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Catalyst beds diameter

A typical catalyst bed is very shallow (10 to 50 mm) (76,77). In some plants the catalyst is contained in numerous small parallel reactors in others, catalyst-bed diameters up to 1.7 and 2.0 m (77,80) and capacities of up to 135,000 t/yr per reactor are reported (78). The silver catalyst has a useful life of three to eight months and can be recovered. It is easily poisoned by traces of transition group metals and by sulfur. [Pg.493]

Fig. 8.4 shows industrial catalytic converter (hence catalyst bed) diameters as a function of measured 1st catalyst bed feed gas volumetric flowrates. Bed diameters are between 8 and 16 m. They increase with increasing input gas flowrate. They are quite precisely predicted by the trendline equation on the graph. [Pg.96]

By means of a syringe pump 1 gram of feedstock is charged over the catalyst which is placed in the reactor in the furnace. The catalyst is placed in the reactor in an anular bed with an internal diameter of 9 mm and an outer diameter of 14 mm. The center of the bed is filled with a stainless steel preheater. The shape of the bed prevents a temperature drop over the catalyst bed diameter. It also increases the surface of catalyst contacting the wall, which helps to prevent the catalyst from dropping out of the reactor. [Pg.149]

Total Molar Feed Mass Flow Rate Inlet Pressure Inlet Temperature Catalyst Bed Diameter Catalyst Bed Length Catalyst Bulk Density Catalyst Particle Diameter... [Pg.450]

Studies were made over a range of temperatures, flow rates, and NH3/NO ratios. The position of the thermocouple probe tip in the catalyst bed was fixed at 0.125 in. of catalyst ahead of the tip. Catalyst bed diameter was 0.128 in., the volume 0.026 cm3. The vanadia-alumina catalyst was the same used for prior work on HC oxidation (I). Am-... [Pg.22]

The most reliable recycle reactors are those with a centrifugal pump, a fixed bed of catalyst, and a well-defined and forced flow path through the catalyst bed. Some of those shown on the two bottom rows in Jankowski s papers are of this type. From these, large diameter and/or high speed blowers are needed to generate high pressure increase and only small gaps can be tolerated between catalyst basket and blower, to minimize internal back flow. [Pg.60]

An alternate form of catalyst is pellets. The pellets are available in various diameters or extruded forms. The pellets can have an aluminum oxide coating with a noble metal deposited as the catalyst. The beads are placed in a tray or bed and have a depth of anywhere from 6 to 10 inches. The larger the bead (1/4 inch versus 1/8 inch) the less the pressure drop through the catalyst bed. However, the larger the bead, the less surface area is present in the same volume which translates to less destruction efficiency. Higher pressure drop translates into higher horsepower required for the oxidation system. The noble metal monoliths have a relatively low pressure drop and are typically more expensive than the pellets for the same application. [Pg.480]

The catalytic decomposition of acetylene was carried out in a flow reactor at atmospheric pressure. A ceramic boat containing 20-100 mg of the catalyst was placed in a quartz lube (inner diameter 4-10 mm, length 60-100 cm). The reaction mixture of 2.5-10% C2H2 (Alphagaz, 99.6%) in Nj (Alphagaz, 99.99%) was passed over the catalyst bed at a rate of 0.15-0.59 mol C2H2 g h for several hours at temperatures in the range 773-1073 K. [Pg.15]

There is no separate shift conversion system and no recycle of product gas for temperature control (see Figure 1). Rather, this system is designed to operate adiabatically at elevated temperatures with sufficient steam addition to cause the shift reaction to occur over a nickel catalyst while avoiding carbon formation. The refractory lined reactors contain fixed catalyst beds and are of conventional design. The reactors can be of the minimum diameter for a given plant capacity since the process gas passes through once only with no recycle. Less steam is used than is conventional for shift conversion alone, and the catalyst is of standard ring size (% X %= in). [Pg.150]

Kinetic measurements were made with a glass tubular one-pass fixed bed reactor. The internal diameter of the reactor was 9-12 mm, and the thermocouple well of external diameter 5-6 mm reached into the catalyst bed. The amount of the catalyst varied within the range of 0.01 to 1 g for pseudodifferential measurements (depending upon the activity of the catalyst... [Pg.25]

The three principal catalyst bed configurations are the pellet bed, the monolith, and the metallic wire meshes. An open structure with large openings is needed to fulfill the requirement of a low pressure drop even at the very high space velocities of 200,000 hr-1. On the other hand, packings with small diameters would provide more external surface area to fulfill the requirement for rapid mass transfer from the g .s stream to the solid surface. The compromise between these two ideals results in a rather narrow range of dimensions pellets are from to 1 in. in diameter, monoliths have 6 to 20 channels/in., and metallic meshes have diameters of about 0.004 to 0.03 in. [Pg.82]

The catalytic reforming of CH4 by CO2 was carried out in a conventional fixed bed reactor system. Flow rates of reactants were controlled by mass flow controllers [Bronkhorst HI-TEC Co.]. The reactor, with an inner diameter of 0.007 m, was heated in an electric furnace. The reaction temperatoe was controlled by a PID temperature controller and was monitored by a separated thermocouple placed in the catalyst bed. The effluent gases were analyzed by an online GC [Hewlett Packard Co., HP-6890 Series II] equipped with a thermal conductivity detector (TCD) and carbosphere column (0.0032 m O.D. and 2.5 m length, 80/100 meshes), and identified by a GC/MS [Hewlett Packard Co., 5890/5971] equipped with an HP-1 capillary column (0.0002 m O.D. and 50 m length). [Pg.614]

The flow pattern of fluids in gas-liquid-solid (catalyst) reactors is often far from ideal. Special care must be taken to avoid by-passing of the catalyst particles near the reactor walls, where the packing density of the catalyst pellets is lower than in the centre of the bed. By-passing becomes negligible if the ratio of reactor to particles diameter is larger than 10 a ratio of 20 is recommended. Flow maldistributions might be serious in the case of shallow beds. Special devices must be used to equalize the velocity over the cross-section of the reactor before reactants are introduced onto the catalyst bed. [Pg.296]

Several pilot plants have been built to test periodic flow direction reversal. Pilot-scale reactors with bed diameters from 1.6 to 2.8 m were operated with flow reversal for several years. The units, described by Bunimovich et al. (1984,1990) and Matros and Bunimovich (1996), handled 600 to 3000 m3/h and operated with cycle periods of 15 to 20 min. Table VIII shows the performance of these plants for different feeds and potassium oxide promoted vanadia catalysts. The SVD catalyst was granular the IK-1-4 was in the form of 5 (i.d.) x 10-mm cylinders, while the SYS catalyst was... [Pg.227]

The packing itself may consist of spherical, cylindrical, or randomly shaped pellets, wire screens or gauzes, crushed particles, or a variety of other physical configurations. The particles usually are 0.25 to 1.0 cm in diameter. The structure of the catalyst pellets is such that the internal surface area far exceeds the superficial (external) surface area, so that the contact area is, in principle, independent of pellet size. To make effective use of the internal surface area, one must use a pellet size that minimizes diffusional resistance within the catalyst pellet but that also gives rise to an appropriate pressure drop across the catalyst bed. Some considerations which are important in the handling and use of catalysts for fixed bed operation in industrial situations are discussed in the Catalyst Handbook (1). [Pg.426]

The most difficult problem to solve in the design of a Fischer-Tropsch reactor is its very high exothermicity combined with a high sensitivity of product selectivity to temperature. On an industrial scale, multitubular and bubble column reactors have been widely accepted for this highly exothermic reaction.6 In case of a fixed bed reactor, it is desirable that the catalyst particles are in the millimeter size range to avoid excessive pressure drops. During Fischer-Tropsch synthesis the catalyst pores are filled with liquid FT products (mainly waxes) that may result in a fundamental decrease of the reaction rate caused by pore diffusion processes. Post et al. showed that for catalyst particle diameters in excess of only about 1 mm, the catalyst activity is seriously limited by intraparticle diffusion in both iron and cobalt catalysts.1... [Pg.216]

As expected, D decreases and L increases as (-AP) increases. For a given amount of catalyst, a reduced pressure drop (and operating power cost) can be obtained by reducing the bed depth at the expense of increasing the bed diameter (and vessel cost). [Pg.519]

See other pages where Catalyst beds diameter is mentioned: [Pg.508]    [Pg.220]    [Pg.74]    [Pg.508]    [Pg.220]    [Pg.74]    [Pg.95]    [Pg.508]    [Pg.217]    [Pg.660]    [Pg.35]    [Pg.44]    [Pg.708]    [Pg.77]    [Pg.97]    [Pg.137]    [Pg.26]    [Pg.98]    [Pg.109]    [Pg.310]    [Pg.554]    [Pg.389]    [Pg.296]    [Pg.388]    [Pg.420]    [Pg.179]    [Pg.5]    [Pg.6]    [Pg.52]    [Pg.458]    [Pg.243]    [Pg.531]   
See also in sourсe #XX -- [ Pg.82 , Pg.83 , Pg.84 , Pg.85 , Pg.86 , Pg.95 , Pg.224 , Pg.225 , Pg.226 ]

See also in sourсe #XX -- [ Pg.82 , Pg.83 , Pg.84 , Pg.85 , Pg.86 , Pg.95 , Pg.224 , Pg.225 , Pg.226 ]

See also in sourсe #XX -- [ Pg.82 , Pg.83 , Pg.84 , Pg.85 , Pg.86 , Pg.95 , Pg.224 , Pg.225 , Pg.226 ]



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