SE437614C - PLATTERY VAPOR - Google Patents

Description

m, .Ha, 10 15 20 25 30 35 {0 rsedd with a layer of porous material etc .. i 1àos294- 9 2 described method can be called nucleation. via nuclear steam vehicles It is known that the developed bubbles have a stirring effect on the heated liquid in the duct, so that the heat transfer leading to the formation of steam.

When the heat transfer surfaces of the plate elements are smooth, it becomes more difficult for bubbles to develop at the lower ones the parts of the liquid channels due to relatively high pressure caused by the pressure head, so that it becomes impossible to fully reach the increase in steam formation caused by the formation of bubbles, which have a stirring effect on the liquid.

In this type of evaporator, various solutions have been tried. with a view to improving the heat transfer of the evaporator speech and efficiency. Such solutions include, for example a corrugated heat transfer surface, a heat transfer surface In the former the heat transfer surface is designed with vertically extending corrugations, which form wide and narrow areas in the flow in a liquid to be heated, so that the proportion of liquid in the wide areas where the heat is concentrated safely steam, while the proportion of fluid in the narrow areas, after having heated, allowed to flow to the wide areas, where evaporation is in progress, thereby increasing the efficiency.

The latter solution aims to cause nuclear vapor formation. of the liquid in the pores of the porous layer on heat transfer the guide surface, so that the liquid evaporates effectively.

However, each solution is designed solely to provide an area for easy heat transfer and that concentrate heat in this area, so that steam is formed concentrated in this area. In other words, it formed the steam grows to a certain degree and leaves the heat transfer the surface using its own buoyancy. But as the steam leaves the stationary state, the time is extended from it, that the bubbles form until they leave the heat transfer surface is that the bubbles stop between the heat transfer surface and the liquid until they leave the latter, so that they turn off the heat transfer between them and thereby also lowers heat transfer rate. This problem is particularly serious at a porous heat transfer surface. Such a heat transfer surface is intended to increase the appearance of bubbles through core vapor? on the formation of the liquid in the pores, as described above, but ïe if? Yes? I J ”a? . . | _¿ a, _ because? _ s. ¿ 10 15 20 25 30 35 40 i 799612: '4-9 3 ”i the bubbles that have developed in the pores collide on an unwanted way with liquid flowing to spaces just abandoned of leaving bubbles, so that the movements of the bubbles are slowed down.

This means that the time that the bubbles switch off the heat transfer the transfer between the liquid and the heat transfer surface becomes length, thereby lowering the heat transfer rate. That's all- so impossible to take full advantage of the increase in the emergence of bubbles, which characterize a porous surface.

An object of the present invention is to provide keep a new design of heat transfer surface for evaporators of plate type, which is capable of increasing the appearance of bubbles at nuclear vapor formation.

A plate type evaporator according to the invention consists of a plurality of plate elements, each of which has a plurality vertically extending, transversely spaced folds, which shoot towards the adjacent channel for a liquid to be steam, said fold abuts against the surface of the opposite plate. the element, so that the liquid channel is divided into a plurality of narrow ones departments, in which narrowing can easily take place.

~ The contact areas between said fold and the adjacent plate the surface facilitates the formation of bubbles. Even in the lower the areas of the channels, where evaporation hardly occurs due to the pressure caused by the pressure level of the liquid, increases the core vapor formation, and because in addition the bubbles formed grows when they rise a long distance, it does not evaporate part of the liquid is stirred, so that the evaporation increases further.

This results in a heat transfer surface which is satisfactory. position in all respects.

To ensure greater heat transfer provided The invention holds a plate type evaporator comprising a return line, which connects a meadow outlet with an inlet for evaporating fluid and serves as a circulation line for the evaporator fluid to circulate in, as well as a nozzle for liquid supply in the circulation line to supply liquid to compensate for the amount that has evaporated. The natural fluid circulation is caused by the pumping effect of arises through evaporation. In addition, fluid circulation increases by supplying new liquid from said nozzle, whereby the liquid is forced to flow along the heat transfer surface.

In addition, if the heat transfer surface has particles . ....., ¿.........._ z .......... .. eooa onaiirïf »« 10 15 20 25 _w 35 40 7906294-9 4 which are meltblasted or bonded thereto in the form of a porous layer with labyrinth-shaped spaces, heat transfer the core number for core vapor formation improved compared to a smooth transfer plate, so that an effective extender can provided.

These and other features will be clarified by the following description, which refers to the accompanying drawings.

Pig. 1 and 2 show the construction of heat transfer the surface of an evaporator according to the invention, wherein fig a cross-sectional view of heat transfer plates joined side side, and Fig. 2 is a front view of a heat transfer device. plate taken along the line II-II in Fig. 1; Fig. 3 is a longitudinal section of a plate type evaporator shown in Figs. 1 and 2; and Figs. 4 and 5 show another embodiment of heat transfer a the surface construction according to the invention, of which Fig. 4 is a part of a front view of a porous heat transfer surface and Fig. 5 is a section taken along the line V-V in Fig. 4.

According to Figs. 1 and 2, the heat transfer plates are marked la-1f. Each plate has vertically extended folds _2a-Zf, separated transversely by fixed distances. Fig. 1 shows a number of heat transfer plates joined side by side, between them delimiting channels A for supply of liquid which shall be evaporated and ducts B for supply of heating medium.

. Said channels A and B are arranged alternately with each other.

On each heat transfer plate, the folds 2 project towards it adjacent channel A. More specifically, for example, at a pair of adjacent plates 1a and 1b, the folds Za on the plate 1a offset half the dividing distance in relation to the folds Zb on the second plate 1b, so that they can abut against the I plan the parts between the folds Zb on the second plate 1b. Here in- through the folds Za and 2b abut against the surfaces of the opposite ones plates 1a and 1b at places marked with 3, so that the channel A between the plates 1a and 1b is divided into a plurality vertically extended and laterally separated sections SA.

The plates 1c-1f, which have folds 2c-2f, are arranged as shown in the same way. In addition, there are, not shown, between the plates delimiting the channel B, e.g. plates 1b and 1c, appropriate spacers to maintain the proper alignment the space for the channel B. '_ A liquid to be evaporated is filled in the liquid channels 10 15 20 25 30 35 40 5 11901621914-9 A while the heating medium is supplied to the heating medium channels B, whereupon the liquid receives the heat of the heating medium through the plates, i.e. heated. In this connection, it should be noted that the contact the areas 3 between the folds and the surfaces of the plates help at the formation of vapor nuclei, so that bubbles form with full strength adjacent to said contact areas 3. Since the steam the bubbles rise a long distance along the fold Z, they appear stirring on the liquid. This increases the formation of steam in the liquid.

Pig. 3 shows a longitudinal section of a plate-type evaporator, also referred to as "supersaturated liquid" precursors and utilizing the heat transfer plates shown in fig. 1 and 2.

The designations 11 and 12 show body parts between which transfer plates 1 are held, which form the main part of the evaporator. Seals 13 are arranged between said plates 1 to delimit channels A and B.

When a liquid to be evaporated is added to the liquid ducts A while heat medium is being supplied to the heating medium ducts B, the liquid is heated by the heating medium in the adjacent adjacent heat media ducts B. In this connection, which .written above, the contact areas 3 (fig. 1) help at the formation of bubbles and a large number of bubbles occur in near the contact areas 3. As these bubbles rise along the narrow compartments 4A (Fig. 1), it becomes the vaporized liquid is stirred so that its vapor formation increases. At the same time causes the pumping action, which has arisen through the evaporation, a natural circulation of the liquid in the liquid channel A, which is shown of the arrows 17, through a return line 14, through which it the upper opening 15 of the liquid channels A communicates with it lower opening 16. This provides heat transfer surfaces variable heat: In addition, to supply liquid as compensation for the vaporized, spray nozzle 18 liquid, at any desired speed, into the lower end of the return line 14, which results in an increase in the flow rate of said natural circulation of the liquid. The flow rate (marked with arrows 17) along the heat transfer surfaces of the plates 1 are therefore increased, so that ensured. The generated steam is extracted through an effluent high evaporating heat conduction opening 19 on the top of the evaporator.

Fig. 4 and 5 show a heat transfer plate having one porous surface, which can be used in a plate type evaporator for 10 15 20 25 30 35 40 19oe294-9 5 to increase the appearance of bubbles during the core meadow formation. As shown the surface of a metal plate 21 is formed with a porous layer ' 23, composed of a large number of particles 22. The porous the layer 23 can be formed by heating the particles 22 to a suitable temperature, at which the surfaces of the particles are just beginning melt and by blasting them on the surface of the plate 21 with high speed, for example, through compressed gas. Alternatively, the layer can formed by bonding the particles 22 to the surface of the plate 21 using suitable binders. The particles 22 may present lie in single or multiple layers. Fig. S shows a two-layer Construction. If the surface of the plate 21 is smooth, the particles may 22 difficult to bind by melting. Thus, labyrinthine shaped spaces 24 defined in the interior of the porous layer 23 and the surface 25 is rough. 5 In addition, although the particles 22 for clarity appear as spheres, they need as long as spaces are delimited in it interior is not limited to such. Furthermore, the porous layer can 22 is designed to cover all or part of the surface of plate Zl.

The heat transfer plates in the construction described above tion are joined side by side, so that the side where it porous layer 23 is present, facing the channel of one liquid to be evaporated. As a result, the liquid enters the outlet. the spaces 24 of the porous layer 23 and are heated by the plates 21 and the surrounding particles 22, thereby concentrated heating is achieved. Ie. nucleation occurs in spaces 24. As a result, the appearance of bubbles increases, so that bubbles 26 develop with force from the surface 25 thereof porous layer 23 and growing. As the bubbles 26 grow, they increase their buoyancy, which causes the bubbles 26 to move through the labyrinth-shaped spaces 24 to reach the surface Of the porous layer, from which they are then separated by the fluid flow (marked with an arrow 27) in channel A. Briefly the resulting bubbles 26 pass through the labyrinthine spaces 24 to surface 25 and flushed downstream. Fluid- the flow in channel A is so shaped that especially when the channel A is narrow tend the bubbles, which are formed to an increasing degree through nuclear vapor formation, to float up and press the storing the bubbles on the downstream side. Such movement in the bubbles provide flow in the liquid. This is the so-called 10 20 25 rareszèsevø natural circulatory phenomenon. The resulting bubbles 26 are taken 4 out through the outflow opening 19 at the far end of the downstream side, which is the case of the evaporator shown in Fig. 3, while the the vaporized liquid flows past to circulate to the upstream side. Such currents 17 and 27 serve to force separate the bubbles 26 from the surface of the porous layer 23.

The same can be said about forced circulation.

Because the large number of "maze exits" on the surface 25 of the porous layer communicates with the "labyrinth passages" 24 in the interior of the porous layer 23, the liquid emerges one or another labyrinth exit at each moment thereafter that a bubble has left such an output. This does not interfere the supply of liquid and the effluent or separation of a bubble each other at some maze exit. Therefore implemented the separation of bubbles from the heat transfer surface rapidly, which in connection with the forced separation of bubbles through the liquid flow greatly shortens the time period then the bubbles obstruct each other between the liquid and the heat transfer surface and turns off the heat transfer in between.

As can be seen in more detail from the drawings, it is porous the surface of the layer 25 an uneven surface which interacts with the flow in the liquid by stirring the liquid flowing along the surface.

This ensures uniform contact between liquids and heat transfer surface for better heat exchange. Since its except this liquid agitation shakes the bubbles on the heat transfer the lining surface, which helps in the separation of the bubbles from there, the heat transfer rate for steam formation further improved.

Claims (1)

Patent plate evaporators, comprising a plurality of vertically extending elements, which are joined side by side to alternately delimit channels for a heating medium and for a liquid to be evaporated, e.g. characterized in that the heat transfer surfaces of each plate element (21; ia-if) are formed with a plurality of vertically directed and laterally spaced folds or axes (2a-2f) which project in associated channels (A) for the liquid which are to be vaporized and which abut against flat surface portions between the folds or axes (2a-2f) of adjacent opposite plate elements (21; 1a-1f), for dividing the associated channel (A) into a plurality of vertically directed narrow sections (4A), which are at each other laterally, the contact areas between la-1f) and the planar part of the adjacent plate element (21; the folds or axes (2a-2f) of a plate element (21; la-lf) forming places on the heat transfer surface n where bubbles can easily develop; that porous layers (23) acting as the core-forming area are formed on the vapor transfer surfaces of the plate elements (21) facing each other, which delimit the channels (A) for the liquid to be evaporated, the porous layers (23) being composed of a quantity particles (22), which are placed next to and on top of each other in several layers and are connected to each other and to the wall surfaces of the plate elements (21) which are in contact with the liquid to be evaporated, so that between the particles (22) a lot of spaces (24) which communicate in a labyrinth-like manner with each other and with the outside of associated porous layers (23); and that between the channels (A) upper and lower portions is connected a circulation line (14, 15, 16) with a vapor discharge opening (19) formed at its top and with a nozzle (18) for supplying liquid as compensation for liquid evaporated, wherein in the circulation line (14, 15, 16) a natural liquid circulation is provided by pumping effect caused by the evaporation of the liquid, and wherein the natural liquid circulation is arranged to be enhanced by the liquid supply from the nozzle (18).