JP2007144424A - Catalyst production method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To prevent adhesion of slurry on the side of a carrier by accurately controlling the position of a slurry surface when carrying catalyst components on the carrier. <P>SOLUTION: When a liquid material containing catalytically active components is introduced into a honeycomb monolith carrier from the bottom end of the carrier, surface level detection in the top part of the carrier is carried out by using an image processing sensor. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a method for producing a catalyst. More specifically, the present invention relates to a method for manufacturing a catalyst for controlling the liquid level of the upper end surface of a honeycomb monolith support using an image processing sensor, and more particularly to a method for manufacturing a catalyst for exhaust gas purification.

  When a catalytically active component is supported on a honeycomb monolith support, even if an expensive catalytically active component is supported on the side of the support, it does not contribute to the treatment of exhaust gas. There is a need for a loading method in which a catalytically active component is not loaded or adhered to the side surface of a carrier.

  In this method, the slurry containing the catalytically active component is moved up from the lower side of the carrier, and after the slurry reaches the upper end surface of the carrier, the slurry is discharged to the lower side of the carrier without overflowing from the upper end surface of the carrier. The way to do is taken. As a method for controlling the slurry so that it does not overflow from the upper end surface, a visual method can be mentioned. In consideration of productivity, there is a method using a laser sensor, an ultrasonic sensor or the like.

  However, in the method using these sensors, the position of the slurry cannot be confirmed accurately until the slurry reaches the upper end surface of the honeycomb carrier, and the liquid level is detected only after the slurry exceeds the upper end surface of the honeycomb carrier. There is a problem that it cannot fully cope with changes in the viscosity and press-fitting speed of the slurry. Therefore, in order to completely coat the slurry on the carrier, a certain degree of overflow is unavoidable, and there is a problem that the slurry adheres to the carrier side surface and the supporting device.

  In order to solve the above problems, the present inventors have intensively researched a method for accurately detecting the liquid level of the slurry near the upper end surface of the carrier when the slurry ascends in the carrier. The present inventors have found that the liquid level position of the slurry can be accurately detected by using the image processing sensor used, and the present invention has been completed.

  An object of the present invention is to use a CCD camera to detect the liquid level at the upper end of the carrier when a liquid material containing a catalytically active component is introduced and supported on the honeycomb monolithic carrier from the lower end surface of the carrier. This is achieved by a method for producing a catalyst, which is performed using an image processing sensor.

  Another object of the present invention is to provide image processing having a number of pixels of 100,000 to 300,000 when a liquid material containing a catalytically active component is introduced and supported on a honeycomb monolith support from the lower end surface of the support. The color of the carrier is extracted as the number of pixels by a sensor, and when a color different from the extracted color appears and falls below a preset pixel number tolerance, the press-fitting of the liquid material is stopped, and the carrier is pressed from the upper end surface of the carrier. This is achieved by a method for producing a catalyst, characterized in that the liquid level detection at the upper end of the carrier is performed by using an image processing sensor without overflowing the liquid material.

  Another object of the present invention is to extract and extract the color of the carrier with an image processing sensor when a liquid material containing a catalytically active component is introduced from the lower end of the carrier onto the honeycomb monolith carrier. When a color different from the color appears, the number of pixels of the designated color is 100,000 to 300,000, and the tolerance of the number of pixels is 600 to 70,000, the liquid is removed from the upper end surface of the carrier. This is achieved by a method for producing a catalyst, characterized in that the liquid level detection at the upper end of the carrier is carried out using an image processing sensor while stopping at the upper end without overflowing from the surface.

  The technical scope of the present invention is not limited to the wording of each claim in the claims, and extends to a range easily replaceable by those skilled in the art.

  According to the present invention, the slurry in the carrier and in the vicinity of the upper end surface of the carrier is obtained by using the image processing sensor when the liquid material containing the catalytically active component is introduced and supported on the honeycomb monolithic carrier from the lower end surface of the carrier. The position of the liquid surface of a liquid material containing a catalytically active component such as can be detected with high accuracy. In addition, problems such as loss and contamination of expensive liquid materials can be solved, and the production cost can be reduced by reducing coating material stability and liquid material loss.

  Hereinafter, the present invention will be described in detail.

  The honeycomb monolith carrier used in the present invention is not particularly limited as long as it is a refractory structure having a plurality of cells penetrating the inside of the carrier, and examples thereof include a monolith honeycomb carrier and a metal honeycomb carrier.

  Monolithic carriers are usually honeycomb carriers made of cordierite, mullite, α-alumina, zirconia, titania, titanium phosphate, aluminum titanate, betalite, sponge semen, aluminosilicate, magnesium silicate, stainless steel, Fe-Cr -An integrated structure using an oxidation-resistant heat-resistant metal such as an Al alloy is used.

These monolithic carriers are manufactured by an extrusion molding method or a method of winding and solidifying a sheet-like element. The shape of the gas passage port (cell shape) may be any of a hexagon, a quadrangle, a triangle, and a corrugation. Cell density (number of cells per unit square 6.45 cm ² (1 square inch)) is exhaust gas in the tunnel to be processed, industrial exhaust gas, unburned hydrocarbons from internal combustion engines such as automobiles and diesel engines, carbon monoxide Usually, 100 to 1500 cells are exemplified, although it varies depending on the type of exhaust gas such as nitrogen oxides. Incidentally, the outer shape of the carrier can be used without any particular limitation as a cross-sectional shape such as a circle, an ellipse, or a rectangle.

  The honeycomb-shaped monolithic carrier is used by previously coating the carrier with a refractory inorganic oxide or simultaneously coating the carrier with a catalyst component effective for exhaust gas treatment together with the inorganic oxide. In the present invention, these inorganic oxides, catalyst components, and mixtures thereof are referred to as catalytically active components. Examples of refractory inorganic oxides include activated alumina such as γ, δ, η, θ, cerium oxide, zirconium oxide, tungsten oxide, titanium oxide, silicon oxide, alkaline earth elements, and complex oxides thereof. . The catalyst component is not particularly limited as long as it can treat harmful substances in the exhaust gas, but noble metals such as rhodium, platinum and palladium, base metals such as manganese, cobalt, chromium, nickel and iron, oxides and salts, etc. It can be illustrated.

  The catalytically active component is slurried by a known method such as a wet mill and supported on a monolith support. The slurry that can be used in the present invention is not particularly limited as long as the inside of the carrier cell can be raised, but the slurry obtained by slurrying an inorganic oxide such as alumina oxide using an aqueous solution containing a small amount of an inorganic or organic acid, Examples include those obtained by slurrying an inorganic oxide such as alumina and a catalyst component such as a platinum salt with an aqueous solution containing a small amount of an inorganic or organic acid. In addition to the above slurry, the liquid material in the present invention includes those in which the catalyst component is an aqueous solution.

  Also included are coatings with multi-layer coated catalysts. A multilayer-coated catalyst is a catalyst in which the same or different kinds of catalytically active components are coated in multiple stages. In a high heat-resistant catalyst, a high-performance catalyst, and the like, a multi-layered catalyst such as a two-layer is common.

  Next, the contents of the present invention will be described in more detail with reference to the drawings.

  FIG. 1 is a partial cross-sectional view for explaining an example of holding a carrier. A method of holding the carrier will be described using a cylindrical carrier as a representative example. In FIG. 1, a hollow frame 3 having a shape into which a carrier 4 can be inserted and having at least one floating ring-shaped holder 2 that presses the carrier 4 from the side surface is prepared in advance.

  In order to impregnate the carrier 4 with a slurry (not shown) or the like, the carrier 4 is held, and the floating ring-shaped holder 2 is used to seal the side surface of the carrier 4. The floating ring-shaped holder 2 is made of an elastic material such as rubber because it holds the carrier 4 by inflating with a gas such as air. Gas is introduced from a nozzle 5 provided on the outer surface of the floating ring-shaped holder 2. The floating ring-shaped holder can also be used by being installed at one place on the lower end.

  The inner shape of the hollow frame 3 is not particularly limited as long as the carrier can be inserted, but is preferably similar to the outer shape of the carrier. Specifically, if the outer shape of the carrier is circular, the inner surface of the gantry is cylindrical. This is because by adopting such a configuration, the carrier 4 can be uniformly held from the entire side surface and further the side surface of the carrier can be sealed by inflating the floating ring-shaped holder 2 when holding the carrier.

  Next, the carrier 4 is put into the impregnation device 1 from above the impregnation device 1, and when the carrier 4 reaches a position corresponding to the lower end portion of the carrier 4, the movement of the carrier 4 is stopped and the floating ring-shaped holder 2b is inflated. 4 is fixed. The floating ring-shaped holder 2b is inflated and maintained as it is. Thereafter, similarly to the upper end portion of the carrier, the floating ring-shaped holder 2a is inflated and fixed. Thus, the carrier is fixed to the slurry impregnation apparatus.

  Next, the supporting method will be described using slurry as a representative example. FIG. 2 is a partial cross-sectional view of an example of a slurry impregnation apparatus for supporting a slurry on a carrier. In FIG. 2, the slurry 26 in the hollow frame 23 rises in the frame 23 by the action of a known liquid feeding device such as a piston (not shown) type. The rise of the slurry 26 in the monolith carrier 24 is monitored and detected by the image processing sensor 27 from above the carrier. It is preferable that the position of the image processing sensor 27 is located above the monolith carrier, and the distance from the monolith carrier is appropriately determined in consideration of the accuracy of the image processing sensor 27, the color of the slurry, and the like.

  The image processing sensor 27 is set as follows. A honeycomb monolith support 24 made of a refractory inorganic oxide or the like is set in the slurry impregnation apparatus 21. An image processing sensor (CCD camera) 27 is used to extract the color of the carrier 24. Here, the image processing sensor 27 is a sensor that performs color extraction by determining the degree of matching of colors designated on the screen by setting a range based on a color video signal from a camera. For example, the number of pixels of a designated color (such as a carrier) is reduced due to the appearance of a different color (slurry). The increase in the liquid level of the slurry can be detected by the change in the number of pixels. For example, the carrier white is extracted as the designated color. In the case of a multi-layer coated catalyst, the color of the catalyst supported one stage before is extracted. At that time, a certain number of pixels is measured. The number of pixels is, for example, in the range of 100,000 to 300,000, depending on the characteristics of the CCD camera. Normally, any slurry is different from the color of the carrier. Therefore, when the slurry rises and reaches the vicinity of the upper end of the carrier, a color different from the extracted color appears on the camera screen. When a color different from the color extracted in advance appears on the camera screen, the number of pixels of the color extracted in advance decreases. Due to the decrease in the number of pixels, it is possible to detect that the slurry has risen near the upper end of the carrier. Here, the vicinity of the upper end portion of the carrier is a range that can be detected by the image processing sensor on the upper end surface of the carrier and inside the carrier. The range that can be detected by the image processing sensor varies depending on the cell density and cross-sectional area of the carrier, the characteristics and lens of the CCD camera, and the accuracy of the image processing sensor. It is difficult to set the slurry stop position on the upper end surface of the carrier because it is affected by the viscosity of the slurry, the rising speed of the slurry, etc., but the slurry rises near the upper end surface of the carrier by using an image processing sensor. This can be detected, and the slurry can be stopped at the upper end surface without overflowing from the upper end surface of the carrier.

  Further, when the image processing sensor 27 is used, not only the vicinity of the upper end surface of the carrier 24 but also the inside of the cell can be detected, so that the liquid level of the slurry 26 in the cell can be detected. Therefore, the slurry 26 can be completely covered up to the upper end surface of the carrier 24, or a certain amount of unsupported portion can be left quantitatively in the vicinity of the upper end portion.

  Furthermore, the position where the CCD camera is set may be directly above or obliquely above the upper end surface of the carrier 24 as long as it can be detected.

  Although lighting can be installed if necessary, the type, number, installation position, etc. are not particularly limited as long as they do not hinder detection by the image processing sensor.

  The catalyst production method of the present invention is such that when a liquid material containing a catalytically active component is introduced from the lower end of the carrier onto the honeycomb monolith carrier and supported, the color of the carrier is extracted by an image sensor. When the number of pixels of the specified color is 100,000 to 300,000 and the pixel number tolerance is 600 to 70,000, the liquid material is placed on the carrier. An image processing sensor is used to detect the liquid level at the upper end portion of the carrier, which is stopped at the upper end surface without overflowing from the end surface.

  The pixel number tolerance is preferably 900 to 61,000.

  In the method for producing a catalyst of the present invention, when a liquid material containing a catalytically active component is introduced and supported on a honeycomb monolithic carrier from the lower end surface of the carrier, the number of pixels is 100,000 to 300,000. The color of the carrier is extracted as the number of pixels by the processing sensor, and when a color different from the extracted color appears and falls below a preset pixel number tolerance, the press-fitting of the liquid material is stopped, and from the upper end surface of the carrier The liquid level detection at the upper end of the carrier, which is performed without overflowing the liquid material, is performed using an image processing sensor.

  The press-fitting of the liquid material is desirably performed at a slurry feed rate of 700 to 5,000 L (liter) / hr, more preferably 900 to 3,500 L / hr.

  As described above, when the image processing sensor 27 is used, the position of the slurry 26 can be detected with high accuracy, so that the slurry can be stopped without overflowing from the upper end surface of the carrier 24. After the upper end surface of the carrier 24 is completely covered with the slurry, excess slurry is removed by sucking from the lower end portion of the carrier or by blowing from above the carrier, and the coating of the slurry is completed.

  These series of operations can be performed independently, but can also be performed automatically continuously.

  The carrier is removed from the impregnation apparatus by removing the gas from the floating ring-shaped holder. Then dry. If necessary, it is calcined to complete the catalyst.

  FIG. 3 is a partial cross-sectional view of another slurry impregnation apparatus for supporting a slurry on a carrier. In FIG. 3, the slurry 36 in the hollow base 33 made of a hard resin is raised in the base 33 by a known liquid feeding device such as a piston (not shown) type. If the raised slurry 36 leaks from between the carrier 34 and the gantry 33, the slurry 36 adheres to the carrier 34 and the gantry 33, resulting in loss of expensive slurry. Is made liquid-tight using a holder 38 made of an elastic material such as rubber or plastic to prevent the slurry 36 from leaking to the outside.

  Using the image processing sensor 37, the liquid level is controlled as in FIG. 1, the slurry is supported, dried, and calcined as necessary to form a catalyst.

  FIG. 4 is a partial cross-sectional view of another slurry impregnation apparatus for supporting slurry on a carrier. In FIG. 4, since the carrier holder 48 made of an elastic material such as rubber is used to hold the carrier 44, the carrier 46 can be held in close contact with the carrier, and even if the slurry 46 rises, the slurry 46 is supported by the carrier 44 and the carrier. Since there is no leakage from between the holders 48, the slurry 46 containing an expensive material can be used or reused without loss.

  The carrier holder 48 is fixed to a pedestal 43 made of a material that does not interact with slurry such as stainless steel.

  The slurry 46 ascends in the carrier holder 48 by a known liquid feeding device means (not shown) such as a piston.

  Using the image processing sensor 47, the liquid level is controlled as in FIG. 1, the slurry is supported, dried, and calcined as necessary to form a catalyst.

  As the carrier holding or impregnating apparatus, other known apparatuses can be used except for the image processing sensor.

  A method of automating the method of supporting the slurry by controlling the liquid level using an image processing sensor is also included in the scope of the present invention.

  EXAMPLES The present invention will be specifically described below with reference to examples, but the present invention is not limited to these examples.

Example 1
A DENSO monolith carrier (400 cpsi / 6 mil) is set in the slurry impregnation apparatus shown in FIG. A white part of the carrier is extracted using a CCD camera set above the carrier. The number of pixels at that time was 100,000 to 120,000.
Next, a slurry containing a Pd-based catalytically active component was press-fitted from the lower end of the carrier. The specific gravity of this slurry was 1.600 g / ml, and the viscosity was 500 cps. The slurry feed rate when the slurry was press-fitted was 3,000 L / hr. The brown slurry was raised near the upper end surface of the carrier, the number of extracted white pixels was lowered, and the press-fitting of the slurry was stopped when the number of pixels exceeded 1,000. This is called a pixel number tolerance of 1,000. The slurry overflowed from the upper end surface of the carrier, and the apparatus could be stopped without adhering to the side surface.
At this time, the upper end surface of the carrier was completely covered with the slurry, and no overflow to the side surface was observed.

(Example 2)
The carrier was coated with the slurry in the same manner as in Example 1 except that the slurry flow rate was 2,800 L / hr. At this time, the upper end surface of the carrier was coated with the slurry except for two cells from the outermost periphery.

(Example 3)
Except that the slurry feed rate was 1,000 L / hr, the carrier was coated with the slurry in the same manner as in Example 1, and about 5 mm from the upper end surface of the carrier was unsupported.

Example 4
Except that the slurry viscosity was 1,000 cps, the carrier was coated with the slurry in the same manner as in Example 1, and about 5 mm from the upper end surface of the carrier was unsupported.

(Example 5)
Except that the pixel number tolerance is 60,000, the slurry was coated on the carrier in the same manner as in Example 1, and about 5 mm from the upper end surface of the carrier was not carried.

(Example 6)
The catalyst prepared in Example 1 was set again in the slurry impregnation apparatus shown in FIG. The brown part of the catalyst was extracted using a CCD camera set above the prepared catalyst. The number of pixels at that time was 150,000 to 170,000.
Next, a slurry containing an Rh-based catalytically active component was press-fitted from the lower end of the catalyst. The specific gravity of this slurry was 1.300 g / ml, the viscosity was 150 cps, and the slurry feed rate when the slurry was injected was 2,500 L / hr.
It was set so that the press-fitting was stopped when the yellowish white slurry rose near the upper end surface of the catalyst and the number of extracted brown pixels decreased and the number of pixels fell below 10,000.
As a result, the apparatus could be stopped without the slurry overflowing from the upper end surface of the catalyst and adhering to the side surface. At this time, the upper end surface of the catalyst was covered with the slurry except for 3 cells from the outermost periphery.

(Comparative example)
A DENSO monolith carrier (400 cpsi / 6 mil) was set in a slurry impregnation apparatus.
Next, a slurry containing a Pd-based catalytically active component was press-fitted from the lower end of the carrier. The specific gravity of this slurry was 1.600 g / ml, and the viscosity was 500 cps. The slurry feed rate when the slurry was press-fitted was 3,000 L / hr.
The liquid level of the slurry was detected using a laser sensor. Since the laser sensor could not detect unless it exceeded the upper end surface of the carrier, the slurry overflowed and adhered to the side surface of the carrier.

As described above, the conventional laser sensor cannot control the stop position of the liquid surface of the slurry, whereas in the present invention, the pixel number tolerance of the CCD camera, slurry viscosity, press-fitting, etc. By optimizing conditions such as speed, it is possible to control the liquid level stop position such as unloading or overflow.
If the image processing sensor and the floating ring-shaped holder are combined, they can be carried with high accuracy and can be carried without causing extra adhesion on the side surface of the carrier.

These are the fragmentary sectional views for demonstrating an example for hold | maintaining a support | carrier. These are the partial cross sections of an example of the slurry impregnation apparatus which carry | supports a slurry on a support | carrier. These are the fragmentary sectional views of the other slurry impregnation apparatuses which carry | support a slurry on a support | carrier. FIG. 3 is a partial cross-sectional view of another slurry impregnation apparatus for supporting a slurry on a carrier.

Explanation of symbols

1, 21, 31, 41 ... Impregnation device 2a, 2b, 22a, 22b ... Floating ring-shaped holder 3, 23, 33, 43 ... Base 4, 24, 34, 44 ... Carrier 5a, 5b, 25a, 25b ... Nozzle 6, 26, 36, 46 ... Slurry 27, 37, 47 ... Image processing sensor 28, 48 ... Holder

Claims (4)

  When a liquid material containing a catalytically active component is introduced and supported on the honeycomb monolith support from the lower end surface of the support, the liquid level detection at the upper end of the support is performed using an image processing sensor. To produce a catalyst.   When a liquid material containing a catalytically active component is introduced and supported on a honeycomb monolith carrier from the lower end surface of the carrier, the color of the carrier is changed by an image processing sensor having 100,000 to 300,000 pixels. When a color different from the extracted color appears and falls below a preset pixel number tolerance, the press-fitting of the liquid is stopped and the liquid is not overflowed from the upper end surface of the carrier. A method for producing a catalyst, wherein the liquid level at the upper end of the carrier is detected using an image processing sensor.   The method for producing a catalyst according to claim 2, wherein the press-fitting of the liquid material is performed at a slurry feed rate of 700 to 5000 L / hr.   When a liquid material containing a catalytically active component is introduced and supported on the honeycomb monolith support from the lower end of the support, the color of the support is extracted by an image processing sensor, and a color different from the extracted color appears. When the number of pixels of the designated color is 100,000 to 300,000 and the pixel number tolerance is 600 to 70,000, the liquid material does not overflow from the upper end surface of the carrier. A method for producing a catalyst, characterized in that the liquid level detection at the upper end of the carrier is carried out using an image processing sensor.

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