DD161076A3 - METHOD FOR THE REGENERATIVE USE OF THE WET CONTENTS PURELY SOLUTIONS - Google Patents

Abstract

The invention relates to a method for the regenerative use of the heat content of poor solutions or of sump products after the desorption of a working medium with thermal separation of liquid components, in particular in sorption processes with working substance pairs or multicomponent mixtures. The essence of the invention is that the supplied rich solution divided into two Teilstroeme, a partial flow is fed to a Desorber and the other a Teilstromdesorber, these Teilstroeme parallel to each other both apparatuses under heat absorption and release of working material and durchroemen the poor solution collected in the Suempfen becomes. Subsequently, both bottoms are combined and the total current poor solution is passed as a heat carrier through the mantle space of a Heizbuendels the Teilstromdesorbers, in countercurrent to the trickle stream of rich solution, and serves to heat the Teilstromdesorbers. The invention finds application in desorption and distillation plants of the chemical industry for the utilization of process waste heat in desorbers of absorption coker plants, sorption heat pumps, sorption processes for the generation of mechanical energy and heat transformation plants.

Description

Title of the invention

Process for the regenerative use of the heat content of poor solutions

Field of application of the invention

The invention relates to a method for optimal regenerative use of the heat content of poor solutions or of. Sumpfprodukten in the desorption of a working fluid or »in the thermal irrigation, especially in Absorptionsbzw» desorption with working pair for the refrigeration technology, sorption heat pumps for die'Heiz- and air conditioning and for processes of power generation and energy for waste heat utilization ·

Characteristic of the known technical solutions'

The conventional regenerative utilization of the heat content of a poor solution, which is obtained during the thermal desorption of a working fluid, z, B, from a two-substance mixture in the bottom of a desorber, takes place by heat exchange with the colder rich solution "This heat exchange becomes the more lossy the larger the difference in quantity between poor and rich solution. But since great concentration differences between poor and rich solution are to be striven for; This conventional method increasingly disadvantages, These disadvantages are further increased by the fact that the cold, rich solution is often used as a cooling medium and even before the heat exchange with the poor solution absorbs heat in the return generator or dephlegmator or absorber. "The rich solution is then so much Heat supplied _} that the working fluid already partially before entering the desorber

aasgast (Teilverdampfung) and the same MaJSe the concentration of the remaining liquid phase decreases · The bedeatet reduction of the working agent concentration at the top of the desorber, increased cooling capacity of the dephlegmator, Irhöhang the Desorptionsanfangstemperator, Haizenmitteltemperatar and higher heat consumption A partial bypass of the heat exchanger between poor and rich solution it also increases the exit temperature of the poor solution at the cold end, that is, the heat of the process, and thus does not provide a satisfactory solution to the problem. "

Another regenerative utilization of the poor content of the poor solution has been known and carried out under the term "solution recirculation" in thermal compressors for the refrigerant in absorption refrigeration plants. "(Zeitschrift ganz Kälteindustrie - Bd, 20 (1913), S * 1-9? S» 114-119, pp. 150-161, Bd, 21 (1914), pp. 7-14, 21 ".24" Discharge recycling ", ie by heat release of the hot, poor solution to the mixture to be separated in the desorber itself An improvement can be achieved in an expeller column without any mixing between the poor solution and the mixture to be separated. By "solution recirculation" into the: desorber itself, the excess of heat and the pre-evaporation in the rich solution can be avoided.

Nevertheless, this theoretically clear advantage of "solution recycling" has not led to a breakthrough in the practical application of this principle, because it can only be realized with spiral-wound drilling apparatus. The reliability of such drilling systems is unsatisfactory, as is the productivity of their production Heating surface density and repair options * They were therefore only used in the upper part of the Desorb heating system and were previously only used with a thermodynamically low 2 effect *

In the interest of lowest pressure losses and the realization of the countercurrent principle in the readelphase a defined film flow is sought, the construction of the desorber

-3-

in the form of tube columns (hut, II B, 28th edition, page 244). These tube columns work with vertical tube bundles, in which most of the mixture to be separated flows out of the tube inner surfaces as a film and the heating takes place from the outside in the jacket space. "With polluting heating media, the media is reversed." However, the realization of a "solution return" is not satisfactory. On the one hand, the jacket space of such a heating register has a very large YoIu. men, while the flow rate of reaching as film flow in the tubes to the bottom of the column poor solution is very low. A sufficiently high speed of the poor solution as a heating medium can therefore not be achieved even with the use of additional internals, or it is to achieve this high speed; a very complicated technical solution required. "Another Hachteil is that the heating coils must be built to achieve a falling film flow for the mixture to be separated on top of each other * This leads on the one hand to an undesirable increase in the number of heating. register and on the other hand to a limitation of the usable (temperature difference of the poor solution as a heating medium, for example, if the solution recycling as the middle of three heating registers is arranged. (DD-PS 124 936) Furthermore, this also leads to a limitation of the cooling of the heat carrier and undesirable large temperature differences between the poor solution and the solution to be separated on the "hot" side of the heating register when the solution recycling is carried out as "topmost heating register *

Because of these difficulties and because of the so far only small carried out degassing (concentration difference between rich and poor solution) is dispensed in almost all cases on.Lösungsrückführung.

Object of the invention

The aim of the invention is to use the known and hitherto only imperfectly used method of solution recycling

_ 4 · -

To replace regenerative use of the heat content of the poor solution of desorbers in sorption by a more effective and feasible process, the poor solution, ie the bottom product of the desorber is cooled in a wide temperature range and by ensuring a subcooling for the inflow of the rich solution a prerequisite for a stronger cooling of the waste heat carrier fulfilled ·

At the same time it should reduce the heat required for the return generation and, where appropriate, can be dispensed with the application of an amplifier column to increase the vapor concentration of the working medium vapors.

Explanation of the essence of the invention

The invention is based on the technical object of developing a method in which sensible heat of the desorbent hot waste poor solution of a working fluid is used by countercurrent flow to a partial flow of the rich solution to be degassed outside the actual Besorbers, wherein the poor solution cools and the working fluid, which is the light component, is desorbed from the cable flow of the rich solution and by adjusting the amount of partial flow small temperature differences between the heating medium and degassing of the solution can be realized and thus the conversion losses during heat transfer to the cable flow are minimal

According to the invention, this object is achieved in that the inflow of the rich solution for thermal separation on a externally heated desorber and a regeneratively heated or regenerativ and, foreign-owned T e ilstromdesorber is divided "Yiird the division of the amount of rich solution in two cable flows through the usable heat content of the total amount of the poor solution in relation to the heat consumption of the externally heated desorber determined * The partial streams of rich solution flow parallel to each other in the diesel stream in the desorber externally heated Heizbün-

del and in Teilstromdesorber only a regeneratively heated or a regenerative and a externally heated tube bundle and are collected as a poor solution in each case in the swamps of the desorber or «Teilstromdesorbers. Subsequently, both partial flows are brought together again and the total flow of the poor solution is conducted as a regenerative heat transfer medium through the jacket space of the regeneratively heated heating bundle, in countercurrent to the partial flow of the rich solution.

In a particular embodiment of the method it is provided that to ensure a same Desorptionsendtemperatur and a same concentration of the poor solution of desorber and Teilstromdesorber the trickle stream in Teilstromdesorber at the hot end is additionally guided by a Fremdbesheiztes heating bundle.

O ^v

embodiment

The invention will be explained in more detail below with reference to Ausiührungsbeispielen. The individual process steps are shown using the principle circuit of plants!

Fig. 1: shows a system according to the invention with a desorber with reinforcing column and dephlegmator, a parallel-connected Teilstromdesorber in a standing version with distribution of the rich solution by regulation.

Fig. 2; shows a system according to the invention similar to FIG. 1 ₅ but with horizontal Heizrohrbü- bundles for the externally heated desorber and a distribution of the rich solution according to different cross-sectional areas, all mass transfer devices are arranged in a common rectification column.

Pig. 3 shows a plant according to the invention similar to Pig. 1, but with steam as a heat carrier for heating the desorber in automatic division of the rich solution by means of connected, equal height arranged inflow,

The execution of the heated part of the desorber 1 can take place both standing and lying · The heating medium is, if it is to be expected with contamination, through the hearing of the heating bundle 4. The well-known condition of low temperature differences between the outgassing rich solution 12 and the heating medium is best satisfied with such heat carriers, which have no latent heat and are characterized by countercurrent flow of the heating medium, e.g. in standing desorbers 1 (Pig. 1)

For lying Heizbündeln 4, which are also used for flowing heat transfer without latent heat, the countercurrent principle is only approximately fulfilled by a higher number of bundles 4 heating. (5 ¹ Ig x 2)

The Teilstromdesorber 2 also operates without latent heat. Here also standing and horizontal versions are feasible, but standing Teilstromdesorbern is due to the better Eealisierbarkeit a countercurrent and the elimination of the risk of contamination to give preference. If steam is provided as a heating medium for external heating, the countercurrent principle can be approximated by the use of several pressure levels for the heating steam, the heating steam pressure is staggered so that it is higher in the lower heat bundles than in the upper »Ci ¹ Ig. 3)

The product route and thus the procedure for the systems according to FIGS. 1 to 3 are as follows:

The rich solution 12 is distributed via a feed 14 to the sesorber 1 and to the parallel-connected partial flow desorber 2. The division is carried out according to the heat content of the sumps of Desorber 1 and Teilstromdesorber 2 resulting poor solution or sump products and in accordance with small and economically acceptable temperature differences between the total current of the poor solution 11 as a heating medium for the heating beam 7 Teilstromdesorbers 2 and degassed therein Partial amount of electricity after the heat balance. Thereafter, the rich solution 12 is distributed over distributing means 5 _{a to} the column cross section of desorber 1 and partial flow desorber 2.

The division of the rich solution 12 on the desorber 1 and the Teilstromdesorber 2 can also be made only after the distribution in S äulenquer cut following the flow through the mass transfer device 6. (Figures 2 and 3)

The rich solution trickles as a film through the Sfeoffau.sfcau.scheinrichtung 6 and a Heizbündel 4 in Desorber 1 bzw..durch a mass transfer device 6 and bundles 7 or «7 and 8 in ieilstromdesorber 2. The light components are thermally separated (degassing or Desorption). Those in the swamps of the desorber 1 and of the; Teilstromdesorbers 2 resulting poor solution is combined, optionally via a solution collector 22, and then passed as a heating medium through the He izbündel 7 <ies Teilferomdesorbers 2 in countercurrent to the trickle stream of the mixture to be separated and thereby cooled. The poor solution 11 then leaves the desorption.

The expelled component is also passed in countercurrent to the mixture to be separated, but in direct contact with this from bottom to top through the desorber 1 and the Teilstromdesorber 2, it saturates in the mass transfer device 6, the inflowing rich solution 12, wherein the concentration of the vapor of the working medium or the light fraction increases from bottom to top. Depending on the concentration of the supplied rich solution 12 or the required purity of the working medium vapor 13, a reinforcing column 3 above the inlet of the rich solution is required. Both systems shown in FIGS. 1 to 3 were assumed to have this requirement and, as return generators, a dephlegmator 17 with a coolant inlet 15 and a coolant outlet 16 was shown.

The heating medium of the heating bundles 4 of the desorber 1 or »for the heating bundle 8 of the leilstromdesorbers 2 has an inlet 9 and an outlet 10 * If steam is used as the heating medium, then the arrangement of a second vapor pressure stage in the desorber 1 for the desired high Entgasungsbreite

useful, in the aac3a the flash vapor from the condensate; low-pressure steam enters the heating bundle 4 of the desorber 1 at the inlet 18, leaves it as condensate at the outlet 19, u & cL is led into the zone-liquid tensioner and collector 20 * 4 from the condensate collector 20 is the condensate together with the other condensates 10 via a condensate outlet 21 discharged from the plant.

Claims (2)

invention claim 1 * A method for the regenerative use of the heat content of accumulating as Suiapfprodukt poor solutions of thermal desorption or distillation with low conversion losses in the regenerative heat transfer, wherein the thermal separation as a top product low-boiling agent is obtained and between the mixture to be separated rich solution and the poor solution a large Komssntrationsunterschied consists, characterized in that the inflow of the rich solution 12 for thermal separation on a freehbeheizten desorber (1) and a regeneratively heated or regenerative and externally heated Teilstromdesorber (2) is divided, the division of the amount of rich solution (12) is determined in two part streams by the usable heat content of the total amount of the poor solution (11) in relation to the heat consumption of the externally heated desorber (1) and that the partial streams of the rich solution parallel to each other in the Eieselstrom in the desorber (1) heating bundle (4). or in the partial flow desorber (2) one or more heating bundles (7 or 7 * -md 8) flow through and collected as a poor solution in each case in the sumps of the desorber (1) or the partial flow desorber (2) and subsequently both partial flows are brought together again, and the total flow of the poor solution (11) is conducted as regenerative heat transfer medium through the jacket space of the heating bundle (7) of the partial flow desorber (2), in countercurrent to the substream of the rich solution * 2. »Process according to item 1, characterized in that, in order to ensure a same desorption end temperature and an equal concentration of the desorber (1) and part-stream desorber (2), the desalting stream in the partial stream desorber (2) is additionally heated by a heat-heated heating bundle (2). 8) « HierziLÄ pages drawings