RU102774U1 - STEAM-WATER HEAT EXCHANGER - Google Patents

Abstract

 1. A steam-water heat exchanger comprising a vertical housing with nozzles for supplying heating steam, condensate and non-condensable gases, a lower water chamber and an upper water chamber with nozzles for supplying and discharging feed water, a pipe system located in the housing, including a casing with an open entrance from the side heating steam supply pipe, horizontal partitions separating the casing into sections, upper and lower floating pipe boards with holes for the first and second bundles passed through them located on the input side of the casing, strokes, and a condensate level pre-installed in the casing, characterized in that the casing is provided with an additional horizontal partition blocking the first stroke bundle, limited by the second stroke bundle and located on the side of the lower tube plate at a distance t1 from it, and a slot with a height h1 from the lower tube plate from the side of the first stroke beam, the lower tube plate is provided with a protrusion of height h2, covering the second stroke beam and located between the casing and the casing so that h2> t1> h1, and Level of condensate is preset above the lower tube plate by an amount t2 so that h2> t2> t1. ! 2. The steam-water heat exchanger according to claim 1, characterized in that the protrusion is provided with one or more windows with sides located so that on one side of each window is adjacent to the lower tube plate, the opposite sides of the windows are separated by a distance from the lower tube plate, not exceeding h1, and the total area of the windows is less than the area of the slot of the casing.

Description

The utility model relates to energy, namely, to steam-water heat exchangers-devices for heating water with heating steam, for example, from turbine selections or from heating boiler houses.

Known steam-water heat exchangers containing a housing with nozzles for supplying, removing network water, supplying heating steam, condensate drainage, inlet, outlet, and rotary chambers, a tube system located in the housing, including a fixed and movable tube plate, in which openings for tube bundles are made first and second moves (RF Patent No. 2098732).

The known technical solution is implemented in a network water heater of the PSV type, selected as a prototype (), which is a vertical-type steam and water heat exchanger, the main nodes of which are: a housing, a pipe system, upper and lower water chambers. The assembly of nodes is carried out using a flange connection, providing the possibility of their preventive inspection and repair. The heater body consists of a cylindrical shell, an elliptical bottom and a flange for connection to the pipe system. In the upper part of the shell of the casing there is a steam supply pipe, and below it are located: condensate supply pipe, air exhaust pipe, couplings for connecting a level indicator, pipe for connecting a level regulator sensor. A steam condensate outlet pipe and a pipe for the level regulator are installed in the bottom. The pipe system consists of a casing with an open lead-in from the side of the heating steam supply pipe, dividing the casing into sections of horizontal partitions and upper and lower (floating) pipe boards, frame pipes, direct heat-exchange pipes, the ends of which are flared in pipe boards. On the upper tube plate, an air valve is provided for venting air from the housing during hydrotesting and a valve for draining water from the upper water chamber. The upper water chamber consists of a cylindrical shell, an elliptical bottom and a flange for connection to the pipe system, pipes for supplying and discharging network water. The internal volume of the chamber is divided by partitions into compartments, due to which the network water makes the required number of moves. An air valve clutch is installed in the upper part of the bottom for venting air from the pipe system during hydrotesting. The lower water chamber consists of an elliptical bottom and a flange for connection to the pipe system. A clutch is installed in the bottom for draining the water. The mains water in the heater moves through the heat exchange tubes, and the heating steam enters through the steam supply pipe into the annulus. Condensate vapor flows into the lower part of the housing and is discharged from the heater through a control valve controlled by an electronic automatic device. The automatic condensate level control equipment maintains a normal level of condensate in the housing, releases excess condensate into the drainage network and prevents the steam from leaving the housing.

The disadvantage of this heater is its low efficiency, due to the incomplete use of the possibilities of taking heat from condensate.

The utility model is aimed at solving the problem of increasing the efficiency of the heater.

The technical result is the most complete use of heat from condensate.

The technical result in the implementation of the utility model is achieved by the fact that in the steam-water heat exchanger containing a vertical housing with nozzles for supplying heating steam, condensate and non-condensable gases, a lower water chamber and an upper water chamber with nozzles for supplying and discharging mains water, a pipe system located in the housing including a casing with an open lead-in from the side of the heating steam supply pipe, dividing the casing into sections horizontal partitions, the upper and lower floating pipe with holes for the tubes of the first and second beams passed through them, located on the inlet side of the casing, strokes, and the condensate level pre-installed in the casing, the casing is equipped with an additional horizontal partition blocking the first-stroke bundle, bounded by the second-stroke bundle and located on the lower pipe side boards at a distance t ₁ from it, and a slot with a height h ₁ from the lower tube plate from the side of the first stroke beam, the lower tube plate is provided with a protrusion of height h ₂ , covering the second stroke beam and located between the casing and the casing so that h ₂ > t ₁ > h ₁ , and the condensate level is preinstalled above the lower tube plate by a value of t ₂ so that h ₂ > t ₂ > t ₁ , in addition, the protrusion is equipped with one or more windows with the sides located so that on one side of each window they are adjacent to the lower tube plate, the opposite sides of the windows are separated from the lower tube plate by a distance not exceeding h ₁ , and the total area of the windows is less than the area of the slot of the casing.

The utility model is illustrated by drawings, which do not show only those elements that fully coincide with the prototype and, accordingly, are not necessary to illustrate the proposed technical solution:

Figure 1 - sectional steam-water heat exchanger;

Figure 2 is a section along aa in figure 1;

Figure 3 is a section along BB in Figure 1;

Figure 4 is a section along BB in Figure 1; Figure 5 is an additional horizontal partition in plan.

Steam-water heat exchanger (Figure 1) contains a vertical housing 1 with nozzles for supplying heating steam (not shown), condensate 2 and non-condensable gases (not shown), a lower water chamber 3 and an upper water chamber with nozzles for supplying and discharging network water (not shown), a pipe system 4 located in the housing, including a casing 5 with an open lead 6 (Figure 2) from the side of the heating steam supply pipe, dividing the casing 5 into sections horizontal partitions 7, the upper (not shown) and lower floating 8 tube boards with hole for the tubes of beams of the first 9 and second 10 passes passed through them (FIG. 2, FIG. 3, FIG. 4), and a condensate level 11 pre-installed in the housing 1. The casing 5 is equipped with an additional horizontal partition 12 (Figure 5), tightly welded to the casing 5 along the adjacent perimeter, overlapping the first beam 9, and located on the side of the lower tube plate 8 at a distance t ₁ from it. The casing 5 is provided with a segmented slot 13 (FIG. 3, FIG. 4) of height h ₁ from the lower tube plate 8 from the side of the first stroke 9 beam. The lower tube plate 8 is provided with a protrusion 14 of height h ₂ , which completely or partially covers the beam of the second stroke 10 and located between the housing 1 and the casing 5 so that h ₂ > t ₁ > h ₁ . The condensate level 15 is preinstalled above the lower tube plate 8 by a value of t ₂ so that h ₂ > t ₂ > t ₁ .

The protrusion 14 is provided with one or more windows 16 (Figure 4), on one side of which (lower sides) are adjacent to the lower tube plate 8, and the opposite sides are separated from the lower tube plate 8 by a distance not exceeding h ₁ . The total area of the windows 16 is formed less than the area of the slot 13 of the casing.

Steam-water heat exchanger operates as follows.

When supplying network water, it passes sequentially through the branch pipe for supplying network water, the tube bundle of the first stroke 9, the lower water chamber 3, the tube bundle of the second stroke 10 and leaves the steam-water heat exchanger through the pipe of the outlet of network water. When supplying heating steam through a pipe for supplying heating steam to the cavity of the casing 5 through the inlet part 6 to the pipe system 4, steam is condensed and network water is heated. The formed condensate settles on the horizontal partitions 7 and flows into the lower part of the housing 1 and leaves the heater through the condensate drain pipe 2.

A feature of the proposed steam-water heat exchanger is the structural flooding of the lower part of the tube bundles of the first 9 and second 10 strokes and the constructive organization of the horizontal condensate movement in the annulus in the direction from the second-stroke beam to the first-stroke beam.

In the case of longitudinal flow (typical for the downward movement of condensate in the annulus), the heat transfer coefficient from the condensate to the heat exchange pipe is calculated by the following formulas:

α ₁ = 0.023 · λRe ^0.8 · Pr ^0.4 / d _equiv Re = W ₁ · d _equiv / υ d _equiv = 4f / P, where

α ₁ - heat transfer coefficient for longitudinal flow, W / m ² · K;

λ is the coefficient of thermal conductivity, W / m · K;

Re - Reynolds criterion;

Pr - Prandtl criterion;

d _equiv - equivalent diameter, m;

W ₁ - condensate velocity during longitudinal flow, m / s;

υ is the kinematic viscosity coefficient, m ² / s;

f is the bore of the heat exchange pipe, m ² ;

P - wetted perimeter, m.

In the case of a transverse flow around heat transfer pipes (typical for a specially organized horizontal movement of condensate in the annulus in the direction from the second-stroke beam to the first-stroke beam), the formulas for calculating the heat transfer coefficient are as follows:

α ₂ = 0.334 · λRe ^{0.6 ·} Pr ^0.35 / d _tr Re = W ₂ · d _tr / υ, where

α ₂ - heat transfer coefficient during transverse flow, W / m ² · K;

d _tr - the outer diameter of the heat exchange pipe, m;

W ₂ - condensate velocity during transverse flow, m / s

Taking into account the actual condensate velocities in the steam-water heat exchanger W ₁ = 0.008 m / s and W ₂ = 0.15 m / s, the ratio of heat transfer coefficients will be approximately equal to α ₂ / α ₁ = 22, and the ratio of the corresponding heat transfer coefficients K ₂ / K ₁ = 14.

The windows 16 of the protrusion 14 perform a flushing function, preventing the formation of a zone of stagnation and slag deposition. The formation of the total area of the windows 16 is less than the area of the slot 13 of the casing 5 allows you to not violate the direction of condensate washing of the tube bundles in the direction from the second-stroke beam to the first-stroke beam.

Based on the foregoing, we can conclude that the heat transfer rate in a real steam-water heat exchanger with the constructive organization of condensate movement, providing a transverse flow around the heat exchange tubes (the proposed technical solution), is significantly higher compared to the known ones.

Claims (2)

1. A steam-water heat exchanger comprising a vertical housing with nozzles for supplying heating steam, condensate and non-condensable gases, a lower water chamber and an upper water chamber with nozzles for supplying and discharging feed water, a pipe system located in the housing, including a casing with an open entrance from the side heating steam supply pipe, horizontal partitions separating the casing into sections, upper and lower floating pipe boards with holes for the first and second bundles passed through them Disposed side lead-in portion of the housing, moves, and preset in the hull of the condensate level, characterized in that the housing is provided with additional horizontal baffle overlapping the beam of the first stroke, limited beam of the second stroke and positioned by the lower tube plate at a distance t ₁ from it, and a slot with a height of h ₁ from the lower tube plate from the side of the first stroke bundle, the lower tube plate is provided with a protrusion of height h ₂ , covering the second stroke bundle and located between the casing and the casing so that h ₂ > t ₁ > h ₁ , and the condensate level is pre-set above the lower tube plate by t ₂ so that h ₂ > t ₂ > t ₁ . 2. The steam-water heat exchanger according to claim 1, characterized in that the protrusion is provided with one or more windows with sides arranged so that on one side of each window is adjacent to the lower tube plate, the opposite sides of the windows are separated from the lower tube plate by a distance, not exceeding h ₁ , and the total area of the windows is less than the area of the slot of the casing.