DE4041170C1 - Double-walled insulated container - incorporates metal woven band with shield made of aluminium - Google Patents

Abstract

The double-walled insulated container has a cooling line fixed to a cooled radiation shield within the insulated space. Between the shield (16) and line (14) there should be a metal weave band (25) acting as contact material. The band is pref. an E-Cu woven band, the shield made from aluminium and the line made of copper. Line and contact material (24) are clamped by collars (26) to the radiation shield. The collars are riveted to the shield. USE/ADVANTAGE -Low-boiling liquefied gas storage. Metal woven band allows for temp. movement and requiring no adhesive time reduces assembly and on-streaming period.

Description

The present invention relates to a double-walled insulated container for low-boiling liquefied gases with at least one cooled radiation shield in the Isolation room on which a cooling pipe is attached.

This generic term refers to a state of the art referenced, as for example from the following ver has become known:

• - DE-OS 25 48 289
• - Technical book low temperature technology "Author Hansen / Linde ", 2nd edition 1985, page 489
• - gas aktuell (company magazine of the applicant) No. 36 1989, pages 17-21 "liquid hydrogen  as fuel in test vehicles "and
• - Pages 22-29 "Liquid Hydrogen - a new one Product line "
• - gas aktuell (company magazine of the applicant) No. 39 1990, pages 9-11, "Cryogenic space Equipment for CRISTA ".

From these publications are double-walled containers ter known in the isolation room (vacuum room with multi-layer super insulation), especially for Improved insulation and thus the evaporation rate cooled radiation shields are provided. In which be specified in the container mentioned above is the radiation shield made of copper sheet which the cooling line (copper pipe turns) is soldering.

In the containers currently described in gas 36, the radiation shield is made of aluminum sheet, to which the cooling line is glued with an adhesive (Al-offset synthetic resin, 80 % by volume Al, 20 % by volume epoxy resin), as there is no connection technology (soldering, welding) ) for Cu and Al.

When using this known connection there may be fluctuations in the process Isolation and thus the evaporation rate of itself the same trained containers come out, creating a quality scatter can occur, which is particularly the case with a Series production e.g. B. of vehicle tanks for liquid Hydrogen, is unfavorable.

Starting from this prior art is a container  to create a connection between radiation shield and cooling line, which both a poss The smallest possible spread of quality, especially with regard to on the tank insulation and evaporation rate at loading Series production of containers, guaranteed as well Exhaust gas cooling improved.

This object is achieved by the specified in claim 1 Features solved.

It is advantageous due to the metal fabric tape enough,

• - an economical connection technology between same materials (shield and cooling line made of copper) and also different materials (aluminum minium shield, copper cooling line), since only a small one Preparation effort is required and also z. B. the hardening of the adhesive that is necessary when gluing omitted, which shortens the manufacturing time.
• - an elastic connection (not available during soldering) dung, so that the thermal expansion and shrinkage behavior of the materials as well as a dynamic loading contact point to no quality deterioration leads.
• - an elasticity of the connection, which is also the case with kryo temperatures is maintained, which is the case with the Adhesive connections are not guaranteed.
• - compensation of surface irregularities between Radiation shield and cooling line  
• - an increase in the contact area (surface contact), which significantly improves heat transfer becomes
• - An average of 2000 times better warmth conductivity of Cu in contrast to synthetic resin, the the rapid removal of the sun's heat ensures an improvement in the evaporation rate is reached
• - A connection without heat development and therefore none Damage to the high temperature unstable super isolation.

The metal fabric tape is advantageously a copper front preferably E-Cu fabric tape, which is particularly economical is also the contact area between radiation shield and cooling line enlarged and beyond the requirements of thermodynamics (good thermal conductivity ability (λ) in the range 20 K ... 273 K), the mechanics (Elasticity with dynamic behavior of the base mat rialien Al-Schild and Cu-Rohr) and the Economical corresponds to.

The copper mesh tape is particularly advantageous for different materials can be used, especially in the Case when the radiation shield made of aluminum and the Cooling line made of copper. It is done before pulls the connection radiation shield, fabric tape, cooling cable via clamps with a connection tech nik without heat development, e.g. B. screws, rivets, are connected to the radiation shield.  

With the clamps and the associated connection preferably exerted pressure on the contact material and so advantageously a compensation of surfaces bumps by pressing the fabric tape together reached.

In addition, the "warm connection" no damage to the not high temperature resistant Super insulation around the contact point follows what regarding the quality of the insulation is also cheap.

According to the invention, the clamps are preferred with the Radiation shield riveted as this riveted connection particularly quick and easy and therefore economical can be manufactured.

An embodiment of the invention is in the Drawing shown and is closer below described. Here illustrated

Fig. 1 is a schematic representation of a motor vehicle tanks for liquid hydrogen with control and regulation devices,

Fig. 2a + b, Fig. 3 shows the connection radiation shield cooling tube according to the invention.

In Fig. 1, a motor vehicle tank for liquid hydrogen is designated 10 , and is designed as a double-walled, insulated container.

The tank 10 consists of an inner container 11 with a capacity of z. B. 93 liters at 0.5 MPa maximum operating pressure, which is surrounded by the outer container jacket 12 at a distance of 40 mm. In order to reduce the heat transport between the warm outer shell and the -253 ° C cold surface of the inner container due to convection, conduction and radiation to less than 10 ^-4 (Wm ^-1 K ^-1 ), the space 13 is evacuated. In the vacuum space 13 there is a multi-layer super insulation ( 10 µm aluminum foils; 70 µm glass fiber paper). The gas evaporating in the inner container 11 is first fed to the cooling lines 14 , 15 , as a result of which two radiation shields 16 , 17 which are arranged around the inner container 11 are cooled. The radiation shields 16 , 17 are made of aluminum and the cooling lines 14 , 15 are made of copper, the cooling lines 14 , 15 being guided as cooling coils around the radiation shields 16 , 17 .

The correct operation of the tank 10 in the vehicle, he calls for additional control and regulating devices. A total of three lines lead into the tank itself. Two ( 18 , 19 ) are required for filling or removing and supplying the motor. The third line (not shown) serves as a bushing for the electrical connections of a capacitive level probe 20 arranged in the inner container 11 and an additional electrical heater 21 . This additional heater 21 ensures under certain removal conditions that the container pressure does not drop too far.

In order to keep the total heat input into the container as low as possible, all of the valves required for the refueling and engine supply are accommodated outside the tank in a separate control unit 22 . This vacuum-insulated valve combination itself contains the connections for refueling and is connected to the vehicle tank 10 or the fuel line 23 leading to the engine via detachable, vacuum-insulated lines. The combination and switching of the valves (4 solenoid and 3 check valves) are combined in a very compact, weight and space-saving arrangement. The valves are controlled in all operating states via a freely programmable electronic control. So z. B. - depending on the current tank pressure - the engine can be supplied with either liquid or cold gas. In this way, the storage economy can be improved; If you have lowered the tank pressure by removing it from the gas phase before the vehicle is parked, the remaining tank content can then be stored for a long time without loss of evaporation.

The connection between the aluminum radiation shield 16 (or 17 ) and the cooling line 14 (or 15 ) is shown in Fig. 2a and b. Here, between the shield 16 , which is made of an aluminum sheet with a thickness of 2 mm and the copper cooling line 14 (dimension 16 × 1 mm), a copper fabric tape 24 is arranged as a contact material.

An E-Cu fabric tape is preferably highly flexible in Based on DIN 46 444 (flat-rolled hoses) Material: E-Cu-blank used, which in the execution example shows the following characteristics:  

Cross section: 6 mm ² , conductor structure: 24 × 66 × 0.07 mm, width: 10 mm, thickness 1.3 mm, weight: 6 kg /% m.

The cooling line 14 and the contact material (copper fabric tape) 24 are pressed against the radiation shield 16 via clamps 25 made of copper, the copper fabric tape being pressed together. The clamps 25 are preferably provided at the same distance of approximately 50 mm and fastened to the shield with rivets 26 . Of course, it is also possible to fasten the clamps 25 using screw connections.

Studies have shown that taking into account the thermodynamic, mechanical and economic Aspects of the Cu fabric tape a particularly advantageous Contact material is.

Because of the above-average heat conductivity ability in the low temperature range becomes essential improved heat dissipation to the outside Gas reached. The contact area becomes "Heat sink", the temperature gradient rises and favors the heat flow along the cooling shield Contact point from where the heat is trans to the outside is ported. The effect of exhaust gas cooling is ver strengthens. The good contact remains even at low temperatures received with certainty. Thermal expansion and Shrinkage is compensated. The low material and manufacturing costs also add up to a total cost saving compared to the previous connections what This is particularly important for series production is.  

The connection proposed according to the invention is of course also at other low temperatures directions, devices etc. can be used where equi valent problems as with the described containers occur as z. B. is the case with cryostats.

There is another possible application (see FIG. 3) for contacting the Al radiation shields 30 on the container neck tube 31 . The Al shields 30 are bent in the middle (collar 32 ), the "plate" is slit, placed around the neck tube 31 and fastened with a clamp 34 . By interposing the Cu tape 33 , the heat transfer is significantly improved according to known material properties (heat capacity, elasticity).

Another possible application is replacement the previous contact with containers with soldered pressure additive. The pressure build up necessary copper lines not on the inside as before walls of the outer container made of stainless steel, but z. B. with clamps between the outer container and copper lines arranged Cu fabric tape consolidates.

The following advantages are achieved:

• - Saving of the entire soft solder (up to 3 kg)
• - Elimination of heat treatment
• - Cleaning work before or after soldering is not necessary
• - Better thermal conductivity
• - Less manufacturing effort (time saving)
• - Better occupational safety (no flux fumes).

Claims (5)

1. Double-walled, insulated container for low-boiling liquefied gases, with at least one cooled radiation shield in the isolation room, on which a cooling line is attached, characterized in that between the radiation shield ( 16 or 17 or 30 ) and the cooling line ( 14 or 15 or 31 ) a metal fabric tape ( 24 or 33 ) is arranged as a contact material. 2. Container according to claim 1, characterized in that the metal fabric tape ( 24 or 33 ) is a copper, preferably E-Cu fabric tape. 3. Container according to claim 1 or 2, characterized in that the radiation shield ( 16 or 17 or 30 ) made of aluminum and the cooling line ( 14 or 15 or 31 ) consists of copper. 4. Container according to one of claims 1 to 3, characterized in that the cooling line ( 14 or 15 or 30 ) and the contact material ( 24 or 33 ) by means of clamps ( 26 or 34 ) on the radiation shield ( 16 or 17 or 30 ) are attached. 5. A container according to claim 4, characterized in that the clamps ( 24 ) with the radiation shield ( 16 or 17 ) are riveted.