SE467190B - DEVICE FOR DISPOSAL OF WATER SOLUBLE POWDER - Google Patents

Description

4 7 190 dosed into the working solution by means of a dosing pump controlled by from a conductivity cell in the working solution.

In this process, the dust problems are eliminated at least in part end user, but is replaced with the problems with regard to deficiencies compatibility between different components and risky handling of strongly alkaline solutions, which are mentioned in connection with liquid products above. In addition, there are problems with clogging of the strainer and wet strongly alkaline residues in the emptied packages. The upturned the strainer is intended to reduce clogging problems.

Technically, the procedure is space consuming and complicated with requirements special space and equipment for handling the heavy containers and preparation of the concentrated solution and dosing system with pipes, valves and pumps for supplying the concentrate to the individual machines.

The Swedish exposition 422 650 deals with a further development of the system according to the previously mentioned publication. You work here with a lidded powder container intended for refilling with powder.

Otherwise, there are the features regarding the upwardly curved screen and it centrally located nozzle with spray, which provides an even wetting of the silane entire surface, which already appears in exposition 357 670. This type equipment is intended to work with a relatively small amount of powder (a few kilograms), which are dissolved at the rate required to produce or complete the use solution. During the procedure, the dusting the problem of powder handling is largely unchanged and can only partially solved by means of portion bags and the like.

A further development in the field has been pastors and powders in various types of plastic cassettes. For the pastors, what has been said above applies to component compatibility and component degradation in the manufacture of the pasta. For both pastors and powders it applies that any satisfactory solution to the problem of achieving a complete constant emptying of the packaging so far not presented.

The solution that could be proximate with regard to the the inscriptions as above, i.e. with an upwardly arched sieve and one 467 190 centrally located nozzle, which provides a uniform wetting of the entire screen surface, works only with fully open containers, where the powder container open ends have approximately the same surface area as a horizontal section through the center of the container. Practically useful cassettes have, however openings, the surface of which is only a fraction of the cross-sectional area of the container.

Cassettes with openings whose surface is only half of the container surface or less dominates.

A satisfactory system for handling powders in exchangeable cassettes must meet the following requirements: 1. ergonomically satisfactory handling of the cassettes with regard to weight, lifting height and working position, 2. safety against spillage and dusting of often strongly alkaline or strongly acidic products, 3. protection against drips from emptied cassettes in connection with removal and handling. 4. safety against splashes from the dissolution device 3. provide an at least reasonably concentrated solution for preparation and supplementation of utility solutions without time delay throughout useful life, 4. allow restart of the system with partially used cartridges even after longer breaks such as weekends and long weekends, without time delays with respect to dosing, 5. complete emptying of the cassette.

A utility solution of the type in question has a concentration of active material in the range 0.01 to%, more often 0.05 to 0.5% and most often in the range 0.1 to 0.3%. For that to be possible to complete the solutions quickly enough, the complementary strength should be at least about 10-potency higher, that is at least 1 to 10% depending on the area of use. 4 i 7 190 The inventor has carefully studied the problem and thereby surprisingly nit, that a nozzle with a spray pattern, which gives non-uniform water division on the surface of the screen provides unexpected advantages in terms of resolution of a powder or granules consisting of mixed active ingredients stored in a container with a relatively narrow opening closed with a strainer. This is contrary to the teachings of the above the explanatory notes, where the importance of uniform water distribution over the entire screen surface is emphasized as basic ideas for the respective invention.

Additional advantages with respect to the dissolution of powder and granules and complete emptying of the containers can be obtained if the net, or grids, which are required to prevent the powder or granulate from flowing down out of the container is designed as a double mesh with relatively coarse openings (1 to 20 mm, preferably 1 to 10 mm) in the side which facing the nozzle and very fine openings (0.01 to 0.8 mm, preferably hence Û, 02 to 0.5 mm) in the side facing the powder container internal. In the future, the term coarse net will be used and also include cases where the design is more like a grid.

A device according to the invention thus comprises in its basic form one with a net or grid closed replaceable container with an outlet an opening whose surface is less than half the cross-sectional area of the container, filled with a free-flowing, water-soluble granulate and, with the mouth downwards, by means of a holding device placed over an upward nozzle, which provides uneven water distribution over the surface of the net, connected to a_ pressurized water line with a valve, which is controlled by a manual or automatic mathematical signal. The nozzle and the mouthpiece of the powder container are surrounded by a cylindrical or funnel-shaped container for collecting the con- centered solution formed when water is injected through the nozzle into the container and dissolves the water-soluble granulate. The solution container is provided with a drain, which in turn is connected to containers for utility solution.

To the extent that an automatic signal is used to control the water spray the connection should be made so that the water supply is inter- mid for example 5 seconds water supply, 5 seconds drainage, new water supply and drainage etc. Appropriate time intervals depend on the water pressure, the area of use and the composition of the agent and can 467 190 be between 2 and 20 seconds for spraying and 2 to 30 seconds for drainage. Interval-controlled supply of water provides a smoother dosage, as the drainage period gives the concentrate time to drain into the container for working solution, mix with it and give a correct results from the measuring cell. In addition, the interval coupling contributes to the "replace powder container" signal does not come before the container is emptied.

From a practical point of view, it is desirable that the concentrate from the the device maintains the highest active content as possible. Interval control contributes to this. Other possibilities for control lie in the of the amount of water sprayed in relation to the dissolution and run-off rate of the water-soluble granulate. At the same time the jet speed after the nozzle must be high enough to especially at the end of a cassette's consumption time, shall reach such far into the container, that the last remnants can be flushed up to the grid and dissolve. The nozzle is normally connected to a water line with heated water (20 to 60 OC) and pressure within range 2 to 5 kg / cm 2. Suitable nozzles have the capacity under these conditions in the range of 3 to 15 liters / min.

The spray pattern of the nozzle can be designed in a number of different ways for so long it clearly deviates from a uniform pattern that is to say from one pattern, where virtually all points on the web obtain approximately equal amounts of water with only random deviations. Good results thus obtained with oblique circular, oval, cruciform, triangular etc. spray patterns. The essential thing is that the pattern, which formed when the rays hit the net, shall not be uniform and not allow the remaining powder to ingest a dome-shaped or annular form configuration.

The uniformity applies to the distribution of the amount of water along the surface. In order to the distribution shall be considered non-uniform provided that the amount of water which per unit area, for example mm2 or cm2 hits the network must be at least 2%, preferably at least 50%, and most preferably at least c1D0% greater in the areas receiving the largest amount of water brought with the areas that receive the least amount of water.

Particularly good results have been obtained with a flat-beam nozzle. 467 190 In preferred embodiments, the replaceable container is surrounded by a housing with connection to the container for collecting solution and provided with a combination of door and lid, which when opened exposes one side of the house and the opening of the house upwards. This for convenient deposit and removal of the replaceable containers. It is also preferred that the device one is provided with a safety system, which allows water spraying through the nozzle cannot be made when the powder container is not inserted and / or when the door / - the lock combination is in the open position.

Fig. 1 shows a container with a sieve plug insert with a fine mesh and a coarse mesh net combined into a strainer suitable for use in the device according to the invention.

Fig. 2 shows at the top a detail of a sieve plug with a number of coarse ones network openings drawn and below a photocopy of a fine-mesh net.

Fig. 3 shows a flat radiating nozzle suitable for use in the device according to the invention.

Fig. 4 shows the spray pattern of the flat radiating nozzle according to Fig. 3.

Fig. 5 shows in its upper part a front plan view of a preferred embodiment. embodiment of the invention with the front of the surrounding housing removed and in its lower part a horizontal section through the device in height with the bottom of the solution container.

In the figures, (1) denotes the container, (2) the fine-mesh net, (3) the coarse mesh net, which in this case is designed as a sieve plug, which holds the fine-mesh net by clamping it against the container neck, (4) denotes the nozzle with a non-uniform spray pattern, (5) is the supply the line for water to the nozzle, (6) stands for the line, which connects the solution container (7) to the working solution container, (B) denotes the surrounding house.

The powder container (1) can be designed in a number of different ways and be cylindrical, oval, rectangular, etc. Cylinder shape is preferred. The insides should be straight and as smooth as possible. The container should be finished with one 467 190 conical part, which connects the straight part of the container to the mouth and whose sides should be inclined at least 200, preferably at least 300 against the sontal plane to facilitate the sliding of semi-dissolved powder, which is a prerequisite for complete emptying of the container. A preferred container is formed of polyolefin plastic by so-called blow molding and consists of a bottom, which can be provided with handles for to facilitate handling, a cylindrical part, a terminating conical part and a mouth part, which carries the previously mentioned network combination nen (2,3). The ratio between the height of the cylindrical part and the container the diameter of the valve should be between 2: 1 and 1: 2. Ratios 1: 1 and 1: 1.5 are particularly suitable.

The ratio between the diameter of the mouth and the diameter of the container can range from 1: 4 to 1: 1.5. Particularly appropriate is a relationship around 1: 2, which means a ratio between the surfaces of around 1: 4.

From an ergonomic point of view, it is appropriate for the container plus the product to weigh between 2 and 8 kg. Depending on the volume weight of the product, which may vary from 600 grams per liter to 1500 grams per liter, this gives a volume between 2 and 15 liters. Particularly suitable volumes are between 2 and 5 liters.

The combination of coarse - mesh and fine - mesh net and its attachment in the container mouth can be designed in many different ways, for example as two separate woven nets with special support construction or as shown on the drawing, in which the coarse net is made of olefin plastic by molding pressing and at the same time combined with the support structure into one strainer plug with press fit to the container neck. The design allows the coarser mesh at the same time serves as an attachment for the woven fabric. mesh net. This is a preferred embodiment. The choice of material is in indifferent as long as the network combination can withstand the chemicals that used. Although it is not, but very comprehensive measurements and calculations possible to determine with certainty why a nozzle, which gives a different shaped water distribution on the mesh surface is completely superior to a nozzle, which provides 467 190 a uniform water distribution, when the opposite seems to be the case in the circumstances prevailing under the two above-mentioned the following documents can be reasonably assumed to be the following.

The relatively narrow opening of containers according to the invention provides completely different flow conditions, compared to the large surfaces man uses according to previous technology. Probably, for example, one some arching in the granulate is not avoided. Arch with a circular construction of the kind you get with a rotationally symmetrical nozzle is out strength strength significantly more stable than the non-circular arches, obtained with a nozzle with non-uniform water distribution. This will be even more pronounced when the resolution continues so far that the powder tops surface was pierced and a ring of undissolved material was obtained along it the sides of the container. Support for this view is obtained by comparison experiments, where it was found that residues remain in the container after use of a rotationally symmetrical nozzle are distributed as one in general seen uniform ring, which rests against the sides of the container. To that extent residues remain in the container after using a nozzle with different water distribution, these are considerably smaller and consist of random moderately distributed powder clusters without interrelationships.

As already mentioned, it is preferred that the nozzle, which gives a non-uniform water supply sharing on the network, combined with a closure combination for consisting of a coarser net or grid and a fine-mesh net.

In addition to the obvious advantage, that the fine-mesh net minimizes the risk of extremely fine-grained granules leaking out of the container turned upside down, the combination provides benefits that cannot be obtained either with a coarse net only or a fine mesh net only. The change of direction which the droplets from the nozzle are forced to give rise to a finely divided mist, which is very little affected by gravity and therefore can rise and contact the powder from above, so that it dissolves a concentrate, which flows down to and through the double nets. Cone- at the same time, the center drags powder not yet dissolved to the mesh surface, there it is exposed to the direct spraying of water through the nozzle.

Only fine-mesh mesh also gives it some disintegration of the spray aimed at it but the balance between permeability and requirements atomization of the spray droplets becomes extremely problematic. To it- 467 190 the purely practical problem will bring about a satisfactory attachment and strength of a fine mesh net, without too much reduce the permeable surface. A fine-mesh net like is not exposed to the voltage that the load with the powder column entails can vibrate with greater amplitude under the influence of the water jets.

This is probably a not unimportant detail in the context.

With only one coarse net, you get a soft ket fast resolution, which can even be so fast that not completely dissolved particles follow with the dissolved concentrate. This can give one undesired temporary overdose, as the measuring cell does not react in time gerar.

After this rapid dissolution, a more normal period occurs, as, when the container has been emptied so far that the net is not completely covered by collapsing granules, is replaced by a period of relatively long dosing time, because the liquid that is injected into the container flows back quickly and then gives solution with low concentration of active material. Dose- the ringing time is getting longer and it may happen that you get a signal for changing the container before it is completely emptied. The combination of rough and fine mesh eliminates or reduces both of these problems, that is say leads to no overdose due to undissolved powder in the working solution occurs and contributes to the dosing times being within acceptable limits until the container is completely emptied.

The process of using the device according to the invention is as follows those after starting with a new container. The spray from the nozzle, which gives different shaped water distribution, hits the underside of the net and penetrates the net a few millimeters, whereby the water comes into contact with granules, which dissolves and leaves room for new granules, which collapse from higher uplying layers. Dissolution and degradation of powder continue on the take steps until a powder-free cone-like configuration emerges the tip towards the net and an upward-facing bottom surface, which in addition to the dimensions are determined by the race angle of the granulate. When this happens a surface begins to appear on the net, which is free of granules or has a very thin layer of granules. In this area, the syringe penetrates and gives drops at high speed, which reach high up in the container and possibly bounce against the bottom of the container before falling on the remaining 467 190 '10 they powder like a torrential rain.

At the same time, the sudden changes of direction at the network passage are formed an 'extremely fine fog, which is likely to be further stabilized by a some electrostatic charge. The fog rises upwards in the container and strikes down on the granules that remain. The very concentrated solution formed flows down through the granules, is mixed with the flow from above and moves the remaining granules towards the container mouth.

Experiment 1: In this experiment, a device according to the invention was compared equipped with a flat-jet nozzle with tapered spray towards the edges pattern with the corresponding device equipped with a nozzle according to those above mentioned both expositions, that is, with the spray pattern which is usually called stuffed cow. The replaceable powder container in both the equipment had a mouth, the surface of which was about a quarter of the cross-sectional area of the container. The mouth was closed with a strainer plug a simple, relatively coarse-mesh net. The water supply to the nozzle occurred at a pressure of about 4 kg / cm 2. At this pressure they left both nozzles about 9 liters of water per minute. The spray was interval controlled with 5 seconds spraying and 5 seconds drainage.

To mimic the conditions during practical operation at, for example, a dishwasher, the trials were discontinued after 10 dosing and resumed day, when the powder has had time to drain off and to some extent bake together.

When the equipment no longer left a solution with sufficient strength, in order to be able to be used for adjusting the con- concentration, only 20 g of the previous equipment remained as minor soaked powder accumulations, which adhered to the container sides especially at the transition from the cylindrical to the conical parts. In the device, which was equipped with a full condenser, 0.5 kg remained in the form of a soaked continuous ring at the sides of the container. IN In both cases, the containers originally contained 4.0 kg of a granulated mixture with the composition "' 30% sodium tripolyphosphate, 40% sodium metasilicate, 25% sodium hydroxide G 4 of polyacrylate, IN 1 »chloroisocyanurate.

Claims (8)

467 19o 11 Experiment 2: Experiment 1 was repeated with containers, which were closed with a net combination consisting of a net with square meshes with a mesh size of 2 mm and above this a net with square meshes and a mesh size of 0.5 mm. In the device with a flat-jet nozzle, the container was completely emptied except for a few grains, which were attached to the bottom surface of the container. In the device with full-cone nozzle, in this case 0.1 kg of product remained even now in the form of a soaked continuous ring. The double mesh thus leads to an improvement even when using a rotationally symmetrical nozzle, but the result is still not entirely satisfactory. Note that the experiments are typical examples and constitute a summary of experimental series, which for reasons of space are not appropriately included here. Patent claims Apparatus for dissolving water-soluble powder or granules and producing a concentrated solution, suitable for preparation or supplementation of a working solution, consisting of a replaceable powder container (1) having an opening area less than half the cross-sectional area of the container and closed with a net (3), which prevents powder or granules from flowing out when the container is placed with the mouth downwards, a holding device, an upwardly directed nozzle (4) connected to a pressurized water line (5) with a valve, which is controlled manually or automatically and a second container (7), which surrounds the nozzle and the lower part of the powder container and collects the solution formed, characterized in that the nozzle provides a non-uniform water distribution on the net. Device according to Claim 1, characterized in that the water supply to the nozzle is controlled by an automatic signal with interval connection so that periods of water supply alternate with run-off periods. Device according to claims 1 and 2, characterized in that the net (2,3) which closes the powder container (1) is a combination of a coarse-mesh net (3) with a mesh size of 1 to 20 mm, preferably 1 to 10 mm and a fine-mesh net. (2) with a mesh size of 0.01 to 0.8 mm, preferably 0.02 to 0.5 mm. 4-67 190 12 Device according to claims 1, 2 and 3, characterized in that the nozzle is a flat-radiating nozzle. fm Device according to claims 1, 2, 3 and 4, characterized in that the powder container (1) is a straight-walled, cylindrical container with a ratio between the height of the cylindrical part and the diameter, which is in the range 1: 2 to 2: 1, a conical end with a slope, angle in relation to the horizontal plane of at least 200 and a mouth with a diameter whose ratio to the diameter of the cylindrical part is between 1: 4 and 1: 1.5. Device according to claims 1 to 5, characterized in that the powder container (1) is surrounded by a housing (8) with a combination of door + lid, which opens forwards upwards and exposes a wall surface and the opening upwards of the housing for convenient insertion and removal of the replaceable powder container. Device according to Claims 1 to 5, characterized in that it is provided with a safety system which prevents the spray nozzle from being activated if no container is inserted in the device. Device according to Claim 6, characterized in that it is provided with a safety system which prevents activation of the nozzle if no powder container is inserted and / or if the door / lid combination is in the open position.