Data centers use immersion cooling tanks to provide for cooling and temperature control of electronic components. Data and power cables external to the tanks connect with the electronic components in the tanks, and the fluid used for immersion cooling can leak from the tanks through the cables. Since the fluid is an expensive component for the data centers, it is advantageous to minimize or reduce the loss of such fluid. Accordingly, a need exists for data and power cables better suited for immersion cooling.
A sealed cable assembly includes a jacket enclosing a plurality of insulated wires and including an air gap between the jacket and the insulated wires. Each insulated wire includes a bare wire covered by surrounding insulation. A sealant surrounds the insulated wires in the air gap between the jacket and the insulated wires in a location along the jacket, and the sealant fills the air gap at the location.
Another sealed cable assembly includes a jacket enclosing a plurality of insulated wires and including an air gap between the jacket and the insulated wires. Each insulated wire includes a bare wire covered by surrounding insulation. A sealant surrounds the insulated wires in the air gap between the jacket and the insulated wires in a location at an in-between section of the jacket, and the sealant fills the air gap at the in-between section.
The accompanying drawings are incorporated in and constitute a part of this specification and, together with the description, explain the advantages and principles of the invention. In the drawings,
Embodiments include materials and design approaches which can prevent or reduce cooling fluids from leaving immersion cooling tanks via cables which are inside the tanks and exit the tanks to an external environment. Examples of cooling fluid include the NOVEC product and the FLUORINERT product, both from 3M Company.
These Steps 1-4 illustrated in
These Steps 1-4 illustrated in
These Steps 1-3 illustrated in
Although the Steps illustrated in
The following are exemplary materials to seal cables using the Steps and assemblies described above.
Sealants include the following: 3M SCOTCH-WELD Structural DP100 Plus Epoxy Adhesive product (3M Company); SCOTCH Advanced Formula Super Glue product (3M Company); 3M Super Strength Adhesive product (3M Company); SCOTCH Maximum Strength Adhesive product (3M Company); and 3M SCOTCH-WELD EC 2216 Epoxy Adhesive product (3M Company). Other sealants that are flexible as cured, heat-resistant, and fluid-proof can also be used for the cable sealing. Other sealant chemistries that are also useful in this application include polyester, polyurethane, PVC, polyacrylates, polyamide, polyimide, or combination thereof. The curing process for the sealant could be selected from thermal curing, UV curing, electron beam curing, gamma radiation curing, moisture curing, or chemical curing.
Tapes or films include 3M Weatherproofing Film Wrap product (3M Company). Other tapes or films that are flexible, heat-resistant, and fluid-proof can also be used for the cable sealing. Such films or tapes can be selected from polyester film/tapes, polyurethane film/tapes, PVC film/tapes, acrylic film/tapes, or combination thereof.
Cables were sealed and tested by immersion in perfluorochemical fluid. Weight loss and extraction tests were performed. These Examples are merely for illustrative purposes only and are not meant to be limiting on the scope of the appended claims. All parts, percentages, ratios, etc. in the examples and the rest of the specification are by weight, unless noted otherwise. The following abbreviations are used herein: cm=centimeters; g=gram; ° C.=degrees centigrade; min=minute.
To determine the compatibility of the adhesives/sealants with perfluorochemical fluid, soxhlet extraction tests were run. The method as described in the publication “Design Considerations Relating to Non-Thermal Aspects of Passive 2-Phase Immersion Cooling”, 27th IEEE SEMI-THERM Symposium, section 3.2 was used. The soxhlet extraction test was run with the perfluorinated fluid F2. The amount of adhesive/sealant extracted by the fluid=me % (percent extracted mass). The amount of fluid absorbed by the adhesive/sealant=ma % (percent mass adsorbed fluid). Results are shown in Table 1.
The power cable consisted of an outer jacket which surrounded 3 individual wires. The wires each had an insulation layer around them. The gap area was defined as the region between the outer cable surface and the insulation of the individual wires. The gap seal was defined as the sealant applied to the gap. The wire area was defined as the region between the individual wire insulation and the bare wire. The wire seal was defined as the sealant applied to the region between the bare wire and wire insulation.
A 15 cm long portion of the power cable was cut for each Example (both ends of the cable were cut with a wire cutter). At one end of the power cable, the outer jacket was removed with the wire cutter. This exposed about 2 cm of insulated individual wires. Then the same tool was used to remove the insulation on the 3 individual wires. This exposed about 1.5 cm of bare wire.
In each Example, an adhesive/sealant was applied to either 1) the gap area to fill the region between the cable and wire insulation, or 2) both the gap area and the wire area. See Table 2 for the configurations tested. The sealed cables for each Example configuration were left to fully cure at room temperature for at least 180 minutes to achieve sufficient solidification.
To create an enclosed space for the weight loss testing, a bottle with cap was used. A drill press was used to create a hole (the same diameter as the power cable) in the center of the cap of the bottle. Two samples were made and tested for each Example configuration. The average of the two results are reported in the Table 2.
The bottle was first weighed by an analytical balance (wt1). Then about 90 g of F1 fluid was poured in the bottle and was weighed (wt2). After that, the sealed power cable for each Example configuration was put through the bottle opening, followed by applying the same adhesive/sealant to the inside of the cap thread and around the hole of the cap. Then quickly the cap was screwed on top of the bottle with F1 fluid inside to create an air tight seal. The exact depth of the power cable was adjusted to ensure that the end of the cable was 1 centimeter from the bottom of the bottle and fully submerged inside the liquid.
Examples configurations that were used in the Weight Loss Tests:
Then, the bottle was left for 24 hours at room temperature to fully cure.
After the sealant was fully cured, the whole assembly was weighed on an analytical balance (wt3). Then the whole assembly was put in an oven set at 50 C and removed at pre-determined time (T) to be weighed, (wt[T]). The following equations were used to determine weight loss:
wt4=wt2−wt1 Initial Weight of Fluorochemical:
Wt Loss % (T)=(wt[T]−wt3)/wt4×100% Weight Loss % at Time (T):
A Comparative Example was made and tested using the same protocols described above except that the jacket and wire were not removed, and no sealant was applied. The cap thread and the space between the cable and the cap around the drilled hole were sealed with sealant Si.
Filing Document | Filing Date | Country | Kind |
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PCT/IB2020/050712 | 1/29/2020 | WO |
Number | Date | Country | |
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62801285 | Feb 2019 | US |