DE10122240A1 - Low-energy spray tower reactor for chemical reactions as well as drying liquids and also process for drying liquids, especially glycerol, to extremely low water contents - Google Patents

Abstract

A spray tower reactor comprises: (a) a spray tower; (b) a refrigerator; (c) a gas feed system; (d) a fan; and (e) a collecting container for solids and/or a piping system. A reactor comprises: (a) a spray tower (10) with a spray device (12) in the upper part connected to a feed container (16); (b) a refrigerator (30) with an evaporator (32), condenser (34) and condensed water run-off (40); (c) a gas feed system with its inlet end connected to the upper region of tower (10) and its branched outlet connected not only to the tower upper end but also to the lower end of tower, such that the gas in the closed system is led over the evaporator (32) and condenser (34); (d) a fan (42) redirecting the gas into the circuit; and (e) either a collecting container (22) in the lower region of the tower for solids and/or reaction products or a piping system for leading off the reaction products. An Independent claim is also included for drying of liquids (preferably organic) by: (i) spraying the liquid into a countercurrent of a dry gas (especially air) to evaporate it; (ii) collecting the solids and/or reaction products of the liquid in the lower region of the spray tower; (iii) drawing off moist gas from the upper region of the tower and heat-exchanging it with an evaporator of a refrigerator to collect condensed liquid at the evaporator; (iv) heating the cooled dry gas by contact with the condenser of the refrigerator; and (v) recycling the heated dry gas to step (i).

Description

The invention relates to a method for drying liquids, in particular especially for drying organic liquids to extremely low water hold. The invention further relates to a reactor for a chemical reaction.

The invention has for its object to provide a low-energy method Drying liquids, especially organic liquids in which the liquids are dried to extremely low water contents the. The invention is also based on the object of a reactor for a surface Mix reaction to provide control of the in a manageable manner chemical reaction equilibrium allows.  

The object is achieved by using the known method EP 0 504 647 B1, in particular the method with the features from claim 1 in EP 0 504 647 B1, for organic liquids. Here, surprisingly organic liquids, especially hydrocarbons, to extremely low levels serum contents are dried. For example, glycerin with a water content of less than 0.2%.

The task related to the reactor is accomplished through the use of the plant EP 0 504 647 B1, in particular a system with the features from claim 3 in EP 0 504 647 B1 solved. When used as a reactor, the necessary activation energy for the reaction via the nozzles and the spray system. In Components that have a catalytic effect can be used in the reactor have. These components can be inherent in the system. With the cont removal of water or other (volatile) reaction products the chemical balance is shifted. In contrast to the one from The reactor according to the invention does not serve as a system known from EP 0 504 647 B1 Evaporation and drying system alone, but serves to generate a che mix reaction. The reaction proceeds with the continuous removal of water or other volatile reaction products. For example, the facility particularly advantageous for a transesterification of trimethyl ester.  

In the invention, the liquid is sprayed into a spray tower in countercurrent with dry gas, especially dry air. Spray towers for the production of Granules are state of the art. For drying food or pharma Teutonic products are also known due to the fluidized bed of the product to send warm (hot) air that dehumidifies in the circulation and the circuit again is supplied (DE-C-27 07 065). A similar process is for spray drying of perishable liquid products such as skimmed milk and whey Obtaining milk powder has become known (DE-A-27 43 724). When spraying Troclmen usually evaporate water, while at inventive method, the water sprayed in the spray tower only ver steams. From DE-A-31 21 561 a device for solvent Distillation known, in which the evaporated solvent first through the evaporator and then passed over the condenser of a refrigerator.

The moist gas is exchanged with the evaporator of a chiller brought. This cools the gas; the moisture is condensed and caught. The water collected has a high degree of purity, which the of deionized water. A return to a water network for ver supplying an industrial company is therefore easily possible. The removal of the collected water in a public sewage network is harmless.  

The heat of condensation on the evaporator heats up the refrigerant. The dry, dehumidified air exchanges heat with the condenser and is warmed up again. In other words, the moisture release Heat energy (condensation heat) taken from the moist gas stream is transferred to this Returned to the gas stream.

The dry, slightly warmed air is now returned to the spray tower, a portion being dispensed into the spray tower as the liquid is sprayed and another part forms the counterflow to the sprayed water flow.

Since energy is not lost in the gas cycle, only the energy has to be supplied from the outside Maintenance of the gas cycle as well as for the motor of the chiller and that. Injecting the liquid into the spray tower can be applied. The efficiency the method according to the invention is therefore high.

As already mentioned, the water obtained is of high quality. It shows none Algae or organic substances and is similar in quality to distilled Water.

The process takes place in a closed system, there is no environmental impact instead of.  

Mechanical energy must be available to circulate the gas flow and the refrigerant be turned. This mechanical energy is called the circuits as heat energy supplied so that an excess of heat can be used elsewhere can.

The reactor consists of two basic units, namely a spray tower and a chiller. The spray tower has a spray device in the upper area, which is connected to a liquid reservoir. On the line there is a suitable pump for the spraying device. It goes without saying that one pressure-free nebulization can be carried out. e.g. B. by means of ultrasound or the like. The chiller, which is preferably a compressor chiller, has in the usual way an evaporator and a condenser, which in the Plant according to the invention serves as a heat exchanger for the gas in the circuit is led through the spray tower to evaporate the sprayed liquid and to separate the moisture as condensate. As already mentioned, the Combination of the spray tower with the chiller is an extremely low-energy Ver get driving. The dimensions of the system according to the invention are small, so that it can be easily integrated into existing systems. The cost of that Production of the system according to the invention and its operation are also conceivable low.

The reactor according to the invention will now be described with reference to drawings explained.

Fig. 1 shows extremely schematically a system according to the invention.

FIG. 2 shows the top view of a spray tower of the system according to FIG. 1.

A spray tower 10 has a spray device 12 in the upper region, which is connected to a reservoir 16 via a line 14 . A pump 18 and heat exchanger 20 are arranged in line 14 .

Depending on the area of application, it may be necessary for each reaction participant use individual components.

In the lower area of the spray tower 10 there is a collecting container 22 for dried substances. Above the collecting container 22 , a conical sieve 24 is arranged.

A refrigeration machine, generally designated 30 , has an evaporator 32 in the form of fins and a condenser 34 in the form of a downpipe evaporator. The refrigerator 30 is located in an enclosed space, which is drawn with a dash-dot line and is designated 32a. The refrigeration machine 30 has, in a known manner, a compressor 36 which is driven by a motor 38 . The United steamer 32 is assigned a condensate drain 40 . In the closed space 32 a, in which the heat exchanger 20 is arranged, a radial fan 42 is net angeord, the output of which is connected to a line 44 which leads to a branch point 46 . A branch line 48 is led from the branch point 46 to the ceiling of the spray tower 10 and is connected to four inlet openings 50 . The second branch line 52 leads into the interior of the spray tower 10 in the lower region below the conical strainer 24 .

The system described works as follows: Liquid from the reservoir 16 is sprayed with the aid of the spray device 12 in the spray tower 10 and introduced together with air from the line 48 . The "spray stream" flowing from top to bottom flows in countercurrent to dry air which is introduced via branch line 52 . Their flow is shown with arrows 54 . It is understood that suitable precautions have been taken to achieve intimate and uniform contact of the air stream 54 with the spray stream. The dry air entered via lines 52 and 58 was previously previously in the heat exchanger 34 to a temperature of z. B. heated to 45 ° C. It also contains, for example, a moisture content of 1 g per m ³ . It is loaded with moisture and leaves the spray tower via an upper central opening 56 in the ceiling of the spray tower 10 and reaches the cooling machine 30 via a line 58 . The moist air, which has a moisture content of 24 g per m ³ , for example, is sent in heat exchange via the evaporator 32 of the refrigerator 30 . Here, the air cools down and releases the water by condensation, which is collected in the condensate collector 40 . The cool dry air, which in turn now has a moisture content of 1 g per m ³ , reaches the condenser 34 of the refrigerator 30 . There it is heated by the condensation heat of the refrigerant that is released. The dry air leaves the heat exchanger 34, for example at a temperature of 45 ° C. It gives off part of its heat in the heat exchanger 20 in order to heat the waste water in the line 14 . The heated dry air then returns via line 44 to spray tower 10 in the manner described.

As can be seen, the air flow is conducted in a closed circuit. Temperature control can take place by changing the pressure and by controlling the extent to which the medium is heated. Without the heat exchanger 20 , relatively high temperatures for the dry air could be reached. Heating the medium further facilitates the evaporation of non-volatile reaction products.

The following system components are essential for the reactor:

• a) a spray tower 10 with a spray device 12 in the upper area, which is connected to a storage container 16 ;
• b) a refrigeration machine 30 containing an evaporator 32 and a condenser 34 , a condensate water outlet 40 being associated with the evaporator 32 ;
• c) a pipe system for gas, the inlet end of which is connected to the upper region of the spray tower 10 and the branched outlet end of which is connected both to the upper region and to the lower region of the spray tower 10 , the pipe system being arranged such that the gas in the closed system between the ends are passed at least over the evaporator 32 and then over the condenser 34 of the refrigerator;
• d) a blower 42 in the pipe system for circulating the gas in the circuit, and
• e) a collecting container 22 for solids and / or reaction products in the lower region of the spray tower or a piping system for deriving the reaction products.

When used as a reactor (i.e. not as an evaporation or drying system alone) the necessary activation energy for a chemical is supplied Reaction mechanically via the nozzle and spray systems. The catalytic Effect of suitable components immanent to the system and the con Continuous removal of water or other volatile reaction product used to shift the chemical equilibrium. In this case it’s about creating a chemical reaction like that Transesterification of trimethyl ester.  

Important process steps of the process for drying liquids, in particular organic liquids, are:

• a) the liquid is mixed with dry gas, especially dry air, in a spray tower in the counterflow of dry gas, especially dry air sprayed and evaporated;
• b) the solids of the liquid are applied in the lower area of the spray tower to catch;
• c) the moist gas is withdrawn from the upper part of the spray tower and in Heat exchange with the evaporator of a refrigerator brought, the liquid condensed on the evaporator is collected;
• d) the cooled dry gas is then in heat exchange with the condenser brought to the chiller and warmed and
• e) the heated dry gas is in a closed loop process step a) returned.

This method is for example when drying glycerin on a what content of <0.2% by weight is particularly advantageous.

Claims (3)

1. Reactor for a chemical reaction, with the following parts:

• a) a spray tower ( 10 ) with a spray device ( 12 ) in the upper region, which is connected to a storage container ( 16 ),
• b) one of an evaporator ( 32 ) and a condenser ( 34 ) have the refrigeration machine ( 30 ), the evaporator ( 32 ) being assigned a condensate drain ( 40 ),
• c) a pipe system for gas, the inlet end of which is connected to the upper region of the spray tower ( 10 ) and the branched outlet end of which is connected to both the upper region and the lower region of the spray tower ( 10 ), the line system being arranged in such a way that the Gas in the closed system is passed between the ends at least over the evaporator ( 32 ) and then over the condenser ( 34 ) of the refrigeration machine,
• d) a blower ( 42 ) in the line system for circulating the gas in the circuit and
• e) a collecting container ( 42 ) for solids and / or reaction products in the lower region of the spray tower or a pipeline system for discharging the reaction products.

2. Process for drying liquids, especially organic liquids:

• a) the liquid is sprayed and evaporated together with dry gas, in particular dry air, in a spray tower into the counterflow of dry gas, in particular special dry air,
• b) the solids and / or reaction products of the liquid are collected in the lower region of the spray tower,
• c) the moist gas is drawn off from the upper part of the spray tower and brought into heat exchange with the evaporator of a refrigerator, the liquid condensed on the evaporator being collected,
• d) the cooled dry gas is then brought in heat exchange with the condenser of the refrigerator and heated and
• e) the heated dry gas is fed to the process step a) in a closed circuit.

3. Use of the method according to claim 2 for drying glycerin a water content of less than 0.2% by weight.