DE8535376U1 - Arrangement for the quick determination of fines in sand and gravel - Google Patents

Description

Arrangement for the rapid determination of Feih shares in Sahden and Kiesen

Because sand and gravel because of their natural formation material supply fluctuating composition, it is important, especially in the case of continuous processing, the fines of the goods to be continuously determined in order to be able to control the processing plant based on the measurement results in such a way that End products that are as constant as possible are created. So far this has usually been done by taking a sample of the earth-moist raw material dried, weighed, freed from the fines by sieving and weighed again. This procedure is so time consuming that often in the time from the sampling to the determination of cies Result, the composition of the raw material has changed with the result that the processing plant is not the desired one Product quality delivered.

In an older utility model, an arrangement is described with which these difficulties can be avoided, since it is allows all necessary weighings to be carried out in one liquid. This older arrangement consists, in short, of a balance, a weighing vessel and an agitator, and possibly also a metering device.

1 When extracting sand or gravel for technical an |

Change materials, for example for the production of Betonzuschlag- \, it is common to separate the Rohgut by continuously operating screen and sludge plants into fractions according to grain size, and indeed generally in the following ¹ I

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8 to 16 mm and (5) 16 to 32 mm grain diameters. The service water I bility of such fractions for specific applications depends \

now very much depends on how many fine-grained constituents { also referred to as fines, they still contain. These fines have grain diameters of up to about 0.25 mm. They are mainly found in the sand fraction (1), but can also be present in the coarse-grained fractions and then usually form coatings on the coarse fraction components.

It has now been found that when processing raw material, which essentially consists of fractions of up to 4 mm grain diameter, can do without the stirrer if the inner surface of the weighing vessel has the shape of a paraboloid of revolution with essentially has a vertical axis.

Accordingly, the arrangement according to the invention contains

(a) a balance and

(b) a weighing vessel connected to the balance, open at the top, the inner surface of which has the shape of a Paraboloids of revolution with a substantially vertical axis and that with at least one Provided liquid inlet and at least one liquid outlet designed as an overflow is, as well as where applicable

(c) a metering device for the item to be examined and / or

(d) a liquid storage vessel which preferably holds the liquid in the inlet (s) of the weighing vessel supplied via a valve.

i The balance (a) can basically be any

Be construction. Weighing range and weighing accuracy depend on jj

on the weight of the weighing vessel filled with liquid (b) and |

on the selected sample size. Preferably it is |

an electronic scale with a digital display and the option of suppressing a large tare weight. The weighing vessel (b) connected to the balance can have any shape on the outside, for example cuboid, barrel, parabolic or be cone-shaped. It preferably has the shape of an upright cylinder on the outside or - like the inner surface - that of a cylinder Paraboloids of revolution with an essentially vertical axis. The vessel can be made of any material that is resistant to the The liquid used is essentially inert and resistant to the mechanical stresses caused by filling, swirling and emptying

is sufficiently stable. Plastics and metals, for example, come into consideration as materials. The dimensioning of the The vessel should be selected so that it is both light and stable enough to prevent the weighing result from being too large To falsify the tare weight by volume fluctuations resulting from changes in shape.

The weighing vessel is open at the top, either because the entire upper boundary is free of wall material, or because a sufficiently large filling opening is provided at the top. The vessel has at least one liquid inlet (e). In the simplest case, this is a feed pipe _f which is connected to the vessel and opens into the vessel at the side. It has proven advantageous to let the feed pipe open into the vessel near the bottom. At its other end, the supply pipe can carry a flexible hose which connects it to a fine liquid storage vessel or a pipeline network supplying the liquid, with or without the use of a constant pressure regulator. It goes without saying that this hose connection must not noticeably affect the weighing result.

Another possibility is that the liquid inlet Via an easily detachable connection, for example a magnetic flange or a conical pressure connection, which mechanically, can be operated hydraulically, pneumatically or magnetically, with is connected to the arrangement supplying the liquid only, when liquid is to be added while it is being used for weighing is separated from it.

Instead of one, the weighing vessel can also have several, for example be provided with two, three or four liquid inlets. These can include different or the same angles (measured perpendicular to the axis of the paraboloid of revolution and can attack the vessel at the same or different heights. The liquid inlets can in principle in any Pierce angles through the inner surface of the weighing vessel, for example tangential or radial.

ι The weighing vessel also has a liquid drain (f) that

is designed as an overflow * so in the upper part of the vessel is located. In the simplest case it is the

I upper edge of the vessel or one or more depressed areas of the

I the upper edge of the vessel or around one or more bores below

■■ half of this edge near it. De.T overflow can also

I? 'The shape is sine or several firmly attached to the vessel

Have 1 tubes. Finally, the process can take the form of a

1 overflow channel running around the weighing vessel.

'' We recommend connecting the weighing container to the balance in such a way that

I that it can be tilted. The weighing vessel can also be equipped with a bottom valve be provided to after the inspection of the property

I this together with the cleaning water from the vessel, if possible

(■ to drain through a large opening; in

, in this case the vessel is fixed. In a special version

S form, a rising bottom cup opens through the bottom valve

", Pressure for emptying. In this way the vessel can be lowered

} Empty completely quickly and easily for each determination.

In a preferred embodiment, the inventive Arrangement provided with a metering device (c) for the material to be examined. This can be a Act weighing device. More advantageous because it is easier to use of the construction, is a volume measuring device, for example in the form of a scoop, which optionally with

I always fill the same amount in a scraper

can, or in the form of a rectangular cross-section in a tube

I snugly sliding frame attached to a

'· ■ end of the tube through an opening in the top wall of the

Tube filled and at the other end through an opening in

"I 'the bottom wall of the tube is emptied.

The arrangement according to the invention can be provided with a liquid storage vessel (d) be provided, which delivers the liquid to the weighing vessel via a valve. The valve can be mechanically, be pneumatically or electrically operated. The storage vessel itself is equipped with a liquid inlet,

which appropriately locks automatically when the vessel is full is. The storage vessel can also be connected to the supply line with the connection of a pressure stabilizer be replaced.

Preferably, however, the arrangement according to the invention is off a pipeline network fed with liquid. It has proven useful to have a pressure between 1.5 and 2.5 bar to be provided for pipe cross-sections of 3/8 to 3/4 inch.

The figures show an arrangement according to the invention. 1 shows a longitudinal section through the entire arrangement, with a weighing vessel that is cylindrical on the outside and paraboloid of revolution on the inside is including liquid storage vessel and dosing device. 2 a supervision a weighing vessel with an inlet and outlet each in a tangential arrangement, FIG. 3 longitudinal section through paraboloid of rotation inside and outside shaped vessel with bottom valve, FIG. 4 a top view of a weighing vessel with three tangential liquid inlets and bottom valve, FIG. 5 a top view with 4 radial ones Liquid inlets and bottom valve, Fig. 6 is a view of a Overall arrangement with a quick-release pressure device for the water supply to the weighing vessel that is permanently mounted on the balance, this in turn provided with a bottom valve actuated by a moving bottom cup.

(a) Libra

(b) Weighing vessel

(c) Dosing device

(d) liquid storage vessel

(e) Liquid inlet

(f) Liquid drainage.

(g) bottom valve

(h) pneumatic pressing device

(i) Floor cups

(k) pneumatic lifting device for the bottom cup

The arrangement according to the invention is applied in such a way that the weighing vessel (b)

(1) completely with a liquid - preferably j with water or an aqueous salt solution - filled and then weighed \ (weight tuning G 1), '

(2) a sample of the goods into the weighing ι filled with liquid

vessel and weighs it again after leveling up §

(Weight determination G 2),

(3) the goods in the weighing vessel while allowing more to flow in Liquid is whirled up with this so that the fine-grained components of the goods up to one through the selected feed rate and the one achieved with it Liquid flow given maximum grain size over the Overflow are flushed out, and weighs again (weight determination G 3),

(4) the fine-grain content of the sample in percent by weight according to the formula

Weight-S = (G 2 - G 3) χ 100 _(I) G 2 - G 1

calculated and, if necessary, the measurement result as a manipulated variable to optimize production.

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Claims (1)

1.) Arrangement for quick determination of the weight fraction on fine-grained components in sand and gravel and, if necessary, use of the determination result to optimize the preferably continuous production a defined quality of the goods, characterized in that they (a) a balance and (b) a weighing container connected to the balance, open at the top, whose inner surface has the shape of a paraboloid of revolution with a substantially vertical axis and that with at least one liquid inlet and at least one liquid drain designed as an overflow is provided, contains.) Arrangement according to claim 1), characterized in that she (c) a metering device for the material to be examined contains. 3.) Arrangement according to claim 1) or 2), characterized in that that they (d) into the liquid inlet of the weighing vessel via a Valve supplying liquid storage vessel contains. 4.) Arrangement according to one of claims 1) to 3) characterized that the outside of the weighing vessel has the shape of an upright cylinder. • · * «« · MIl 5.) Arrangement according to one of claims 1) to 3), characterized characterized in that the weighing vessel also has the shape of a paraboloid of revolution on the outside with a substantially perpendicular Axis has. 6.) Arrangement according to one of claims 1) to 5) thereby characterized in that the liquid drainage the shape an overflow channel running around the weighing vessel and / or the rim of the vessel as a protruding edge is trained. 7.) Arrangement according to one of claims 1) to 6) thereby characterized in that the liquid inlet via a flexible hose connection is connected to a liquid storage vessel. 8.) Arrangement according to one of claims 1) to 6) thereby characterized in that the liquid inlet has a substantially funnel-like feed opening above of the maximum liquid level in the weighing container carries, through which the liquid can be supplied without contact. 9.) Arrangement according to one of claims 1) to 6), characterized in that the liquid inlet via a Compression connection is easily detachably connected to the liquid-supplying arrangement. 10.) Arrangement according to a dec claims 1) to 9), characterized in that the weighing vessel is tiltably connected to the scale for complete emptying. 11.) Arrangement according to one of claims 1) to 9) thereby characterized in that the weighing vessel is provided with a bottom valve for complete emptying.