Abstract
Aluminum closed-cell foam blocks (ACCFBs) are small blocks of foam shielded with small aluminum (Al) tubes developed to enhance the energy absorption of Al foam in limited volumes, such as one cubic inch. It is designed to overcome the problems of the high cost of production, maintenance, and heat insulation properties of foam sheets. Al blocks ideas quoted from human and animal bone parts, and it is designed to absorb energy laterally. This work presents the designs of remote operating vehicles (ROVs) and electric vehicles (EVs) battery carriers, constructed from a cube block of ACCFBs and two Al sheets. The carrier design is based on the properties of Al foam blocks. It is designed to withstand temperatures up to 120 °C. The carrier idea relies on replacing large sheets of Al foam with small, distributed blocks. It has good energy absorption, and at the same time, it helps solve the problems of harness design for crossing wires in narrow areas, such as in ROVs. The results show that the ROVs battery carrier made from the Al sandwich panel (AFS) needs 900 s to transfer 120 °C from the upper sheet to the lower sheet, while the carrier made from ACCFBs with the same volume needs 40 s only. It can also bear a load of up to 0.8 kN and has a working strength δ(working): 1.093 MPa. The EVs battery carrier can bear a load of 117 kN (about 25 times the battery weight) at yield strength (0.45 MPa), and it has a δ(working): 0.516 MPa. The calculated total time of cooling for the conduction and forced convection for both the ROVs and EVs carriers at a cooling temperature of 25 °C and at air velocity 1 m/s were 4:31 min and 32:25 min, and at 2 m/s were 3:15 min and 20:41 min, respectively, at a summer working temperature of 40 °C.