• EcoHomes USA are Built “Custom” from Scratch, we do not Utilize Recycled Containers (Who can ever know what Conditions that any used Container was subject to in terms of Misuse and Damage??)

  • Note also Below on Comparison Between OUR NEW Units and Standard Buildings Container Roof is 300 Lbs. Per sq. Foot

  • UBS Standard for Homes is 20 Lbs. Per Sq. Foot

  • The Container Home is 15 X Stronger in this aspect.

  • Nest Per Post on a Shipping Container the Bearing weight is an Incredible “53,000 Lbs per Post”

  • UBS Standard is 500 Lbs Per Sq Ft.

  • The Container Home is 106 X Times Stronger than the Standard Building(Or Minimum Codes)

ISO shipping cargo containers are tested in accordance within the requirements of International Standard ISO 1496/1 which stipulates dynamic and static design load factors to be complied with.  In  the case of a 20′ steel container, it is designed to have a maximum gross weight of 52,910 lbs (typically has a tare weight of around 5,000 lbs and a payload (P) potential of 47,910 lbs).  The container when loaded to its maximum gross weight must be capable of withstanding imposed loads of 2g downwards, 0.6g lateral and 2g longitudinal plus be able to withstand eight similar containers loaded to maximum gross weight stacked on top of it in a ship’s hold or at a land terminal.  It therefore has a very sever operational life and, notwithstanding its low tare weight it is very strongly built.

The side walls and end walls/doors have to withstand loadings of 0.6P and 0.4P respectively, these values equate to 28,746 lbs and 19,164 lbs based upon the payload given above.  The side wall area in contact with the load is 146.56 sq. ft. giving a pressure of 196 lbs/sq. ft.  Corresponding figures for the end wall/doors are 51.78 sq. ft. and 370 lbs/sq. ft.  These figures are well in excess of the 20 lbs/sq. ft. wind load required for structures less than 50 ft. high.  A wind of 100 MPH produces a pressure of only 30 lbs/sq. ft.

The roof load test is 660 lbs over an area of 2′ x 1′ applied to the weakest part of the roof.  The load is usually applied at the center of the containers positioned with the 2′ dimension aligned longitudinally.  Thus the roof is able to support an imposed load of a minimum of 330 lbs/sq. ft.  The design is easily capable of supporting the basic snow loads of 30 lbs per sq. ft. evenly distributed.

It is difficult to quantify uplift and suction forces.  Unlike a building, the roof of a container is an integral part of the structure; it is continuously welded around its entire periphery and is itself made from sheets of corrugated 14 ga. Cor-Ten steel also continuously welded together.  This steel, also used for the side and end walls has a minimum yield strength of 50 ksi, and tensile of 70 ksi.  The probability of the roof being removed by these forces is practically zero as the entire container structure would have to be destroyed for this to happen.