DE102008003375A1 - Catalytic active coating of ceramic honeycomb bodies, metal surfaces and other catalyst carriers for exhaust air purifications and burner installations - Google Patents

Abstract

It is an invention in the form of the device for the catalytic coating of surfaces and honeycombs described by a noble metal powder precoating higher life, lower sensitivity, higher temperature range and longer life and in the form of the method for use in flammeless catalytic condensing boilers, in the catalytic post-purification of thermal exhaust air purification systems and as coating of fuel cell membranes ...

Description

The Patent application describes as an active coating device and as a method, a method of using this active coating. The method and the device are described.

task The invention is the improvement of exhaust air purification and combustion in 2 stages by the realization of a flameless catalytic gasification with intermediate cooling and flameless catalytic combustion the gasification gases on catalytic surfaces with the The aim of pollutant reduction of the exhaust gases and the resulting reduction in consumption while minimizing the pollutant production of nitrogen oxides and combustible residual gases, such as CO and hydrocarbons.

Of the basic thought assumes that it is possible is essential, the properties of the exhaust air purification and combustion to improve, if it becomes possible, the oxidation reactions of the fuel catalytically at lower temperatures to stable catalytic surfaces evenly over large temperature ranges and completely up to to run extremely low residual levels.

In the patent application PA 198 00 420.6 "Compact system for catalytic exhaust air purification on furnaces" is described a device for the catalytic purification of hydrocarbon-containing exhaust air.

there become catalytic honeycomb body in a sheet metal housing by the preheating with electric heating rods in the Location offset, conducted on, hydrocarbon-containing air the surface of the honeycomb body to the reaction bringing, causing the hydrocarbons to water vapor and carbon dioxide oxidize and clean the air.

there becomes an innovative catalyst from the components cobalt, cerium and lanthanum, which has high activity through crystal formation reached. This allows the reduction of platinum content essential and leads to a cleaning effect in the temperature range between 300 and 600 ° C.

It It has now been found that this invention has a number possesses disadvantages that are overcome by a new technique shall be. These disadvantages are the loss of activity even at low excess temperatures through the wash-coat, only tolerates a maximum of 600 ° C, the lower Adhesion of the catalytic layer on the surface, the at higher flow rates it dissolves and the arrangement of the device, which only allows cold exhaust gases initiate, but not suitable, a Nachschalteinrichtung to design for burner systems.

Burners, which are also used for thermal exhaust air purification systems, are also suitable for the downstream connection of catalytic systems with reduced burner output. But they have to do that, unlike PA 198 00 420.6 moreover, have the property that the catalytic layer must have much higher temperatures, flow rates and mechanical resistance. That's with the coating, according to the PA 198 00 420.6 not possible.

Alone the surface enlargement by the necessary in the catalytic technique surface enlargement by molecularly fine alumina, the Condea, is a temperature limit where.

These Alumina component loses its structure at 600 ° C, causing the overlying catalytic layer replaces. The same happens at higher flow rates and the application of entrained fine particles.

These disadvantages also make the catalytic coatings of the cobalt, cerium and lanthanum catalysts in this coating form unsuitable. Although they have comparable catalytic properties as platinum, in the form as in the Patent Application 198 00 420.6 described, but they are just like platinum in the form not suitable for the catalytic reaction in thermal exhaust air purification plants.

Surprisingly It has now been found that there is a way that all eliminated these disadvantages. The key in the invention lies in a new coating technology and in a resulting new use of these newly coated catalysts in the Exhaust air cleaning and burner technology.

Completely surprising Precoats with precious metal powder with a grain size are suitable less than 10 μm to the subsequent coating The crystal of lanthanum, cerium and cobalt firm hold, temperature stability and sufficient surface for the catalytic Reaction that starts at low temperatures to give (Figure 1). It has proved to be particularly advantageous if the metal powder precoat with sugar solution.

So far It was not known that the stainless steel powder metal alloys an ideal, abrasion-resistant substrate for the catalytic Coating forms (picture 2). The field of application of the Catalyst beyond 600 ° C up to 1000 ° C extended.

The previously necessary, temperature-sensitive surface enhancer of molecular alumina (Condea) become complete replaced and are no longer necessary.

Also blowing out with compressed air (> 50 m / s) did not reduce the activity of the catalyst. Temperature peaks of 1100 ° C were from the metal coated Catalyst without measurable loss of activity coped. (Fig. 3 / diagram 2).

Recurrent Continuous loads of 550 ° C are without loss of performance tolerated by the new catalyst.

One complete loss of catalyst activity was only at temperatures> 1200 ° C observed. Thus, the so inventive Coatings in the mold also for the downstream thermal Exhaust air purification systems suitable. In the form they lead to a fuel saving by lowering the burner temperature from 50-70%.

One Example of the device according to the invention the coating of honeycomb body. The honeycomb body are dried by heating to 200 ° C. After cooling They are in a suspension of sugar solution with precious metal powder dipped with a grain size <10 microns, with a Honeycomb with the size of 150 mm × 150 mm × 150 mm, a metal powder amount of 500 to 1,000 g takes up, d. H. per liter of catalyst volume are 150 to 300 g Metal powder on the surface of the honeycomb body and their channels are absorbed evenly.

The Honeycombs are then heated in the oven by rapid heating to 800 to 1000 ° C within 1-3 hours with calcined the suspension into a solid coating. After cooling of the honeycomb body, these are turned into a watery Bath of lanthanum-cerium cobaltite and oxalic acid bathed.

there From the lanthanum-cerium-cobaltite crystal powder is added a lot of 37-185 g / honeycomb body, ie 10 to 50 g / liter over applied the aqueous solution. The soaked Honeycomb body is then at 500-800 ° C burned and is then ready to use.

The The following figures show the invention Method and the device according to the invention on the pictures of the coating and the effects of the catalysts in the conversion of hydrocarbons in the gases to CO2 and H2O.

1 shows the image of the double-coated catalyst 1 , The inhomogeneous surface of the stainless steel coating is clear 2 to see. The second coating with lanthanum-cerium cobaltite crystals 3 can be recognized by the inhomogeneous surface. The coating takes place in a honeycomb structure with a web spacing 4 , also called pitch.

For a more detailed explanation of the preparation of the coating shows the 2 an enlargement of the surface of the honeycomb body with the same elements, wherein the surface is coated and fired only with the metal powder. The reference numerals are, since I act around the same body, drawn analogously. The second step of the coating is the application of the lanthanum cerium cobaltite powder in aqueous solution with the binder oxalic acid.

The result of the 2nd coating is in the 3 which shows the finished catalyst body in operation. Due to the hydrocarbon fraction in the gas, which is passed through this body, arises in the oxidation reaction, a temperature increase without a flame, which is visible at 900 ° C as lights from the catalyst body.

4 shows the operation of the catalytic coating. T1 denotes the inlet temperature of the hydrocarbon-air mixture.

With T2 is the temperature designated at the catalyst inlet established. With T3, the temperature is further back in the honeycomb body designated. This is therefore less, as the heating of the ceramic Part of the heat energy removes and thus the temperature lowers. With T4 the room temperature is designated, the below the lowest diagram line lies. With T5 is the temperature scale and T6 denotes the time scale.

5 shows another scale from a technical application. Again, the terms are the same as in the 4 , T1 denotes the inlet temperature, T2 the temperature at the catalyst inlet, T3 the temperature further back in the catalytic converter, and T4 the temperature at the end of the technical device. T5 is the temperature scale and T6 is the time scale.

From the 4 and 5 It can be seen that the device according to the invention a substantial extended scope. Temperature fluctuations up to over 1000 ° C and speeds of the gas at the catalytic surface to 5 m / s are tolerated without loss of activity and the catalytic coating works in the same manner as before.

The Effect of heat dissipation of the metal undercoat has an extremely stabilizing effect on the catalytic activity out. The same active ingredients as platinum and lanthanum cerium cobaltite tolerate without this inventive coating no Such temperatures, but lower at 400 ° C Temperatures more or equal attacked, as in the invention Coating at the higher temperatures.

The Method is described by the description of 3 applications this coated honeycomb body described.

One Condensing boiler has in a flammeless catalytic combustion chamber one behind the other the igniter, the gasification catalyst layer in the form of metal honeycomb, ceramic honeycomb and / or metal mesh, the heat exchanger 1, the mixing chamber for the gasification gases and the secondary air and the combustion catalyst layer with subsequent heat exchangers.

A Flame is avoided. The volume of the condensing boiler is reduced by the omission of the flame. The achieved emission values of these catalytic combustion are only at a fraction of the flame combustion, d. H. the combustion is extremely clean.

One Another embodiment of the method is the catalytic Post-cleaning in thermal exhaust air purification process. By the Arrangement of a honeycomb catalyst layer after the thermal burner Exhaust air purification can do this at a fraction of the burner output Shut down as the layer reaches an average temperature of 350 ° C is fully active. A mean temperature of 450 ° C-600 ° C is optimal.

The retrofitted in the thermal burner plants catalytically Coated honeycombs are introduced as segments and in the corners of the honeycomb body braced by screws. The honeycombs cut to the round cross-section have outside a metal frame, which by a screw connection the frame clamped flush with the outer tube. This outer frame transmits the bracket over the attached in the corners of the honeycomb Screw on the inner honeycomb.

One third example of use of the method for use the coating is the application to a fuel cell. The on the fuel cell membrane applied metal powder layer takes over in addition to adhesion and surface enlargement In addition, the task of power dissipation.

The Lanthanum-cerium-cobaltite layer does not replace the platinum coating only complete, but also allows one much longer service life. This lifetime factor is 5-100, depending on the application and temperature range, d. H. the activity of the shift is longer by a factor.

Specific Application examples for the device of the coating and the methods of use in the field of burner technology, the retrofitting of thermal exhaust air cleaning and the Fuel cell to illustrate the invention in more detail.

In a first application example, a condensing boiler with a capacity of 18 kW of thermal power has a ball distribution nozzle, which uses compressed air to supply 1.5 kg of fuel oil through a notched rotating ball uniformly into an air volume of 12 m ³ / h, ie a lambda of 0.5 distributed and converted in a ceramic honeycomb of the image 1 to a fuel gas. In this case, no flame is formed, but the reaction takes place according to Figure 3 flammeless catalytically on the surface according to the invention.

Of the subsequent heat exchanger is traversed with water and gives the heat first in the hot water tank and the residual heat in the heating circuit from. By the heat emission in the heat exchanger, the gasification gases cool to temperatures below 300 ° C from. The heat exchanger is because of the CO corrosion of stainless steel.

In the subsequent mixing chamber with a tangential blowing of the secondary air preheated in the heat exchanger at the end of the boiler and the subsequent mixer, a venturi mixer from Sulzer, a gasification gas-air mixture is produced by the secondary 12 m ³ / h of lambda close to 1.0.

Thereby can the exhaust gases through a three-way catalyst, as in the vehicle, both in terms of nitrogen oxides and the Air are brought to similar low levels.

In this case, the sulfur-resistant mode of action of the catalyst according to the invention relative to the conventional autocatalyst has a decisively positive effect. The catalyst brings the Temperature of the combustion mixture to the optimum temperature of 800 ° C, which allows in the subsequent heat exchangers in the heating of the heating circuit and the hot water at peak demand.

In a second application example is a retrofit a thermal exhaust air purification by the invention Honeycomb body described. For this purpose, the thermal exhaust air purification of the operating temperature of 900 ° C to the operating temperature of 500 ° C by reduced addition of the fuel, natural gas or fuel oil, reduced. The round combustion chamber receives an intermediate chamber for the catalytic honeycomb bodies.

These consists of a honeycomb retaining ring with a ring spacing of 155 mm, the 4 honeycomb pieces, like the 4 quarters of a whole cake be used. The honeycomb pieces are made of a porous honeycomb ceramic honeycomb 150 × 150 × 150 mm with the pitch of 4 mm produced.

These are tailored to the geometry of the quarter circle, coated according to the invention and in the corners of the honeycomb body by threaded rods with both sides Washers and nuts bolted together. This will the holding force of the ring on the pipe over the tension of the Transfer ceramic pieces to each other up to the innermost honeycomb body and this can not be blown out of the bandage because he over the outer ring and the threaded rods is held.

The Effect of the catalyst disk is shown in Figure 3. To the To safely maintain limits, a 2 honeycomb layer is placed. It is in the catalyst chamber with a second outer ring attached. The assembly of the two layers takes place in the catalyst chamber from the two sides of the tube, which subsequently flanged to the combustion chamber. This is at the end of the combustion chamber a radiation disk with baffles arranged to absorb the radiation completely prevent the flame on the catalyst and thus to ensure a long service life of the catalyst layers.

In A third application example is the use of the invention Use of the catalyst coating in a fuel cell described. Here is the coating according to the invention of particularly excellent effect, as it also the current dissipation extreme on the membranes by the metal powder surface improved.

A Aluminum fiber fuel cell membrane with the invention Coating on both sides and in a fuel cell for the fuels hydrogen, methane, methanol, ethanol and vaporous hydrocarbons on one side and air used on the other side. Here is the potential the coating for the conversion or gasification of Hydrocarbons with the coating according to the invention additional advantage.

The Membrane is in size 150 × 150 mm made, coated and in the frame with the appropriate evenly provided distributed gas ducts. This will be the inputs each alternatively connected to the fuel side and the air side. The wiring of the fuel plates takes place in the same way as with conventional fuel cells.

The Effect of the coating according to the invention consists in a significantly improved efficiency due to the reduced electrical resistances of the catalytic coating in the derivative and in the significantly increased life.

The Coating does not require platinum, even with fuel cells, originally intended for platinum coating are. The coating behaves the coating of Platinum equivalent with less resistance to contraction, less poisoning sensitivity and much longer life as a result of the higher Stability of the crystals of the invention Coating against the platinum flake coating.

QUOTES INCLUDE IN THE DESCRIPTION

This list The documents listed by the applicant have been automated generated and is solely for better information recorded by the reader. The list is not part of the German Patent or utility model application. The DPMA takes over no liability for any errors or omissions.

Cited patent literature

• - PA 19800420 [0004, 0008, 0008, 0011]

Claims (7)

Apparatus for the catalytic coating of honeycomb bodies and surfaces which can be used for the oxidation reactions, characterized in that these surfaces are precoated with a layer of fine noble metal powder and subsequently post-coated with the catalytically active substance. Device according to claim 1, characterized in that that the coating with the noble metal powder with a Powder of grain size <10 μm with a sugar solution takes place and the bodies subsequently at 800-1000 ° C be burned. Device according to claim 1, characterized in that that pre-coated with metal powder and fired Surface then with an aqueous Solution of lanthanum-cerium cobaltite crystal powder and oxalic acid is recoated. Process for the catalytic purification of exhaust gases from the thermal exhaust air purification, characterized in that a Honeycomb chamber or a honeycomb ring is used, the catalytic is coated. Method of using the device or coating, characterized in that the honeycomb body thus produced from metal powder pre-coating and catalytic post-coating used as a component after a thermal exhaust air purification become. Method of using the device or coating, characterized in that the catalysts in 2 layers as gasification layer with subsequent heat exchanger, Secondary injection, combustion layer and subsequent Heat exchangers are used. Method of using the device or coating, characterized in that the inventive layer on the separating membrane of fuel cells are applied and there as Hydrogen or methanol reaction layer and as an oxygen layer be used.