the ejector at low loads, if the HVAC is installed above the HPC by 2 or more meters. The pipeline 19 is a pipeline for the extraction of deaerated water from the tank 1 (pipeline to the pump).

The drip deaerator shown in FIG. 3 has a barrel 1 (a perforated tube or a pipe with slotted holes, which are shown on the drip deaerator of FIG. 2), a swirl head 2 with a tangentially attached nozzle 3. In the drip deaerator shown in FIG. 4, a swirl device indicated the number 20 in FIG. 4, is made in the form of a scapular apparatus in its upper part (see L.3).

The operation of the deaeration plant is as follows. Consider the option of working in atmospheric mode.

Most of the deaerated water (HOV) through the pipeline 6 through the flow regulator 7, which works by the water level in the tank 1, enters the centrifugal-vortex deaerator 2, where it contacts the steam supplied through the steam pipe 9 through the steam flow regulator 10 and heats up without water hammer to a temperature of 105-106 degrees Celsius. Formed vapor through the pipe 14 comes from the CVP to the HVAC. The amount of vapor can be controlled by a valve on the pipe 14. Partially deaerated water with a temperature of 104-105 degrees enters the drip deaerator 3 - KD (in figure 1 through the pipe 11, in figure 4 through the swirl device 20). Through the openings or slots of the CD, water enters the vapor space of the tank 1 dispersed into small drops. The swirling of water in the CD makes it possible for the steam generated in the CD to not separate separately from water at low loads (steam through the upper holes, and water through the lower ones). Water rotates around the periphery of the barrel of the CD, and steam in the center. Steam leaves with water, which significantly reduces specific evaporation with good quality of deaeration of water. Each drop of water boils to form a vapor. Water is cooled to 101-102 degrees and accumulates in the storage tank 1, from where it is pumped out via pipe 19 or discharged into a large battery tank located at zero.

The vapor from tank 1, which makes up most of the total vapor of the installation, is sent through pipe 13 to the HVAC. Dry water through pipe 12 enters the HVAC and contacts the vapor, condensing water vapor. The non-condensable part of the vapor is separated in the lower part of the HVAC and discharged into the atmosphere through the pipe 16. A part of the deaerated water from the pipe 6 through the pipe 8 is sent to the water-jet ejector (injector) 5, or the steam from the steam pipe 9 or from any other steam pipe through the pipe 9a is sent to the nozzle part of the steam jet ejector (injector) 5. The ejector 5 creates a vacuum and draws cooling water from the HVAC through the pipe 15 and directs it to deaeration to the CVP. Steam jet ejector (injector) helps to ensure that part of the water entering the deaeration is heated by steam. Therefore, less than steam enters the HPP through the pipe 9, which goes to heat the water. Part of the kinetic energy of the steam is used to transport water instead of a pump.

Variant of the unit operation in vacuum mode. If the evaporator pipe 16 from the HVAC is connected via pipe 17 to a vacuum system (steam or water jet ejector or to a vacuum pump), then the entire installation becomes vacuum. If the deaerated water is heated, for example, to 70 degrees, then a vacuum of 0.7 kgf / cm ^{2 will be} established in the tank 1 (Rabs = 0.3 kgf / cm ² ). Steam is not supplied to the installation via steam line 9. The installation works on the “initial effect”. The water boils and cools by 2-3 degrees, forming a vapor in the HPP and in the tank 1. If the deaerated water has a temperature below 60 degrees Celsius, then it is possible to supply steam to the HPP and heat the water to 70-80 degrees and work in a vacuum mode. The rest of the deaeration process is similar to the previous one.

The installation of a water-jet or (and) steam-jet ejector (injector) on a cooling water pipeline connecting the HVAC to the CVP (to cut the latter) and connecting the working water pipeline (chemically purified water pipeline) or the steam pipeline to the nozzle nozzle of the ejector (injector) allows: to simplify the installation design for due to the compact arrangement of CVP and HVAC near each other, which reduces the metal consumption, prevents the possibility of installing HVAC on the roof of the boiler building, eliminates the need to install an additional a cooling water collection tank after the HVAC and a pump to it. Prevents the need to install HVAC 10 meters above the cooling water drain tank when operating in a vacuum mode.

Claims (5)

1. A deaeration plant containing a storage tank of deaerated water, a centrifugal vortex deaerator, which is the first stage of the installation, a drip deaerator, which is the second stage of the installation, a contact cooler for vapor, pipes for supplying deaerated water and drainage of deaerated water, and pipes for removing the vapor from the battery tank and from a centrifugal-vortex deaerator, connected to the contact cooler of the vapor through a pipe, a cooling water pipe connected to the contact cooler of the vapor and through with a centrifugal-vortex deaerator, characterized in that on the cooling water pipe connecting the vapor cooler to the centrifugal-vortex deaerator, a water-jet or steam-jet injector is installed in the cut of this pipe so that the suction nozzle of the injector is connected to the outlet contact of the cooling water evaporator, the discharge pipe of the injector is connected to a centrifugal-vortex deaerator, and the nozzle pipe of the injector is connected to the pipeline deaerating second or water to the steam pipe. 2. The deaeration plant according to claim 1, characterized in that the centrifugal vortex and drip deaerators are made in the form of a single unit. 3. The deaeration plant according to claim 1, characterized in that a nozzle for supplying a deaerating medium is connected to the centrifugal-vortex deaerator. 4. The deaeration installation according to claim 1, characterized in that the drip deaerator is made in the form of a perforated pipe placed in the vapor space of the storage tank, that is, a pipe having openings of circular or rectangular cross section, and in the upper part of this pipe there is a device for imparting water rotational motion. 5. The deaeration plant according to claim 1, characterized in that a centrifugal vortex type kinetic pump is installed as an injector.

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