Vacuum insulated structure with sheet metal features to control vacuum bow

What is claimed is: 1. A vacuum insulated structure, comprising: a first cover member of a unitary sheet member defining a perimeter portion, an outer frame portion defined radially inward of the perimeter portion, and an inner area surrounded and supported by the outer frame portion, the inner area initially defining a first planar level with at least a portion of the outer frame portion extending to a second planar level parallel to and spaced apart from the first planar level in an axially outward direction; a second cover member of a unitary sheet; and a thermal bridge interconnecting the first cover member and the second cover member at the perimeter portions thereof to define an insulating cavity therebetween, wherein the insulating cavity is a sealed cavity having a vacuum drawn therefrom, and further wherein the outer frame portion deforms such that the inner area moves axially inward away from the first planar level under a force of the vacuum within the insulating cavity with at least the portion of the outer frame portion remaining at the second planar level. 2. The vacuum insulated structure of claim 1 , wherein the outer frame portion includes a first side wall extending from the first planar level to the second planar level in a direction perpendicular to the first planar level, a face wall extending radially inwardly along the second planar level, and a second side wall extending from the second planar level to join with the inner area at the first planar level. 3. The vacuum insulated structure of claim 2 , wherein the outer frame portion deforms by axially inward flexing of the face wall adjacent the second side wall such that the second side wall moves inward with respect to the first side wall opposite the direction perpendicular to the first planar level. 4. The vacuum insulated structure of claim 2 , further including a perimeter portion extending outward from the first side wall of the outer frame portion and disposed at the first planar level. 5. The vacuum insulated structure of claim 1 , wherein the inner area is configured to resist deformation when moving axially inward such that deformation of the first cover member is predominantly within the outer frame portion. 6. The vacuum insulated structure of claim 5 , wherein the inner area defines a plurality of ribs arranged in a grid pattern and extending from the outer frame across the inner area to provide structural support for the inner area to resist deformation. 7. The vacuum insulated structure of claim 1 , wherein the second cover member defines a perimeter portion, an outer frame portion defined radially inward of the perimeter portion, and an inner area surrounded and supported by the outer frame portion, the inner area defining a third planar level with a portion of the outer frame portion extending to a fourth planar level parallel to and spaced apart from the third planar level in an axially outward direction. 8. The vacuum insulated structure of claim 7 , wherein the outer frame portion of the second cover member deforms such that the inner area of the second cover member moves axially inward from the third and fourth planar levels under the force of the vacuum within the insulating cavity with the at least a portion of the outer frame portion of the second cover member remaining at the fourth planar level. 9. The vacuum insulated structure of claim 1 , further including an insulating material disposed within the insulating cavity. 10. The vacuum insulated structure of claim 1 , wherein the outer frame portion defines multiple stepped segments from the perimeter to the inner area and a plurality of beveled corner segments extending between the multiple stepped segments. 11. A method of making a vacuum insulated cabinet structure, including: assembling first and second cover members with a thermal bridge, at least the first cover member defining a perimeter portion, an outer frame portion defined radially inward of the perimeter portion, and an inner area surrounded and supported by the outer frame portion, the inner area initially defining a first planar level with at least a portion of the outer frame portion extending to a second planar level parallel to and spaced apart from the first planar level in an axially outward direction, wherein assembling the first and second cover members with the thermal bridge defines a sealed insulating cavity therebetween; and drawing a vacuum from the sealed insulating cavity, causing the outer frame portion to deform such that the inner area moves axially inward from the first and second planar levels under a force of the vacuum within the insulating cavity with at least the portion of the outer frame portion remaining at the second planar level. 12. The method of claim 11 , wherein: the first cover member is a wrapper structure defining an exterior of the cabinet structure; and the second cover member is a liner structure defining an interior of the cabinet structure. 13. The method of claim 12 , wherein: the first cover member defines a first exterior side on which the perimeter portion, the outer frame portion, and the inner area are defined; and the second cover member defines a second exterior side further defining an additional respective perimeter portion, outer frame portion, and inner area. 14. The method of claim 11 , wherein: the outer frame portion includes a first side wall extending from the first planar level to the second planar level in a direction perpendicular to the first planar level, a face wall extending radially inwardly along the second planar level, and a second side wall extending from the second planar level to join with the inner area at the first planar level; and drawing the vacuum from the sealed insulating cavity causes the outer frame portion to deform by axially inward flexing of the face wall adjacent the second side wall such that the second side wall moves inward with respect to the first side wall opposite the direction perpendicular to the first planar level. 15. The method of claim 11 , wherein the inner area is configured to resist deformation when moving axially inward such that drawing the vacuum from the sealed insulating cavity causes deformation of the first cover member predominantly within the outer frame portion. 16. The method of claim 15 , wherein the inner area defines a plurality of ribs arranged in a grid pattern and extending from the outer frame portion across the inner area to provide structural support for the inner area to resist deformation. 17. The method of claim 11 , further including introducing an insulation material into the insulting cavity. 18. The method of claim 17 , wherein the insulation material includes one of fumed silica, glass beads, processed rice husks, and a combination thereof. 19. A refrigerator, comprising: a vacuum-insulated cabinet structure, including: an outer wrapper having a first side defining a perimeter portion, an outer frame portion defined radially inward of the perimeter portion, and an inner area surrounded and supported by the outer frame portion, the inner area initially defining a first planar level with at least a portion of the outer frame portion extending to a second planar level parallel to and spaced apart from the first planar level in an axially outward direction; an inner liner disposed inward of the outer wrapper; and a thermal bridge interconnecting the outer wrapper and the inner liner at the perimeter portions thereof to define an insulating cavity therebetween, wherein the insulating cavity is a se