Patent Number: 
Section: claims

1. A method of adjusting a moisture content of a pulverulent bentonite having an initial grain size distribution as a raw material for artificial barriers, comprising the steps of stirring and mixing fine granular ice and a low-temperature preserved amount of the pulverulent bentonite that is sufficiently cold to not melt the fine granular ice during the step of stirring and mixing, restoring the pulverulent bentonite homogeneously mixed with the fine granular ice to its normal temperature state to melt the fine granular ice and obtain bentonite having a uniform moisture content distribution and a restored grain size distribution that is substantially the same as said initial grain size distribution, and maintaining said restored bentonite with said uniform moisture distribution and restored grain size distribution as a raw material free of granular lumps tending to cause seepage and/or cracks in artificial barriers. 2. The method of claim 1, wherein, the stirring and mixing step is done without absorption of water by the bentonite. 3. The method of claim 1, wherein said artificial barrier formed of the restored bentonite has a higher dry density than an identically formed artificial barrier except for the use of liquid to obtain the same moisture content. 4. The method of claim 1, wherein said artificial barrier formed of the restored bentonite has a lower coefficient of initial permeability than an identically formed artificial barrier except for the use of liquid to obtain the same moisture content. 5. The method of claim 1, wherein said restored bentonite may be compacted to a selected dry density with a lower compaction energy than required to compact to said selected dry density an identically formed bentonite raw material except for the use of liquid to obtain the same moisture content. 6. The method of claim 1, further including providing said fine granular ice by aspirating water with a flow of low-temperature high pressure gas and freezing aspirated water in said flow of low-temperature high pressure gas to form said fine granular ice. 7. The method of claim 1, further including providing a mixing tank, cooling said mixing tank to a low temperature to inhibit melting of said fine granular ice, depositing said fine granular ice and low-temperature preserved pulverulent bentonite in said mixing tank and performing said stirring and mixing step within said mixing tank while maintaining said mixing tank at said low temperature. 8. The method of claim 1, further including providing a forcible feed pipe, cooling said forcible feed pipe to a low temperature to inhibit melting of said fine granular ice, putting said fine granular ice and low-temperature preserved pulverulent bentonite in said forcible feed pipe, and performing said stirring and mixing step within said forcible feed pipe while maintaining said forcible feed pipe at said low temperature. 9. The method of claim 1, further including providing said low-temperature preserved pulverulent bentonite and fine granular ice prior to said stirring and mixing step. 10. A method of adjusting a moisture content of a pulverulent bentonite having an initial grain size distribution as a raw material for artificial barriers, comprising the step of stirring and mixing fine granular ice and a low-temperature preserved amount of the pulverulent bentonite that is sufficiently cold to not melt the fine granular ice during the step of stirring and mixing, said stirring and mixing step being performed without the absorption of moisture by the bentonite, and restoring the pulverulent bentonite homogeneously mixed with the fine granular ice to its normal temperature state to melt the fine granular ice and obtain bentonite having a uniform moisture content distribution and a restored grain size distribution that is substantially the same as said initial grain size distribution, and maintaining said restored bentonite with said uniform moisture distribution and restored grain size distribution as a raw material for artificial barriers, whereby an artificial barrier formed of the restored bentonite has a higher dry density than an identically formed artificial barrier except for the use of liquid to obtain the same moisture content. 11. The method of claim 10, wherein said artificial barrier formed of the restored bentonite may be compacted to said higher dry density with a lower compaction energy than required to compact to said higher dry density an identically formed bentonite raw material except for the use of liquid to obtain the same moisture content. 12. The method of claim 11, further including providing said fine granular ice by aspiration of water with a flow of low-temperature high pressure gas and atomizing said aspirated water in said flow of low-temperature high pressure gas to form said fine granular ice. 13. The method of claim 11, further including providing a mixing tank, cooling said mixing tank to a low temperature to inhibit melting of said fine granular ice, depositing said fine granular ice and low-temperature preserved pulverulent bentonite in said mixing tank and performing said stirring and mixing step within said mixing tank while maintaining said mixing tank at said low temperature. 14. The method of claim 11, further including providing a forcible feed pipe, cooling said forcible feed pipe to a low temperature to inhibit melting of said fine granular ice, putting said fine granular ice and low-temperature preserved pulverulent bentonite in said forcible feed pipe, and performing said stirring and mixing step within said forcible feed pipe while maintaining said forcible feed pipe at said low temperature. 15. The method of claim 10, further including providing said low-temperature preserved pulverulent bentonite and fine granular ice prior to said stirring and mixing step. 16. The method of claim 10, wherein said low temperature preserved pulverulent bentonite and fine granular ice in the form of fine grains are blended together in said stirring and mixing step as pulverulent materials. 17. A method of adjusting a moisture content of a pulverulent bentonite as a raw material for artificial barriers, comprising the step of stirring and mixing fine granular ice and a low-temperature preserved amount of the pulverulent bentonite that is sufficiently cold to not melt the fine granular ice during the step of stirring and mixing, restoring the pulverulent bentonite homogeneously mixed with the fine granular ice to its normal temperature state to melt the fine granular ice and obtain bentonite having a uniform moisture content distribution, forming the restored bentonite into an artificial barrier, the artificial barrier having a higher dry density than an identically formed artificial barrier except for the use of liquid to obtain the same moisture content. 18. The method of claim 17, wherein the stirring and mixing step is done without absorption of water by the bentonite. 19. The method of claim 17, wherein said artificial barrier formed of the restored bentonite is compacted to said higher dry density with a lower compaction energy than required to compact to said higher dry density an identically formed artificial barrier of the same bentonite raw material except for the use of liquid to obtain the same moisture content.