DE202023103234U1 - coating device - Google Patents

Abstract

Coating device (1) for producing catalytically coated flow-through monoliths (2) for exhaust gas catalysis, the flow-through monoliths (2) having two end faces, a lateral surface of length L and flow-through channels which ensure gas flow from one end face to the other, having:
a first unit (3) for accommodating the flow monolith (2) in a vertical orientation;
a second unit (4) for applying a coating suspension (7) to the upper face of the flow monolith (2); and
a third unit (5) for applying a coating suspension (7`) through the lower face of the flow-through monolith; and
a fourth unit (6) for sucking off excess coating suspension downwards from the flow channels of the flow monolith,
characterized in that
the coating device (1) is designed in such a way that the third unit (5) comes into contact with the coating suspension (7`) over less than 20% of the length L of the flow-through monolith and so much coating suspension (7) is applied by the second unit (4), that with a subsequent suction pulse through the fourth unit (6), the entire flow channels over the entire length L come into contact with the coating suspension (7, 7').

Description

The present invention is directed to a coating apparatus for producing catalytically coated flow-through monoliths for automotive exhaust treatment.

The exhaust gas from internal combustion engines in motor vehicles, for example, typically contains the pollutant gases carbon monoxide (CO) and hydrocarbons (HC), nitrogen oxides (NO _x ) and possibly sulfur oxides (SO _x ), as well as particles, which mainly consist of soot residues and possibly adhering organic agglomerates. These are referred to as primary emissions. CO, HC and particulates are products of the incomplete combustion of fuel in the engine combustion chamber. Nitrogen oxides are formed in the cylinder from nitrogen and oxygen in the intake air when the local combustion temperatures exceed 1400°C. Sulfur oxides result from the combustion of organic sulfur compounds, which are always present in small amounts in non-synthetic fuels. A large number of catalytic exhaust gas purification technologies have been developed to remove these emissions, which are harmful to the environment and health, from motor vehicle exhaust gases. and a catalytically active coating applied thereto and/or therein. The catalytic converter promotes the chemical reaction of various exhaust gas components to form harmless products such as carbon dioxide and water.

The flow-through or wall-flow monoliths just described are accordingly also referred to as catalyst carriers, carriers or also as substrate monoliths, since they carry the catalytically active coating on their surface or in the pores of the wall forming this surface. The catalytically active coating is often applied to the catalyst support in a so-called coating process in the form of a coating suspension (washcoat).

An important aspect of the production of these heterogeneous catalysts is the precise coating of substrates with a washcoat, especially with regard to e.g of layered or zoned coating designs - coating quality for short.

There are two basic groups of production processes for producing these catalytically active catalyst bodies. What both groups of processes have in common is that the coating suspension is introduced into the substrate monolith by applying a pressure difference, ie by the presence of different pressures on the two end faces of the latter. The coating suspension moves in the channels of the substrate monolith in the direction of the lower pressure.

The first group also works with an excess of coating suspension, which is brought into the filter substrate by a pressure difference and where the excess coating suspension is removed from the channels again by a subsequent pressure difference reversal. In the present case, excess coating suspension means that the amount of suspension used for the coating process is significantly above the value required for the desired loading of the filter with catalytically active material. The excess coating suspension must be removed from the substrate monolith by appropriate measures, e.g. In the context of the invention, a pressure difference reversal is understood to mean that a pressure difference present at the respective ends of the wall-flow filter is reversed, and therefore its sign changes. This pressure difference reversal therefore acts in the opposite direction to the original coating direction.

The second group works without a pressure difference reversal and a washcoat excess, i.e. the entire amount of suspension intended and provided for the coating essentially remains, i.e. > 97% of the solids content of the coating suspension, in the substrate monolith.

In the EP2533901 B1 a coating technique for substrate monoliths is presented, which makes it possible to achieve a particularly precise, zoned coating. A special coating system is used to pump an excess amount of coating suspension into an upright substrate monolith from below. The excess coating suspension in the channels is then sucked off downwards. It is particularly important that a precisely specified amount of coating medium remains on the substrate monolith. Since the coating suspensions often contain expensive precious metals such as platinum, palladium and/or rhodium, too much suspension would mean wasting expensive precious metal. Too little, on the other hand, can result in the catalyst no longer having the necessary catalytic activity.

The EP2415522B1 also shows a coating process in which a coating medium is applied to a substrate from above - so-called top-down coating. The coating medium is fed into a cavity with a plunger via a supply line and then applied to the substrate via openings in a base plate - similar to a shower head. The coating suspension is then sucked into the substrate by applying a negative pressure on the other side of the substrate monolith.

The processes just discussed are all carried out with specially designed coating devices or coating stations. There is therefore still a need for optimized coating devices for the production of catalytically active substrate monoliths, in particular flow-through monoliths, which set new standards in the requirement triangle of cycle time, robustness and coating quality.

These and other tasks familiar to a person skilled in the art are solved by a coating station according to the features of claim 1 in question. Claim 2 - x is directed to preferred embodiments of the coating device according to the invention.

• eine erste Einheit (3) zur Aufnahme des Durchflussmonolithen (2) in senkrechter Ausrichtung;
• eine zweite Einheit (4) zur Applikation einer Beschichtungssuspension (7) auf die obere Stirnfläche des Durchflussmonolithen (2); und
• eine dritte Einheit (5) zur Applikation einer Beschichtungssuspension (7`) durch die untere Stirnfläche des Durchflussmonolithen; und
• eine vierte Einheit (6) zum Absaugen überschüssiger Beschichtungssuspension aus den Durchflusskanälen des Durchflussmonolithen nach unten, wobei
• die Beschichtungsvorrichtung (1) so ausgebildet ist, dass die dritte Einheit (5) weniger als 20% der Länge L des Durchflussmonolithen mit der Beschichtungssuspension (7`) kontaktiert und durch die zweite Einheit (4) so viel Beschichtungssuspension (7) appliziert wird, dass bei einem folgenden Saugimpuls durch die vierte Einheit (6) die gesamten Durchflusskanäle auf der gesamten Länge L mit Beschichtungssuspension (7, 7`) in Kontakt kommen, gelangt man recht einfach, dafür aber nicht minder vorteilhaft zur Lösung der gestellten Aufgabe. Mit der vorliegenden Beschichtungsvorrichtung ist es möglich insbesondere im Hinblick auf die Beschichtungsmengen, welche nach der Beschichtung auf dem Durchflussmonolithen verbleibt, einheitlichere Werte über die gesamte Beschichtungskampagne zu erhalten. Gleichfalls lässt sich die Zyklenzeit für die Beschichtung weiter senken, da verglichen mit den Stand der Technik kein komplettes Hereinpumpen eines großen Überschusses an Beschichtungssuspension in den Durchflussmonolithen von Nöten ist und andererseits keine zwei getrennten Beschichtungsvorgänge ggf. mit einem Drehen des Durchflussmonolithen erfolgen müssen. Gleichfalls erhält man eine einheitlichere Beschichtungslänge verglichen mit Ausführungen, bei denen ausschließlich über die gesamte Länge der Durchflussmonolithen beschichtet werden soll. Dies war vor dem Hintergrund des bekannten Standes der Technik mitnichten zu erwarten gewesen.

By using a coating device (1) for producing catalytically coated flow-through monoliths (2) for exhaust gas catalysis, the flow-through monoliths (2) having two end faces, a lateral surface of length L and flow channels which ensure gas flow from one end face to the other , indicating, having:

• a first unit (3) for accommodating the flow monolith (2) in a vertical orientation;
• a second unit (4) for applying a coating suspension (7) to the upper face of the flow monolith (2); and
• a third unit (5) for applying a coating suspension (7`) through the lower face of the flow-through monolith; and
• a fourth unit (6) for sucking excess coating suspension downwards from the flow channels of the flow monolith, wherein
• the coating device (1) is designed in such a way that the third unit (5) comes into contact with the coating suspension (7`) over less than 20% of the length L of the flow-through monolith and so much coating suspension (7) is applied by the second unit (4), that during a subsequent suction impulse through the fourth unit (6) the entire flow channels come into contact with coating suspension (7, 7`) over the entire length L, the solution to the task set is quite easy, but no less advantageous. With the present coating device it is possible to obtain more uniform values over the entire coating campaign, in particular with regard to the coating quantities which remain on the flow-through monolith after the coating. Likewise, the cycle time for the coating can be reduced further, since compared to the prior art, it is not necessary to completely pump in a large excess of coating suspension in the flow-through monolith and, on the other hand, no two separate coating processes, possibly with a rotation of the flow-through monolith, have to be carried out. Likewise, a more uniform coating length is obtained compared to designs in which coating should only be carried out over the entire length of the flow-through monolith. Against the background of the known state of the art, this was by no means to be expected.

Flow-through monoliths are catalyst carriers customary in the prior art, which are made of metal (e.g. corrugated carrier, WO17153239A1 , WO16057285A1 , WO15121910A1 and literature cited therein) or ceramic materials. Refractory ceramics such as corderite, silicon carbide or aluminum titanate etc. are preferably used. The number of channels per area is characterized by the cell density, which is usually between 200 and 900 cells per square inch (cpsi). The wall thickness of the canal walls is between 0.5 - 0.05 mm for ceramics. More can be found in the literature ( Catalytic Air Pollution Control, Heck et al.. John Wiley & Sons, Inc. 2009, p. 176ff .).

In the present case, the catalytically active material or coating is applied to the channels of the flow-through monolith in the form of a suspension by means of the coating device according to the invention. The coating suspension is usually a suspension of insoluble oxidic components and possibly soluble metal compounds, e.g. precious metal compounds in water. The coating suspension has a desired rheology, which can be adjusted in a targeted manner to meet requirements by adding surface-active substances, thickeners or acids/bases, etc. The expert knows how to proceed here. The coated flow-through monolith is then dried and, if necessary, tempered and/or calcined. The finished flow monolith is then installed in the appropriate exhaust gas system.

The catalytically active coatings (7, 7') can be selected from the group consisting of a three-way catalytic converter, SCR catalytic converter, ammonia oxidation catalytic converter, nitrogen oxide storage catalytic converter, oxidation catalytic converter and hydrocarbon storage. Combinations are also possible. The catalytically active coatings used can be located in the pores and/or on the surfaces of the channel walls of the flow-through monolith. It is possible to coat the flow-through monolith with two different coating suspensions using the coating device according to the invention. With the device according to the invention, however, the flow-through monolith can be coated particularly well over its entire length L with a uniform coating suspension.

The preparation of the coating suspensions for the intended purpose are well known to those skilled in the art. So-called three-way catalytic converters, for example, are used to reduce exhaust gas in engines that burn stoichiometrically. Three-way catalysts (TWCs) are well known to those skilled in the art and have been required by law since the 1980s. The actual catalyst mass here mostly consists of a high-surface metal compound, in particular an oxidic carrier material, on which the catalytically active components are deposited in extremely fine distribution. The noble metals of the platinum group, platinum, palladium and/or rhodium are particularly suitable as catalytically active components for the purification of stoichiometrically composed exhaust gases. Aluminum oxide, silicon dioxide, titanium oxide, zirconium oxide, cerium oxide and their mixed oxides and zeolites, for example, are suitable as carrier material. So-called active aluminum oxides with a specific surface area (BET surface area measured according to DIN 66132—latest version on the filing date) of more than 10 m ² /g are preferably used. To improve dynamic conversion, three-way catalytic converters also contain oxygen-storing components. These include cerium/zirconium mixed oxides, which may be provided with lanthanum oxide, praseodymium oxide and/or yttrium oxide. Zoned and multi-layer systems with three-way activity are now also known (US8557204; US8394348 ). For the area of lean-burning diesel and direct-injection petrol engines, reference is made to the relevant literature ( Catalytic Air Pollution Control, Heck et al.. John Wiley & Sons, Inc. 2009, pp. 238ff .).

In a preferred embodiment, the coating device (1) according to the invention has a second unit (4) with which the coating suspension (7`) can be applied to the upper face of the flow-through monolith (2), the second unit (4) having a shower head , through which the coating suspension is applied. Other application devices are also conceivable (EP application EP22181902.2).

In a further preferred embodiment, the coating device (1) has a container (8) which helps to prevent the coating suspension (7`) from running down the outer casing of the flow-through monolith (e.g DE202022000455U1 ). The container (8) can be attached to the second unit (4). However, it is also possible to attach the container (8) to the first unit (3). The person skilled in the art knows how to accomplish this with equipment.

The coating device according to the invention is part of a coating station in which the flow-through monoliths to be coated are brought to the coating device, e.g. via belt conveyor systems. Once there, a first weighing step can be carried out in order to be able to determine the gross weight of the flow monolith. The flow-through monoliths are then accommodated in the first unit. The coating suspension is applied by the coating device. The coating device, which is controlled via a digital process control, can be designed in such a way that the coating is first applied and sucked off by the third and fourth unit, before the coating suspension is applied and sucked through by the second and fourth unit. However, according to the invention, the coating device is set up in such a way that only one suction pulse is required. For this purpose, the control device controls the coating device in such a way that the coating is first carried out by the third unit from below. After that or at the same time, the coating suspension is applied from above by the second unit. The following suction impulse through the fourth unit then transports both excess coating suspension out of the channels of the flow-through monolith and the coating suspension applied from above into the flow-through monolith. The result is a complete, preferably homogeneous coating of the channels of the flow monolith with an extremely good accuracy in the wet absorption, which can then be determined by a further weighing step.

Examples of a first unit can be found in the following documents: WO2011098450A1 ; EP3887063A1 ; EP3865211A1 ; EP3285936A1

Examples of a second unit can be found in the following documents: US9227184B2 ; EP1900442B1 ; JP5925101B ; JP2015039672A ;

Examples of a third unit can be found in the following publications: DE102017122254A1 ; EP3122458B1 ; US2021170386 aa

Examples of a fourth unit can be found in the following writings: EP3386642A1 ; CN114289253A ; CN112756190A ; EP3865211A1 ; CN208839891U ; EP3285936A1 ; WO16143811A1 ; JP2014233713A2

1

Beschichtungsvorrichtung

2

Durchflussmonolith

3

erste Einheit zur Aufnahme des Durchflussmonolithen

4

zweite Einheit zur Applikation der Beschichtungssuspension von oben

5

dritte Einheit zur Applikation der Beschichtungssuspension von unten

6

vierte Einheit zum Absaugen der Beschichtungssuspension

7, 7'

Beschichtungssuspension

8

Container

numbering 1 :

1

coating device

2

flow monolith

3

first unit to accommodate the flow monolith

4

second unit for application of the coating suspension from above

5

third unit for applying the coating suspension from below

6

fourth unit for suction of the coating suspension

7, 7'

coating suspension

8th

Container

QUOTES INCLUDED IN DESCRIPTION

This list of documents cited by the applicant was generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Patent Literature Cited

• EP 2533901 B1 [0008]
• EP 2415522 B1 [0009]
• WO 17153239 A1 [0013]
• WO 16057285 A1 [0013]
• WO 15121910 A1 [0013]
• US8394348 [0016]
• DE 202022000455 U1 [0018]
• WO 2011098450 A1 [0020]
• EP 3887063 A1 [0020]
• EP 3865211 A1 [0020, 0023]
• EP 3285936 A1 [0020, 0023]
• US 9227184 B2 [0021]
• EP 1900442 B1 [0021]
• JP 5925101B [0021]
• JP 2015039672 A [0021]
• DE 102017122254 A1 [0022]
• EP 3122458 B1 [0022]
• US2021170386 [0022]
• EP 3386642 A1 [0023]
• CN 114289253A [0023]
• CN 112756190A [0023]
• CN 208839891 U [0023]
• WO 16143811 A1
• JP 2014233713 A2 [0023]

Non-patent Literature Cited

• Catalytic Air Pollution Control, Heck et al.. John Wiley & Sons, Inc. 2009, p. 176ff [0013]
• Catalytic Air Pollution Control, Heck et al.. John Wiley & Sons, Inc. 2009, p. 238ff [0016]

Claims (3)

Coating device (1) for producing catalytically coated flow-through monoliths (2) for exhaust gas catalysis, the flow-through monoliths (2) having two end faces, a lateral surface of length L and flow-through channels which ensure gas flow from one end face to the other, having: a first Unit (3) for accommodating the flow monolith (2) in a vertical orientation; a second unit (4) for applying a coating suspension (7) to the upper face of the flow monolith (2); and a third unit (5) for applying a coating suspension (7`) through the lower face of the flow-through monolith; and a fourth unit (6) for sucking off excess coating suspension downwards from the flow channels of the flow-through monolith, characterized in that the coating device (1) is designed in such a way that the third unit (5) covers less than 20% of the length L of the flow-through monolith with the Coating suspension (7`) is contacted and so much coating suspension (7) is applied by the second unit (4) that with a subsequent suction pulse through the fourth unit (6) the entire flow channels over the entire length L are filled with coating suspension (7, 7` ) get in touch. Coating device according to claim 1 , characterized in that the second unit (4) has a shower head through which the coating suspension (6) is applied. Coating device according to claim 1 , characterized in that it has a container (8) which prevents the coating suspension (7) from running down the outer casing of the flow-through monolith.