NL1007199C2 - Sand washer and method for washing contaminated sand. - Google Patents

Description

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Sand washer and method for washing contaminated sand.

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The present invention relates to a contaminated sand scrubber scraped from filter media in a filter pond or from the bottom of a waste water pond or a settling basin or cover sand to remove mud or materials covering the sand surface.

Filter sand used in a water purification station is collected on a river bottom or in a river estuary, but these resources are limited, so that the sand is reused after use after it has undergone a cleaning or similar process. It has been found that, due to a rapid contamination of the water or under the influence of contaminants or pollutants flowing into the filter pond, the grain diameter of the filter material increases due to the deposition of sludge, or that sludge is separated from the filter media. When the grain diameter of the filter media increases as described above, the space between the filter media decreases and the filtering becomes less efficient. It is therefore necessary to regularly remove the filter media from the filter pond and to remove the mud from the surface of the filter media by washing them.

Traditionally, in the washing process of the filter media, a washing machine with agitation blades is usually used to mix the contaminated sand and the cleaning water and to agitate the mixture, but when a large amount of contaminated sand is strongly agitated, the sand grains are pulverized by the collision with the 10 0 7 1 9 9 2 agitation blades or as a result of the friction between the filter media themselves, so that the part that cannot be recycled increases; moreover, when there is only a small amount of cleaning water, the separated contaminants are redeposited on the sand grains, so that a high efficiency of the cleaning process cannot be expected.

As a so-called sand washing device, an apparatus 10 has also been proposed with a sand scraping section in a central position of the base part for agitating and washing sand by rotating a screw conveyor arranged in the sand scraping section. This sand washer is one = 15 which is mainly used for the removal of salt deposited on the surface of sea sand, and it has a construction where the screw conveyor is equipped with sand scraper blades in its bottom part and with agitation blades in its top part 20 and with dividing blades arranged in the top part of the sand scraper section.

In such sand washers as described above, the sand contained in a cleaning tank is raised to the agitation blade section through the sand scraper blades, where the sand is mixed with cleaning water which is poured in; the sand in the cleaning water is agitated, diluted and washed and further raised as a result of the rotation of the agitation blades, after which the sand is homogenized and transferred vigorously from the sand scraper section to the cleaning tank. Because of this construction, it is necessary to spray sand into the cleaning tank to at least the height of the distribution blades; Furthermore, the cleaning water is supplied in a 10 0 7 1 9 8 3 section where the agitation blades rotate and 20 hours of water after cleaning overflows from a water discharge pipe in the upper part of the cleaning tank, so that the cleaning tank must always be filled with the cleaning water.

As described above, the traditional sand washer generally has an arrangement where sea sand flows into the tank and is agitated with cleaning water to dissolve the salt deposited on the surface of the sand grains in the cleaning water, so that clean sand is obtained.

Even when filter media are washed with a traditional sand washer as described above, contaminants other than salt deposited on the surface of the sand grain are not dissolved in the cleaning water, so that high cleaning efficiency could not be expected. In addition, when the feed rate of the cleaning water is decreased to stop the flow of sand to be cleaned, the grains of sand are often pulverized by striking a large amount of contaminated sand with great force against the agitation blades. In addition, because the sand scraper blades and agitation blades continue to rotate in the sand, the friction between the agitation blades and the sand is very great, which is disadvantageous.

The present invention contemplates a sand washer which can effectively remove contaminants that have deposited on the surface of a grain of sand and which cover it without pulverizing the injected sand and wherein the agitating part also suffers little wear.

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In order to solve the above-described problems, the sand washing device according to the invention comprises a cleaning tank for storing sand and cleaning water, equipped with a sand inlet channel in the top part and a sand outlet channel in the bottom part, and an agitation tank standing upright in this cleaning tank is placed, the agitation tank having openings in the top and bottom edge portions, and a screw conveyor 10 rotating about a predominantly vertical axis in this agitation tank, driven by a rotation mechanism at a speed that causes the sand and the cleaning water is lifted, so that at least part of the pollutants on the grains are removed under the surface of the cleaning water as a result of the contact between the sand grains, whereby cleaning water is always introduced between them, and the sand grains above the surface of the cleaning water fluidized on the surface of the screw conveyor, so that at least some of the residual contaminants are removed from the sand grains due to the contact between the sand grains.

2 5 The amounts of sand and cleaning water that are injected into the cleaning tank are adjusted so that the top half of the screw conveyor protrudes above the sand and the water into the agitation tank. When the screw conveyor is turned, the sand and the cleaning water which is gradually supplied from the lowest opening part of the agitation tank rise upwards along the spiral blade. By setting the speed of rotation of the screw conveyor high so that the sand stored in the tank and the water can rise to 35 at the top edge of the blade, the sand is fluidized; in this state the grains of sand collide and rub against each other in the water flowing upwards. The rotational speed must be set so that the fluidized sand is discharged from the agitation tank to the cleaning tank.

Precipitated sand and cleaning water are pushed up here. they are stopped by the screw conveyor, which limits their free movement; in the part in which the fluidized sand flows upwards, however, the screw conveyor exerts no restriction, so that the cleaning water continues to flow upwards. The fluidized sand then forms a discontinuous eddy current and friction occurs between the sand grains, so that a water effect is obtained.

The amount of water falling from the free space between the outer edge part of the screw conveyor and the inner wall of the agitation tank is greater than the amount of sand, so that the density of the sand increases as it moves to a higher part of the screw in compared to when it settles on the bottom of the agitation tank. The chance that the grains of sand rub against each other in the fluidized sand on the conveyor projecting above a layer of deposited sand is greater than when sand with water is agitated in the deposited part. Hereby, the washing effect obtained by abrasion of the grains of sand against each other is effective and contaminants or contaminants which have deposited on or cover the surface of a sand grain can be effectively removed.

When the fluidized sand flows upwards on a blown-inclined surface of the screw conveyor, the sand grains, all of which have the same hardness, will rub against each other due to the eddy current present here. However, the grains of sand rarely collide with a higher hardness part, so that they are not exposed to excessive force and that they cannot be pulverized. Even when the grains of sand collide with the inner wall due to the centrifugal force, they move in the water, so that the energy released by the collision is rather small and so that the risk of the sand grains being pulverized is extremely small. Furthermore, since there is always water between the grains of sand that rub against each other, the separated contaminants are dissolved in the cleaning water; reprecipitation as a result of sanding is therefore excluded. This increases the cleaning effect on the sand. In the part in which the fluidized sand flows upwards, the sand grains only come into contact with the upper surface 20 of the agitation blade, so that the wear of the agitation part is rather minimal-

We note that the free space between the outer edge portion of the screw conveyor and the inner wall 25 of the agitation tank is preferably at least 3 times wider than the diameter of the sand grain to prevent the sand grains from being pulverized. The fluidized sand flowing upwardly to the opening in the top edge of the agitation tank then enters the cleaning tank 30 and is recycled through the opening in the bottom edge into the agitation tank; furthermore, a eddy current is created in the cleaning tank as well as a washing effect as a result of the sanding between the grains of sand. Also in the part where the fluidized sand flows upwards, some of the sand that has fallen 1007 199 7 from the outer edge of the screw conveyor is pushed up again, so that the washing phase by sanding takes longer, washing effect is beneficial.

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The sand washing device according to claim 2, characterized in that a plurality of wing-shaped agitation blades which are arranged predominantly in parallel with a surface of the screw conveyor in the portion to cause the sand to flow upwards. This agitation blade has the shape of a wing, it has a considerable curved surface and several agitation blades are arranged in the direction of rotation of the screw conveyor. The fluidized sand flowing along the curved surface of the agitation blade first creates a liquid flow and then a vortex flow. This eddy current supports the eddy current produced by the upward pressure effect of the screw conveyor, so that the movement of the abrasive grains of sand is further supported by the improved washing effect.

Each agitation blade has a sharp or slightly rounded end to prevent the grains of sand from being crushed. In order to take into account that the grains of sand can be pulverized or that the load on the agitator blade can be increased, each blade is placed at an angle which is mainly parallel to a surface of the screw conveyor. The agitation blade is preferably attached to a support arm placed on the surface of the screw conveyor. Furthermore, the fluidized grains of sand are moved from the center along the outer circumference and the agitation blades are preferably applied in this section. In order to avoid pulverization of the sand grains, a round arm is preferably chosen as the supporting arm, but several alternating vertical and wing-shaped blades may be arranged in the direction of rotation of the screw conveyor.

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In the portion in which the fluidized sand flows upwards, the sand grains mainly come into contact with the top surface of the spiral blade and the wing-shaped agitation blade and the sand grains 10 flow along these parts, so that the agitation part is subject to little wear.

This invention also relates to a method for cleaning contaminated sand.

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More particularly, the invention also relates to a method for cleaning contaminated sand, which is characterized in that 2e consists of: - providing a cleaning tank for storing contaminated sand and cleaning water, wherein contaminated sand and cleaning water in predetermined quantities and in which a screw conveyor is arranged which is rotatable about a substantially vertical axis, such that the lower part of the screw conveyor is located below the surface of the cleaning water in the cleaning tank and the upper part of the screw conveyor above the surface of the cleaning water is located in the cleaning tank; - raising the sand and the cleaning water by rotating the screw conveyor below the water surface; I .. 7 19 9 9 - fluidising, above the surface of the water, the sand on the surface of the screw conveyor and thereby contacting the grains of sand, whereby cleaning water is introduced in each case to at least part of the remove residual pollutants from the sand grains; and - lowering the sand that has been brought up to the lower part of the screw conveyor via a path located outside the screw conveyor; - where the contaminated sand is washed by repeated ascent and descent.

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Below is a detailed description of embodiments of the present invention with reference to the accompanying drawings.

Figure 1 is a sectional view of a sand washing device according to an embodiment of the present invention;

Figure 2 is a cross-sectional view of a sand washer according to another embodiment of the present invention;

Figure 3 is a sectional view showing the top portion of the agitation tank;

Figure 4 is a front view of the agitation blade; n Figure 5 is a sectional view showing agitation blade 30 taken along line V-V in Figure 4.

Figure 1 is a cross-sectional view of the sand washer of the present invention. The sand washing machine 1 comprises a cleaning tank 2, an agitation tank 3, a screw conveyor 4 and a drive unit 5, the; 7 1 0 0 10 Correct amounts of contaminated sand 6 and cleaning water are placed in the used tank. The cleaning tank 2 has an inlet channel 2a for the sand in the upper part and an outlet channel 2b in the lower part, the surface of the bottom being inclined so that the deposited contaminated sand 6 is gradually introduced into the agitation tank 3.

The agitation tank 3 is a cylindrical body which is placed upright in a central position of the cleaning tank 2 and has an opening 3a in the top edge and an opening 3b in the bottom edge; a rotary axis 4a of the screw conveyor 4 is introduced via a central part thereof. A spiral blade 4b attached to the pivot axis 4a is sufficiently distant from an inner wall 3c of the agitation tank 3 and effectively transports the contaminated sand 6 to the opening 3a in the top edge. If the distance mentioned above is too great, more sand will fall during the upward movement, but if the distance is too small, the space can become clogged with sand grains, the sand grains can be pulverized or the blade 4b can wear out; the distance must therefore be at least 3 times greater than the diameter of the sand grains. In order to be able to adjust the distance from time to time according to the grain size of the contaminated sand to be washed, the screw conveyor 4 and the agitation tank 3 are preferably interchangeable.

A pressure chamber 4c is provided below the bottom surface 3d of the agitation tank 3 and an interface of the rotary axis 4a. Hydraulic pressure or air pressure is supplied to this pressure chamber 4c via the nozzle shown here to prevent the cleaning water 7 and the contaminated sand 6 from leaking out.

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The screw conveyor 4 has a part that protrudes above the layer of contaminated sand 6 deposited in the agitation tank 3 as well as above the surface of the cleaning water 7. The total amount of contaminated sand 6 and cleaning water 7 that is introduced into the agitation tank 3 must in particular be controlled so that this section protrudes above it. The weight ratio of the contaminated sand 6 to the cleaning water 107 must be high enough so that a better cleaning effect is obtained.

The speed of rotation of the screw conveyor 4 must be set high enough so that the cleaning water 7 can flow upwards to the upper edge of the blade 4b. When the drive unit 5 is activated, the contaminated sand 6 and the cleaning water 7 which are successively supplied from the opening 3b of the bottom edge of the agitation tank 3 move upwards along a surface of the blade 4b and reach the projecting part ; if the cleaning water 7 still flows upwards during this phase, the contaminated sand 6 starts to float, so that the sand is fluidized. In the section 4d in which the fluidized, washable sand flows upwardly to the opening 3a in the upper edge, the fluidized sand causes a discontinuous eddy current and the grains of sand rub against each other in the upwardly moving water stream, so that pollutants or contaminants that are deposited on the surface of the grains of sand and which cover them can be effectively removed.

We note that although at least enough cleaning water 7 must be introduced to allow the sand to fluidize in the protruding portion, if too much cleaning water 7 is supplied, there is less chance of the sand grains will rub against each other, so that removing the contaminants is less effective. Even when the projecting part is small, washing becomes less effective. On the other hand, when the protruding portion is too large, the absolute amount of 2and being washed decreases, making washing less effective. Therefore, the total; 10 quantities and the ratio between the contaminated sand 6 and the cleaning water 7 that is introduced are calculated taking into account all the factors described above.

Next, the sand washing machine according to another embodiment of the present invention is described with reference to Figure 2 to Figure 5. Figure 2 is a cross-section of the sand washing machine according to another embodiment of the present invention. Figure 3 is a sectional view of the top portion of the agitation tank. Figure 4 is a front view of the agitation blade. Figure 5 is a cross-sectional view of the sand washer as seen on line V-V in Figure 4. We note that the same reference numbers are assigned to parts having the same composition or effect as those shown in Figure 1; its description is therefore omitted hereinafter.

Figure 2 shows an agitation blade 8 attached to the blade 4b of the screw conveyor 4 protruding above the top layer of the deposited contaminated sand 6 as well as above the top layer of the cleaning water 7. The agitation blades 8 are arranged symmetrically around a center point in the outer circumference, the wing 8a having a clearly curved surface predominantly parallel

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10 0 7 1 9 9 13 runs with the blade 4b in the direction of rotation of the screw conveyor 4. In this embodiment, the agitation blade 8 is attached to the support arm 8b between the blades 4b, but the agitation blade 8 can also be attached to a support arm which protrudes in the radial direction of the rotary axis 4a. Furthermore, although the support arm 8b is a vertical agitation blade in the form of a wing and is arranged in the same direction as the blade 8a, the support arm can also be designed in other shapes than the above described form, for instance as a round arm.

Furthermore, the fluidized 2and flowing along a curved surface of the blade 8a of the agitation blade 8a causes the liquid to separate as shown in Figure 4 and causes a vortex flow to the rear thereof. This eddy current supports the eddy current caused by the upward pushing effect of the screw conveyor 4, so that the sanding of the grains of sand is promoted, resulting in a better washing effect.

After the fluidized sand has been moved to the opening 3a in the top edge of the agitation tank 3, it then enters the cleaning tank 2, after which it passes through the opening 3b in the bottom edge and is recycled again into the agitation tank 3 by tare weight. As the sand falls, air is supplied to the stream of cleaning water 7; by this air flow the sand grains are moved upwards and the falling sand grains cause an irregular eddy current; in this section the grains of sand also start to rub against each other.

The following description refers to a case where the contaminated sand was washed with the sand washing machine described above. The sand washer used in this experiment is shown in Figure 1. The contaminated sand washed by this unit had a turbidity level of 1150, a flank diameter of 0.513 mm; 5 has a homogeneity coefficient of 1.532 and it was placed in a 430 liter tank along with a specified amount of cleaning water. Table 1 shows the relationship between the rotational speed of the screw conveyor and the turbidity. We note that the turbidity shown in Table 1 was measured 30 minutes after agitating and the frequency of 40 MHz j corresponds to about 90 rpm.

Table 1 15 Quantity Water Sand Frequency Turbe (1) (kg) (1) (Hz) 1-screw (degree) ______ conveyor__ 1-1__100__100 74 40__17.4 1-2 __ "__” _ "_ 50__20 1- 3 __ * __ "__60__12.8 2- 1 __" ___ 200 148 40__21 2 0 2-2 __ ”__ J | _ · __50__16.9 2-3 __" __ * __ "60__14.7 2- 4 ____" __ 70__14.4 3- 1 __ ”__ 300 220__60__18.4 3-2 "" "75 12.9 25

As described above, in all cases where the ratio of the water to the sand is changed, the turbidity will generally decrease as the frequency increases. Table 2 also shows a relationship between the frequency of the appliance and the inflation height of the water or the inflation portion of the sand, and it can be stated that the sand and the cleaning water are preferably supplied to a volume that is equal to about 1/2 to 2/3 of the total volume of the tank (about 210 to 280 liters), whereby the 5 screw conveyor is rotated at a frequency of about 60 Hz to increase the pumping height of the water sufficient for washing (HO / 3 to HO / 21; HO = height of the tank).

10 Table 2 - - _ - - - - 11 - - —— -,

Inflation stroke Inflation height water Inflation height sand

Hz _______ __40__HO / 4 __ — _ _55__HO / 3__HO / 2_ 15 _65__HO / 2 3 HO / 4

Table 3 shows the relationship between the frequency and the turbidity in a case where the total amount of sand and water is larger and the portion of fluidized sand that is pumped up is extremely small.

Table 3

Quantity Water Sand 200 1 300 kg _______ (220 1) _

Frequency Turbidity __ (Hz) _ (degree) __ 25 4-1__ 70_ 19.1_ _4 ^ 2 ____ 75____21_ _4-3__80 ____ 19.1 _4-4__05 ____ 17__ 4-5 90 19.9 l —— w— - -L- - ^ - - J30

As described above, when the portion 10n 7 199 16 in which the: fluidized sand flows upward reaches a value of HO / 4 or less, the turbidity cannot be reduced during agitation even when the frequency is increased; it will hardly fall below a degree of turbidity 19. In order to lower the turbidity of this sample to about 14 or less, the total amount of sand and cleaning water is preferably kept agitating in a range of about 1/2 to 2/3 of the total contents of the tank and the frequency 10 set at about 60 Hz.

As for the grain density of the sand grains after washing, the grain does not change even when washed at a high speed with a frequency of 90 Hz. As described above, the device that agitates the contaminated sand with a screw conveyor will not pulverize the sand grains in the least.

Following is the description of an example where the contaminated sand was washed with the 2washing device shown in Figure 2. The contaminated sand washed by this device has a turbidity degree of 1150, it has a solubility in hydrochloric acid of 2.93%, a flank diameter of 0.583 mm and a homogeneity coefficient of 1.420. 200 kg of contaminated sand and 100 kg of cleaning water were fed into a 420 liter tank; the contaminated sand was washed at a rotation speed of 159 rpm (70 Hz) for 30 minutes. By comparison, the same experiment was performed.

30 carried out under the same conditions, but with a traditional type of sand washer that does not exhibit an agitation blade as shown in Figure 1. We note that it was a traditional sand washer of the type in which contaminated sand is agitated vigorously with water in an agitation tank.

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Table 4 17

Sandwash- Sandwash- Traditio- appliance appliance neel with no kind of agitation- agitation- sand wash- ____ sheet __ appliance

Cloudy- Before 1150 1150 1150 heath cleaning 5 degree_________ 10 11.5 17.4 73 minutes after cleaning____ 30 4.7 10.8 S3 minutes after cleaning____

Solution- Clean the 2.93 2.92 2.92 bar 10 in hydrochloric acid e Ό 10 1.65 2.01 2.36 minutes after cleaning _____ 30 0.97 1.52 2.07 minutes after cleaning _______ 15 Flank- Before 0.583 0.587 0.592 diameter cleaning mm_______ 10 0 7 1 9 9 18 10 0.589 0.590 0.584 minutes after cleaning____ 30 0.587 0.587 0.570 minutes after cleaning___

Homogeneous- Before 1,420 1,419 1,419 niceits- cleaning 5 coefficient ___.___ 10 1,419 1,417 1,426 minutes after cleaning____ 30 1,417 1,415 1,445 minutes after cleaning | As shown in Table 4, the turbidity after washing with the sand washing machine of the present invention was 4.7, which was about 1/13 compared to the washing result obtained with the traditional sand washing machine type and half or less than the result which was obtained with the sand washer without agitation blade. The solubility in hydrochloric acid when it was washed with the sand washer of the present invention was 1/2 of what was obtained with the traditional type of sand washer and about 1 / 1.5 of the result obtained with the sand washer without agitation blade, indicating that the separation of contaminated sand was promoted, however, when using the traditional sand washer, the flank diameter was reduced from 0.592 i • 10 0 7 1 99 19 cot 0.570, while the homogeneity coefficient increased from 1.419 to 1.445, indicating that the grains of sand were pulverized and the homogeneity was lost by washing. However, when the sand was washed with the device according to the present invention and with a device without agitation blade, neither the flank diameter nor the homogeneity coefficient underwent significant changes, indicating that no pulverization took place.

As described above, the screw conveyor of the sand washer according to the present invention has a portion in which the fluidized sand flows upwards, so that the fluidized sand causes a discontinuous eddy current, causing a friction between the sand grains, and thus a washing effect. Therefore, contaminants deposited on or covering the surface of sand grains can be effectively removed. The fluidized sand therefore exhibits an abrasive effect between the grains of sand, but the grains of sand hardly collide with parts of higher hardness, so that the grains of sand are not exposed to an excessive force, so that they are pulverized. Moreover, there is always cleaning water between the sand grains, so that the contaminants that are separated from the surface of the sand grains are dissolved in and carried along with the water. Furthermore, only the top surface of the blade comes into contact with the sand in the part in which the fluidized sand flows upwards, so that the agitating part is subject to little wear.

In the sand washing device according to claim 2, a wing-shaped agitation blade is also arranged in the part in which the fluidized sand flows upwards, so that the fluidized sand flowing along a curved surface of the agitation blade causes a eddy current, so that the eddy current caused by the upward pushing effect of the screw conveyor, so that I also promote the sanding of the grains of sand, resulting in a better washing effect.

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The agitation blade of claim 3 is attached to a support arm and is disposed in a portion of the outer circumference of the conveyor so that it can effectively agitate the fluidized sand that is knocked out as a result of the centrifugal force. The support arm according to claim 4 is a vertical 1 wing-shaped agitation blade which promotes the creation of a eddy current.

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Claims (7)

1. A sand washer (l) with a cleaning tank (2) for storing 5 sand (6) and cleaning water (7), equipped with a sand inlet channel (2a) in the upper part and a sand outlet channel (2b) in the lower part , and an agitation tank (3) placed upright in this cleaning tank, characterized in that the 10 agitation tank (3) has openings (3a, 3b) in the upper and lower edge sections, and a screw conveyor (4) is provided rotating about a predominantly vertical axis in this agitation tank (3), driven by a rotation mechanism at a speed 15 which ensures that the sand and the cleaning water (7) are lifted, so that at least under the surface of the cleaning water (7) some of the pollutants on the grains are removed as a result of the contact between the sand grains, 20 of which cleaning water is introduced between them, and the sand grains are above the surface of the cleaning water. and fluidized on the surface of the screw conveyor (4), so that at least some of the residual contaminants are removed from the sand grains due to the contact between the sand grains. Sand washing machine according to claim 1, characterized in that it is provided with a large number of relatively small agitation blades (8) which are predominantly parallel to and between the adjacent relatively large blades of the screw conveyor (4). Sand washing machine according to claim 2, characterized in that the agitation blades (8) are mounted on support arms (8b) which are arranged upright on a surface of the screw conveyor (4) and which are located in part of the outer circumference of the screw conveyor (4 ). 10 Sand washing machine according to claim 3, characterized in that the support arms are wing-shaped agitation blades arranged in the direction of rotation of the screw conveyor (4). 15 Sand washing machine according to claim 1, characterized in that the distance between the outer circumference of the screw conveyor (4) and the wall of the agitation tank (3) is at least three times greater than the diameter of the 20 sand grains. 6. Method for washing contaminated sand, characterized in that it comprises: - providing a cleaning tank for storing contaminated sand and cleaning water, in which contaminated sand and cleaning water are introduced in predetermined quantities and in which a screw conveyor is arranged which is rotatable about a substantially vertical axis such that the lower part of the screw conveyor is located below the surface of the cleaning water in the cleaning tank 0υ 0 7 199 and the upper part of the screw conveyor is above the surface of the cleaning water in the cleaning tank located; - raising the sand and the cleaning water by rotating the screw conveyor below the water surface; - fluidizing, above the surface of the water, the sand on the surface of the screw conveyor and thereby contacting the sand grains, whereby cleaning water is interposed each time to remove at least a part of the remaining pollutants from the sand grains , And - lowering the sand that was brought upwards to the lower part of the screw conveyor via a path located outside the screw conveyor; - where the contaminated sand is washed by repeated ascent and descent. Method according to claim 6, characterized in that the screw conveyor is driven at such a speed that the water rises to the top of the screw conveyor. 10 0 7 1 99