RU2303225C1 - Contact heat-exchange heater and contact jet network heat-exchanger - Google Patents

Abstract

FIELD: power engineering, possible use in contact heat-exchanging apparatuses.

SUBSTANCE: in the heater, mixing chamber is connected at inlet to end cylindrical chamber for turbulization of liquid substance flow, and at outlet end it is connected to diffuser branch pipe with pressure decreasing unit and dissipative head for final condensation of steam-liquid substance. A contact jet network heat exchanger is also claimed, in which contact heat-exchanging heater is mounted in the body with a gap relatively to internal diameter of heat exchanger body for division of network water flow onto internal one, passing through heater, and external one, streaming the heater on the outside, while the mixing chamber is connected at inlet to end cylindrical turbulization chamber for internal flow of network water, and at outlet end the chamber is connected to diffuser branch pipe with pressure decreasing unit and dissipative head for final condensation of steam-liquid substance.

EFFECT: increased efficiency, increased reliability, expanded area of possible use.

2 cl, 6 dwg

Description

The invention relates to a heat power industry and can be used in contact heat exchangers.

Known contact heat exchanger, selected by the applicant as a prototype, comprising a housing with a nozzle for supplying a heated liquid medium (water) and steam, a heater with a medium mixing chamber with a confuser part, a steam pipe with a steam nozzle mounted along the axis of the heater to form a peripheral annular gap of the liquid nozzle . The annular gap is partially blocked by segmented elements with profiled holes uniformly distributed around the perimeter of the gap with the formation of radial slots. Segment elements are oriented perpendicularly or at an angle to the axis of the housing (see the description of the invention to patent No. 2206847 F28C3 / 06 of 2001.11.23, publ. 2003.06.20).

The technical task is to increase efficiency, reliability and expand the scope of use.

The problem is solved by performing a known contact heat exchange heater containing a mixing chamber with an inlet confuser part, a steam pipe with a steam nozzle installed in the confuser part of the mixing chamber along the axis of the heater to form an annular gap of the liquid nozzle, in which, according to the invention, the mixing chamber is connected at the inlet with the end cylindrical chamber for turbulization of the fluid flow, and at the output end, with a diffuser nozzle with a pressure and dissipation unit hydrochloric nozzle for final condensation of the vapor-liquid medium.

The turbulization chamber is formed by vanes uniformly distributed along the perimeter of the turbulization chamber at the angle to the axis of the heater.

The pressure reducing unit is made in the form of holes evenly distributed around the perimeter of the diffuser pipe.

The dissipative nozzle is made in the form of curved blades rigidly interconnected.

A contact jet network heat exchanger is also claimed, comprising a housing with liquid water supply pipes and steam, at least one contact heat exchange heater with a mixing chamber with an inlet confuser part, a steam pipe with a steam nozzle installed in the confuser part of the mixing chamber along the axis of the heater with the formation of an annular gap of the liquid nozzle, in which, according to the invention, the contact heat exchange heater is mounted in the housing with a gap relative to the inner diameter of the housing and a heat exchanger for separating the network water flow into an internal one passing through the heater and an external flowing heater from the outside, the mixing chamber being connected at the inlet to the end cylindrical turbulization chamber of the internal network water stream, and at the output end to a diffuser pipe with a reduction unit pressure and dissipative nozzle for the final condensation of the vapor-liquid medium.

The turbulization chamber is also formed by the blades uniformly distributed around the perimeter of the turbulization chamber at an angle to the axis of the casing.

The pressure reducing unit is made in the form of holes evenly distributed around the perimeter of the diffuser nozzle, and the dissipative nozzle is made in the form of curved blades rigidly interconnected.

The claimed inventions (contact heat exchanger heater and contact jet heat exchanger) are united by a single inventive concept, because the use of the proposed design in a contact jet network heat exchanger is one of the applications for a contact heat exchange heater.

The contact heat exchange heater is designed to heat liquid media (water, solution) by injecting steam into a heated medium, direct contact (mixing) of a heat carrier (steam) with a heated medium in a pipeline (hydraulic network) under pressure or in a container at atmospheric or overpressure a heterogeneous system into a homogeneous one, ensuring the use of the full heat content (enthalpy) of the vapor and the absence of condensate discharge.

As a result of turbulization of the heated medium stream at its outlet from the liquid nozzle, a dispersed liquid stream enters the mixing chamber, which intensifies heat transfer and provides a more efficient use of steam energy. In addition, the location of the steam nozzle in the confuser part of the heater mixing chamber provides crushing of the liquid and, as a result of the developed contact surface of the steam with the heated medium (liquid), a high heat and mass transfer coefficient is ensured.

The diffuser nozzle reduces the flow rate at the outlet, and the side openings around the perimeter of the diffuser nozzle reduce the pressure of the heated stream.

The dissipative nozzle equalizes the temperature field along the flow cross section, reduces the length of the temperature equalization zone of the heated medium by dispersing the jet to finally condense the vapor-liquid medium, which ensures the use of the total heat content of the steam without removing condensate.

The proposed design of a contact jet network heat exchanger using a contact heat exchange heater increases reliability by ensuring the hydraulic stability of the network (does not create hydraulic resistance) in the absence of steam supply (when the heat carrier-steam is turned off) and provides the same piezometric pressure graph, because the heater does not occupy the full cross-section of the hydraulic pipe, but only part of it. As a result, only part of the network stream passes through the heater (internal stream), and the other part of the network stream passes, washing the heater from the outside, between the housing and the heater (external stream). In addition, the installation intensifies heat transfer due to heat transfer from the outer surface of the heater to the external streamlined stream. Mounting a heater block in one housing allows you to increase the thermal power of the installation.

The patent research did not reveal similar technical solutions, which allows us to conclude about the novelty and inventive step of the claimed technical solution.

The domestic industry has all the means (materials, technology, equipment) necessary for the manufacture and widespread use of the proposed devices for heating network water in heating systems, heat supply, hot water supply of industrial facilities and municipal services (housing and communal services), for heating solutions in technological installations (pipelines ) chemical, paper and other industries.

The invention is illustrated by drawings, where:

figure 1 - shows a General view of a heat exchanger contact jet network in a perspective view;

figure 2 - contact heat exchange heater in a longitudinal section;

figure 3 is a contact jet network heat exchanger in longitudinal section;

figure 4 is a view along arrow a in figure 3;

figure 5 is a view along BB in figure 3;

Fig.6 is a connection diagram of a contact heat exchange heater in a tank of a process unit for heating water or a process solution.

Heater contact heat exchange 1 is an apparatus for direct mixing of two media: heating (steam) and heated (water or technological solution) by injection of steam into the heated medium and is a non-separable monoblock (heating module).

The contact heat exchange heater 1 comprises a mixing chamber 2 with a confuser part 3 made at the inlet 3. The mixing chamber 2 is connected at the inlet to an end cylindrical turbulization chamber 4 of a heated medium flow, in which a steam pipe 5 is located with a steam nozzle 6 installed in the confuser part 3 of the mixing chamber 2 along the axis of the heater 1 with the formation of an annular gap of the liquid nozzle 7. The cylindrical turbulence chamber 4 is formed by uniformly distributed along the perimeter of the chamber oriented at an angle to the axis of the heater 8 blades flat or curved shape. At the output end, the mixing chamber 2 is connected to a diffuser nozzle 9 for braking the flow, equipped with a pressure reducing unit and a dissipative nozzle 10 for aligning the temperature field along the flow cross section and ensuring the final condensation of the vapor-liquid mixture. The pressure reducing unit is made in the form of through holes 11 evenly distributed around the perimeter of the diffuser pipe 9. The dissipative nozzle 10 is made in the form of curved blades 12 rigidly interconnected.

When the heater 1 is turned on, the heated medium is supplied to the liquid nozzle 7 in the turbulization chamber 4, where the flow is divided by the blades 8 into separate jets and twisted. At the outlet of the confuser part 3 of the mixing chamber 2 in the reduced pressure zone, the heated medium comes into contact with the steam and then passes (injected) into the condensation zone of the mixing chamber 2. The steam through the steam pipe 5 enters the steam nozzle 6 and then into the mixing chamber 2, where it breaks the liquid stream into particles at high speed, gives it acceleration and comes into contact with the liquid medium. As a result of the developed heat exchange surface with a heated medium, the steam actively condenses.

The entire process of steam condensation takes place in a relatively short area. Passing through the diffuser pipe 9, the flow rate decreases, and the pressure increases. Performed side holes 11 around the perimeter of the diffuser pipe 9 provide the exit of part of the steam-water mixture into the external stream and thus reduce the pressure in the cross section of the stream. Next, the heated stream through the dissipative nozzle 10, where the temperature is balanced over the flow cross section and the final condensation of the vapor-liquid mixture, is discharged for technological purposes.

When using a contact heat exchange heater 1 in a closed heat supply system (for heating solutions in a tank of 13 process plants), a system is provided to maintain a constant return water pressure before installation by venting excess water through a safety valve (not shown in the drawing) and the working pressure in the pipeline should not exceed 1.6 MPa (16 kgf / cm ² ).

To control the temperature of the outgoing liquid medium, the steam flow rate is changed by means of shut-off valves 14 manually or using an automatic control system (block 15), controlled by a signal from a thermometer 16 for measuring the temperature of the heated liquid medium at the outlet of the installation.

The contact jet heat exchanger 17 comprises a cylindrical body 18 with water and steam supply pipes, at least one heat exchange heat exchanger heater (or heater block) 1 described above, which is rigidly mounted in the housing 18 (by means of connecting elements 19) with a gap relative to the inner diameter of the housing 18 of the heat exchanger 17 for separating the network flow of a liquid medium into an internal flowing through the heater 1 and an external flowing heater 1 from the outside. Contact jet network heat exchanger 17 is mounted in the gap of the pipeline of the heated medium before or after the network (circulation) pumps. Valves and instrumentation are installed according to a typical installation scheme. The automation system for maintaining the set temperature of the heated medium can be performed with a local control panel or with connection to a centralized control center. The unit can operate in manual control mode (in the presence of instrumentation).

The heat exchanger 17 is mounted in the gap of the pipeline of the heated medium with an internal pressure of not more than 1.6 MPa (16 kgf / cm ² ) and the temperature of the heated water not higher than 250 ° C. The connection to the pipelines is carried out by means of a flange connection 20. Before turning on the heat exchanger 17, the presence of liquid pressure in the network is checked according to the pressure gauges before and after the heat exchanger 14. Steam is supplied from an inlet steam manifold equipped with a pressure regulator and a safety valve. The vapor pressure should be higher than the pressure of the liquid medium. To prevent liquid from entering the steam line when the steam pressure decreases, a non-return valve is installed on the steam line.

The heat exchanger contact jet network 17 operates as follows. The liquid medium enters through the inlet pipe of the housing 18. Next, the network flow of the liquid medium branches out into an internal flowing through the heater 1 and an external flowing heater 1 from the outside and not directly in contact with the steam stream. When steam is supplied to the steam nozzle 6 (in the confuser part 3 of the mixing chamber 2), a reduced pressure zone is formed and the turbulent internal flow of the liquid medium rushes into the mixing chamber 2. Steam condensation occurs in the mixing chamber 2. The heat transfer is intensified due to heat transfer from the outer surface of the heater 1 to the outer streamlined stream. In the diffuser pipe 9 there is a decrease in flow rate. In the zone of the dissipative nozzle 10, the temperature is equalized over the flow cross section. Next, the heated liquid medium enters the network.

The heat exchanger is connected to the lines of the liquid medium and steam, in the presence of the following list of (calculated) parameters:

- water flow through the water line (heating network); t / h;

- water pressure at the inlet to the installation, MPa (kgf / cm ² );

- steam pressure at the inlet to the installation, MPa (kgf / cm ² );

- temperature of heating steam, not more than ° С;

- water temperature at the inlet to the heat exchanger, ° C;

- water temperature at the outlet of the heat exchanger, ° C;

- conditional diameter of the supply line, mm.

The proposed devices were manufactured and tested in accordance with the requirements of the "Rules for the Construction and Safe Operation of Steam and Hot Water Pipelines" PB 10-573-03 Section VI, as for category IV pipelines: contact heat exchange contact heater 1 at FSUE PA Mayak, Ozersk, Chelyabinsk region, and a contact jet network heat exchanger 17 at the OJSC in the heat supply system of OJSC "Combine of building structures", Chelyabinsk.

Claims (8)

1. Contact heat exchange heater containing a mixing chamber with an inlet confuser part, a steam pipe with a steam nozzle installed in the confuser part of the mixing chamber along the axis of the heater to form an annular gap of the liquid nozzle, characterized in that the mixing chamber is connected at the inlet to the end cylindrical chamber turbulization of the liquid medium flow, and at the output end with a diffuser nozzle with a pressure reducing unit and a dissipative nozzle for the final condensation of the vapor-liquid medium. 2. The heater according to claim 1, characterized in that the turbulization chamber is formed by vanes uniformly distributed along the perimeter of the turbulization chamber at an angle to the axis of the heater. 3. The heater according to claim 1, characterized in that the pressure reducing unit is made in the form of holes evenly distributed around the perimeter of the diffuser pipe. 4. The heater according to claim 1, characterized in that the dissipative nozzle is made in the form of rigidly interconnected curved blades. 5. A contact jet heat exchanger comprising a housing with water and steam supply nozzles, at least one contact heat exchange contact heater with a mixing chamber with an inlet confuser part, a steam pipe with a steam nozzle installed in the confuser part of the mixing chamber along the axis of the heater to form annular gap of the liquid nozzle, characterized in that the contact heat exchange heater is mounted in the housing with a gap relative to the inner diameter of the heat exchanger housing for separating the network about the water flow to the internal, passing through the heater, and external, flowing around the heater from the outside, while the mixing chamber is connected at the inlet to the end cylindrical turbulization chamber of the internal flow of network water, and at the output end to a diffuser nozzle with a pressure reducing unit and a dissipative nozzle for the final condensation of the vapor-liquid medium. 6. The heat exchanger according to claim 1, characterized in that the turbulization chamber is formed by vanes uniformly distributed along the perimeter of the turbulization chamber at an angle to the axis of the casing. 7. The heat exchanger according to claim 1, characterized in that the pressure reducing unit is made in the form of holes uniformly distributed around the perimeter of the diffuser pipe. 8. The heat exchanger according to claim 1, characterized in that the dissipative nozzle is made in the form of curved blades rigidly interconnected.

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