CS257575B1 - Air-cooled steam condenser - Google Patents

Abstract

The capacitor consists of a parallel beam heat-exchange and after-cooling pipes, arranged in rows in succession and fitted on the side air flow through transverse ribs. Heat exchange the tubes exit the upper ends into a common upper common chamber a collecting chamber into which the lower end opens at least one row of aftercooling pipes. The upper ends of the cooling tubes open into separate ones upper chamber. The essence of the solution is that all rows of aftercooling pipes and at least part of the rows of heat transfer tubes have transverse ribs fitted with longitudinal cuts. In order to reduce pressure losses on the air side are not cuts made in the ribs of at least the first series of heat exchange of pipes that can also exhibit even more rib pitch than the rest tubular series. The regrooving depth is selected in the range 0.025 to 0.200 smooth tube diameter, pitch in the range of 0.05 to 0.40 diameter of the smooth tube and a cut width in the range of 0.02 to 0.15 diameter smooth tubes. The first line of heat transfer tubes optionally, a series of baffle blades, exhibiting kil-example cylindrical portions areas of 0.04 to 0.06 length a tube bundle and a radius of 0.01 to 0.02 tube bundle length with pitch the blades are 0.01 to 0.02 tube length volume.

Description

The invention relates to an air-cooled water vapor condenser arrangement.

In the prior art air-cooled condensers, condensation takes place inside the heat exchange tubes, which are externally cooled by forced air. The tubes are arranged in parallel rows and flow through the cooling air in a direction perpendicular to the longitudinal axis of the tube bundle. The tubes are connected to common chambers at both ends and are provided with transverse ribs on the air inlet side which increase the heat exchange surface of the tubes by 1,500 to 2,000% compared to plain tubes. The individual rows of tubes are arranged vertically or in an oblique position, or two opposing tube bundles form an A-shaped assembly. The steam is fed into the upper chamber of the condenser and flows downwardly through the condensation tubes. The condensate also flows downstream of the steam into the common lower collecting chamber from which it is discharged for reuse.

In addition, one or more rows of tubes intended to cool the inert gases and complete the condensation of the steam residues may be arranged downstream or downstream of the individual rows of heat exchange tubes in the direction of the air flow. At the lower end, a plurality of coolant tubes terminate in a chamber common to the heat exchange tubes in such a way that the inert gases and vapor residues exiting the heat exchange tubes change their direction in the chamber, enter the coolant tubes and flow through their space in the bottom direction and the condensation in the coolant tubes. The condensate flows down into the common lower chamber, f is removed again. The inert gases are extracted from a separate upper chamber of the aftercooling tubes.

In addition, manually or remotely controlled louvers are located downstream of the rows of heat exchange tubes, by means of which the flow cross section of the cooling air can be closed or completely closed and thus its flow can be regulated. The louvers are mainly used to assemble opposed tube bundles into an A-shaped assembly. In this case, they are placed above the bundles of heat exchange tubes and can be used in addition to regulating the amount of air to prevent rain, snow and air from entering the condenser.

The main drawback of the described condensers is the uneven condensation of steam in the individual rows of the heat exchange tubes downstream. In the first series of heat transfer tubes, which bypass the relatively coldest air, initially the largest proportion of steam condenses and the tubes of this series exhibit the greatest hydraulic resistance. On the other hand, in the last row of tubes by-passing the heated air, the smallest amount of steam condenses and the pipes in this row have the least hydraulic resistance. This also results in different vapor pressures at the lower ends of the individual tubular rows at the point of their entry into the common lower chamber, which cause backflow of steam through the lower openings of the first (front) row of tubes.

While the backflowing steam condenses gradually, the inert gases contained in the steam cannot be extracted from the tubes. Due to the given pressure conditions, they are collected in the tubes and form stable gas pockets, which also retain condensate. The parts of the heat exchange tubes filled with inert gases and condensate cannot then participate in the condensation process and at the outdoor ambient air temperatures they reduce the condensation performance, while at low air temperatures the accumulated condensate cools and freezes, so that the pipes crack.

To overcome the described drawbacks, therefore, the condenser tube bundles are designed such that condensation terminates výši of all successive rows of tubes at the same level, as close as possible to the location of the lower inlet of the tubes into the collecting chamber, utilizing the maximum heat transfer surface of the tubes. The required effect is achieved by gradually decreasing the cross-section of the tubes in individual rows, increasing the heat exchange surface of the individual rows in the direction of air flow, further reducing the rib spacing in individual rows of tubes, changing the rib spacing along the tubes, the distribution of steam distributors into individual tubes, by changing the vacuum in the individual rows of tubes or by installing steam ejectors for the suction of inert gases for each row separately. Thus, either the amount of steam flowing through the individual rows of tubes, or. the heat exchange surface of the tubes so that condensation is partially suppressed in some rows.

However, these solutions present new disadvantages, which are primarily due to the complexity and complexity of production, as well as the necessity of producing a wide range of ribbed tubes of different cross sections and rib spacing. Moreover, when changing the pitch along one pipe, it is not possible to use powerful rib winding technologies, but less powerful rib ribs with a step, ie the so-called L-ribs, where there is a risk of repeated heating and cooling of the pipe. to reduce the rigidity of the contact between the fin and the tube and thereby reduce the heat transfer.

The production of orifice plates, nozzles or flaps in the steam distributor or in individual pipes is also difficult to manufacture. In addition, these elements also cause an increase in pressure drop and hence the need for an increased output of inert gas ejector exhausters. The use of ejectors for each individual row then increases the complexity of the operation of the exhaust ejector system, the steam consumption and the investment costs.

An arrangement is also known in which, in order to overcome the above-mentioned shortcomings of the heat exchanger tube bundle in the direction of the air flow, a thermally hydraulic grille is provided upstream. The lattice is formed by at least one row of plain or low-ribbed tubes, which are connected at their upper ends to a common upper distribution chamber with a steam inlet and lower ends to a common lower condensate outlet. The last row of heat exchanger tubes is followed by a louver, possibly divided into two or more superimposed, separately manually or automatically controlled parts. The advantage of this arrangement is that the cooling air will increase its turbulence as it passes through the heat-hydraulic grille, which in turn will favorably influence the heat transfer of the heat transfer tubes themselves.

However, all of the modifications described are aimed at preventing the condenser from freezing when used in areas with very low outdoor air temperatures, resulting in an increase in the complexity and weight of the condenser, and thus an increase in acquisition cost. On the other hand, when used in areas where the temperature does not fall below freezing, these adjustments are rather undesirable from an economic point of view.

Disadvantages of the known capacitors of the prior art are suppressed by the air-cooled water vapor condenser according to the invention, which consists of a bundle of parallel heat exchange and quench tubes arranged in rows and provided with transverse ribs on the air flow side. a chamber with a steam inlet and lower ends to a common lower condensate discharge chamber into which at least one row of aftercooling tubes terminates simultaneously at the lower ends, while the upper ends of all aftercooling tubes open into a separate upper chamber.

The condenser is essentially characterized in that all rows of cooling tubes and at least a part of the rows of heat exchange tubes have transverse ribs provided with longitudinal slits, which preferably have a depth equal to 0.025-0.200 of the diameter of the smooth tube, pitch equal to 0.05-0.40 diameter smooth pipe and a cutting width equal to 0,02-0,15 of the diameter of the smooth pipe.

The main benefit of heat exchange and aftercooling tubes equipped with transverse ribs with longitudinal slits is a substantial increase in the turbulence of cooling air as it passes between the ribs and thus an increase in heat transfer between the air and the medium to be cooled.

From this point of view, it is particularly advantageous to provide at least the first row of heat exchange tubes with smooth ribs, possibly having an even greater pitch or pitch than the transverse ribs of the other rows of heat exchange and cooling tubes. Since the maximum thermal gradient between the cooling air and the cooled condensing medium occurs in the first row of heat exchange tubes, the reduction in the effect of turbulence and the reduction of heat transfer are less significant. More significant, on the other hand, is the reduction of the pressure loss of air from the free space into the channels formed by the smooth fins of this first heat exchange row of tubes, especially if the series is additionally provided with fins of greater pitch. The pressure loss due to the turbulence of the air is also lower due to the reduction in the number of rows of heat exchange and aftercooling tubes fitted with ribs with slits.

Another alternative to reducing the pressure loss of the air, whether caused by changing the direction of the air flow or by entering the air from the free space into the channels formed by the fins of the heat exchange tubes, in particular ribs provided with slits, is upstream of the row of baffles before the first row of heat exchange tubes. This arrangement results in both a reduction in the pressure loss of air due to a change in the direction of its flow, as well as a pressure loss caused by the inlet of air from the free space into the channels formed by the ribs. A certain disadvantage compared to the first variant, i.e. the use of at least one row of heat exchanger tubes with ribs without slits on the cooling air inlet side or rib pitch pitch, is the increase in the total capacitor weight.

An exemplary embodiment of the air-cooled water vapor condenser of the present invention is further illustrated in the accompanying drawings, in which: Figure 1 is a longitudinal vertical section of a condenser consisting of a combination of two rows of heat exchange tubes and one row of aftercooling tubes, Fig. 2 is a similar vertical section through a condenser with two rows of heat exchange tubes and one row of coolant tubes, wherein the first row of heat exchange tubes is provided with non-pruned ribs and spacing greater than the ribs of the remaining tubular rows; Fig. 4 is a cross-sectional side view of a portion of the pipe of Figs. 3 and 5, in detail of the formation of the deflector vanes.

The air-cooled condenser of the embodiment according to FIG. 1 consists of two rows of 2 heat exchange tubes and one row of 2 coolant tubes. The tubes of all rows are provided with transverse ribs 21 ^with longitudinal slits 12. The first row 2 of the heat exchange tubes is preceded by a row 2 of baffles 13. The air flow is directed through the row 3 of baffles 13 so that it passes through the bundle beam axis. The steam is supplied through the throat 7 ° of the upper manifold chamber where it is divided into both rows of 2 heat exchange tubes. Steam flows through the inner space of the tubes from top to bottom with simultaneous condensation. The condensate flows downstream with the advancing steam into the lower collecting chamber 5, which is common to both the rows of 2 heat exchange tubes and the row of 2 aftercooling tubes. 2e ^{, the} condensate is discharged through the neck 2 for reuse. The inert gases and the residues of non-condensed steam advance from the common collecting chamber 2 upwardly through the interior of the row 2 of the quench tubes. In the aftercooling tubes, the remainder of the steam condenses and the condensate flows back into the common collecting chamber 5, where it is discharged together with the main portions through the neck 2 # while the cooled inert gases are exhausted from a separate upper aftercooling chamber 2.

The air-cooled condenser shown in Fig. 2 has a similar configuration to that shown in Fig. 1, except that in the second arrangement the row 2 of the baffles 13 is omitted and the heat exchange tubes of the first row 2 have smooth fins without longitudinal slits. the ribs 11 of the first heat exchanger row 2 have a larger spacing than the ribs 11 of the remaining pipe rows 2 ^and Z. In this arrangement, the air flow direction is directed only in the first heat exchanger row 2 so that air flows again through the second heat exchanger pipe in a direction perpendicular to the axis of the tube bundle. The function of the steam side of the condenser is the same as that of Fig. 1.

FIG. 3 is a cross-sectional view of one heat exchange tube 10 provided with ribs 11 with longitudinal slits 12.

The cutting depth h is selected, which is usually chosen in the range 0.025-0.200 of the diameter d of the smooth tube 10, the cutting pitch t is selected in the range 0.05-0.40 of the diameter d of the smooth tube, and the cutting width s_, whose value it is usually 0.02-0.15 of the diameter d of the plain pipe. In addition, in the side view of FIG. 4, the spacing in the individual ribs 11, the value of which can be scaled, is also indicated. In the first row of heat exchange tubes 9 in the embodiment according to FIG. 2, the spacing or pitch of, for example, ^ selected in the range 0.07 to 0.15 the diameter d of the smooth tube 10, whereas the spacing or pitch of rows ₂ y JL, two heat exchanging tubes and aftercooler in the range 0.05-0.10 diameter d of smooth pipe.

FIG. 5 shows a portion of a row 2 of baffle blades 13 which may alternatively be placed upstream of the first row of heat exchange tubes. The length x of the blade 13, which in the illustrated embodiment is in the form of a portion of the cylindrical surface, is usually chosen between 0.04-0.06 length 2 of the tube bundle, the radius r of the blade within 0.01-0.02 length 1 of the tube bundle and pitch y blades in the range of 0.01-0.02 length of 2 tube bundle.

Claims (4)

SUBJECT OF THE INVENTION An air-cooled water vapor condenser, consisting of a bundle of parallel heat exchange and aftercooling tubes arranged in rows and provided with transverse ribs on the air flow side, the heat exchanger tubes being connected at their upper ends to a common upper distribution chamber with a steam inlet and lower at the end of a common condensate discharge chamber, wherein at least one row of aftercooling tubes are concurrently connected to the lower end of the common conduit, while the upper ends of all aftercooling tubes are discharged into a separate upper chamber, and at least a portion of the heat transfer tube rows (1) have transverse ribs (11) provided with longitudinal slits (12). 2. The air-cooled condenser according to claim 1, wherein the longitudinal slits (12) have a depth (h) equal to 0.025-0.200 of the smooth pipe diameter (d), a pitch (t) of 0.05 to 0.40 diameter (d). smooth tubes and a cutting width (s) equal to 0.02-0.15 of the smooth tube diameter (d). An air-cooled condenser according to Claims 1 and 2, characterized in that the transverse ribs (11) of at least the first row (9) of the heat exchange tubes have a pitch (pitch) equal to 0.07-0.15 smooth tube diameter (d). while the remaining rows (1, 2) of the heat exchange and coolant tubes are pitch or pitch (v ₂ ) equal to 0.05-0.10 of the diameter (d) of the plain tube. Air-cooled condenser according to one of Claims 1 to 3, characterized in that a first row (3, 9) of the heat exchange tubes is provided with a row (3) of rectifier vanes (13), e.g. 0.04-0.06 of the tube bundle length (1) and the radius (r) equal to 0.01-0.02 of the tube bundle length (1), the pitch (s) of the blades (13) being 0.01-0.02 length (1) of the tube bundle.