RU108553U1 - STEAM GENERATION PLANT - Google Patents

Abstract

 Installation for generating steam, comprising a steam boiler, equipped with a burner for burning fuel supplied to the boiler and having the ability to communicate with the fuel supply system, a heat exchanger for heating the water supplied to receive steam, a pipe for removing flue gases from the boiler, characterized in that the installation equipped with a water treatment module, the output of the heat exchanger is connected to the input of the water treatment module, the output of which is connected to the water inlet of the boiler, and the installation is equipped with an anti-scale and anti-corrosion device water treatment installed on the communication line of the water treatment module and the boiler water inlet, the steam outlet of which can be connected to the injection well and / or to the heat exchanger inlet, while the installation is additionally equipped with an air heater installed on the flue gas exhaust pipe, the outlet of which is connected to the burner device.

Description

The utility model relates to equipment for the production of water vapor, designed for steam and thermal exposure of oil reservoirs in order to increase oil production.

Known downhole steam and gas generator, lowered into the well in the zone of the oil reservoir and containing an evaporation chamber, a prechamber equipped with an ignition unit, a combustion chamber with a cooling jacket formed between the inner and outer shells of the chamber. The inner and outer shells of the combustion chamber are arranged to move relative to each other and form a cooling chamber. On the outer surface of the inner shell there is a multi-auger screw for introducing water into the evaporation chamber, and along its length narrowing devices with discharge sectors are installed on the inner surface of the wall. An outlet nozzle is installed in the lower part of the steam and gas generator.

To ensure the operation of the steam and gas generator, ground-based equipment is used, which includes compressor and process units, water and fuel consumables, well fittings, pipelines connecting all ground units, and a compressor unit. The technological unit includes systems for supplying fuel and water to a steam-gas generator, control and automatic control devices for the production of a gas-vapor mixture, shut-off and control valves and pipelines for water, fuel, air, voltage supply cables to the ignition device of the pre-chamber and thermometry of the gas-vapor generator, heat-resistant packer.

To ensure the operation of the steam and gas generator, surface equipment is being mounted at the well being processed. The steam and gas generator is lowered into the well on tubing and installed in the formation perforation zone using a packer. Air is supplied to the combustion chamber, and fuel and water are supplied through pipelines. Ignition of the working flow rates of fuel and air supplied to the combustion chamber through the nozzle head occurs using a pre-chamber, where the starting flow rates of fuel and air are preliminarily ignited.

Water is piped from the surface of the earth (from the annular space) into the cooling jacket between the inner and outer shells of the combustion chamber, and then through the multi-auger into the evaporation chamber. In this case, water is heated and its partial evaporation. When water enters the narrowing device with a discharge sector, water is introduced into the high-temperature flow of combustion products, which contributes to a more complete evaporation of water and an increase in the vapor content in the vapor-gas mixture. The vapor-gas mixture obtained in this way enters through the nozzle into the reservoir, warming it and contributing to a more complete extraction of oil from the reservoir. The presence of the output nozzle ensures reliable start-up and stable operation of the steam and gas generator in conditions of increased backpressure.

(see RF patent No. 2316648, CL EV 43/24, 2008).

As a result of the analysis of the well-known steam and gas generator, it should be noted that the equipment for producing the gas-vapor mixture directly in the perforation zone of the well formation requires the use of long water and fuel supply lines, moreover, the process of steam formation is difficult to control, for repair and maintenance of the equipment it is necessary to remove it from the well .

A device for producing steam is known, including a steam boiler with a nozzle unit and two convective coils. The boiler is connected to a water tank, from which water is pumped through the economizer's pipe space through a pipeline through an input collector to heat one pipe into the first convective coil and through the second pipe into the second convective coil.

When it enters through a steam boiler into which heated products of fuel combustion are supplied from the nozzle block, the water is heated, evaporates, and through the collecting and dispensing collectors, enters the separator through the steam-water pipeline, where water is separated from the steam, which is supplied to the consumer through the steam collector.

Flue gases from the bottom of the boiler through the chimney are directed into the annulus of the economizer, in which they give their heat to the water supplied to the boiler. Further, the gases go to the discharge into the chimney.

(see RF patent No. 2163324, class F22B 33/18, 2001) is the closest analogue.

As a result of the analysis of the known device, it should be noted that through the use of a separator, water is separated from the steam, which improves its quality, and the use of the heat of the exhaust flue gases to heat the water reduces heat loss and increases the productivity of the steam generator. However, the absence in the known device of the possibility of proper preparation of water and fuel before supplying them respectively to the steam boiler and for burning, reduces steam productivity, requires quite frequent maintenance to remove deposits accumulating in the boiler. The known device does not provide for the possibility of preparing the fuel supplied for combustion, which reduces its efficiency.

The technical result of this utility model is the development of a plant for generating steam, which ensures the preparation of high-quality fuel before burning it in the boiler, as well as characterized by an increased service life of the boiler.

The specified technical result is ensured by the fact that in the installation for generating steam containing a steam boiler, equipped with a burner for burning the fuel supplied to the boiler and having the ability to communicate with the fuel supply system, a heat exchanger, for heating the water supplied to receive steam, a flue gas exhaust pipe from the boiler, it is new that the installation is equipped with a water treatment module, the output of the heat exchanger is connected to the input of the water treatment module, the output of which is connected to the water inlet of the boiler, and the ka is equipped with an anti-scale and anti-corrosion water treatment device installed on the communication line of the water treatment module and the boiler water inlet, the steam outlet of which can be connected to the injection well and / or with the heat exchanger inlet, while the installation is additionally equipped with an air heater installed on the flue gas exhaust pipe, the output of which is connected to the burner device.

The essence of the utility model is illustrated by graphic materials on which the installation diagram for generating steam is presented.

The installation includes a steam boiler 1, containing a thermally insulated body, in which a convective bundle of pipes is placed, connected at the inlet to the water preparation line, and at the outlet to the exhaust steam withdrawal line.

A burner 2 is installed on the upper part of the boiler body, which can be used as a standard nozzle unit.

The installation contains a line for the preparation of fuel (gas-air mixture) for the boiler, the output of which is connected to the burner device. The fuel preparation line includes a filter 3 for cleaning the gas supplied for combustion, the output of the filter 3 is connected to the gas pressure regulator 4, and its output through the compensator 5 is connected to the input of the burner device 2.

The water treatment line includes a pump 6 for pumping raw water, which through the heat exchanger 7 enters the water treatment module 8. A commercially available heat exchanger is used to complete the installation. The output of the water treatment module is connected to the inlet of the convective pipes of the steam boiler 1. A pressure pump 9 is connected to the communication line of module 8 with the boiler 1. On this line, a device 10 for anti-scale and anti-corrosion treatment of water supplied to the steam in the boiler is installed on the front of the boiler.

The steam exhaust line connected with the boiler’s steam output is able to communicate with the injection well and / or with the raw water heat exchanger 7, which is pumped through it before being fed to module 8. To ensure steam is distributed along the supply lines to the well and / or heat exchanger gate valves 11 and 12. An emergency steam vent valve 13 is provided on the steam exhaust line.

The flue gases resulting from the combustion of the gas-air mixture in the burner 2 from the boiler 1 are discharged through the pipe 14 into the atmosphere. An air heater 15 is mounted on the pipe for heating the air supplied to the burner device 2 for preparing the gas-air fuel mixture burned in the boiler, which is used as fuel.

For the operation of the installation, a standard steam boiler is used. To ensure the mobility of the installation, it is preferable that the boiler be mounted on a self-propelled vehicle.

Naturally, to ensure the functioning of the installation, it is equipped with highways for transporting fuel, water, steam, shut-off and control valves, sensors for measuring the temperature and pressure of water, steam, and fuel. Connections and lines in this application are understood as water, steam, fuel pipelines.

As a device 10, the apparatus used was a Hydroflow apparatus, modification “S”, manufactured by the company “Hydropath Holding Limited” (Great Britain.

The design of the remaining units of the installation, not disclosed in this application, is known and does not constitute the subject of patent protection of this utility model.

Installation for generating steam works as follows.

The operation of the installation begins with the preparation of water intended for receiving steam and ensuring the operation of the installation, and the preparation of fuel that can be carried out in parallel.

To ensure the operation of the installation, various sources of water can be used (lakes, rivers, borehole water and circulating water supplied to injection wells, etc.).

It should be noted that the water supplied to the formation of steam contains a variety of impurities. In addition, its contamination by household, industrial effluents is possible. Recycled water may contain residues of oil and salts, chemicals, etc.

Using untreated water can lead to deposits on the boiler tube blocks (scale and corrosion).

Primary scale in the boiler results from the dissolution of calcium, magnesium, iron, silicon compounds with increasing water temperature. The highest water temperature is on the inner surface of the boiler, therefore, here, on the wall, a solid layer of deposits forms. Secondary scale is also deposited on the inner surface - solid particles formed in the volume of water and “stuck” to the wall. The thermal conductivity of scale is much (20 times or more) less than the thermal conductivity of the metal. Because of this, as the thickness of the scale deposits increases, the temperature of the wall metal inevitably increases. In this case, the metal loses its strength, cracks, fistulas, etc. are formed. In addition, an increase in wall temperature leads to a deterioration in heat transfer and a decrease in boiler efficiency. It is tentatively considered that every millimeter of scale causes a loss of 1% of the boiler efficiency. Typically, scale does not form in systems where demineralized water is used.

Oxygen dissolved in water causes pitting corrosion of the nodes and parts of the mains and the boiler, forming small craters on the metal surface. Some of these craters continue to increase until fistulas occur and the plant aggregates fail. With increasing water temperature, the solubility of oxygen decreases and its aggressiveness increases.

Water treatment is carried out in module 8, usually in several stages, the amount of which depends on the state of the water supplied to the installation.

As a rule, at the first stage, the source water is clarified irrespective of its sources of supply, passing through filters loaded with quartz or crushed anthracite. This allows you to clean the water from oil and solids.

At the second stage, water is passed through an ion-exchange filter, in which its Na-cation is carried out.

In the third stage, the water is subjected to electromagnetic, ultrasonic and silicate treatment to ensure reduction of oxygen and carbon dioxide corrosion. This processing can be carried out using devices of the Ecofor type.

Thus, the water treatment module 8 may include series-connected filling filters, ion-exchange filters, and Ecofor-type apparatuses. The number of filters and the combination of their types can be different and depends on their performance and water condition. For each stage of water treatment, several filters installed in parallel can be used. In module 8, the water heated in the heat exchanger 7 is supplied by a pump 6.

From module 8, purified water is pumped 9 to the water inlet of boiler 1 to produce steam.

Passing through the device 10, salts of salts dissolved in water are repelled from the walls of the pipes and accumulate in the central part of the water flow and their crystallization does not occur on the heating surfaces of the boiler, but in the mass of water. As studies have shown, the use of device 10 allows you to increase the overhaul period of the boiler by 2-2.5 times.

Fuel preparation is as follows.

As fuel for the burner device 2 installation use gas.

When gas is supplied from a gas pump station (not shown), it is initially cleaned from mechanical impurities and excess moisture in the filter 3. Next, the purified gas through the pressure regulator 4 and the compensator 5 enters the burner device 2, where it is mixed with air heated by flue gases discharged through the pipe 14 and passed through the air heater 15. The resulting gas-air mixture is ignited in the device 2 and its combustion products, moving in the working convection bundles of pipes flow around the volume of the boiler, giving off heat to the water pumped through them, as a result of which the water is heated, turning into steam, and flue gases are removed from the boiler cavity into the atmosphere through the pipe 14 .

The use of the gas pressure regulator 4 ensures a constant flow rate on the burner 2, regardless of pressure fluctuations in the gas supply system, as well as gas flow control. The use of gas-air mixture as fuel provides almost complete combustion of gas in the burner 2.

The compensator 5 is performed in the form of bent pipe elbows. The use of a compensator eliminates damage to the gas supply line from thermal deformations.

Depending on the position of the adjustable valves 11 and 12, the steam received in the boiler is supplied either to the injection well, or to the heat exchanger 7 for heating the water supplied by the pump 6, or simultaneously to the injection well and the heat exchanger 7.

When the steam pressure rises above the calculated one, the valve 13 for emergency steam pressure relief is activated.

The installation can be performed in a stationary version or placed on a transportable platform, moved by tractor means.

Claims (1)

Installation for generating steam, comprising a steam boiler, equipped with a burner for burning fuel supplied to the boiler and having the ability to communicate with the fuel supply system, a heat exchanger for heating the water supplied to receive steam, a pipe for removing flue gases from the boiler, characterized in that the installation equipped with a water treatment module, the heat exchanger output is connected to the inlet of the water treatment module, the output of which is connected to the water inlet of the boiler, and the installation is equipped with anti-scale and anti-corrosion devices water treatment installed on the communication line of the water treatment module and the boiler water inlet, the steam outlet of which can be connected to the injection well and / or to the heat exchanger inlet, while the installation is additionally equipped with an air heater installed on the flue gas exhaust pipe, the outlet of which is connected to the burner device.