DE19731052A1 - Making supercooled water ice for mixing cold concrete to prevent poor bonding and fissuring - Google Patents

Abstract

The method makes ice particles from water, which is distributed into a bath of liquid gas. The ice particles are extracted from the bath as frozen droplets. It also involves using equipment including a vessel for the liquid gas, with atomisers directed within or into it. Suitable pipework and fittings (3, 4) introduce the raw materials, and means of ice particle extraction are provided. Preferably, the dry constituents are dosed and mixed with ice at set temperature, before making-up judiciously with a minimum of water.

Description

The invention relates to a method according to the preamble of the main claim and an order for implementation of the process and the use of the manufactured Ice particles.

It is problematic when using a liquid concrete mix Gravel, cement and water a certain temperature otherwise the concrete is not in the sets required way. Then there is a risk that cracks form.

So it is known, the liquid concrete slab-shaped ice to add. On the one hand, this has the disadvantage that ice only has a temperature of a few minus degrees, on the other the large ice sheets only slowly dissolve within the Concrete mix on. The disadvantage is therefore the corresponding large amount of ice sheets that must be added to to achieve a certain cooling. On the other hand, one even distribution of the ice water of the melting Ice sheets in the concrete mix poorly reached.  

The invention is therefore based on the object Method and an arrangement for the production of Ice particles from water and their use propose with the unrelated ice particles of considerable minus degrees of the order of lower than -50 ° C can be obtained.

This task is carried out in a generic method according to the preamble of the main claim according to the invention solved in that the water is distributed in drops a bath of liquid gas, preferably liquid Nitrogen is entered and that in the form of ice particles formed in drops of frozen water be removed from the bathroom.

As a result, non-contiguous small and smallest ice particles in the form of frozen drops Get water that has a granular pourable structure and do not stick together. You are also at Use of liquid nitrogen as a liquid gas colder than -100 ° C. These ice particles with a diameter less than 1 cm, preferably less than 1 mm can be processed as bulk goods.

It is of particular advantage to use the ice particles Setting the fresh temperature for the production of use chilled fresh concrete, the ice particles at a certain temperature in a metered amount of dry Added concrete mix and mixed thoroughly with it will. Only then will the measure of water be used for production of the liquid concrete added in an amount that - regarding the total amount of water - around that of the dosed Amount of ice particles added corresponding amount Water is diminished.  

The dried ice particles can be used with advantage manufacture by using a finely atomizing Water spray drops of water into the liquid gas is sprayed. After that, the frozen ice particles only by means of a sieve with an appropriate mesh size be removed.

Furthermore, an arrangement is provided according to the invention which is characterized by a container for holding the liquid gas, means provided in the container for Atomizing water and introducing the atomized Water into the liquid gas, by means of supplying the liquid gas and water into the tank and through Means for bringing out the frozen water particles the liquid gas. Such arrangements can be used build and operate with relatively little effort.

A continuously operating arrangement and also one in batch operation arrangement are in the Subclaims marked.

Further details and advantages of the invention are the further subclaims, as well as the following description exercise and the associated drawing of the invention Arrangement described. In the essentially schematic Drawing shows:

Fig. 1 shows a first embodiment of the invention in longitudinal section;

. FIG. 2 shows a section along the line II-II in Fig 1,

Fig. 2a shows a cross section through the screw conveyor with the housing,

Fig. 3: another embodiment of the invention in longitudinal section.

In the exemplary embodiment according to FIG. 1, a container is provided in the form of a preferably heat-insulated drum 1 , which can be rotated about its horizontally extending longitudinal axis AA. In the drum 1 , liquid nitrogen can be introduced with line 3 and water with line 4 . The water introduction ends in spray nozzles 5 , which are distributed over the length L of the interior of the drum 1 , that the bath 6 located in the lower region of the drum made of liquid gas, preferably liquid nitrogen, by means of the nozzles 5 from above with finely sprayed Water 2 can be applied. The surface of the gas bath 6 is numbered 7 .

Either concentrically to the drum 1 , that is, with a central longitudinal axis that coincides with the axis AA of the drum, but preferably eccentrically to the vorgenann th axis AA, a screw conveyor 8 is provided, which is the material given to him by the scoops 14 of the ice particles formed in the bath 6 leads to the outside in the direction of arrow 10 , so that it reaches the schematically indicated container 12 via a slide 11 . The container 12 can be the mixing container of a concrete mixing vehicle or a container containing the additives. The above-mentioned eccentricity is preferably chosen so that the longitudinal center axis of the screw conveyor 8 is at a corresponding distance above the longitudinal center axis AA of the drum 1 . This creates more space below the screw conveyor 8 for the accommodation of the bath 6 , for the means of what water supply and for atomizing the water on the Bado surface.

As already explained at the beginning, the small water particles 2 generated by the spray nozzles 5 are frozen in the bath 6 to form a correspondingly small ice particle. The scooping bowls 14 rotating in the direction of the arrow 13 (see FIG. 2) are provided. For reasons of structural simplicity, these shells 14 are firmly connected to the drum 1 and circulate with it. In the present exemplary embodiment, two scooping bowls 14 are provided, which are offset by 180 degrees in the direction of rotation 13 . When passing through the bath 6, these scoops take the ice particles is formed therein, scoop them out of the liquid 6 and insert them into the screw conveyor. 8 For this purpose, the housing 15 of the screw conveyor is open in its upper region for unloading the ice particles from the scoops 14 ( FIG. 2a); while the lower region of the housing 15 is closed and prevents the ice particles from falling back into the bath 6 .

The scoops 14 can have very small slits or openings in their diameter or width which allow the bath liquid 6 to pass through, but not the ice particles formed therein. This prevents the scoops 14 from carrying liquid gas with them when they leave the bath 6 .

The sprayed water meets the liquid nitrogen part of this nitrogen evaporates. This gaseous fractions are counteracted by a fan Pressure of the outside atmosphere derived into this. That gas can optionally be used to add aggregates (Gravel, etc.) to cool down.

Furthermore, a feed 16 of gaseous nitrogen or the like to the water line 4 is provided to prevent ver that after interrupting or stopping the ice manufacture the nozzles 5 freeze. For this purpose, any remaining water is removed using the gaseous nitrogen.

An electric motor drive 17 drives the drum 1 and the scoops 14 via a belt drive 18 as well as the screw conveyor 8 via a belt drive 19 . Regulation of the speed of the belt drive 18 and the belt drive 19 can be provided (not shown in detail in the drawing).

The supply of water can be clocked with a solenoid valve 20 in line 4 so that water is only sprayed out of the nozzles 5 when the scoops 14 are not directly in the area of the spray jet 2 .

Another regulation can be made regarding the height of the surface level of the bathroom should be provided with the aim of this Control height and halve to a certain value ten.

Provided you know how much of the mix in total for the concrete substances (cement, water and aggregates) comes together, can be adjusted by adjusting the amount of supplied ice particles relatively exactly a desired one Temperature of the cooled concrete mix to be produced to reach.

Which can be prepared with the arrangement of Fig. 1 to 2a chen in kontinuierli operation ice particles with a maximum diameter of 10 mm and a temperature which is below 100 degrees C, usually at about -180 degrees C, according to the embodiment described below, also be made to FIG. 3 with an arrangement in the discontinuous mode, ie batch processing tet. Here, too, finely atomized water is converted into the deeply liquefied gas, preferably nitrogen, into the ice particles described above.

Fig. 3 shows a preferably made of steel liquid gas container 21 , in the interior 22 of which is the bath of liquid gas, preferably liquid nitrogen. The container 21 is preferably also heat insulated, e.g. B. with perlite. A basket-like ice bucket 23 can be suspended from above in the direction of arrow 24 into the interior 22 of the liquid gas container 21 by means of a cable 25 and pulled out again. The wall of the ice bin and the bottom of which are permeable to the liquid so that the liquid is at a gebrachtem ice container in the interior of which the 26th The liquid level of the liquefied gas is numbered 27.

Here, too, water is finely atomized into the interior of the ice container 26 via a nozzle 29 or a plurality of nozzles, in order to become small deep-frozen ice particles there in the manner already explained. The permeable areas of the wall of the ice container 23 are dimensioned so small that the ice particles cannot pass through beforehand, but the liquid gas can. If a sufficiently large batch of ice particles is created in the ice container 23 after a certain time, it is pulled out of the liquid gas container 21 and reaches the position 30 shown in broken lines. The located in the ice container 23 liquid nitrogen or the like flows in this pulling out of the container 23 in the space 22 back. The container 23 can then be tilted about a pivot axis 31 in the position already presented Darge, so that via a discharge channel 32 the ice particles get into a slide 33 , which che in principle in structure and function the same as the slide 11 from the previously described embodiment is.

The liquid gas, preferably nitrogen, is supplied through a line 34 with a metering valve 35 for regulating the quantity supplied. A corresponding metering valve is also available in the embodiment according to FIGS . 1-2a.

All features shown and described, as well as their Combinations with one another are essential to the invention.

Claims (20)

1. A process for the production of ice particles from water, characterized in that the water is introduced dropwise into a bath of liquid gas, and that the ice particles in the form of the dropwise frozen water are removed from the bath. 2. The method according to claim 1, characterized characterized in that the liquid gas is liquid nitrogen is. 3. The method according to claim 1 or 2, characterized characterized in that the water is sprayed or atomized into the bath is entered. 4. The method according to any one of claims 1 to 3, characterized in that the ice particles by sieving or abseiling can be removed from the bath. 5. Arrangement for performing the method according to any one of claims 1-4, characterized by a container ( 1 ; 21 ) for receiving the liquid gas, means provided in or on the container ( 5 ; 29 ) for atomizing water and introducing the atomized water ( 2 ) into the liquid gas, by means ( 3 , 4 ; 34 , 28 ) for supplying the liquid gas and water into the container and by means for removing the ice particles from the liquid gas. 6. Arrangement according to claim 5, characterized in that a rotatable drum ( 1 ) is provided as a container and rotatable about a horizontal axis (AA) that above the liquid gas-absorbing lower region of the drum one the water down into liquid gas spraying over the substantial region of the drum length (L) extending spray device ( 5 ) is arranged, and that a scoop ( 14 ) for removing the ice particles from the liquid gas and transport means ( 8 , 11 ) for removing the ice particles from the drum are provided. 7. Arrangement according to claim 6, characterized in that as scooping revolving scoops ( 14 ) are provided which have openings of such a size that they allow the passage of the liquid gas, but not the passage of the ice particles. 8. Arrangement according to claim 7, characterized in that the scooping means ( 14 ) are fixedly attached to the inside of the rotating drum. 9. Arrangement according to one or more of claims 5 to 8, characterized in that a screw conveyor ( 8 ) is provided for the removal of the ice particles from the drum ( 1 ) which extends in the axial direction (AA) of the drum ( 1 ) and itself in the storage area of the scooping means ( 14 ). 10. The arrangement according to one or more of claims 5 to 9, characterized in that the central longitudinal axis of the screw conveyor ( 8 ) either coincides with the central longitudinal axis (AA) of the drum ( 1 ) or is arranged eccentrically offset upwards. 11. The arrangement according to one or more of claims 5 to 10, characterized in that the drum ( 1 ) with the scooping means ( 14 ) on the one hand and the screw conveyor ( 8 ) on the other hand each rotate at different speeds. 12. The arrangement according to claim 11, characterized by a common drive ( 17 ) with different ratios ( 18 ; 19 ) for the rotation of the drum ( 1 ) with scooping means ( 14 ) and the screw conveyor ( 8 ). 13. The arrangement according to claim 5, characterized in that an upwardly open liquid container ( 21 ) with an interior 22 ) is provided for receiving the liquid gas, the liquid gas supply ( 34 ) opening into this container that a in the liquid gas container ( 21 ) insertable ice container ( 23 ) is provided, the wall of which allows the passage of liquefied gas, but not the passage of the ice particles, and that a water atomizing device ( 28 , 29 ) is placed in the liquefied petroleum gas container above the freely accessible liquid gas level. 14. Arrangement according to claim 13, characterized in that a lifting device ( 25 ) for the introduction and removal of the ice container ( 23 ) in the liquid gas container ( 21 ) is provided. 15. An arrangement according to claim 13 or 14, characterized by means for emptying the ice container ( 23 ) removed from the liquid gas container ( 21 ). 16. The arrangement according to claim 15, characterized in that the ice container ( 30 ) about a perpendicular to its longitudinal axis tilt axis ( 31 ) is pivotable and by a located in the emptying direction of the container slide or the like ( 33 ) for the removal of the ice particles is provided. 17. The arrangement according to one or more of claims 5 to 16, characterized by control valves ( 35 ) for metering the supply of liquid gas in the relevant lines ( 3 ; 34 ). 18. Arrangement according to one or more of claims 5 to 17, characterized by a gas supply ( 16 ) for emptying the water spray devices ( 5 ; 29 ) after completion of the operation. 19. Use of the method according to Claims 1 to 4 produced ice particles for Setting the fresh concrete temperature, especially for Production of chilled fresh concrete. 20. Use according to claim 19, characterized characterized in that the ice particles with certain Temperature in a metered amount of the dry concrete mix added and thoroughly mixed with this and that only then the water to make the liquid Concrete is added in an amount that - with respect to the Total amount of water - around that of the metered amount of added ice particles corresponding amount of water is reduced.