SE462549B - KEEPING AND DEVICE FOR PARTICULATE DISPOSAL AND APPLICATION OF THE DEVICE - Google Patents

Description

462,549 major fire damage and accompanying major loss of production for the plant.

It is known that when using conventional sprinkler systems, each sprinkler head produces relatively large amounts of water per unit time and where the requirement as above is that virtually all sprinkler heads must be in operation, the total amount of water must therefore be minimized in order to avoid unnecessary water damage to the plant and partly reduce the total amount of polluted water that must be disposed of.

To solve these and other accompanying problems, the water must be atomized. Therefore, tests have been made with sprinkler heads provided with nozzles, hereinafter referred to as nozzle openings, which atomize the water into very small water droplets or mist, with which a more efficient extinguishing and a limitation of the amount of water can be achieved. It has been found that in these nozzle openings, which in the present case have a diameter of about 1.2 mm and which in addition have in themselves arranged additional atomizing means before the openings are very sensitive to clogging.

In commonly used sprinkler systems, thermal nozzles are provided, ie each nozzle has a thermal fuse, which is opened at the selected temperature, eg 7000. In this case, the pipe system is filled with water and pressurized.

In the event of any impact on the nozzle, water sprays uncontrollably and the same effect is of course also present in the event of pipe rupture. In plants where such a malfunction cannot be accepted, a group trip system can be useful. In these cases, the system is filled with water and pressurized up to a padrag valve. After the paddle valve up to the nozzle openings, the pipe network is not filled with water. In the event of, for example, a signal from a fire alarm or the like, the pad pull valve opens.

The pipe network is filled with water and water begins to spray from the nozzle openings.

Since you do not want to take the risk of such a malfunction of the system, you therefore choose to install a dry-pipe system with a central pass valve. The supply pipes in these systems can sometimes have lengths of a few kilometers. These pipes are usually of the galvanized pipe type, which entails the risk of flakes forming from the galvanization or for rust flakes, and in addition water always has a unique composition for the water source in question, and can, for example, despite waterworks and treatment, have such a composition that leaves solid deposits of eg calcium carbonate CACO; or the like, which spreads in the system. 3 r 462 549 In the event of a pass release of the water flow in the system, these types of particles will in all probability be torn off and quickly fill the nozzle openings. (In practical tests, it turned out in one case that 96 of 126 sprinkler heads quickly became unusable). This means that some form of particle separation must take place before the water enters the sprinkler nozzles.

This cannot be achieved with conventional filters due to the rapid clogging thereof.

Of course, these problems do not exist alone. in sprinkler systems, but they can just as easily be present in all types of flows, which are polluted by particles and which must pass through narrow passages, such as nal valves and the like, and where the flow must not be stopped. Compare, for example, fuel supply. The problem also exists, of course, not only when the flux has a lower density than the solid particles but also when the solid particles have a lower density than the flux.

Brief Description of the Invention The object of the present invention is to obviate the problems which arise in the separation of solid particles from a flow, wherein device with the constituent parts cooperates to prevent the separated solid particles from clogging the filtering surface, hereinafter referred to as the screen. .

This object is achieved according to the invention by a method for continuously separating solid particles from a liquid flow flowing in a line, wherein the liquid flow at the entry into the device is set in rotation by means of a rotating means and that the flow is then passed through a filter arranged at the downstream end of the device. , the filter comprising at least one screening surface. The invention also relates to a device for continuously separating solid particles from a liquid flow flowing in a line, the device, which is placed in a filter housing comprising an upstream end and a downstream end, that the upstream end of the wide device is a flow rotating means arranged in rotation. about an axis of rotation, and that at the downstream end of the device a filter is arranged with a screening surface arranged in the path of flow substantially parallel to the axis of rotation of the flow, and a screen surface is arranged so that it constitutes a downstream barrier for the non-filtering flow. 462 549 Depending on the density of the flow versus the density of the solid particles, two effects arise.

As the particles are heavier than the flow, they will move outwards and accumulate on the inside of the surface surrounding the device, which is substantially parallel to the axis of rotation of the feed. In Da the particles are lighter than the flow the opposite will happen ie the particles will move towards the device center.

The invention will now be described with reference to the accompanying drawings in which: Fig. 1 shows an embodiment of a separating device for use with sprinklers. Fig. 2 shows another embodiment of a separating device for placement in a trunk line. Fig. 3 shows an embodiment with support pipe, screening surface and guide rail.

Fig. 4 shows an embodiment according to the invention with a different design of the guide rail than in Fig. 3. Fig. 5 shows an embodiment according to the invention, similar to that in Fig. 2, with guide rail.

Fig. 6 shows an embodiment of the filtering end of the device with a draining possibility arranged at the downstream end of the device alt. a constant small outflow.

Fig. 7 shows an embodiment similar to that in Fig. 6.

Figs. 8, 9, lüa + b show embodiments of the filter for combination with different guide rails depending on the density of the flow versus the density of the particles.

Figures 11-12 show examples of different conceivable embodiments of the guide rail.

Brief description of preferred embodiments.

Fig. 1 shows a preferred embodiment of the device as it is used in a sprinkler device with so-called fog nozzles.

The device consists of a pipe or a filter housing 1, which at the end opens into a sprinkler nozzle 17. This nozzle 17 is provided with a plurality of nozzle openings 18 with a diameter of about 1.2 mm. At the upstream end of the device there is a rotating member, here in the form of a spiral-like rail. In this embodiment, the guide rail 7 is attached to, or rests on, a support tube 10, which is provided with a slot 11. At the end of the support tube, also the downstream end S of the device, the support tube is provided with a halved washer 13, which is fixed to the tube by means of eg the sprinkler head 17. On the upstream side of the washer 13 and the support tube 10 is the filter, ie the screen surface 20.1 and the screen surface 20.2 .

The device works as follows. The inflowing flow is denoted by the reference numeral 3, the direction of the flow being indicated by the arrow. When the flow has passed the guide rail 7 at and the particles in the case that they are heavier than the liquid have moved out towards the wall, the rotating movement of the liquid continues even below the rail. Due to the rotating movement of the water, the particles will follow the inside 16 of the tube and abut against it, ie the endurance of the screen against clogging increases. The particles will pack at 15. The water will now flow out unhindered through the slot or semi-equipped support pipe. The upper part of the slit opening can be left open as a safety measure, or can, depending on the special requirements, be covered with a strainer or completely clogged. The mesh size of the screen parts must be <1.2 mm (this dimension is of course dependent on the nozzle openings 18, here mist nozzles are used, which in this special case have a diameter of 1.2 mm.). The mesh size can of course be selected as needed.

The screen surface 20.2 is arranged for the reason that in the event of a pass release of water in the sprinkler system, air first passes, which quickly passes through the system, then comes a turbulent water front mixed with air which will tear off particles, the front will carry the larger part of the contaminants (particles) and these will then primarily be pressed down against the "bottom" 20.2 at the beginning of the process. The screen surface 20.2 which is not parallel to the conduit may in this case be completely covered, which has no significance since the flow in which case mainly passes through the screen surface 20.1. A major advantage of the device according to Figure 1 is the simplicity with which an existing plant can be supplemented with the rotating means and the filter according to the invention. This is easily achieved by unscrewing existing sprinkler heads, inserting filters with rotating means and then screwing on the sprinkler head. Of course, these can also be replaced with the device shown in Figure 1 with a mounted sprinkler comprising fog nozzles. This means that in existing plants 462,549, at a comparatively legal cost, and in addition with easily manufacturable components and with a small work effort, the safety with regard to fire protection can be increased in a very simple and economically advantageous manner.

A further preferred embodiment of the device is shown in Fig. 2. This embodiment can be arranged in, for example, a main line in the Sprinkler system as above and is used as a kind of pre-filter for the filters placed at the sprinkler heads.

The device consists of a filter housing 1, which is incorporated in a conduit (main conduit). Device can of course be connected to the cable in different ways, for example as shown in fig with one or more flange connections 2.

At the upstream end 4, a cone 14 with guide rail (s) (not shown) is arranged with the tip directed towards the flow. In this cone opens a hal-l or slotted support pipe 10. The support pipe is attached to the semi-fitted bottom plate 13. This is located at the device downstream end 5. On the upstream side of the semi-fitted tray and surrounding the support pipe the filter is arranged, ie the screening surface 20.1 and the sieve surface 20.2. Of course, the support tube can be omitted and a self-supporting filter used instead.

The function of the device is broadly the same as that of the device in Fig. 1. The cone 14 can, if desired, be mounted and it is suitably mounted in such a way that it is movable. This movement in the upstream or downstream direction thereby provides a flow rate suitable for the peeling through the device. For the same purpose, the cone can be made so that its base is adjustable.

Combinations of these two embodiments with different guide rails are of course conceivable. This device also proves to be easy to manufacture, easy to assemble and it entails low manufacturing and assembly costs, and of course greatly increases operational reliability. The assembly of the device in figure 2, also entails all the advantages mentioned above, and entails that it will take additional time before the filters are put at the sprinkler heads: again. Figs. 3, 4 and 5 show more schematically similar embodiments of the previously shown shapes. Fig. 5 shows how the guide rails can be arranged on the cone 14 and a slightly different design of the filter housing. What has been said in connection with Fig. 2 about the cone's mobility and base radius naturally also applies here. 462 549 Figures 6 and 7 show how the filter draining device is intended. Fig. 6 shows an arranged draining device and in addition a tapping point 26 for a constantly small outflow and in Fig. 7 there is a draining device, for example in the form of a valve 25.

The filter in Fig. 8 consists of a tube 1 in which a circular support tube 10 is concentrically arranged. Around the support tube 10 is the screening surface 20.1 and the downstream end of the filter consists of the screening surface 20.2. This filter is intended for cases where the particles 15 have a higher density than the liquid flow.

The filter in Fig. 9 in the same way consists of a tube 1, in which a filter is arranged consisting of two circular wall surfaces arranged cononentrically with the tube, the outer of the two constituting the screening surface 20.1. This filter also terminates at the downstream end of the screen surface 20.2. This filter is intended for the case that the particles 15 have a lower density than the liquid flow.

In experiments with the embodiment according to Fig. 1, it has been found that about 90% of the particles, in the event that a mixture of soil, sand and styrofoam is used, stick tightly packed towards the bottom (in the resulting densely packed mass there is also some styrofoam) and the rest of the styrofoam was found to spin around with the flow at a small distance from the 'silane surface'. In case the particle distribution is such that both particles with a higher density than the liquid and particles with a lower density are present, problems can be predicted. To solve this, a further type of filiai, namely dai in Fig. 100a, b is depicted.

The filter shown in Figs. 10a, b is a variant of a combination of the two previous filters. Fig. 10b shows a section through the filter according to Fig. 10a along the line A-A. The filter consists of a tube 1, in which four circular wall surfaces 20.21 arranged concentrically with the tube are arranged. These walls are connected two and two to each other at the downstream end of the filter by, for example, a screen surface 20.2 and thereby form two sub-filters arranged in a circular manner.

In this case, all walls consist of sifting surfaces 20.1. In this filter, particles l5a having a lower density of the liquid flow and l5b having a higher density than the liquid flow can be separated from the liquid flow. The embodiments shown in Figs. 11a-11 and 12a-12b schematically represent examples of different types of guide rails. The guide rail according to Fig. 11a forms a helical band, which is arranged around a central support. The guide rail according to Fig. 11b consists of two bands in the form of a double spiral arranged around a central support. The guide rail according to Fig. 11 consists of a 462,549 helical band which is arranged without support. In Figs. 12a and b, the rotating member is constituted by wings arranged on a central support. Guide rails 11a - 11c can of course be modified in various ways within the scope of the invention, for example by varying the pitch within a rail, varying the number of turns, changing the angle of the guide rail with the shaft, and so on. The guide rails in Figs. 12a and 12b can of course be varied in terms of profile, number of blades and the like.

It is, of course, within the scope of the invention to mount the filter and associated guide rails in a filter housing (in the pipe) separately without departing from the spirit of the invention. It is also within the scope of the invention that these guide rails of varying appearance, mounted on the support tube, the cone, the inside of the filter housing or in another way suitable for the special circumstances, do not necessarily have to occupy the entire flow area but at the cone a space can be left between the wall guide rail or ledskena-kon. This naturally applies to all embodiments. With regard to the method, it is noted that the screening surface must of course not necessarily assume the embodiments described in the device. Instead, the only limitation on this surface is that the particles, in their movement when they are forced away from the screening surface and towards the downstream end of the device, do not come into contact with the screening surface. For example, in Fig. 1, the upper circumference of the screening surface 20.1 should preferably be larger than the circumference at the screening surface 20.2, ie the part of the filter which constitutes the screening surface can assume a shape generally tapered towards the downstream end. Within the scope of this invention. it is conceivable to vary guide rails and filter designs according to the liquid flow and the nature of the particles. The embodiments described herein are not to be construed as limiting the method and apparatus of the claims, but are merely illustrative embodiments.

Claims (2)

A method for the continuous separation of solid particles from a liquid flow flowing in a conduit, characterized in that the liquid flow upon entry into a device is set in rotation by means of a rotating means and that the flow is then passed through a filter, sornx / is arranged at the downstream end of the device, the filter comprising at least. a screening surface and a screen surface, the screen surface having a longitudinal extent along the axis of rotation of the flow and the screen surface being positioned so as to constitute a downstream barrier for the unfiltered flow, with a sudden increase in pressure of the flow, the screen surface allowing an initial rotational movement is built up, at the same time as separation of entrained particles takes place towards the screen surface, whereby the rotational movement of the flow has time to stabilize and accompanying particles are forced away from the screen surface by centrifugal force and whereby they are simultaneously moved towards the screen surface by the movement of the feed. Device for continuously separating solid particles from a liquid flow flowing in a line, characterized in that the device, which is located in a filter housing (1), comprises an upstream end (4) and a downstream end (5), and that in the case of the device upstream end (4) a flow-giving means (7) is provided, which causes the flow to rotate about an axis of rotation and that at the downstream end of the device (5) a filter is arranged with a filtering surface arranged substantially parallel to the axis of rotation of the flow. . (20.l), and a screen surface (2U.2) so arranged that it constitutes a downstream barrier for the unfiltered flow. '_ 3.. Device according to claim 2, characterized in that the filter housing (1) 'consists of the conduit in which the device is located. Device according to any one or more of claims 2 to 3, characterized in that on the upstream side of the farthest end of the filter, with respect to the flow direction, there is an extension intended to constitute a 'collection space' (24) for the solid particles (15). ), whereby draining possibility (25, 26) for the solid particles can be arranged in connection with this space (24). Device according to one or more of the claims (2 - 4A, characterized in that the screen surface (2U.1) forms part of a self-supporting filter. Sf462 549/0 Device according to one or more of Claims 2 to 4, characterized in that the screening surface (20) forms part of a filter with a halo-ooh and / or slot provided in the center of the device, substantially parallel to the axis of rotation of the flow. support tube (10), provided with a fixedly mounted heeled washer (13), which covers the flow-through area, the support tube (10) and the washer (13) on the upstream side of the flow carrying a filter, where the screening surface (20, 1) covers the outside of the support tube . in Device according to any one or more of claims 2 to 6, characterized in that the rotating member (7) is arranged on the inside of the tube (1) or the line upstream of the filter device, or on the wall of the filter housing (1) at its inlet end. Device according to one or more of Claims 2 to 7, characterized in that the rotating means (7) is arranged "on the guide rail or the upstream end of the self-supporting filter. Device according to any one or more of claims 2 "- 8 kfa 'n n e t e c k n a d in that between the rotating means and the filter there is an enzkon whose position and / or base radius can be set to regulate the flow. Use of the filter device according to one or more of claims 2 to 9, either alone or in combination with several, as protective filters for sensitive components. W ll. Use of the filter device according to one or more of claims 2 to 9 as a pre-filter at sprinkler heads, the screen having a mesh size which is smaller than the diameter of the nozzle openings. 462 549 ll Pipe or filter housing 2. Flange connection 3. Flow Upstream End Downstream End 6. Passage after rotating means. Guide rail / or 8. Maximum flow rate behind the guide rail 10. Support pipe ll. Slits 1.2. Stir with free genor run 13. Semi-equipped tray 14. Kon 15. 'Separated particles l5a. - "- -" - "lighter" than l5b. - "- -" - "heavier" than 16. Inside of the tube / filter housing 17. Sprinkler head 18. Nozzle openings 20. Filter wall 20.1 The filter surface 20.2 Screen surface 24. Collection space 25. Draining device 26. 2 Flow with a constantly small outflow