DE2115978C2 - Device for the intimate mixing of two gas streams - Google Patents

Description

The invention relates to a device for intimately mixing two gas streams according to the The preamble of claim 1.

The mixture of such gas streams is for the production of acetaldehyde from ethylene or ethyl alcohol, for the production of acetaldehyde and acetic acid from ethane, for the production of isopropanol and acetone from propane, for the production of methyl alcohol, formaldehyde and acetaldehyde from butane, for the production of ethylene oxide from ethylene and for the production of phthalic anhydride from naphthalene 5 or orthoxylene, the production being carried out in a reactor by catalytic or thermal conversion to which the mixed gas streams are fed.
Such mixtures are known to have a tendency to form explosive or flammable compositions. In order to avoid the formation of such compositions, in conventional devices for mixing large gas volume flows, one gas emerging from tube bundles is jetted into the flow of a second gas, so that, as a result of the turbulence that occurs, good mixing is obtained in a chamber located downstream from the tubes however, it cannot be avoided that in such a mixing chamber mixtures form locally or temporally which are within the potentially explosive limits, the remaining gas mixture having a composition which lies outside the danger area
In addition, in the case of transient states, for example at the beginning, at the end or as a result of a disruption or interruption of the process sequence, different oxygen concentrations can occur or be necessary, as a result of which the organic compounds to be oxidized can diffuse back through the

Pipes and thus the formation of explosive mixtures can occur. To avoid back diffusion as is known, the gases are allowed to flow through the pipes at a correspondingly rapid rate and, in addition, continues Inert gas, for example nitrogen. Argon, carbon dioxide or inert gas mixtures. However, this has the disadvantage that this means that enormous amounts of inert gas have to be made available in some cases.

A generic device for mixing two gas streams is known from FR-PS "! ^ 04 737.

In this mixing arrangement pipes are provided for a first gas, the pipe mouths through a Perforated plate are assigned to annular flow openings for the second gas flow. This will initially a number of substreams created, each from a core of a first gas and a surrounding jacket consist of a second gas. This group of individual streams becomes only in the course the onward flow brought about the desired mixing, with perforated plates to support the mixing and to even out the flow are provided. Since the tubes for the first gas flow do not extend through these perforated plates, there is also no equalization of the first gas flow before it merges with the second partial flows instead, but merely an equalization of the already mixed at least to a certain extent Gastrointestinal. There is a mixture of the gases from partial flow with partial flow, and it is with uncontrolled Mixing processes to be expected because

thus the individual partial flows of the second gas flow flowing through the annular spaces around the pipes after exit from the annular spaces only after a certain flow path spread so far that they are with the mix adjacent partial flows, d. that is, a real mix only takes place at some distance from the pipe mouths and the perforated plate instead. As a result of these envelope currents, a large number is local Flow disturbances and turbulence to be expected

which can lead to an increased risk of explosion.

The object of the invention is to develop a device according to the preamble of claim 1 so that that uniform mixture formation is achieved over a housing cross-section.

This task is achieved with the device of the generic type solved by the characterizing features of claim 1. Further refinements of the device are placed under protection in the subclaims

The device according to the invention increases the operational safety in that by one or more Perforated plates are first provided for a uniform first gas flow over the housing cross-section. In This uniform and homogeneously flowing gas stream then becomes the second gas stream in the form of partial streams introduced, so that for uncontrolled, uneven mixing processes over the cross-section of the housing there is no room at all. As a result of this improvement compared to the known prior art, the invention is technically advanced and has an enrichment of the technology in that through the uniform mixture formation over the housing cross-section a uniform reaction of the two reactants with a far lower risk of explosion is achievable

Advantageously, perforated plates through which the tubes for pass the first gas flow through it, with holes provided that do not correspond to the passage points of the pipes are assigned by the perforated plates. Without the perforated plates, the speed distribution would be transverse to the first gas stream entering second gas stream as a result of its right-angled deflection when entering non-uniform at the housing outlet. The perforated plates ensure the formation of a uniform speed profile. During the axial flow of the second gas stream past the pipe ends, through which the first gas flow exits is generated at these pipe ends? in suction pressure, which is a back diffusion of gases of the second gas stream through the pipes can be impossible. Because the speed of the second gas flow is uniform, the suction pressure occurring at the pipe ends is also uniform distributed. Since this eliminates the risk of back diffusion and the formation of detonation gangs, There is also no need to add inert gas.

If an oxygen-containing gas stream, which is essentially consists of pure oxygen, air or oxygen diluted with an inert gas, with a hydrocarbon containing gas stream are mixed, so trir. the gas stream containing the oxygen in Longitudinal direction into the housing, while the gas flow with the hydrocarbon is fed in transversely.

Due to the uniform velocity profiles of the gas streams to be mixed, seen over the cross-section of the housing In the mixing area, a spatially and temporally uniform mixture formation is obtained. The uniformity of the profiles or the mixture formation can be further improved by the holes in the perforated plates are all the same size. The holes are preferably in the perforated plate or plates evenly distributed and the area of a hole cross-section exceeds 54% of the cross-sectional area of one Rohres not. The total area of the holes in the perforated plate or plates should be at least 57% of the total area the associated! .ochplat'.e. The cross-sectional shape the holes can, for example, be triangular, square or circular. Will holes with straight, drilled or punched edges are used, the total area of the holes is expediently used as a percentage of the cross-sectional area of the housing greater than the total area of the holes on the have rounded edges upstream.

It has been found to be advantageous that the tubes by at least ten times a hole diameter protrude beyond the perforated plate furthest downstream into the outlet. This is preferably Distance twenty times the diameter of a hole. For holes whose cross-section is not circular the "equivalent diameter" is used as the reference value, which is four times the quotient Cross-sectional area divided by the circumference of the cross-sectional area This protrusion of the tubes over the last perforated plate results in pulsations or fluctuations in the speed and throughput distributions to disappear caused by the gas streams emerging from the holes, causing these fluctuations are eliminated before the carbon-containing gas stream reaches the mouths of the tubes.

The uniformity of the speed and throughput profile of the second gas stream is further enhanced by this improved that two perforated plates are provided, the distance between them preferably at least ten times the diameter of a hole In the housing can of course several perforated plates can also be arranged; however, in order to avoid too high a pressure drop, should the total cross-sectional area of all holes in a perforated plate then be larger than the total cross-sectional area, if only one or two perforated plates are arranged in the mixing device.

The tubes can extend through the perforated plates in such a way that that a free annular space remains around each tube. This has the advantage that the Hydrocarbon-containing gas stream at the ends of the tubes exerted suction by the Jet effect of the gas flow from the annular spaces is still favored. It can, however, in turn happen that the jet effect on the individual pipes is locally different, whereby the risk of Back diffusion is increased again in certain cases. In general, therefore, these annular spaces are omitted or seal it.

The possibility that a back flow develops or a back diffusion sets in continues to do so reduces that the pressure drop of the gas entering in the axial direction of the housing is not too small. This pressure drop can be increased in that the pipes are at least ten times one Extend the pipe diameter upstream of the partition, i.e. the wall in which the pipes are fastened. Optionally or in addition to this, the pressure drop can also be immediately upstream of this dividing wall can be increased in that an intermediate plate between the inlet for the first gas flow and the partition wall is provided with a large number of evenly distributed openings. In addition to the uniform The pressure drop at these openings leads to the distribution of the first gas flow over the housing cross-section in the intermediate plate to an increased gas velocity, which in turn resulted in a Counteracts the return flow of parts of the second gas flow.

The mixing device according to the invention is suitable

especially for mixing two feed streams of a recirculation system conventionally used in the so-called direct oxidation process is used in the production of ethylene oxide.

An exemplary embodiment of the present invention is explained in more detail with the aid of the drawing.

F i g. 1 shows the device according to the invention in a side view, partially in section.

F i g. 2 shows part of the housing in an axial section the device according to the invention with the internal arrangement.

F i g. Figure 3 is a section taken along line 3-3 of Figure 3. 2.

The first gas stream 1 enters the mixing device shown in the figures in the longitudinal direction through an inlet port 10 in a head part 20 , the cross section of which corresponds to the shape of a shark ellipse, with flanges 50 located at the end of the head part 20 opposite the inlet port, which extend in the direction the major axis of the ellipse. In the head part 20 , an intermediate wall 40 is provided, which is provided with a plurality of evenly distributed openings. The first gas stream 1 flows through these holes 40 into a chamber 45, where it is evenly distributed as a result of the holes 40 and a pressure drop has occurred. This pressure drop leads to an increase in the speed of the gas flowing through the chamber 45, which is delimited by the head part 20.

A sampling device 30 protrudes into the chamber 45, with which a possibly occurring backflow of gases of the second gas flow into the head 20 can be determined.

The flange 70 of the upstream housing part 80 is arranged opposite the flange 50 seated on the head part 20. A partition 60 is arranged between the flanges 50 and 70, through which pipes 90 pass which are at the same time held in the partition 60. The tubes 90 are evenly distributed over the cross section of the housing 80, it being possible for the tubes of the tube bundle to be additionally held by support beams 100. The first gas stream flowing through the chamber 45 enters the tubes 90 and flows in these tubes up to their exit downstream from the perforated plates 140 through which the tubes in the downstream housing part 120 pass. The perforated plates are reinforced on their outer circumference by stiffening rings 130 and centered by centering lugs 150 , whereby the tubes 90 are aligned in the housing part 120 at the same time.

The second gas stream 2 enters the mixing device through an inlet connection 160 which is arranged in the side wall of the housing part 80. The gas of the second gas flow is deflected in the axial direction of the housing and flows around the outside of the tubes 90 through the two perforated plates 140 arranged in the housing part 120 , whereby the second gas flow has a uniform velocity profile over the cross section The gas flow mixes with the second gas flow flowing around the tubes 90, FIG. 2 clearly showing that no contact whatsoever is possible between the gas flows to be mixed up to the downstream end of the tubes 90. The gases mixed in this way flow through the housing part 120 and emerge from the housing through the outlet 3 (Fig. 1).

In Fig. 3 is shown a perforated plate 140 having on its outer periphery a Absteifring 130 The perforated plate 140 is held centered by 150 Zentricransäi / e. The tubes 90 protrude through the perforated plate 140 into the downstream housing part 120 . In the embodiment according to FIG. The holes shown in FIG. 3 are square, but, as already mentioned, can be circular, triangular or otherwise shaped, with emphasis only on an even distribution.

The present invention is further illustrated by the following examples.

Example I.

A mixing device according to the invention and a conventional mixing device are to be compared, each of the devices having a diameter of about 50 cm and containing the same number of tubes. In the conventional device, a single partition is provided which separates the upstream housing part 80 from the outlet 3. The gas entering through the second inlet port 160 flows through the outlet 3 through the annular spaces surrounding the tubes.

In the device according to the invention, two perforated plates are provided, the holes of which are evenly distributed and have a diameter of about 12 mm. The perforated plates are at a distance of 12 cm arranged from each other.

In order to avoid the occurrence of explosive compositions in the chamber in the conventional device, it was necessary. Add 1900 nmVh of nitrogen. All other things being equal, the device according to the invention ^{required only 600 nm 3} / h of nitrogen. Depending on the throughput, it has been found that in the mixing device according to the invention only V ₃ to V _{2 of} the

The amount of inert gas to be added to the conventional device to avoid detonation mixtures in the chamber 45 is required.

Example 2

With the aid of a pitot tube, the velocity profiles 5 cm downstream from the mouths of the tubes in the downstream housing part 120 of the devices described in Example 1 are examined. at

equal gas flow rates through each of the devices results in a theoretical gas velocity of about 70 m / s. In the mixing device according to the invention, the measured speed is in one range between 63 and 76 m / s. The speed profile in the conventional device is essential more irregular, the speed fluctuates between 38 and 107 m / s.

1 sheet of drawings

Claims (7)

Patent claims: 1. Device for the intimate mixing of two gas streams with a housing, with a first Inlet in the region of one end of the housing for the first gas stream, with a second inlet for the second gas stream, which is arranged downstream of the first inlet on the side of the housing, with a Partition between the two inlets, with an outlet in the area of the other end of the housing for the gas mixture, with at least one perforated plate between the second inlet and the outlet is arranged and holes of a substantially uniform diameter for the Has passage of the second gas stream, the holes in a uniform distribution over the Perforated plate are arranged, and with several tubes for the passage of the first gas stream, which penetrate the partition and the perforated plate, the tubes being held by the partition and protrude beyond the perforated plate furthest downstream, characterized in that that the tubes (90) are also held by the perforated plate (140), that the entire cross-section each hole in the perforated plate is available for the passage of the second gas stream (2) stands, and that the tubes by at least ten times the diameter of a hole over the the perforated plate furthest downstream protrude. 2. Device according to claim 1, characterized in that that the cross-sectional areas of the individual holes are each 54% of the cross-sectional area of a Do not exceed the pipe (90). 3. Apparatus according to claim 2, characterized in that the total area of the holes in the or in the perforated plates (140) is at least 57% of the total area of the associated perforated plate. 4. Device according to one of the preceding claims, characterized in that the tubes (90) protrude by about twenty times a hole diameter over the last perforated plate (140). 5. Device according to one of the preceding claims, characterized by two perforated plates (140). 6. Apparatus according to claim 5, characterized in that the distance between the two Perforated plates (140) is at least ten times a hole diameter. 7. Device according to one of the preceding claims, characterized by an between the inlet (10) for the first gas stream and the partition wall (60) arranged with a plurality of evenly distributed openings provided intermediate plate (40).