Method for producing glass beads used for curing high-level nuclear wastes

A production method and highly radioactive technology, applied in glass forming, glass manufacturing equipment, manufacturing tools, etc., can solve the problems of increased or decreased leaching rate, increased specific surface area of ​​solidified body, etc., and achieve good anti-devitrification ability, anti- The effect of high compressive strength

Inactive Publication Date: 2010-10-13
天台精工西力玻璃珠有限公司
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  • Summary
  • Abstract
  • Description
  • Claims
  • Application Information

AI Technical Summary

Problems solved by technology

But at the same time, there are also some disadvantages. Glass is a thermodynamically metastable substance, which has a larger internal energy than crystalline substances, and has a tendency to transform into a crystalline state by reducing the internal energy.
At the same time, the crystalline substances precipitated in the glass are more soluble in water, causing the nuclear substances in the vitrified body to be easily leached.
The mechanical strength of the glass is not ideal. Once the glass solidified body is broken, the specific surface area of ​​the solidified body will increase, resulting in an increase in the leaching rate

Method used

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  • Method for producing glass beads used for curing high-level nuclear wastes

Examples

Experimental program
Comparison scheme
Effect test

Embodiment 1

[0029] 1. Weigh the raw materials according to the data in Table 1, mix the raw materials evenly and melt them in an all-electric glass melting furnace at a temperature of 1330°C to make a glass solution, clarify and homogenize for 7 hours, and then cool to room temperature to form a glass block. The final composition of this glass frit is shown in Table 2:

[0030] Table 1

[0031]

raw material

quartz

sand

oxidation

aluminum

oxidation

magnesium

boron

sand

boron

acid

carbonic acid

calcium

carbonic acid

Potassium

carbonic acid

lithium

Titanium dioxide

pink

oxidation

zirconium

number of copies

61

6

1

13

21.3

6

4.4

[0032] Table 2

[0033] Component

SiO 2

Al 2 o 3

MgO

Na 2 o

B 2 o 3

CaO

K 2 o

Li 2 o

TiO 2

ZrO 2

...

Embodiment 2

[0039] 1. Weigh the raw materials according to the data in Table 3, mix them evenly, and melt them in an all-electric glass melting furnace at 1300°C to make a glass solution, clarify and homogenize for 7 hours, and then cool to room temperature to form a glass block. The final composition of this glass frit is shown in Table 4:

[0040] table 3

[0041]

raw material

quartz

stone

oxidation

aluminum

oxidation

magnesium

boron

sand

boron

acid

carbonic acid

calcium

carbonic acid

Potassium

carbonic acid

lithium

Titanium dioxide

pink

oxidation

zirconium

number of copies

62

5

1.2

16.2

13.8

6.3

3.7

4.4

[0042] Table 4

[0043] Component

SiO 2

al 2 o 3

MgO

Na 2 o

B 2 o 3

CaO

K 2 o

Li 2 o

TiO 2

ZrO 2

percentage

...

Embodiment 3

[0049] 1. Weigh the raw materials according to the data in Table 5, mix them evenly and melt them in an all-electric glass melting furnace at 1320°C to make a glass solution, clarify and homogenize for 8 hours, and then cool to room temperature to become a glass frit. The final composition of this glass frit is shown in Table 6:

[0050] table 5

[0051]

raw material

quartz

stone

oxidation

aluminum

oxidation

magnesium

boron

sand

boron

acid

carbonic acid

calcium

carbonic acid

Potassium

carbonic acid

lithium

Titanium dioxide

pink

oxidation

zirconium

number of copies

57.5

4.5

1.4

19.5

11.6

5.4

4.4

3.9

2.5

[0052] Table 6

[0053] Component

SiO 2

al 2 o 3

MgO

Na 2 o

B 2 o 3

CaO

K 2 o

Li 2 o

TiO 2

ZrO 2

perce...

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Abstract

The invention provides a method for producing glass beads used for curing high-level nuclear wastes. The method comprises the following steps of: uniformly mixing raw materials, melting the raw materials into glass solution by using an all-electric glass melting furnace at the temperature of between 1,300 and 14,000 DEG C, clarifying and homogenizing the glass solution for 5 to 8 hours, cooling the glass solution to obtain glass block green bodies, and preparing glass blocks by specifications of finished products from the obtained glass block green bodies; uniformly mixing each 100 parts of the obtained glass blocks with 10 to 25 parts of charcoal powder and 1 to 3 parts of carbon black, and throwing a mixture into a glass bead electrothermal rotary furnace, of which the running speed is 20 to 30 revolution per minute, at a speed of 0.7 to 1.0 kilogram per minute at the temperature of between 850 and 940 DEG C through the glass bead electrothermal revolving furnace, and rolling the mixture to form a ball-shaped mixture; and finally annealing and cooling the ball-shaped mixture to obtain the glass beads used for curing the nuclear wastes. The glass beads used for curing the high-level nuclear wastes produced by the method has ideal high-temperature viscosity, high mechanical strength and high anti-crystallization performance.

Description

technical field [0001] The invention belongs to the field of radioactive nuclear waste treatment, in particular to a production method of glass beads used for solidifying highly radioactive liquid nuclear waste. Background technique [0002] The development of nuclear energy has brought huge social and economic benefits to human beings, but also produced a large amount of radioactive nuclear waste, which will cause great harm to human beings and other living things. For the disposal of radioactive nuclear waste, the most effective way at present is to solidify it, and then make the final geological disposal of the obtained radioactive solidified body. [0003] At present, glass is widely used in the world to solidify high-level radioactive nuclear waste. Glass can solidify all components of high-level radioactive waste, with low leaching rate and relatively good chemical stability. But at the same time, there are also some disadvantages. Glass is a thermodynamically metasta...

Claims

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Application Information

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Patent Type & Authority Applications(China)
IPC IPC(8): C03B19/10C03C12/00
Inventor 胡法卿
Owner 天台精工西力玻璃珠有限公司
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