Glass Liquid Nitrogen Vessels

Coffee servers have the same basic functionality as Dewar flasks. They isolate the inserted liquid from the ambient temperature as long and as well as possible to maintain a stable temperature. Coffee carafes are produced, as the name suggests, for coffee, tea, or other hot or cold beverages. The materials used in the production of a coffeepot must be suitable for their use, a temperature range from −20°C to +100°C. A Dewar flask for laboratory use must resist the temperatures of extremely hot fluids up to +200°C as well as extremely cold fluids such as liquid nitrogen, as cold as −196°C. Dewar flasks dedicated for cryogenic applications are manufactured according to the accepted standards, for example, German DIN standard 12492, US ASTM E1379-90, or in the near future DIN EN ISO 16496. Such documents are setting high standards in the quality of materials and their processing. Unlike a coffee carafe, the specified minimum wall thickness for a Dewar flask must be precisely adhered to because of the high thermal loads. In addition, all Dewar vessels should be pressure-calculated and made from high-quality materials like borosilicate 3.3 glass according to DIN/ISO 3585, which is a typical material used for Dewar manufacturing (Figure 1).

Figure 1 Cryogenic LN₂ Dewar. A Dewar dedicated for cryogenic applications and manufactured from high-quality materials according to the relevant standards is recommended for use with transmission electron microscopes. Note the polystyrene cap that was placed on the top of the Dewar flask.

In the case that a coffee carafe is made of glass, they usually use the so-called soft glass, that is, glass with a high thermal expansion coefficient. Similar to metals, different glass types should be used depending on the expected application field.

Stainless Steel Liquid Nitrogen Vessels

Besides vacuum-insulated glass Dewar flasks, there are also vacuum-insulated cryogenic vessels made of stainless steel or aluminium, common in the cryogenics industry. In Europe, these flasks or containers have to be manufactured according to the “Directive on Pressure equipment 97/23/EG” or be manufactured according to the AD data sheets (AD data sheets are Codes of Practice on Pressure Vessels). For the manufacture of these flasks or containers, only appropriate standard materials, designated for use in this extreme temperature range, can be used. Therefore, proper attention should be paid when choosing the equipment for any cryogenic application.

On the other hand, a coffee carafe can also be produced of stainless steel. When buying a stainless steel coffee carafe, the quality of the stainless steel is not apparent to the customer. Therefore, the user has no knowledge about whether or how long the material of the carafe made of stainless steel will withstand the thermal stresses that occur during filling with liquid nitrogen. Inappropriate types of steel can become brittle at low temperatures, which can lead to the destruction of the vessel.

Surface Damage and Its Consequences

Damage, such as surface scratches on a Dewar flask or a coffee carafe with vacuum insulation, can lead to the implosion of the flask when exposed to the extreme thermal stress experienced when filling the vessel with LN₂. If an implosion occurs, the liquefied gas and the broken pieces remain within the protective casing evaporating the liquid gas. It is quite important when tightening the lid of the LN₂ container that it not be fixed or have ice on top, otherwise any overpressure might not be released fast enough. This could lead to an explosion of the flask or coffeepot, which could cause serious injuries or damage. In the article [Reference Barlow1] you can find that there is a fixed connection between the carafe and the lid through icing. If implosion, takes place, pressure will not be released efficiently, which could lead to an explosion.

If icing cannot be prevented through the testing procedure, we recommend installation of a small fan, like the type used in computer housings. The fan would blow away the humidity and prevent the lid from icing (Figure 2a).

Figure 2 (a) Schematic of a Dewar with a cold trap and fan to prevent icing of the lid. (b) A gas outlet tube (projecting toward the back of the photo).

A glass Dewar flask manufactured according to DIN 12492 or ASTM E1379-90 has an expected lifetime of at least ten years when handled properly. This statement can be made because of the high standards used for the material and its manufacture when it is to be used in vacuum and cryogenic applications.

Dewar flasks made of stainless steel have a higher mechanical strength compared to the glass Dewar flasks. The disadvantage compared to a glass Dewar is the higher thermal conductivity of the stainless steel flasks. However, both materials meet necessary standards for safe use when handled properly.

Surface damage may occur in a metal Dewar or coffee carafe. This can be caused by mechanical stress or corrosion, allowing a crack or a leak to develop in the vacuum space. The liquid nitrogen would be then sucked into the vacuum and come into contact with the warm outer wall of the flask. This would lead to a rapid evaporation during the phase change from liquid to gas, and the volume would increase by about 700 times. This leads to a rapidly increasing pressure inside the vacuum space. The increased pressure cannot be compensated by exhausting gas through the leak, and the valve may become damaged by the extreme overpressure. In order to reduce this overpressure, only Dewar flasks made of stainless steel in accordance to the “Directive on Pressure Equipment - 97/23/EC” have a combined vacuum/overpressure valve placed at the vacuum chamber (Figure 2b). A coffee carafe, for example, does not have this combined vacuum and pressure relief valve. Penetration of LN₂ into the vacuum chamber of a carafe may lead to an explosion in extreme cases.

Such destructive explosions cannot occur when using a glass Dewar correctly. Only implosions happen; the glass splinters collapse and are not ejected with high speed. Because there is a protective casing out of metal or aluminium, the shards of glass as well as the liquid nitrogen will come to rest inside the casing.

Only a tightly closed Dewar flask can lead to an explosion. Therefore, it is standard for Dewar flasks to be operated only with loose plugs when they are filled with cryogenic liquids, such as LN₂ or cold CO₂. When the pressure rises from gassing liquids in a tightly closed Dewar, they cannot exhaust. The increase in pressure would inevitably lead to an explosion. If a lid is required for a specific application of a Dewar vessel, the lid must be provided with an exhaust hole or some other suitable opening so the resulting gas can escape.

Reducing Risks

Safety is of prime concern for all laboratory workers. To avoid workplace risks, users of LN₂ containers should strictly adhere to the following: (a) respect all country-specific requirements for handling liquefied gases, (b) use only devices and components designed for cryogenic applications, (c) follow the operating instructions of the respective manufacturer, (d) use appropriate personal protective equipment, (e) obtain regular training and instructions in the handling of the equipment and the gases, and (f) inspect the surface of the Dewar every time before using. There should be no scratches, no burst of glass, and no residues of any material on the glass. If a visual check finds one of the above-mentioned defects, the Dewar flask should be removed from service directly. The flask could implode when the user fills it with LN₂ because of the high thermal stress experienced when the glass or metal surface cools down within seconds.

In the article by Dr. Barlow [Reference Barlow1] the following incident involving a glass Dewar with a completely iced and fixed lid was described: “When a user gave the Dewar a slight twist to break the icicle, the twist instead broke the LN-filled glass liner. When the LN hit the metal walls of the Dewar, it vaporized. The rapid expansion of LN within the narrow bore of the Dewar, coupled with the fragmentation of the glass into minute pieces, led to an upward explosion of glass fragments that the user described as a “stream of confetti shooting to the ceiling. For weeks afterward, we found glass “confetti” in and around crevices in the TEM room. Discussions with our service engineers revealed that similar breaks in glass-lined Dewars have occurred in labs around the world.”

For us, authors of the present article, it is hard to say what led to this explosion. We can only guess what could lead to such an incident. One obvious aspect is that the icicle closed the Dewar so completely that there was overpressure inside the Dewar. By twisting the icicle to break it away from the Dewar, the user may have brought too much tension to the glass so that it broke seconds before he could divide the Dewar from the iced lid. So the LN₂ headed up inside the casing of the broken Dewar, pressure rose up rapidly, and then the glass parts and the gas flew out the Dewar’s casing.