DE19527960C2 - Method and device for desorbing adsorbers - Google Patents

Description

The invention relates to a process for the desorption of adsorbers according to the preamble of claim 1 and one for the Device suitable for carrying out the method.

Exhaust gases that are loaded with pollutants become Adsorpti for cleaning ons plants in which the pollutants are extracted. Are the adsorption capacities of the adsorbent exhausted, so it must be regenerated by desorption. This is done by using a current of a desorption gas is applied. As a desorption gas Both steam and hot nitrogen gas are used. After desorption, the desorption gases are released by condensation and / or freezing free of their pollutant load. this happens according to the state of the art in conventional coolers, which are used as a single unit be operated. The operation of these coolers is expensive and requires separate coolant circuits.

DE 29 36 873 C2 describes a method for thermal regeneration Described sorption materials in which the gaseous desorbent in egg in a cycle. The desorbent is used as a condenser formed the primary side of a first heat exchanger cooled, the secondary side as the evaporator of a heat pump with its own refrigerant circuit is. In a second heat exchanger, the secondary side of which acts as a condenser  Heat pump is formed, the desorbent is heated before it, together with the expelled desorbate from the first heat exchanger, the second heat exchanger is supplied. The one occurring in the capacitor Heat is to pass into the heat circuit of the heat pump and so in the second Heat exchangers are used.

DE 43 39 667 A1 describes a process for the sorption of organic compounds from gases using a special sorbent, which consists of particulate activated carbon in an oxidic carrier. Both the Erwär desorption gas as well as the cooling of the De loaded with desorbate sorption gas occurs through heat build-up connected to a heat pump care.

The invention is therefore based on the object, a method and a front create direction with which the separation of the pollutants from the De sorption gas without complex cooling units in a cost-effective way is possible.  

Based on the state considered in the preamble of claim 1 the technology, the task is solved according to the invention with the in Drawing part of claim 1 specified features.

It is now with the method and the device according to the invention possible, the desorption gas, preferably nitrogen, the cryogenic and before preferably liquefied is made available in an economical manner use by using it as a coolant to separate the pollutants becomes.

Advantageous further developments are specified in the subclaims.

The drawings show devices for performing the Invention according to the method in schematic form.

It shows:

Fig. 1: An apparatus for performing the method

Fig. 2: A modification of the device in Fig. 1, in which the desorption gas after the separation of the pollutants of the adsorption system is supplied again.

Fig. 3: An embodiment in which the nitrogen used for the desorption and separation of the pollutants is carried out essentially in a closed circuit.

Fig. 4: A device in which the desorber composing the adsorber, loaded with pollutants is cooled by direct contact without heat exchange surfaces with the cold desorbent.

Fig. 1 shows an adsorber 1 with an inlet line 2 for gas which is loaded with pollutants and an outlet line 3 for the cleaned gas. The adsorber 1 is connected via a line 4 b, 4 c to a heater 5 , which is fed with nitrogen as a desorption gas, which is obtained from a reservoir 6 via line 4 a. The adsorber 1 has inlet nozzle 7 and outlet nozzle 8 for the lines 4 c and 4 d. The line 4 a and 4 d is connected behind the reservoir 6 and behind the adsorber 1 with the heat exchange chambers of a heat exchanger shear 9 , which has an outlet port 15 with a line 10 on the output side for the desorption gas, which frees the gas freed of pollutants to the environment. The heat exchanger 9 has a condensate drain 11 .

In the device according to FIG. 2, the same device features are assigned the same reference symbols. In it the line 10 opens into the input line 2 for the gas to be cleaned.

In the device of FIG. 3 there is a heater 12 and a blower 13 instead of the heater 5 in line 4 b and 4 c in FIGS. 1 and 2 in line 10 , which in this embodiment form line 4 e in the inlet 7 and through a branch, which is shown in dashed lines without reference numerals, opens into the line 10 . A valve 14 is attached to the adsorber 1 .

In Fig. 4, the heat exchanger 9 is shown so that the desorption gas laden with pollutants is brought into direct contact with the fresh desorption gas flowing through line 4 a, the pollutants being separated. From the line 4 b, which is connected via the heater 5 , the blower 13 and the line 4 c to the inlet connection 7 , the line 10 branches off, which by means of a treatment both in the input line 2 and in the Environment can flow. If the line 10 opens into the environment, then it is a device analogous to FIG. 1 if it opens into the input line 2 , it is an embodiment according to FIG. 2.

In operation of the apparatus of FIG. 1, the introduced gas to be cleaned into the adsorber 1. Here, the pollutants are adsorbed on the adsorption mass, which is not shown in the drawing. If the adsorption mass is loaded, the desorption phase is initiated by taking liquid nitrogen from the reservoir 6 , which passes through the heat exchanger 9 via line 4 a, where it evaporates at least partially, and is heated by the heater 5 . The temperature must be set to a temperature which is suitable for removing the adsorbed pollutants from the adsorbent with the nitrogen stream. It can therefore vary depending on the type of pollutants.

The tempered nitrogen passes through the line 4 c and the inlet nozzle 7 in the adsorber 1 , which is closed during the desorption phase for the flow of the gas to be purified and leaves it in the loaded state through the outlet nozzle 8 , from which it is the heat exchanger 9 is supplied.

In the heat exchanger 9 , the removal of the pollutants from the loaded desorption gas takes place, which takes place by condensation and / or freezing. As a heat exchanger in the sense of the invention, any device is to be understood that makes it possible, using the cold content of the desorption agent used for desorption, not yet heated, to cause a separation of the pollutants from the desorption gas. As a desorption gas are usually non-flammable, cryogenic liquefied gases such. B. nitrogen. However, other desorption agents such. B. argon or helium can be used, which bring the thermody namic requirements, so that the heat exchanger 9 is usually operated as a cryo system. However, the cryogenic desorbents, which are used here as coolants, do not have to be used in the liquid state. The desorpti onsgas freed from pollutants can leave the heat exchanger 9 through the line 10 and is supplied to the environment. The condensate leaves the heat exchanger 9 through the condensate drain 11 . In the process according to the invention, as a rule, a plurality of adsorbers are operated in alternating operation and desorbed alternately.

However, the device of FIG. 1 can also be designed with a single-stranded adsorber 1 in the case of discontinuously occurring exhaust air flow. Before this is possible, the charge of the desorption gas corresponds to the required emission limit values when exiting the cryo-system.

In the variant shown in FIG. 2, the desorption gas of the input line 2 is fed back via the line 10 after leaving the heat exchanger 9 . At the residual loading of the desorption gas at the outlet of the heat exchanger 9 , requirements are generally considerably lower than in the embodiment of FIG. 1. The adsorption system must, however, always be designed as a multiple system, ie at least two strands or as a continuously operating system .

Fig. 3 shows an embodiment of the method according to the invention with a return of the depleted desorption gas to the Adsorptionsan location and guidance of the desorption gas in the circuit. If the adsorption mass of the adsorber 1 is loaded, the inlet line 2 and the outlet line 3 are closed for the flow of exhaust gas laden with pollutants and the desorption circuit is activated. For this purpose, line 10 is so far flooded with gaseous nitrogen that sufficient amounts of nitrogen are available for desorption.

In the circuit, the nitrogen is compressed by a blower 13 , which can be replaced by a pump, fed to a heater 12 and introduced through line 10 into the adsorber, in which the desorption takes place. After desorption, the nitrogen leaves through the outlet nozzle 8 and the section of line 4, the adsorber 1 and enters the heat exchanger 9 , which is operated by feeding liquid nitrogen from the reservoir 6 . The nitrogen evaporated during the heat exchange in the heat exchanger 9 is used on the one hand to compensate for nitrogen losses in the circuit just mentioned, in which it is either fed directly to the adsorber 1 or the line 10 or it is transferred via the line shown in broken lines from the line 4 into the Given environment or for further use.

Minor nitrogen losses occur because the circuit system cannot be completely closed due to pressure and temperature changes. Intergas is also required at the start of each desorption process. Conversely, pressure building up in adsorber 1 can be reduced via pressure outlet 14 . The condensate sat leaves the heat exchanger 9 through the condensate drain 11 . The devices of FIG. 3 can be single and multi-stranded and kontinuier Lich working. It is also conceivable that only the adsorption system is multi-strand and that all strands are alternately regenerated ge with a desorption device.

The embodiment in FIG. 4 is essentially similar to the device in FIGS. 1 and 2. In it, liquid nitrogen as desorbent passes via line 4 from the storage container 6 into a heat exchanger 9 , which is designed as a cooler, in which the loaded desorbent passes through Mixing with the fresh desorbent entering from the reservoir 6 is cooled directly. The desorbent can also be obtained from the gas phase of the storage container 6 . A pressure swing adsorption system in connection with a cold gas mixer can also be considered as a nitrogen source.

Due to the direct contact of the loaded desorbent with the fresh desorbent condensate the pollutants and can be separated liquid at the condensate drain 11 .

A partial flow of the gas leaving the heat exchanger 9 is fed via the blower 13 and the heater 5 via the line 4 c to the adsorber 1 in the desorption phase as a desorbent.

The residual flow is either passed outdoors or mixed into the exhaust gas flow in an inlet line 2 . It is also conceivable for the desorption gas leaving the adsorber 1 to be cooled, in part by direct cooling by means of direct gas-phase contact and in part by indirect cooling.

In this embodiment, the adsorption system must be designed as a multiple system, that is to say at least two lines, or as a continuously operating system. If the introduction is in line 2 , the device works as a single system.

In the examples described in FIGS . 1 to 4, the inlet nozzle 7 and outlet nozzle 8 are in an arrangement whose connecting line is perpendicular to the exhaust gas flow. However, it is equally possible to integrate the inlet connection 7 in the output line 3 and the outlet connection 8 in the input line 2 . The flow of the desorbent thus takes place in the opposite direction to the gas to be cleaned.

Excess gaseous nitrogen can be produced in all variants. The If it is subtracted from the adsorbers, it is for other purposes usable.

For example, he can use other methods for inerting purposes be applied. With the method according to the invention it is now possible to the nitrogen used for desorption or other high quality Desorption to use suitable gases particularly economically. A Auskon densify or freeze out the pollutants from the loaded desorption Gas can be particularly affected by the deep coldness of the liquid gas done effectively.

Claims (16)

1. A process for the desorption of adsorbers ( 1 ), in which tempered, gaseous desorbent is passed over the adsorbent material, characterized in that the gaseous desorbent is obtained by evaporation from a cryogenic liquid desorbent supply, heated by heating and then the adsorber ( 1 ) is supplied for desorption and that the gaseous desorbent loaded with pollutants is fed from the adsorbers ( 1 ) to a heat exchanger ( 9 ) to which the desorbent is fed from the cryogenic liquid desorbent supply as a coolant. 2. The method according to claim 1, characterized in that the heat exchanger ( 9 ) leaving gaseous desorbent is supplied to the adsorbers ( 1 ). 3. The method according to claim 2, characterized, that the gaseous desorbent is conducted in a cycle. 4. The method according to any one of claims 1 or 2, characterized in that the gaseous desorbent leaving the heat exchanger ( 9 ) is introduced into the laden gas stream before entering the adsorber. 5. The method according to claim 3, characterized in that the pressure arising in the adsorber relaxed by a valve ( 14 ) and losses of gaseous desorbent from the supply of liquid desorbent ( 6 ) are compensated. 6. The method according to any one of claims 1 to 5, characterized, that the gaseous desorbent is a continuously operating Adsorption system is supplied. 7. The method according to any one of claims 1 to 5, characterized, that the gaseous desorbent has at least two adsorbers is supplied, which are applied alternately. 8. The method according to any one of claims 1 to 7, characterized, that nitrogen is used as the desorbent. 9. The method according to any one of claims 1 to 8, characterized in that the heat exchanger ( 9 ) is operated as a cryo system. 10. The device for carrying out the method according to one of claims 1 to 9, with at least one adsorber ( 1 ), at least one inlet line ( 2 ) and at least one outlet line ( 3 ) for the gas to be cleaned, at least one inlet nozzle ( 7 ) and at least An outlet connection ( 8 ) for gaseous desorbent, characterized in that the adsorber ( 1 ) is connected via the outlet connection ( 8 ) by means of a line ( 4 d, 4 a) via a heat exchanger ( 9 ) to a storage container ( 6 ) for the desorbent is. 11. The device according to claim 10, characterized in that the heat exchanger ( 9 ) has an outlet connection ( 15 ) for the gaseous desorbent, which is connected to a line ( 10 ) for returning the cleaned desorbent into the adsorber ( 1 ). 12. The apparatus of claim 10 or 11, characterized in that a heater ( 5 ) is arranged in the line ( 4 b, 4 c) between the heat exchanger ( 9 ) and the inlet connection ( 7 ) for evaporated desorbent from the reservoir ( 6 ) is. 13. The apparatus according to claim 11, characterized in that in the line ( 10 ) a compressor ( 13 ) and a heater ( 12 ) are arranged, which form a closed system with the line ( 4 d) and the heat exchanger ( 9 ). 14. The device according to one of claims 11 to 13, characterized in that the supply of liquid desorbent via the heat exchanger ( 9 ) and the line ( 4 b, 4 c, 4 e) with the inlet connection ( 7 ) and / or the line ( 10 ) is connected. 15. The device according to one of claims 10 to 14, characterized in that the adsorber ( 1 ) has a valve ( 14 ) for outflowing excess desorbent. 16. The device according to one of claims 10 to 15, characterized in that the heat exchanger ( 9 ) is a cryo-system.