JPS62187295A - Collapsible type cask for radioactive waste - Google Patents

Abstract

(57) [Summary] This bulletin contains application data before electronic filing, so abstract data is not recorded.

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Industrial Application] The present invention relates to an impact-absorbing transport cask for radioactive waste.

[Prior Art] U.S. Patent Application No. 831, filed February 21, 1986.
No. 970 discloses an impact resistant structure that is particularly useful for Type B radioactive waste casks. As described in the specification of this U.S. patent application, in the case of type B casks, the standards required to withstand impact forces and other conditions, such as internal and external heat. is relatively strict. This type B cask is generally cylindrical and made of steel. The gist of the invention related to the above US patent application is that a shallow cap-shaped town is formed at each end of the cask! Absorbent skirts are attached, and each skirt is constructed from a unitary member made of a soft light metal material such as aluminum.

The invention of this U.S. patent application is based on "dynamic flow pressure," which is defined as the energy required to displace a unit volume of a substance.
It is based on the fact that it exhibits quasi-material properties, which are sometimes called . The dynamic flow pressure for most light or soft metals is relatively constant over a wide range of metal displacements, and is less than the metal's yield compressive strength, which relates absorbed energy almost directly to metal displacement. Shows a slightly high value.

The specification of the above-mentioned U.S. patent application states that soft metallic materials and skirt geometries should be considered when seeking a situation where the deceleration is relatively constant, where the deceleration force is a function of crushing distance rather than proportional to displacement. It is also pointed out that this is a factor.

U.S. Patent Application No. 627.8 filed July 5, 1984
No. 96 discloses a hexagonal concrete cask or module used for on-site storage and off-site disposal of radioactive waste transported in a Type A transport package.

The impact resistance standard required for Type A casks is a free fall distance of 0.3 m (30 ft) rather than 9 m (30 ft).
The cask for type B is not very strict.

[Problems to be Solved by the Invention] The object of the invention is to provide a structure for imparting impact resistance to the type A cask disclosed in the specification of the last-mentioned US patent application, which is relatively lightweight. To provide a cask using impact-resistant blocks that are inexpensive, reusable, and all of the same design and molded in a single molding pattern.

[Means for Solving the Problems] Accordingly, the present invention provides a cask for transporting radioactive waste in the form of an upright regular polygon, in which An independent shock absorbing member is attached to each corner formed in the cask. and a cask having a certain thickness, the volume of the metal being larger than the volume of the metal being crushed during a particular drop test.

[Embodiments] Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

Referring to the drawings, a concrete radioactive waste cask 10 is of the type disclosed in U.S. Pat. (see application specification), side portion 12 and opposite ends 14 and 16.
and has. The cask constructed as an example of this application is in the shape of a hexagonal prism, with corners 18 chamfered. That is, at each corner between two adjacent side parts, the corner is chamfered.

Each corner formed between two adjacent side portions 12 and end surfaces 14 and 16 is provided with an independent impact block, designated at 20. Therefore, in the case of the hexagonal cask shown in FIGS. 1 and 2, each end face has 6
A total of 12 blocks are required.

The six blocks 20 attached to each end face of the cask are:
They are interconnected by L-shaped steels 22, and at the location of each block, L-shaped steels are placed between the blocks and the cask to help split the shock load (see Figure 4).

These blocks and L-beams effectively form a ring at each end of the cask. The rings on each end of the cask are secured to each other by rods 74 provided with turnbuckles 26, which are adjustable to connect each block on one end of the cask to the axially aligned blocks on the other end of the cask. It becomes a means of pulling. With this configuration, the ring can be removed and reused when storing the cask.

A detail of one of the independent blocks 20 is shown in FIG. 3, and the block 2o consists of a central section 28 attached to the chamfered corners and opposing wings 3o and 33 attached to the side sections 12. .

FIG. 5 is a diagram to help understand the orientation of the cask 10 and block 20 in various drop tests. Numbered arrows indicate the direction of fall as the cask is dropped in various orientations. Arrow 34 indicates a drop with the flat end face down. Arrow 36 is a side drop with the flat side facing down. Arrow 38 is a corner drop with the side corner facing down. Arrow 40 is a corner drop with the corner facing down.

Arrow 42 is a side drop to the corner.

Although various numerical values related to impact resistance can be determined mathematically by the same method as described in the specification of the cited prior patent application, the specification of the prior patent application is incorporated herein by reference. Reference is made to the specification of the earlier patent application for information on how to determine the mathematical values, which are incorporated herein by reference. A common method is to first determine the potential energy absorbed during impact based on the total weight of the package, the falling distance, the crushed volume, the displacement distance of the crushed volume, the crushed area, etc. From the results, the deceleration force and deceleration can be determined, and then the percentage displacement relative to the thickness of the material absorbing the impact can be determined.

As an example of the numbers on which to base the design when designing a particular set of blocks, the total weight of the package is 50,000 Bond (2,27E 44 kg) and 1 ft.
Assume that you are free falling from a height of 3 m). The potential energy is 58,333 ft bonds (79,100 joules) and the crush distance tolerance is 2 inches (0.05 m). The block is made of cast aluminum and has a rating of approximately 15,000 psi (103E + 6Pa
) dynamic flow pre
ssure). This results in a crushed volume of 46.7 square inches (3.0 IE-2 m2) in all cases, regardless of the orientation of the package during the drop.

The dimensions of the block in this example are as follows. All parts of blocks 28, 30, 32 are designated 44 in FIG.
The depth from the outside of the cask to the outside of the block is 3 inches (0.07 m). The overlap of block portion 46 overlapping end 14 is 0.75 inch (
The depth from the end of the cask to the outer edge is 3 inches (0.07 m).

The lateral dimension along the largest side of each wing 30 and 32 is 4 inches (0.1 m), and the lateral dimension along the largest side of the central section 28 is 7.86 inches (0.2 m). .

The table below shows the numerical values determined for a fall in a specific direction using the above specific block, with the above weight and falling distance.

According to the configuration of the present invention, the deceleration is 8.4 to 17 in g.
．． It will be in the range of 2. These results were obtained using an impact-resistant block 20 whose protrusion length from the end and side surfaces was 3 inches (0.07 m) or less. According to the configuration of the invention, by protecting only 12 corners, the entire module is protected from impact as described above. Finally, the weight of the two sets of ring-shaped structures consisting of the blocks described above and the connecting rods and turber buckles is only about 500 bonds (226 kg).

[Brief explanation of drawings]

FIG. 1 is a schematic side view of a shock-absorbing hexagonal concrete cask. 2 is an end view of the cask of FIG. 1; FIG. FIG. 3 is a partially enlarged detail view of a portion of the cask end, with one impact protection block provided at the corner of the cask. FIG. 4 is a sectional view taken along line IV-IV in FIG. 3. FIG. 5 is a perspective view of one independent block along with a small portion of the cask to which the block is attached, illustrating arrows indicating the direction of fall when the cask is dropped in different directions. 10... Cask 12... Side face of cask 14. 16... End face of cask 18... Chamfered corner 20... Shock-resistant block 22... L-shaped steel 24. ...Rod 26...Turnbuckle

Claims (1)

[Scope of Claims] 1. A shock-absorbing transport cask for storing radioactive waste in the form of an upright regular polygon, wherein each corner formed between an end face of the cask and an adjacent side face has an independent cask. Each shock absorbing member consists of a monolithic, uniform, soft, light metal block that wraps around the end face of the cask and the two adjacent side faces for a certain distance, and cask having a thickness of , and having a volume of metal greater than the volume of the metal to be crushed during a particular drop test. 2. The cask is hexagonal, and the corners between adjacent side parts are chamfered, and the shock absorbing member has a corner formed by the end face of the cask, two adjacent side parts, and a chamfered part in between. The cask according to claim 1, wherein the cask is attached to a cask. 3. At least some of the shock absorbing members located on one end of the cask are connected to axially aligned shock absorbing members located on the other end of the cask by adjustable tension members. A cask according to claim 1 or 2. 4. Each shock absorbing member on one end face of the cask is connected to two adjacent shock absorbing members on the same end face of the cask via a connecting means, and a ring-shaped structure is formed by the shock absorbing member and the connecting means. A cask according to claim 1, 2 or 3, characterized in that it is formed. 5. The connecting means is comprised of an angle iron member extending along the corner of each end face of the cask and disposed between the block and the cask. Cask. 6. Claim 1, characterized in that the length of the side face wrapped by each shock absorbing member is greater than the length of the end face wrapped by each shock absorbing member.
The cask according to any one of Items 1 to 5. 7. The cask according to any one of claims 1 to 6, wherein the cask is made of concrete and has a hexagonal prism shape. 8. The cask according to any one of claims 1 to 7, wherein the soft light metal is aluminum.