NL1005413C1 - Method for composing granular mixtures with predetermined specifications, starting from granular starting material. - Google Patents

Description

Short designation: Method for composing granular mixtures with predetermined specifications, starting from granular starting material.

The invention relates to a method for composing granular mixtures with predetermined specifications from granular starting material, in which use is made of a separating device for splitting the granular starting material into granular fractions, comprising at least two classifying devices which each use the liquid splitting the granular material fed thereto into a first granular fraction and a second granular fraction, which are respectively discharged into the underflow and the overflow of the classifier concerned, which method comprises the following steps: feeding the granular starting material to the separator , - splitting the granular starting material into different grain fractions by means of the separating device, determining the composition of each of the grain fractions coming out of the separating device and determining on the basis thereof from a mixing ratio of grain fractions to formulate a grain mixture of a predetermined specification, transporting the grain fractions to a collection point to formulate the grain mixture,

Such a method is used in, for example, the sand extraction industry. The granular starting material consists of coarse sand which is split by the separator into several granular fractions which are stored. After analysis of the grain fractions to determine the composition of each grain fraction, a mixing ratio is calculated in order to be able to produce a sand mixture 100 5 4 1 3 2 that meets the specifications stated by a customer. The grain fractions are transported from the various storage areas to a collection point for the production of the sand mixture.

The drawback of the known method is that each grain fraction is stored separately before mixing the grain fractions into a grain mixture. The storage and transport of the grain fractions to and from the storage sites is very expensive.

The object of the invention is to provide a method in which the granular fractions of the granular starting material coming out of the separator can immediately be mixed in the correct ratio into different granular mixtures with predetermined specifications, without the need for intermediate storage.

This object is achieved with a method described in the preamble, which according to the invention is characterized by the following steps: determining a Tromp curve of each classifying device, withdrawing batchwise from each classifying device the grain fractions, determining the weight and volume of a batch of a mixture of liquid and the respective granule fraction from each grain fraction coming from each classifier and determining the dry weight of the granules present in the batch, using the Tromp curve of each grading machine and the dry weights of the grains contained in the charges calculate the composition of the granular starting material, and calculate the composition of each of the 35 grain fractions.

In this way, intermediate storage of grain fractions is superfluous and considerable savings are made on transport costs 1005413 3. In particular, the energy consumption for transport decreases significantly. Moreover, the installation for producing the desired grain mixtures can be carried out more cheaply, because only storage of end products is required.

Preferred embodiments of the method according to the invention are defined in the dependent claims.

The invention also relates to a device for carrying out the method according to the invention.

The invention will be elucidated hereinbelow with reference to the drawing, in which: Fig. 1 is a schematic representation of an apparatus for splitting sand into two grain fractions, Fig. 2 is a schematic representation of a separation -supplier with multiple classifiers arranged in series for splitting coarse sand into different grain fractions, fig. 3 is a Tromp curve of the classifier K2 of fig. 2 for a separation point of 0.5 mm, fig. 4 a Tromp curve is from the classifier K3 of Fig. 2 for a separation point of 0.25 mm.

Fig. 5 is a Tromp curve of the classifying device K4 of Fig. 2 for a separation point of 0.1 mm.

The following description of the figures is intended only as an example to clarify the method.

The device for splitting sand into grain fractions shown in Fig. 1 comprises a classifying device 1 with an outflow opening 2 for the underflow and an outflow opening 3 for the overflow. The outflow opening 2 can be provided with an adjustable valve (not shown). Furthermore, the classifying device 1 is provided with a water supply line 4, which water is used for classifying sand supplied to the classifying device. The sand is supplied to the classifying device 1 via 1005413 4 sand supply line 27.

Below the outflow opening 2 there is a sliding funnel 5 with an outflow opening 8 which is horizontally displaceable between a first position and a second position. Below the sliding funnel 5 there are two measuring trays 6,7 which are placed such that the outflow opening 8 of the sliding funnel 5 is in the first position above the measuring tray 6 and in the second position above the measuring tray 7. The measuring trays 6, 7 are each provided with a water supply line 9, 10. Above the measuring trays sensors 11, 12 are arranged for measuring a level in the measuring trays. The measuring buckets 6, 7 are each connected to a weighing device 13, 14.

Closable outflow openings 15, 16 of the measuring trays 6,7 are located above a funnel 17. An outflow opening 18 of the funnel 17 opens into a sliding gutter 19. Collecting gutters 20, 21, 22 are arranged under the sliding gutter 19. The collection troughs 20, 22 each open into a dewatering / mixing machine 25, 26. The collection trough 21 opens into a collection container 28 for residual products, which are discharged from the collection container 28. Rotatable conveyor belts 23, 24 are further provided for the transport to storage places of various products P1 -P6.

Like any classifier, the classifier 1 for certain process parameters has a certain degree of separation curve or Tromp curve determined in a laboratory. The Tromp curve indicates how likely grains of a certain size are to enter the underflow or overflow. This probability is independent of the amount of grains of that size in the sand supplied. A 100% probability means that all grains of that size present in the sand supplied will end up in the lower course. A probability of 10% means that 10% of the grains of 35 of this size present in the sand will end up in the underflow and the remaining 90% will end up in the overflow. When only a small amount of grains of a certain size is present in 1005413 5 and the chance for these grains to end up in the underflow is 10%, the amount of these grains in the underflow will be very small. When the amount of grain travel of that size increases in the sand supplied, the amount of these grains in the lower course will increase proportionately. The composition of the sand supplied therefore influences the composition of the classified fractions. The course of the Tromp curve remains the same when the process parameters 10 of the classifying device 1 remain the same. The process parameters are kept constant using precise measuring sensors and control equipment. The accuracy of the separation is determined by the process control.

The device shown in Fig. 1 operates as follows.

Sand A is supplied to the classifying device 1 through the sand supply line 27. Water is supplied to the classifying device 1 via the water supply line 4. The water flows through the classifying device from bottom to top. Large grains of sand fall against the force exerted on the grains by the water flow and end up in the underflow B. Small grains end up in the overflow C. The grain fractions located in the underflow B and the overflow C, have a composition that depends on the composition of the sand A supplied and on the Tromp curve of the classifying device 1 at the prevailing process parameters.

The underflow B flows through the outflow opening 2 into the sliding funnel 5 and then into the measuring vessel 6. The underflow B is a mixture of water and sand. The closable outflow opening 15 of the measuring vessel 6 is closed. The level in the measuring bin 6 is measured with the aid of the sensor 11. Measuring the level can take place, for example, by means of ultrasonic distance measurement. When the level in the measuring hopper 6 reaches a predetermined value, the sliding funnel 5 is moved such that the outflow opening 8 of the sliding funnel 5 opens into the measuring hopper 7. In the measuring hopper 6 a load of water-sand 1005413 6 mixture is now present.

The volume of the water-sand mixture present in the measuring vessel 6 is then measured with the aid of the sensor 11. The weighing device 13 measures the weight of the load present in the measuring vessel 6. The measurement data is recorded using a computer (not shown). Using the data on the volume and weight of the load, it is possible to determine the weight of dry sand in the load.

The overflow C is led via the outflow opening 3 to a next classifying device with a different separation point, where the weight of dry sand in a batch of water-sand mixture coming from this classifying device is determined in the same manner.

From the amounts of dry sand determined in the above manner in the charges originating from the classifiers used and with the probability percentages known from the Tromp curves of the classifiers, the composition of the sand supplied and of the 20 grain fractions in the flooding of the classifiers.

A computer is used to process the observations of the measuring sensors and to perform the calculations.

The data on the composition of the sand supplied and the grain fractions are used by the computer to select from a number of specified products in such a way that as many high-quality products as possible are produced. The amount of waste is as small as possible.

As long as there is no intervention from the outside, the computer immediately determines for each load in the measuring container to which collecting gutter the load is to be removed. When it has been determined to which collection trough the load is to be discharged, the sliding trough 19 is placed in the correct position. The outflow opening 15 is opened and the load from the measuring bin 6 is discharged via one of the collecting troughs 1005413 7 20, 21, 22 to a dewatering machine 25, 26 or the collection bin 28. The dewatering machines 25, 26 also serve as a mixing device for various measuring containers from loads. In order to ensure a smooth discharge, extra water is supplied via water supply pipe 9, whereby the unloading time is shortened and the sand can be discharged via gently sloping chutes. The position of the sliding chute 19 is controlled by the computer. In addition, the computer can calculate the efficiency of the total installation 10 and indicate what the recommended product is in order to achieve the highest possible efficiency with the sand supplied.

Fig. 2 schematically shows a separating device for splitting sand into different grain fractions. The installation includes a first, second, third and fourth classifying device K3, K2, K3, K4. The first grader Klf formed by sieving, splits the coarse sand into three grain fractions, a first grain fraction with grains larger than 4 mm, a second grain fraction with grains of size between 2 mm and 4 mm and a third grain fraction with grains smaller than 4 mm. 2 mm. The amounts of grains in the first and second grains fraction are determined by a weight measurement. The amount of moisture in the grain fractions exiting from the sieve classifier is generally negligible.

Hydrocyclones 30, 31, 32 are placed in front of the second, third and fourth classifying device K2, K3, K4. These hydro-cyclones separate the sand with a grain size smaller than 0.1 mm. The sand with grains smaller than 2 mm is supplied via hydrocyclone 30 to the second classifying device K2 which splits the sand supplied to it at 0.5 mm. That is, the underflow of the second classifying device K2 contains granules with a size between 2 mm and 0.5 mm. Furthermore, the underflow contains an amount of flaw-35 grains smaller than 0.5 mm. The overflow of the second classifying device K2 mainly contains granules smaller than 0.5 mm. The overflow is supplied via the hydrocyclone 100 5 4 1 3 8 31 to the third classifying device K3 which splits the sand supplied to it at 0.25 mm. The overflow from the third classifier K3 is fed via the hydrocyclone 32 to the fourth classifier K4, which splits at 0.1 mm. The amount of granules smaller than 0.1 mm in the underflow of the fourth classifying device K4 is negligible and is not included in the calculations. The amounts of dry sand in the underflows of the second, third and fourth classifying device K2, K3, K4 are determined by means of measuring buckets in the manner described above.

The following is an example of a calculation of the composition of the sand supplied, i.e. of the sand with a grain size smaller than 2 mm, which is fed to the second classifying device K2. In this calculation it is assumed that the grain distribution of the sand supplied has a continuous course. The individual grain size ranges are indicated by letters: D: 0.5 - 2 mm E: 0.25 - 0.5 mm 20 F: 0.1 -0.25 mm

An equation can be drawn up for each underflow, where the percentage of each grain size area that ends up in the underflow of a certain classifying device follows from the Tromp curve of this classifying device.

Fig. 3 shows a Tromp curve of the second classifying device K2 at a separation point of 0.5 mm.

According to this trumpet curve, particles with a diameter of 0.25 mm have a 10% chance of ending up in the lower course of the second classifying device K2. Particles with a diameter of 0.5 mm or larger have almost a 100% chance of ending up in the underflow of the second classifying device K2.

35 In the calculations it is assumed that the probability for a particle from a certain grain size range to end up in the underflow of the classifier is equal to 1005413 9 as the probability of the particles with a size equal to the lower limit of the grain size range to end up in the lower reaches of the classification system. In practice other values can be used, which give a better approximation.

Fig. 4 shows a Tromp curve of the third classifying device K3. The separation point of the third classifier K3 is 0.25 mm.

The probability according to this Tromp curve that particles with a diameter of 0.25 mm end up in the underflow of the third classifying device K3 is almost 100%.

In the underflow of the second classifying device K2 is 10% of the grains from the grain size area E present in the supplied sand. The percentage of 15 grains in the supplied sand from the grain size area F that is located in the underflow from the second classifying device K2. is negligible.

In the underflow of the third classifying device K3 the rest of the grains from the grain size area E and 8% of the grains from the grain size area F present in the supplied sand are located. The amount of the grains from the grain size area F. grains of sand from the grain size area D in the underflow of the third classifying device K3 are negligible.

For the underflow of the fourth classifier K „in this example calculation, it holds that it consists of 92% of the grains in the sand supplied from the grain size area F. The quantities of the grains in the sand supplied from the grain size areas are smaller than 0.1 mm and larger than 0.25 mm in the lower run of the fourth classifying device K4 are negligible.

A number of comparisons can be made on the basis of these data.

35 For a weight amount of dry sand G3 coming from the second classifying device K2, the following applies: G, = D + 0.1 * E.

1005 4 1 3 10

For a weight amount of dry sand G2 coming from the third classifying device K3, the following applies: G2 = 0.9 * E + 0.08 * F.

For a weight amount of dry sand G3 coming from the fourth-classer K4, the following applies: G3 = 0.92 * F.

From these three equations, the weight quantities of the grain size ranges D, E and F in the sand supplied to the second classifier K2 follow.

The calculation of the weight amount of dry sand in a charge from the classifier from the combined volume-weight measurement follows from the following derived formula: 15 Gz = (Gl - VL x 103) 2.65 1.65 in which: VL = volume of the mixture in m3

Gl = weight of the mixture in kg 20 Gz = weight of dry sand in kg

In this equation, the specific gravities for sand and water are 2.65 * 103 kg / m3 and 1 * 103 kg / m3, respectively.

If the rough sand generally deviates relatively little from the desired products, a partial classification can suffice. The part that is then classified must be split off from the main stream of material in such a way that its composition largely corresponds to the rest of the rough sand. After all, after the classification, the composition of the raw sand can then be calculated, so that it can then also be determined which and how many of the classified fractions must be added to the original sand in order to obtain a product of the desired composition. This method provides significant savings in investment and energy costs 35.

1005 4 1 3

Claims (5)

1. Method for assembling granular mixtures of predetermined specifications from granular starting material, using a separating device for splitting the granular starting material into granular fractions, comprising at least two classifying devices, each of which uses the liquid granular material supplied thereto splitting into a first grain fraction and a second grain-10 fraction, which are respectively discharged into the underflow and the overflow of the respective classifying device, which method comprises the following steps: feeding the granular starting material to the separating device, 15. of the separator, splitting the granular starting material into different grain fractions, determining the composition of each of the grain fractions coming out of the separator and determining a mixing ratio of grain accordingly riffle fractions for composing a grain mixture with a predetermined specification, transporting the grain fractions to a collection point for assembling the grain mixture, characterized by the following steps: determining a Tromp curve of each classifier, 30. withdraw batchwise from each grader in the direction of the grain fractions, determine the weight and volume of a batch of a mixture of liquid and the relevant grain fraction for each of the grain fraction coming from each grader and determine the dry weight of the grain fraction. grains contained in the 1005413 charge, calculating the composition of the granular starting material using the Tromp curve of each grader and the dry weights of the grains contained in the charges, and calculating the composition of each of the grain fractions. 2. Method according to claim 1, wherein use is made of a separating device with a plurality of classifying devices placed in series, the overflow of each classifying device being fed to the next classifying device. A method according to claim 1 or 2, wherein at least a portion of the granular starting material is transported directly to the collection point for producing the granular mixture. 4. Apparatus for carrying out the method according to any one of claims 1-3, comprising a separating device for splitting granular starting material into granular fractions, comprising at least two classifying devices, each containing a granular material fed to it in a liquid form. a first grain fraction and a second grain fraction can split, characterized in that at least two measuring bins are arranged in each classifying device for receiving a load of liquid / grain mixture originating from the relevant classifying device and that means are provided for determining the weight and volume of the cargo. Assembly comprising a classifying device, at least two measuring trays for receiving a load of liquid / granule mixture originating from the classifying device and means for determining the weight and volume of 10054 1 3 the load which assembly is arranged for use in a device according to claim 4. 1005413