WO1998002368A1

WO1998002368A1 - Materials for production of containers

Info

Publication number: WO1998002368A1
Application number: PCT/EP1997/003534
Authority: WO
Inventors: Martin Hostalek; Werner Büttner; Jürgen BRAUN
Original assignee: Merck Patent Gmbh
Priority date: 1996-07-16
Filing date: 1997-07-04
Publication date: 1998-01-22
Also published as: ID17644A; DE19628643A1; JP2000514487A; EP0918708A1; AU3443197A; CA2261114A1; TW342376B; KR20000023789A

Abstract

The invention relates to the use of polyethylene materials for the production of solid storage and transportation containers, and also for the production of lined storage and transportation containers for chemicals, and in particular for transportation and storage of high-purity, liquid chemicals for the electronics industry. The invention also relates to the use of said materials for producing equipment which is required to remove the chemicals from said containers.

Description

Materials for the manufacture of transport containers

The invention relates to the use of polyethylene materials for the production of massive transport and storage containers but also for the production of lined transport and

Storage containers for chemicals, in particular for the transport and storage of high-purity, liquid chemicals for the electronics industry. Furthermore, the invention relates to the use of these materials for the production of the equipment which is necessary for removing the chemicals from the transport containers and for filling them.

In the production of electronic components, liquid chemicals are required in many cases, the purity of which places the highest demands. This is especially for those

Manufacturing highly integrated microchips the case. On the one hand, there is

Purity of these chemicals in an area where it is no longer sufficient to produce the chemicals in the required purity, but care must also be taken to ensure that no contaminants get into the product during transport, storage and handling. On the other hand, the storage and

Transport safety can be guaranteed because some of these chemicals are difficult to handle and store due to their aggressive properties. In many cases, they are also not toxicologically safe or harmful due to their chemical properties. Accidental leakage, e.g. B. due to a

Damage to the transport container or due to

Leaks caused by the aggressive properties of some of these chemicals must be excluded with a high degree of certainty. ^y

The choice of materials for such transport containers must be based primarily on the requirements of the chemicals to be transported to exclude any contamination. This requirement is usually met by containers made from fluorinated or perfluorinated materials or from containers lined with such materials. Depending on requirements, these transport and storage containers are manufactured as unpressurized versions or as pressure containers.

Unpressurized containers must not be exposed to internal pressure from outside.

The liquid chemicals must also be removed from such containers without pressure, i. H. with the help of pumps. These pumps inevitably have moving parts, so that contamination from abrasion occurring in the pump area cannot be completely ruled out.

However, it is known in particular when using pressure-resistant containers to remove chemicals with the aid of immersion tubes by supplying inert compressed gases, so that no pumps are required and therefore no abrasion can occur. DE 36 36 886 discloses a transport container for liquid, high-purity chemicals with a double-shell inner container, the innermost lining of which is made of a fluoroplastic. Due to its multi-layer structure, this transport container is dimensioned so that it can be pressurized. However, it is disadvantageous that on the one hand only special fluoroplastics are suitable for the production of such inner linings, which have to be produced in complex and therefore expensive processes, and on the other hand that these plastics are more difficult to process because the plastic does not have to meet the high purity requirements for the chemicals to be transported any

Processing aids can be added and a

Contamination from tools and environmental influences must be largely minimized.

In the choice of materials for the production more massive

The transport container must have the polymeric material next to the

Resistance to possible leaching and embrittlement due to chemicals to be transported additionally have both sufficient rigidity and a certain elasticity, so that containers made of the material against pressure and impact are insensitive and stable and tend neither to deform nor to crack. Furthermore, these material properties must be maintained in the long term, so that both the purity of the chemicals to be transported and the container properties are retained even after prolonged storage.

The object of the invention is therefore to provide a suitable material for the production of transport containers for liquid, high-purity chemicals and the necessary equipment, which is inexpensive to produce, while the synthesis is obtained in high purity, no or only a very low concentration of polymerization catalysts contains, can be processed in a simple manner if possible without the addition of processing aids, or only contains processing aids which do not have a disruptive effect in use or which are not leached out of the material by the chemicals to be transported. The object of the invention is also to provide a suitable polymeric material from which both massive storage and transport containers for liquid, high-purity chemicals and linings for corresponding containers which can be pressurized can be produced.

The object is achieved according to the invention by the use of HD polyethylene (HD = high density) for the production of massive storage and transport containers for liquid, high-purity chemicals for the electronics industry, the associated equipment, and linings for corresponding containers which are pressurized and the equipment required for this. In particular, the object is achieved by using HD polyethylene with a specific density of 0.940-0.970 g / cm ³ , in particular 0.942-0.961 g / cm ³ .

According to current opinion, only materials based on fluorinated hydrocarbons are suitable as materials for containers in which high-purity acids or bases are to be transported. Such materials are, for example, polytetrafluoroethylene (PTFE), perfluoroalkoxy polymers (PFA), polyvinylidene fluorides (PVDF), or poly (ethylene-chloro-trifluoroethylene) (ECTFE) and are generally used with the well-known trademark "Teflon". For the person skilled in the art, this term covers the influence of aggressive chemicals, such as particularly strong acids or bases but also insensitive to temperature influences. These plastics are expensive and therefore not economical.

Experiments have now surprisingly shown that non-fluorinated plastics for the production of high quality transport containers and the associated equipment, such as. B. dip tubes, parts of pumps and hoses, can be used for liquid, high-purity chemicals for the electronics industry. Selected HD polyethylenes (high density polyethylene) have proven to be particularly suitable materials for the desired use, namely those polyethylenes with a specific density in the range from 0.940 to 0.970 g / cm ³ , in particular from 0.942 to 0.961 g / cm ³ . Furthermore, these polyethylene qualities are characterized in the analysis by a particularly low content

Catalyst residues. For this reason, especially small amounts of ionic impurities are released from these materials compared to others in contact with both basic and acidic, high-purity chemicals. In contact with chemicals, comparatively few particles are generated through interactions between the chemicals and the material. This is particularly important with regard to the use of the material for the manufacture of the equipment for filling and removing the chemicals. Surprisingly, these materials are both for the production of immersion tubes and for the production of

Pumps suitable for the removal of high-purity chemicals from unpressurized transport containers and for delivery to the processing station.

This was particularly surprising, since the corresponding other polyethylene materials, which have been used for the transport of dangerous goods for many years, have not been suitable for the Transport and storage of high-purity, liquid chemicals are suitable. In the test, these plastics were both too high

Particle release as well as an unacceptable release of ionogenic

Impurities determined.

Polyethylene materials, which are marketed by the BASF company under the Lupolen trademark, have proven to be particularly suitable materials for the stated purpose.

In particular, bearing tests from this group of polyethylene specifications have proven suitable as material types, which are known under the names Lupolen 6021 D, Lupolen 5021 D, Lupolen

4261 A Q149, and Lupolen 4261 A Q 135 are commercially available.

These materials are particularly suitable for the use according to the invention because they can be extruded but can also be welded without loss of quality. This results in the possibility of producing containers of almost any size by welding suitable plates from this material. By applying textile fabric to one side of these plates and anchored in the material, it is possible to prefabricate relatively thin-walled inner containers. By applying glass fiber-reinforced polyester resin, it is possible to manufacture stable containers which, if appropriately designed, comply with the Pressure Vessel Ordinance. The construction of these containers consequently has a double-shell construction. In particular, these are interconnected shells, the inner shell consisting of the HD polyethylene selected according to the invention and the outer shell made of a glass fiber reinforced polyester resin. It is also possible to modify the surface of the containers produced by methods known to those skilled in the art, for example by painting, laminating or dispersion coating using suitable barrier polymers or by coating with thin metal foils. Barrier polymers suitable for this purpose are polyamide, polyester, polyvinylidene difluoride or polymers based on acrylonitrile. In this way the permeability to gases, vapors and liquids can be reduced. The values given in the following tables are intended to illustrate the invention in more detail, but are not suitable for restricting the invention to the named and investigated polyethylene materials with the designation Lupolen

Table 1

Release of cationic impurities from polyethylene materials in the presence of high-purity chemicals

identified Lupolen Lupolen Lupolen LLDPE LLDPE VEPE

Values in 5021 D 6031 M 6060 D Neste Neste Scairlink ng / g 1 Elution 1 Elution 1 Elution NCPE NCPE 8000 G

Pellet time 7 days time 7 days time 7 days 8682 8682 5

Chemical chemical chemical 1 elution 2 elution 1 elution

HCL 35% HCL 35% HCL 35% time 7 days time 7 days time 7 days

40 ^β C 40 "C 40" C chemical chemical chemical HF 49% HF 49% HF 49% 40 ° C 40 ° C 40 ° C

Aluminum 16 170 8 218 238 815

Antimony - - - - - -

Arsenic - - - - - -

Barium - - - 3 - 3

Beryllium - - - - - -

Bismuth - - - 72 84 18

Boron - - - - - -

Cad ium - - - - -

Calcium 6.6 60 17 97 110 147

Chrome 4 0.3 45 - - -

Cobalt - - - - - -

Copper - - - - - -

Gallium - - - - - -

Germanium - - - - - -

Gold - - - - -

- Continuation of table 1:

Table 2

Release of cationic impurities from other polyethylene materials in the presence of high-purity chemicals

Hostalen Hostalen Lupolen Lupolen Lupolen Lupolen

Values in GM6255 GM6255 4261 A 5261 Z 5261 Z 6021 D ng / g Q 135 Q135 Q 445

Pellet 1 Elution 1 Elution 1 Elution 1 Elution 1 Elution 1 Elution

Time 6 days time. 26 time 7 days time 7 days time 7 days time 7 days

Chemical days chemical chemical chemical chemical

HF 49% chemical HCL 35% HCL 35% HCL 35% HCL 35%

25 X HF 49% 40 X 40 X 40 X 40 X 25 X

Aluminum 60 0.5 60 1040 1110 17

Antimony - - - - - -

Arsenic - - - - - -

Barium 1.5 - - - - -

Beryllium - - - - - -

Bismuth - - - - 84 -

Boron - - - - - -

Cadmium - - - - -

Calcium 90 0.8 10 33 45 3.6

Chrome 13 1.3 70 110 147 3.6

Cobalt - - - - - -

Copper 4 - 1.5 - - -

Gallium - - - - - -

Germanium - - - - - -

Gold - - - - - - Continuation of table 2:

Claims

PATENT CLAIMS

1. Use of HD polyethylene (HD = high density) for the production of massive storage and transport containers for high-purity, liquid chemicals for the electronics industry.

2. Use of HD polyethylene for the production of linings for storage and transport containers for high-purity, liquid chemicals for the electronics industry.

3. Use of HD polyethylene for the manufacture of the equipment, in particular immersion pipes, and of liquid-conveying pumps for storage and transport containers for high-purity, liquid chemicals for the electronics industry.

4. Use according to claims 1 to 3, characterized in that it is polyethylene with a specific density of 0, 945 - 0.970 g / cm ³ .

5. Use according to claim 2, characterized in that it is in the lining of the storage and transport container is a double-shell inner container, the inner shell is made of an HD polyethylene, which is enveloped by a glass fiber reinforced outer shell.

6. Use according to claims 1-5, characterized in that it is an HD polyethylene from the

Group Lupolen 6021 D, Lupolen 5021 D, Lupolen 4261 A Q149, and Lupolen 4261 A Q 135.

7. Storage and transport containers for high-purity, liquid chemicals for the electronics industry, made of HD polyethylene.

8. Linings for storage and transport containers for high-purity, liquid chemicals for the electronics industry, made of HD polyethylene.

9. Immersion tubes for use in storage and transport containers for high-purity, liquid chemicals for the electronics industry, made of HD polyethylene.

10. Liquid-promoting pumps for high-purity, liquid chemicals for the electronics industry, made of HD polyethylene.