FR2582539A1 - Filter cell for separating the liquid phase from a suspension of pulverulent solids - Google Patents

Abstract

This filter cell is characterised in that it comprises two planar sheets 1, 2 adjoining along a joint plane, clamped one against the other and trapping between them at least one planar filter element 3 defining, with the two sheets 1, 2, respectively, a first compartment fed with suspension and a second compartment collecting the filtrate and a channel 10 for guiding the flow of the suspension between the two orifices for entry 8 and exit 9 is housed in the first compartment, this guiding channel 10 following a sinuous or spiral path between these two orifices.

Description

 The present invention relates to a filtration cell for the separation of the liquid phase from a suspension of pulverulent solids.

 Many industries use suspensions of pulverulent solids in liquids. These solids can be mineral materials (minerals, materials, etc.) of various shapes and sizes, the average equivalent diameter of the solid quantities not exceeding 2 min and the minimum value of this diameter being of the order of 0, 1 micron, or even organic materials such as fibers. The concentration of solid matter can vary from 0.01% to 60-70% by mass. The liquids are mainly constituted by aqueous solutions containing more or less concentrated chemical compounds, or even organic solvents.

 In installations using such suspensions of pulverulent solids, it is necessary to be able to carry out, at various points in these installations, checks of the characteristics of the single liquid phase. These characteristics can be various physico-chemical parameters such as the pH, the ox> do-reducing power, the residual concentration in different compounds, the concentration in a determined dissolved gas, the viscosity, the temperature, etc.

 The physico-chemical parameters of the recovered liquid, free of solid particles, can be checked using different techniques such as electro-chemical sensors, spectroscopy, thermal probe, liquid or organic chromatography, atomic absorption, etc.

 The object of the present invention is to provide a filtration cell of particularly simple design making it possible to reliably ensure the separation of the liquid phase from a suspension of pulverulent solids.

 To this end, this filtration cell is characterized in that it comprises two flat plates placed side by side along a joint plane, tightened one against the other and trapping between them at least one plane filter element imitating, with the two plates, respectively a first compartment fed with suspension and a second compartment collecting the filtrate, that is to say the liquid phase separated from the suspension, the first plate in which the first compartment is hollowed out, is pierced with at least one inlet orifice and at least one outlet for the suspension, one of these orifices being close to a side wall of the compartment while the other orifice is located at a distance from the first in a central position or substantially on a central axis, and in the first compartment is housed a channel for guiding the flow of the suspension, between the inlet and outlet orifices, this guide channel extending along a sinuous or spiral path between these two holes.

 According to an additional characteristic of the invention the guide channel of the suspension is delimited by a sinuous or spiral partition forming an integral part of the first plate and which extends perpendicularly from the bottom of the first compartment of this plate.

 According to an alternative embodiment of the invention the guide channel of the suspension consists of a sinuous or spiral partition which is integral with the face of the filter element facing the first compartment.

The filtration cell according to the invention is inserted into the usual circuit traversed by the suspension from which the liquid phase must be extracted, by means of a connection module in bypass on the main pipe.
The filtration cell according to the invention offers the advantage of being very robust and of being very easy to maintain.

Various embodiments of the present invention will be described below, by way of nonlimiting examples, with reference to the attached drawing in which
Figure 1 is an exploded perspective view of a filtration cell according to the invention
FIG. 2 is a plan view of the lower plate of an alternative embodiment of the filtration cell, a plate which is hollowed out so as to present the channel for guiding the flow of the suspension.

 Figure 3 is a sectional view taken along line III-III of Figure 2.

 Figure 4 is a perspective view of a filtration cell whose upper plate is pivotally mounted g about a horizontal axis.

Figure 5 is a schematic elevational view of a connection module of the filtration cell
The filtration cell according to the invention which is shown in FIG. 1, consists of two flat plates, namely a lower plate 1 and an upper plate 2 which are joined together along a joint plane and trap at least one filter element between them. plan 3.

This filter element comprises a filter medium 4, constituted, for example, by a membrane or a canvas, surrounded by a molded border 5 made of plastic.

 In the embodiment of the invention shown in FIG. 1, the filter element is fitted, by its projecting border 5, into a recess 6 of the same shape which is formed in the upper face of the lower plate 1. In the bottom of this recess 6 open two orifices, namely an inlet orifice 8 for the flow of aqueous suspension and an orifice 9 for the outlet of this suspension. The two orifices 8 and 9 are drilled right through in the plate 1 and they open into the underside of the latter to be connected to bypass pipes themselves connected to the main pipe from which the suspension must be extracted, as we will see later.

 According to a variant embodiment, the lower plate 1 could be pierced with several orifices P and with several outlet orifices 8.

 The filter element 3, when clamped between the two plates 1 and 2, delimits with the plates two compar peppers, If knowing a lower compartment in which the suspension circulates, between the orifice of P and the orifice outlet 9, and an upper compartment o is collected the liquid phase which has just been separated from the suspensiOn.

 In the embodiment of the invention shown in Figure 1 the filter element 3 carries, on its underside, that is to say that delimiting the lower compartment, a guide channel intended to channel the flow of the suspension, in the lower compartment, between the inlet orifice (s) and the outlet orifice (s) 9, so that this flow follows a substantially spiral path, as indicated by the arrows ches of Figure 1. This spiral guide channel is materialized by a partition 10 which is integral with the underside of the filter element 3 and which extends in a spiral, so as to form a sealed channel starting from the where the inlet 8 is and going to where the outlet 9 is. As can be seen in Figure 1, the inlet 8 is close to the side wall of the recess 6 in which the filter element 3 is housed, that is to say of the side wall of the lower compartment laughing, while the outlet orifice 9 is located on the longitudinal axis of the lower plate 1 and of the recess 6 or in the vicinity of this axis following that the number of turns of the spiral is even or odd. However, the reverse arrangement could be adopted, that is to say that the suspension could be introduced into the lower compartment through the orifice 9 playing the rote of the inlet orifice and it could exit through the orifice 8.

 According to an alternative embodiment, the flow guide channel could extend along a sinuous path between the inlet orifice (s) 8 and the outlet orifice (s) 9.

 Preferably the inlet orifice 8 is inclined relative to the vertical so that the direction of the flow of the suspension makes, when it enters the lower compartment, an obtuse angle open downwards, as can be seen. see the shape of the first arrow materializing the flow in Figure 1.

 The spiral or sinuous shape of the suspension guide channel makes it possible to minimize the pressure drop in a relatively small space and the filtering surface can thus be used in an optimal manner. Furthermore, the dimensions of the spiral filtration channel are chosen so as to ensure good hydraulic distribution of the liquid. For example the channel delimited by the wall 11 in a spiral can have a width of 4Nmm and a height of 5mm, which gives, for a flow speed of the suspension in the lower compartment of fl, 5m / s a flow of 0 , 35 m3 / hour of suspension inside the cell.

 During the spiral or sinuous flow of the suspension to be filtered in the lower compartment, this remains in contact with the filter element 4 and under the effect of the pressure, the liquid phase passes through the filter medium 4 and passes into the upper compartment which is delimited by the edge 5 of the filter element 3 and the lower face of the upper plate 2. In this plate 2 is pierced a conduit 10 which opens into the lower face of the plate on the one hand in the upper compartment, inside the border 5 of the filter element 3, and on the other hand outside this border, at a point where it is connected with another conduit 11 drilled in the lower plate 1 and opening into a lateral face thereof.

This conduit 11 is connected to an apparatus intended to measure the physico-chemical parameters of the filtrate.

 Figures 2 and 3 show an alternative embodiment in which the filtration channel is delimited by a spiral (or sinuous) wall 12 forming an integral part of the lower plate 1 and extending upwards, perpendicular to the bottom 7 of the recess 6. In this case, the lower face of the filter medium 4 of the filter element 3 is strictly flat and bears on the upper edge of the spiral partition wall 12.

 The plates 1 and 2 feel clamped on each other by any suitable means. Preferably, as shown in FIG. A, the upper plate e 2 is mounted so as to be able to pivot, relative to the fixed lower plate 1, around a horizontal longitudinal axis xx ′ which is offset laterally, which facilitates the opening of the filtration cell, for example when it is a question of changing the filter element 3.

 In all embodiments of the invention the wall delimiting the guide channel is made, preferably rené, in a non-abrasive material.

 FIG. 5 illustrates an embodiment of a connection module 13 which is intended to connect the filtration cell according to the invention to a pipe 14 in which the suspension circulates from which it is desired to extract the liquid phase. The connection module 13 comprises a tube section 15 intended to replace the equivalent part of the pipe 14 and comprising a control valve 16. To this tube section 15 are connected two connection tubes 17 and 18 provided with respective valves 19 and 20 and which are in turn connected, via two respective flexible tubes 21 and 22, to the inlet 8 and outlet 9 ports of the suspension in the cell.

 FIG. 5 also shows a measuring device 23 which is connected to the conduit 11 of the lower plate 1 through which the filtrate exits, the physico-chemical parameters of which must be analyzed.

Claims (6)

REVENDIC7TIO'JS  1.- Filtration cell characterized in that it comprises two flat plates (1,2) joined in a joint plane, clamped one against the other and trapping between them at least one planar filter element (3) delimiting , with the two plates (1,2), respectively a first compartment supplied with suspension and a second compartment collecting the filtrate, that is to say the liquid phase separates from the suspension, the first plate (1) in which is dug the first compartment is pierced with at least one inlet orifice Ce) and at least one outlet orifice (9) for the suspension, one of these orifices (8) being close to a side wall of the compartment while the other orifice (9) is located at a distance from the first in a central position or substantially on a central axis, and in the first compartment is housed a channel (10) for guiding the flow of the suspension, between the inlet (8) and outlet (9) orifices, this guide channel (10) extending along a pa sinuous or spiral course between these two orifices.  2.- filtration cell according to claim 1 characterized in that the guide channel (10) of the suspension is delimited by a sinuous or spiral partition forming an integral part of the first plate (1) and which extends perpendicularly to from the bottom (7) of the first compartment of this plate.  3.- filtration cell according to claim 1 characterized in that the guide channel (10) of the suspension is delimited by a sinuous or spiral partition which is integral with the face of the filter element (s) facing the first compartment.  4.- filtration cell according to any quPlconque of the preceding claims characterized in that in the second plate (2) is pierced a conduit (in) which opens ds the inner face of the plate on the one hand in the second compartment to inside the border (5) of the filter element (3), and on the other hand outside this border, at a point where it is connected with another coniuit (iî # drilled in the first plate (1) and opening into a lateral face thereof, this latter conduit (11) being connected to an apparatus (23) intended to measure the physico-chemical parameters of the filtrate.  5.- filtration cell according to any one of the preceding claims, characterized in that the second plate (2) is mounted so as to be able to pivot, relative to the first fixed plate 1, about a horizontal longitudinal axis xx ' which is laterally offset. The suspension in the cell.  6.- filtration cell according to any one of the preceding claims, characterized in that it is connected to a pipe (14) in which the suspension circulates, from which the liquid phase is to be extracted, by a connection module (13) comprising a tube section (15) intended to replace the equivalent part of the pipe (14), comprising a control valve (16) and b which are connected two connection tubes (17,18) provided with respective valves (19,20 ) and which are in turn connected, via two respective flexible tubes (21,22), to the inlet and outlet ports (8,9) of