FR2582540A1 - Device for controlling the fluidising gas feed at the blowing openings of a fluidisation grid and grid equipped with this device - Google Patents

Abstract

Each passage opening 2A for the fluidising gas is connected to a feed conduit 5 by an individual pipe 3 in which is fitted, below the grid 1, between two flanges 6, 6', a flat semipermeable component 7 through which the fluidising gas passes but which stops the flow in the opposite direction of a substantial fraction of the particles of which the fluidised bed is composed, with the result that, after a stoppage, this bed can be easily returned to a fluidised state.

Description

 The subject of the invention is a device which can be used for controlling the supply of fluidizing gas to the blowing openings of this gas through a fluidizing grid.

 More specifically, the device of the invention has the role of letting the fluidizing gas pass by making it possible to adjust the relative flow rate between the various blowing openings and to oppose the descent of the fluidized material inside. fluidizing gas inlet tubes during the stopping of the fluidization.

 It should be understood that the word grid is used here in the broadest sense to designate any part having blowing openings for a fluidizing gas regardless of the particular configuration elsewhere.

 In addition, as will be understood later, the invention can be used with the grid of any fluidized bed device; in particular with all fluidized bed treatment reactors. It is used as well with reactors for simple thermal treatments with a hot or cold fluidizing gas as with reactors for more complex treatments of a particulate material either by contact of the fluidizing gas with the material, or by contact between them of particles of different materials.

 In certain installations, the fluidization grid has a large thickness and it includes, in its thickness, cavities flared upwards, for example pyramid trunks or cone trunks, overturned, to which flow fluidization gas supply channels .

These flared cavities are arranged in parallel rows.

Their total section forms a polygon which can be inscribed in a round, square or rectangular tray.

 The invention can also be used with this type of fluidization grid which is often called the fluidization plate.

Whatever the general configuration of the fluidization grid and whatever the particular arrangement of the fluidizing gas blowing openings, the following conditions should be observed as best as possible
- Obtain a suitable distribution of the fluidization gas flow through all the openings; this distribution is often that which gives an equal real flow rate of gas through the openings but it may in certain circumstances need a lower flow rate through certain openings in a determined zone of the grid,
- Prevent, when the fluidization stops, that the particles of material descend through the blowing openings of the fluidization gas and invade the inlet pipes of this gas; the more the tubes are filled with particles, and in particular by the larger particles which descend first, the more difficult it is then to return the bed to a state of fluidization.

 Document FR-A-2 171 945 discloses a device which provides a first solution and in which the blowing openings are supplied by individual pipes which each include a flow control valve, a diaphragm, and a siphon. ; the latter has the role of avoiding clogging of the pipe when the speed of the fluidizing gas becomes zero or insufficient. In fact, in general the mass of the particles accumulated in each siphon is not sufficient to prevent the rapid restoration of normal fluidization conditions, that is to say The return of the particles from the bed to the fluidization state, under the simple effect of the introduction of the fluidizing gas at the nominal pressure and flow rate or under the effect of air blowing compresses.

 This device is complex and expensive, since it is necessary to install as many valves, diaphragms and siphons as there are in the grid of openings to be supplied.

The main object of the invention is to provide a simple and inexpensive device making it possible to ensure an entirely satisfactory distribution.
flow rate of fluidizing gas through all openings
tures of a fluidization grid, as well as avoiding the
clogging and sealing of individual tubing ali
lying each of the openings, when the speed
gas flow becomes weak or zero.

In a fluidization grid intended to support
ter a bed of particles to be fluidized, having numerous
openings each joined to a fluidizing gas supply
tion to allow the passage of a fluidizing gas by
a straight section of passage with determined value, according to
The invention each passage opening is associated with an element
ment occupying said straight section of passage and crossed
by channels capable, on the one hand of letting the gas pass
fluidization and able, on the other hand to stop, in sense
reverse to the flow of this gas, at least a fraction
substantial particles from the particle bed. In this
which follows, we will designate this element by the expression element
semi-permeable, for convenience.

The invention does not impose the particular mode
supplying fluidizing gas to each of the openings
of the grid. It is conceivable to supply all of the
grid openings by means of a single chamber where
the fluidizing gas arrives. However, it is more consistent
to the practical needs of designing groups on a grid
determined of openings and to provide for each group a
special supply line for this group of ali gas
mentation. So we can feed when it is desirable
or stop feeding certain groups of openings in the
wire rack. According to this latter design, each blowing opening through the fluidization grid is connected by
individual tubing to the pipe that supplies the group
to which it belongs.

Preferably, according to the invention The semi element
permeable is placed in the tubing that connects each open
of the grid to the corresponding pipe.

 This preferred arrangement does not exclude that the semi-permeable element may be housed in the passage opening itself, for example in the thickness of the grid. But it is more advantageous, as will be shown further on, to mount the semi-permeable element in a tube below the fluidization grid.

According to a preferred embodiment of the invention, each semi-permeable element is flat and constituted by a wire mesh or a perforation plate having passage openings whose dimensions are between 0.15 and 0.60 mm ; preferably the ratio between the passage surface and the total surface is between 0.30 and 0.6C
Alternatively, the semi-permeable element may be a disc of porous refractory material through which extend numerous channels. In this case, the dimensions of these channels can be less than 0.15 mm, but the ratio mentioned above must be respected.

 The semi-permeable elements are chosen according to the nature of the particles to be fluidized, the overall flow rate of fluidizing gas, the geometric and aerodynamic characteristics of the grid, and the pressure drop due to the fluidized bed above the grid. .

 It is estimated that, in most cases, the pressure drop created by the semi-permeable elements of the invention should be between 20% and 100% of the pressure drop due to the fluidized bed.

 Advantageously, each semi-permeable element is installed on the individual supply pipe of each passage opening, below the grid, in an easily removable manner, for example between two flanges bolted together or between two flanges screwed with no screwing opposites.

 Preferably, the distance between the underside of the grid and the location of the semipermeable element on each individual tube is at most equal to four times the diameter of the latter. For example, when it comes to the grid described above with pyramid trunks or inverted cone trunks, the distance between the small base or lower base of these trunks and the location of the semi-permeable element is the as small as possible, in any case less than four times the diameter of the tubing.

 The invention also relates to any fluidization grid, the fluidization gas supply circuits of which include a device according to the invention.

 In order to clearly understand the invention, there will now be described, by way of nonlimiting example, a preferred embodiment of a device according to the invention, usable for example for the fluidization of coal.

 In this embodiment, the fluidization grid comprises a certain number of rows of trunks of inverted pyramids, with a large square base, supplied individually with fluidization gas. A detailed description of this grid can be found, if desired, with reference to French Patent No. 1,422,198.

During the description, reference will be made to the appended drawings in which
FIG. 1 is a view in vertical section of part of a fluidization grid, of a primary fluidization gas supply circuit as well as of a second secondary air supply circuit,
FIG. 2 is a top view of a truncated pyramid which forms part of the fluidization grid of FIG. 1,
FIGS. 3 and 4 are detailed views in vertical section of the pyramid trunk of FIG. 2 and its supply pipe showing two methods of mounting a flat semi-permeable element,
- Figure 5 is a perspective view from above of a semi-permeable element.

In FIG. 1, it can be seen that the fluidization grid designated by the general reference 1 is constituted by a multitude of trunks of inverted pyramids 2 distributed in defined groups, for example arranged in parallel rows
Each pyramid trunk 2 has at its lower end a passage opening 2A for a fluidizing gas. This gas arrives through an individual tube 3 which is connected at 4 to a pipe 5. The latter is intended to supply fluidization gas to a group or a row of trunks of pyramid 2 such as that which is partially represented.

 In practice, each passage opening 2A is situated substantially in the plane of the lower face 1A of the grid 1.

 On each pipe 3 are interposed between this lower face lA and the pipe 5 two complementary antagonistic tightening means 6, 6 ′ between which is held tight hermetically with respect to the surrounding space a semi-permeable element 7 constituted by a metallic fabric .

 Figure 1 shows that the use of the device of the invention does not exclude the use of a secondary air circuit. This circuit comprises, in this example, a secondary air manifold 8, assigned to the row of pyramids considered, to supply the individual tubes 9 which open at 10, substantially above the large upper square base 11 of each of the trunks of pyramids 2.

 Figures 2 and 3 show in more detail a trunk of a pyramid 2 and the method of mounting a semipermeable element.

 These are pyramid trunks with a large square upper base, 324 millimeters on side a, of height h equal to 230 millimeters, with lateral faces which make with the vertical, an angle a of 26 ". Each trunk of pyramid has a lower opening 2A which is connected to an individual tube 3 of 90 millimeters in diameter. Each tube 3 is composed of two successive sections 3A, 3B assembled by means of two flanges 6 and 6 '. Between these two flanges is held tight a circular metallic fabric 7 having meshes the opening of which is a square of 0.250 millimeter on a side. On this fabric the coefficient of free section, that is to say the ratio between the open surface of the meshes and the total surface, is equal to 0.34.

 The length L of the section 3A which starts from the lower opening 2A, at the lower base 12 of the pyramid trunk 11, up to the upper flange 6, is 270 millimeters, or 3 times the diameter D of 90 millimeters of the individual tubing 3.

 Figure 4 shows an alternative mounting of the semi-permeable element 7. The two sections 3A, 3B in extension are each terminated by an external thread 13, 13 'on which is screwed the corresponding flange 6, 6' which is threaded internally. By turning the two screwed flanges 6, 6 'in the correct direction, the semi-permeable element 7 can be clamped together, retaining the possibility of easily dismantling it, simply by turning the flanges 6, 6' in the opposite direction, without disturbing moreover the tubing 3.

 FIG. 5 shows an alternative embodiment of a semi-permeable element 7; it is produced in a sheet having numerous perforations 14 inside a non-perforated peripheral annular zone 15. This is intended to be clamped between the flanges 6, 6 '.

During the manufacture of a device conforming to
The invention respects manufacturing tolerances from which it results in differences between the losses produced by each semi-permeable element 7.

 It is therefore necessary to calibrate beforehand the various elements 7, in order to know the pressure drop of each of them as a function of the different air flow rates. Of course, it is not essential that the pressure drop, at a given flow rate, be strictly the same for all the elements 7 of the same row of trunks of pyramids 2. It suffices that the deviations from the value average pressure drop is less than 10%.

 For a material of a given nature to be fluidized, the speed of flow of the fluidizing gas at its outlet from the passage openings 2A must be greater than a minimum speed below which the largest particles would deposit.

 In the present exemplary embodiment, for the fluidization of the coal, at a flow rate of 400 m3 / h of fluidization gas in each individual tube 3, the pressure drop of each of the semi-permeable elements 7 was close to 5 millimeters of column of mercury (6.66 hPa) and at a flow rate of 1600 m3 / h these losses ranged between 65 and 80 millimeters of mercury (86.65 and 106.65 hPa).

 A similar calibration must be done beforehand when porous elements are used, instead of metallic fabrics, for example porous refractory discs, or porous sintered glass discs, or else compact refractory discs in which narrow passages are provided. in the form of narrow slots or very small diameter holes.

 The advantages of the device of the invention are numerous.

 First of all, the device used is simple and inexpensive. A single valve provided at the inlet of each pipe 5 is sufficient to regulate a determined overall flow rate of fluidizing gas through the passage openings 2A supplied by the pipe considered. Each individual tube 3 is simply provided with a semipermeable flat element 7, fixed between two flanges 6, 6 '.

 Then, a suitable distribution of the fluidizing gas between the various openings 2A supplied by the same pipe 5 is ensured by the choice of the elements 7 as a function of the pressure drop created by each of them. A too low pressure drop per element would allow unequal flow between the openings 2A. Too high a pressure drop would not allow a sufficiently high gas flow rate to ensure good fluidization above the grid 1.

 This is why the semi-permeable element to be placed on each individual tube must be chosen according to each type of fluidization grid.

 Another advantage of the device of the invention is to prevent the entry of solid particles in the upstream part of the individual tubes, that is to say in the section 3B and in the pipe 5. In the part of the tubes 3 located downstream, therefore in the section 3A above the semi-permeable elements 7, particle deposits occur when the fluidization stops, but since this section 3A of the pipes 3 is very short (less than 4 times the diameter) there is no difficulty in re-establishing the fluidization by a simple admission of the fluidization gas into the conduits 5.

 Thus, with the device of the invention, the effect of sedimentation of the particles has no untoward consequence influencing the stopping and the restarting of a fluidization installation.

 The preferred method of mounting, described above, of the semipermeable elements 7 at a location below the grid 1, rather than just in the blowing openings 2A as is possible, provides the advantage that one can access these elements 7 during the stop as during the running of the installation, to replace some elements 7 by others having a different pressure drop for example. In this case, the complementary tightening means, which are of an easily removable type, are part of the device of the invention.

 It is understood that one can, without departing from the scope of the invention, imagine variants and improvements of details, as well as envisage the use of equivalent means.

Claims (15)

 1. Fluidization gas supply control device for fluidization grid (1) intended to support a bed of particles to be fluidized, having numerous blowing openings (2A) each joined to a fluidization gas inlet to allow the passage of a fluidizing gas through a straight section of passage with a determined value, characterized in that it comprises, for each of the blowing openings (2A) a semipermeable element (7) occupying said straight section of passage and traversed by channels (14) allowing passage to the fluidizing gas and capable of stopping in the opposite direction to the circulation of this gas at least a substantial fraction of the particles of the bed of particles to be fluidized at the time of the stopping of the fluidization.  2. Device according to claim 1, characterized in that the semi-permeable element (7) is mounted in the blowing opening (2A).  3. Device according to claim 1 for fluidization grid (1) having blowing openings (2A) each connected, below said grid (1), to an individual tube (3) for supplying fluidization gas, characterized in that each semi-permeable element (7) is mounted in said individual tubing (3) at any location along the length thereof.  4. Device according to claim 2 characterized in that the mounting location is distant from the grid (1) by a distance which is not greater than four times the diameter of this individual tube (3).  5. Device according to claim 1 characterized in that the semi-permeable element (7) is flat.  6. Device according to claim 5 characterized in that it is held in place by additional clamping means (6,6 ') of easily removable type.  7. Device according to claim 3 wherein each tube (3) is composed of two sections (3A, 3B) and the device further comprises complementary clamping means (6,6 ') fixed correspondingly on the two sections (3A , 3B) and able to hold together a semi-permeable element (7).  8. Device according to claim 1 characterized in that the semi-permeable element (7) has passage channels whose orifices have dimensions between 0.15 and 0.60 mm.  9. Device according to claim 1 characterized in that the semi-permeable element (7) is crossed by passage channels so that the ratio between the passage surface and the total surface is between 0.30 and 0 , 60.  10. Device according to claim 5 characterized in that the semi-permeable element (7) is a wire mesh.  11. Device according to claim 5 characterized in that the semi-permeable element (7) is a perforation plate (14), the perforations are preferably located inside a non-perforated peripheral annular zone (15) .  12. Device according to claim 5 characterized in that the semi-permeable element (7) is a disc made of porous refractory material in which the ratio between the passage surface and the total surface is between 0.30 and 0.60 .  13. Device according to claim 1 for a fluidization grid (1) intended to support a bed of particles producing in the state of fluidization a pressure drop of determined value, characterized in that the semi-permeable elements (7) are chosen to create a pressure drop of between 20% and 100 X of said determined pressure drop.  14. Device according to claim 1 for fluidization grid (1) constituted by a multiplicity of blowing openings (2A) located at the base of trunks of pyramids (2) or trunks of inverted cones, characterized in that said openings supply air are divided into groups and the openings (2A) of each group are each connected to a pipe (5) corresponding to By means of individual pipes (3) in each of which a semi-permeable flat element (7) is mounted between the grid (1) and the pipe (5) at a distance from the grid (1) which is at most equal to four times the diameter of the tube (3) on which this semi-permeable element (7) is located.  15. Fluidizing grid with blowing openings (2A) intended to be supplied with fluidizing gas to fluidize a bed of fluidizable particles, characterized in that, on the path of passage of this fluidizing gas, a control device is installed. The supply consisting at least of a semipermeable element (7) traversed by channels (14) for the passage of the fluidizing gas with a ratio between the passage surface and the total surface of between 0.30 and 0.60, these channels (14) being capable of stopping in the opposite direction the passage of at least a substantial fraction of the particles of the particle tit.