RU29104U1 - Steam Boiler Continuous Blowdown - Google Patents

Description

Steam Boiler Continuous Blowdown

The utility model relates to the field of inkjet technology, mainly to inkjet installations used in thermal power plants in the continuous purge system of a steam boiler.

A known installation for continuous purging of steam, including a pipe for removing boiler water from a steam boiler, a continuous purge extender, a water heater and a pipe for discharging water from a steam boiler to a sewer (see the book General Heat Engineering edited by S.Ya. Kornitsky and Ya.M. Rubinshtein, State Energy Publishing House, Moscow-Leningrad, 1952, p. 370-371).

This system involves the discharge of saline water into the sewers, which from an environmental point of view pollutes the environment. In addition, hot water is discharged into the sewer, the heat of which can be used in low-potential heat consumption systems. As a result of useless heat release, the overall efficiency of the heat power plant is reduced.

The task to which the present utility model is directed is to eliminate the discharge of salt water into the sewers and increase the efficiency of the heat power plant, in particular heat and power plants, by using purge water in water heating systems.

This problem is solved due to the fact that the jet unit for continuous purging of the steam boiler contains a pipeline for removing boiler (purge) water from the steam boiler, it is equipped with a jet device and a network pump, while the jet device is included in the bypass line of the network pump, the input of the jet pump is connected to pressure line of the mains pump, exit from the inkjet apparatus

connected to the suction pipe of the mains pump, and the boiler water discharge pipe is connected to the nozzle of the boiler water supply of the jet apparatus.

In the course of analyzing the operation of the steam boiler with the continuous purge system of the steam boiler, it was found that while maintaining the optimal salt concentration in the boiler water, it is necessary to continuously withdraw part of the boiler water from the boiler and at the same time supply network water to the steam boiler. When the boiler water is removed, it is first supplied to the expander, which causes boiling of water, followed by the removal of steam and water. Subsequently, water is passed through a heat exchanger to heat the network water with this water. After this, boiler water containing a sufficiently large amount of salts dissolved in it is discharged into the sewer or, more often, into a nearby body of water or river. The result is environmental pollution.

Analysis of the operation of inkjet devices showed that with their help it is possible to refuse the use of an expander and dramatically simplify the system for utilizing boiler water. It is important that in this case it is possible not only to exclude the discharge of boiler water from the continuous blowdown system of the boiler, but also to use its thermal potential more efficiently, which ultimately allows to increase the efficiency of the entire heat and power plant in which a steam boiler is used. At the same time, boiling of boiler water during its expansion allows creating a flow regime in the jet apparatus in which hot water can be obtained at the outlet of the jet apparatus under pressure and with temperature, which allow it to be used in a water heating system of various kinds of premises, both housing and industrial premises.

Thus, the achievement of the task achieved eliminating the discharge of salt water into the sewer and increasing the efficiency

thermal power plant, in particular heat and power plants, by using purge water in water heating systems.

The drawing shows a schematic diagram of a jet installation for continuous purging of a steam boiler.

The continuous blasting unit of a steam boiler contains a pipeline 5 for discharging boiler (purge) water from the steam boiler 1, an inkjet apparatus 2 and a network pump 4. The network pump 4 is made with a bypass line through which the network pump 4 is connected by a suction pipe to the outlet of the jet apparatus 2 and a pressure head pipeline - to the entrance to the jet apparatus 2 to its nozzle supply network water. The water heating system 3 is connected by a return pipe to the suction pipe of the network pump 4 and a direct pipe to the pressure pipe of the network pump 4, and to the direct pipe of the water heating system 3, the network pump 4 is usually connected through a boiler or heat exchanger 6 to heat the network water. The pipeline 5 drain boiler water is connected to the nozzle of the boiler water supply of the jet apparatus 2.

During continuous purging of the steam boiler 1, part of the boiler water under pressure from the steam boiler 1 is sent to the boiler water supply nozzle of the jet apparatus 2. At the same time, the network pump 4 directs the network water to the network water supply nozzle of the jet apparatus 2. In the nozzles of the jet apparatus 2, the liquid media are accelerated . Further, the accelerated flows of network and boiler water flow into the mixing chamber, and the boiler water boils as a result of the pressure drop in the mixing chamber with the formation of a two-phase gas-liquid flow. Due to the fact that the speed of sound in a two-phase medium is much lower than in a liquid or gas, the two-phase flow is converted into a supersonic two-phase flow. After this, for example, by directing the supersonic flow in the jet apparatus 2 into the expanding channel, in a two-phase supersonic

a pressure jump is organized in the flow, as a result of which the two-phase flow is converted into a single-phase liquid flow with microscopic vapor bubbles, and during the conversion process the pressure rises and a liquid flow of the heated liquid medium is formed, which enters the suction pipe of the network pump 4, from which part of the heated liquid flow is directed to the input of the jet apparatus 2, and most of the flow of heated liquid is directed into the water heating system 3 of the heat consumer, usually through a boiler or heat bmennik 6, wherein heating is carried out main water network. In the water heating system 3, for example, in the water heating batteries of a building or room, the process of heat transfer to the consumer occurs, and due to the collapse of microscopic bubbles as a result of the inhibition of the flow in the water heating system 3, an additional heating of the heated liquid flow occurs, which ensures an increase in heat removal from batteries of the water heating system 3. As a result of heat transfer in the water heating system 3 to the consumer, the flow of heated liquid is converted to cooled liquid a stream that flows through a return pipe into the suction pipe of the network pump 4 for reheating the network water.

This utility model can be used in systems of thermal power plants with steam boilers, for example, in thermal power plants, industrial and municipal boiler houses.

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Claims (1)

A steam boiler continuous purge jet installation comprising a boiler (purge) water discharge pipe from a steam boiler, characterized in that it is equipped with a jet apparatus and a network pump, while the jet apparatus is included in the bypass line of the network pump, the input of the jet pump is connected to the pressure pipe of the network pump, the outlet of the jet apparatus is connected to the suction pipe of the network pump, and the boiler water discharge pipe is connected to the nozzle of the boiler water supply of the jet apparatus.