CS209449B2 - Multislot nozzle for filtration injections - Google Patents

Description

BACKGROUND OF THE INVENTION The present invention relates to a multi-slot nozzle for filter injections, in particular for supplying and discharging liquid reaction mixtures from an ion exchange bed of reactors which are used to carry out ion exchange catalysed chemical processes.

For fine-grained fillers such as ion exchangers, filter nozzles are essential because their design is critical to technological operating results and installation costs. The faultless function of these nozzles guarantees the continuous operation of the entire installation, the simple design and installation of which is crucial for the cost of the reactors. The cost of the nozzle base used so far is up to 60% of the entire device. Flawlessly designed and fitted nozzles should have constant flow resistances, should not be clogged with filler, and should allow liquid to flow on both sides over a wide load range.

The prior art filter nozzles have been used essentially for water purifiers filled with ion exchangers. These operate in cyclic operation, and during the work periods the nozzle cleaning and layer tinting can be performed by means of a return flow and an increased flow rate. Such devices have 100 to 800 nozzles built into the bottom. Hence, candles wrapped with filter cloth or bell-shaped slit nozzles with slit slits have been used as nozzles.

There are also known bottom mounted nozzles which consist of flat, stacked, plastic-made disks, which are connected together by means of a central screw, thereby forming an internal channel for the flow of liquids and slots between the disks.

The basic disadvantage of the prior art nozzle designs is that they become clogged with catalyst particles, which is associated with increasing flow resistances during filtration. The basic reason for this is that filter slots of the same height are too long. Although they show good results for periodic operation of variable flow devices, these filter nozzles are not suitable for filter-filled devices, especially if the filler has a non-uniform grain size. Moreover, these nozzles, constructed of plastic, are not suitable for an environment other than water, especially when it is a chemically aggressive effect of the environment at elevated temperature.

The above-mentioned drawbacks are eliminated by a multi-slot nozzle for filter injections, in particular for the removal of liquid reaction mixtures from the ion exchange bed according to the invention, which consists in the fact that the rings are circumferentially circumferentially disposed in the nozzles. a triangle or a blunt tip triangle whose base lies in the plane of the profile ring, the profile rings being connected by at least three fastening screws, and the top or bottom nozzle plate comprises a nozzle for fluid inlet and outlet through the central channel, while filter slots are expandable inserts , arranged between two adjacent. myself. The thickness of the spacers corresponds to the height of the filter slots and their holes are mounted on the fastening screws.

The design of the nozzle according to the invention makes it possible to use a liquid inlet and outlet with the largest possible diameter and ensures that the flow of liquid between the slots and the central channel occurs at a slight flow resistance, since the flow height δ of the nozzle slot to its central opening widens many times. The inner diameter of the fluid supply nozzle by one of the outer nozzle plates is about half the outer diameter of the nozzle. The possibility of increasing the amount of crates in the nozzle is of particular importance, namely when the liquid flows from the ion exchange bed of the reactor to the nozzle, as this creates an additional filter slot surface which even with partial grain clogging guarantees the necessary nozzle performance in continuous operation. In addition, by increasing the nozzle height, the inflow from the ion exchanger bed of the reactor E facilitates this purpose, but it is possible to produce gray shaped pieces without filter rings from the nozzle rings. Because the projection was formed in the shape of a triangle, is it? konsímikee; solid and stable.

Made and thickened nozzle, according to the botoalysis; ptacaje; and, in a remarkable manner, the essential advantage is that it contains leaking nozzles that must be emptied completely. This operation is particularly difficult and. it takes Mofea time in reactors that work with poisoning. Other advantages of the nozzle according to the primers; It is said that these rods of the device can be installed individually or as a result of the nozzle without making the jets. Most preferably, the nozzles are inserted into the apparatus; using suitable wide nozzles, do not depend on whether these are; aáfeaibky weéottap. a®, the bottom of the iMmk on the cylindrical wall · of the device. The nozzles can also be placed in one plane; or many different heights, eg. for a domed appliance, the nozzle should be at the lowest point of the bottom;

The nozzle according to the invention is characterized by a single construction of all the bosses which can be made of any material by three-part machining, and the final shape of the projection on the profile rings can be made by pressing with a suitable tool. All nozzle components according to the invention can be made of plastics with suitable mechanical and chemical strength by injection molding.

The shape of the nozzle according to the invention with the spacer inserts used is particularly advantageous in that the variation in the thickness of the slot is easily feasible. All you have to do is fit the spacers with others of the required thickness. The nozzle according to the invention with recesses on the profile ring projection allows, if necessary, to increase the thickness of the slots by means of spacers on the fastening screws.

BRIEF DESCRIPTION OF THE DRAWINGS The invention is explained in more detail by means of one embodiment, shown in the drawings, which show, in FIG. 1, a longitudinal section. nozzle. According to an exemplary embodiment, the fastening bolts are located outside the nozzle body and abut its outer cylindrical surface; Fig. 2 shows a cross-section of the nozzle in line A-A of Fig. 1; Fig. 3 is a longitudinal sectional view of the composite nozzle as in Fig. 1, except that the fastening screws are arranged inside the central channel of the nozzle; Fig. 4 shows a cross-section of the nozzle in the plane A '- A' of Fig. 3j in Fig. 5, a section of the profile ring with two recesses at the edge of the projection, one lying in a plane parallel to the plane of the profile ring and the other at 0 ° up to 90 ³ to this plane; 6, 7 and 8 show optimum shapes of the one-sided protrusion; FIG. 9 shows the optimum shape of the double-sided protrusion of rings of steel or other high strength fabrics; 10, 11 show the profiles of rings made of plastics or of other substances of lower meohma-soft jwmaatl; pao-jkdnwwswcnp ^ a to obB. .12 ». 13- oven rings for. Double-sided outletBreakaway visorBbl »nozzle® according to® -w remains. They are provided in the form of profiled rings in the form of profile bodies which are shaped and have a secondary channel> 3 for the flow of liquid. wherein the profile rings 1 and Bpevftseaffil1; screws a and two outer boards, with, game board »3 * and fall ,. they are uncontrolled. In the embodiment shown, the lower plate 3 is stripped with strings:. _of supply or discharge the fluid ůstředoím; 2L ¹ At least - three pieces; Upstream and downstream of the nozzle, these may be located within or within the nozzle compartment of the nozzle. In any case, the fastening screws 4 touch the surface of the nozzle body to prevent the profitable rings-1 from being moved perpendicular to. Central channel-2.

Profiled rings 1 have no SIM its periphery, either ^one-sided protrusion of Fig. 5, 6, 7, 8 ». 10 and 11, not the double-sided projection 8 'according to FIGS. 9-, 12?, 13', wherein the projection can be in the form of a triangular or after heating; angular: corner .do * tn209449

With a trapezoid ru or even like another geometric figure. Selected embodiments of protrusions are shown in Figures 5 and 13, although these are not all embodiments.

The projections 8, 8 ‘of Figs. 6 to 9 relate to profile rings 1 made of high mechanical strength materials such as steel and metal alloys. 10 to 13, on the other hand, show projections 8, 8 'for profile rings 11 consisting of lower strength materials, such as plastics and others.

The filter slots 7 are formed by spacers 6 placed on the fastening screws 4. Between the profile rings 1 there are spacers 6i. of the same thickness; as; filter, slots 7.

The filter slots 7 may also be formed by recesses 9 on the tip circumference of the profile ring, wherein the blunt recesses 9 occur alternately with sections of un-blunt tips 18 of the projections. 8, thereby supporting the counterparty; The proximal profile ring 1 and the intermediate slots 7 loosen, as can be seen in the lower part: the nozzles in FIGS. 3 and 5.

The risk of clogging of the filter slots with the grain of the filter bed has been avoided as far as possible in the flow direction. The length of the filter slots 7 measured in the direction of flow depends on the thickness of the material from which the nozzle is made, as well as on; nozzle diameter and height · filter slots. ¹ The higher strength of the nozzle material, is narrower tí® · slot. E.g. the length 1 of the slit 7 of the steel nozzle may be less than 0.2 mm, while for the plastic nozzles of large diameter and the height h of the slots 7, the length 1 of the slit 7 may be several millimeters long. Most preferably, the length of the slot 7 is less than its height h. This substantially counteracts the clogging of the slot and reduces the flow resistance. The dimensions of the filter slots are shown in Fig. 5. The length of the filter slot 7 is indicated by the letter 1, its height by letter h and the width of the recesses 9 in the protrusion 8 by letter d. the devices did not escape through the slots. The performance of the nozzle according to the invention can be increased as desired either by accumulating a plurality of rings in the nozzle or by increasing its diameter, i.e. the total area of the filter slots.

It is advantageous to design the projection 8 in cross section as a rectangular triangle, one side of which forms the outer wall of the nozzle element. Depending on the technological accuracy of the profile rings 1, the triangular projection 8 can be obscured so that the lateral displacement of these profile rings 1 does not distort the filter slots 7.

The fastening screws 4 should be evenly tightened, especially with a dynamometer wrench, in order to avoid damaging deformation of the expanding protrusion formed by the unsupported tip 10 on the profile rings 1 or spacers 6 on the fastening screws 4. Therefore the bolt nut washers should be used or certain spring washers. Screw nuts must be secured with counter nuts or otherwise against accidental jamming.

The direction of liquid discharge from the nozzle filter slots 7 is generally perpendicular to the nozzle axis. In some cases, however, it is preferable to change the direction of the fluid flowing out of the nozzle filter slots. This change can be made in the nozzle according to the invention by placing a three notch 11 m; This notch 11 can be placed on all nozzle profile rings 1 at the same angle or at different angles of cd 0 ° to 30 °, thereby receiving the flow streams from the different nozzle slots any direction.

The filter slots can be just as well formed as a recess on a portion of the tip of the projection along the entire circumference of the profile ring, the slots protruding alternately with the non-blunt portions of the projections in the form of spacer sleepers which are on. They support the nozzle filter slots together with the recesses.

The screws holding the nozzle set together should preferably be arranged symmetrically either inside or in the central nozzle channel. If they lie close to the periphery of the nozzle, these screws prevent the profile rings from moving vertically to the axis of the central channel of the nozzle.

The direction of fluid flow from the nozzle can be deflected from the nozzle axis by providing recesses that form a triangle in longitudinal section along the entire circumference of the profile rings on the opposite side of the projection. One side of the triangle lies in the plane of the profile ring. The other side, on the other hand, lies in a plane perpendicular to the cylindrical outer surface of the profile ring. The angle of the triangle opposite from the side perpendicular to the cylindrical surface of the profile ring is from 0 ° to 30 °. The length of the filter slot, determined by the length of the shortest trapezoidal base, was formed by blunting the upper edge of the projection in a plane parallel to the base. The length of this trapezoidal base is preferably three times greater than the thickness of the slot, the latter corresponding to the thickness of the spacer between the filter rings or their recess on the partial periphery of the projection.

The nozzle is made of any number of profile rings with at least three screws that connect the rings to the two outer plates into one body, one plate having a built-in nozzle that serves to supply and drain fluid through the central channel of the nozzle.

Claims (7)

PREDMST Multi-slot nozzle for filter injections, in particular for the removal of liquid reaction mixtures from an ion exchange reactor bed, consisting of repeating elements in the form of profile rings assembled into a cylindrical housing with a central channel and filter slots on the liquid flow circuit, the profile rings (1) have, on their circumference, longitudinal section of the nozzle axes, one-sided protrusions (8) or two-sided protrusions (8 ') which are formed as a triangle or a blunt-tipped triangle whose base lies in the plane of the profile ring (1); the profile rings (1) being connected by means of at least three fastening screws (4) and two outer plates, of which the upper plate (3) or the lower plate (3a) comprises a nozzle (5) for the inlet and outlet of the fluid through the central channel (2), whereas the filter slots (7) are formed by spacers (6), arranged between two side-by-side profile rings (1), the thickness of the spacer (6) corresponding to the height (h) of the filter slots (7), and their holes are mounted on the nozzle mounting screws (4). Multi-slot nozzle according to claim 1, characterized in that the nozzle filter slots (7) are formed by recesses (9) at the periphery of the projections (8, 8 ') of the profile ring (1), the blunt tips (10) of the projections (8, 8'). ) stand out alternately between the recesses (9) And support the counterpart of the nearest profile ring (1) to form filter slots (7). Multi-slot nozzle according to claim 1, characterized in that the fastening bolts (4) are located inside the central duct (2) of the nozzle. Multi-slot nozzle according to claim 1, characterized in that the fastening bolts (4) are located on the periphery of the nozzle barrel. A multi-slot nozzle according to claim 1 or 2, characterized in that the length of the short trapezoidal base formed after blunting the upper edge of the projections (8, 8 ') forms the length (1) of the nozzle filter slot (7) which is three times smaller than height. (h) filter slots (7). Multi-slot nozzle according to claim 1 or 2, characterized in that the profile rings (1) with one-sided protrusions (8) have notches (11) on the opposite side, which in longitudinal section through the nozzle axis are triangular with one side in the plane of the profile ring ( 1) and the other side in a plane tangential to the circumference of the profile ring cylinder (1), wherein the angle opposite this tangent plane measures from 0 ° to 30 °. Multi-slot nozzle according to claim 1 or 2, characterized in that cylindrical shaped pieces of the same diameter as the profile rings (1) are inserted between the profile rings (1) and serve to extend the nozzle. 3 sheets of drawings of Severografia, n. P., Plant 7, Most