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A venting method and arrangement for a roof includes a plurality of venting stacks each having a first open base end open to an area on top of the roof insulation layer and below the roof outer membrane, the venting stacks arranged spaced apart around a perimeter of the roof. A venting path grid of

A venting method and arrangement for a roof includes a plurality of venting stacks each having a first open base end open to an area on top of the roof insulation layer and below the roof outer membrane, the venting stacks arranged spaced apart around a perimeter of the roof. A venting path grid of air permeable material is arranged between the roof membrane and the insulation layer. The grid is in air flow communication with the first open base ends. Centrally located wind-driven turbine ventilators can also be in air flow communication to the grid.

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1. A venting arrangement for a roof, the roof having an insulation layer and a roof membrane on top of the insulation layer, the arrangement comprising: a plurality of perimeter venting stacks arranged spaced-apart around a perimeter of the roof, each said perimeter venting stack having a first open

1. A venting arrangement for a roof, the roof having an insulation layer and a roof membrane on top of the insulation layer, the arrangement comprising: a plurality of perimeter venting stacks arranged spaced-apart around a perimeter of the roof, each said perimeter venting stack having a first open base end that is open to an area on the top of the insulation layer and below the roof membrane; anda plurality of venting paths forming a grid on the roof, each said venting path comprising filter material that allows air to pass horizontally and vertically through the filter material, the filter material arranged between the roof membrane and the insulation layer and extending lengthwise or widthwise across the roof and open at opposite ends to respective said first open base ends of the perimeter venting stacks located adjacent to opposite sides of the roof;wherein the filter material includes mutually interconnected voids which provide a sufficient air permeability such that ambient air flow on the roof past one of the plurality of venting stacks draws vapor through a respective said venting path and creates a suction to urge the roof membrane down onto the insulation layer, and wherein the filter material does not transport said vapor by capillary action. 2. The venting arrangement according to claim 1, wherein the filter material has a width of between 9 and 12 inches. 3. The venting arrangement according to claim 1, further comprising intermediate venting stacks located at intermediate positions along each said venting path, each said intermediate venting stack having a second open base end that is open to the area on the top of the insulation layer and below the roof membrane. 4. The venting arrangement according to claim 3, wherein said each intermediate venting stack comprises a wind driven impeller for drawing air up the intermediate venting stack from the second open base end. 5. The venting arrangement according to claim 1, wherein each said venting stack is supported on a base mesh fabric that overlies a respective said venting path. 6. The venting arrangement according to claim 5, wherein each said base mesh fabric has an outer perimeter greater than a perimeter of the respective first open base end that is supported on the base mesh fabric. 7. The venting arrangement according to claim 6, wherein said each base mesh fabric has a widthwise dimension of about 2 feet. 8. A venting arrangement for a roof, the roof having an insulation layer and a roof membrane on top of the insulation layer, the arrangement comprising: a plurality of perimeter venting stacks arranged spaced-apart around a perimeter of the roof, each said perimeter venting stack having a first open base end that is open to an area on the top of the insulation layer and below the roof membrane;a plurality of venting paths forming a grid on the roof, each said venting path comprising filter material that allows air to pass horizontally and vertically through the air filter material, the filter material arranged between the roof membrane and the insulation layer and extending lengthwise or widthwise across the roof and open at opposite ends to respective said first open base ends of the perimeter venting stacks located adjacent to opposite sides of the roof;wherein said each venting stack is supported on a base mesh fabric that allows air to pass vertically through the base mesh fabric that overlies a respective said venting path;wherein each said base mesh fabric has an outer perimeter greater than a perimeter of the respective first open base end that is supported on the base mesh fabric;wherein the filter material includes mutually interconnected voids which provide a sufficient air permeability such that ambient air flow on the roof past one of the plurality of venting stacks draws vapor through the respective venting path and creates a suction to urge the roof membrane down onto the insulation layer, and wherein the filter material does not transport said vapor by capillary action. 9. The venting arrangement according to claim 8, wherein said each base mesh fabric has a widthwise dimension of about 2 feet. 10. The venting arrangement according to claim 8, wherein the filter material has a width of between 9 and 12 inches. 11. A method of venting a roof, the roof having an insulation layer and a roof membrane on top of the insulation layer, the method comprising: arranging a first venting stack having a first open base end open to an area on the top of the insulation layer and below the roof membrane;arranging an air venting path between the roof membrane and the insulation layer and in air flow communication at a first location to the first open base end of the first venting stack and extending to a second location away from the first venting stack; andarranging a second venting stack having a second open base end open to the area on the top of the insulation layer and below the roof membrane, the air venting path being in said air flow communication at the second location to the second open base end of the second venting stack;wherein the air venting path includes mutually interconnected voids which provide a sufficient air permeability such that ambient air flow on the roof past the first or second venting stacks draws vapor from the insulation layer vertically into the air venting path and horizontally through the air venting path and creates a suction to urge the roof membrane down onto the insulation layer, and wherein the air venting path does not transport said vapor by capillary action. 12. The method according to claim 11, comprising the further steps of: arranging a plurality of additional third venting stacks each having a first open base end open to the area on the top of the insulation layer and below the roof membrane, the additional third venting stacks arranged spaced apart around a perimeter of the roof;arranging an air venting path grid between the roof membrane and the insulation layer and in air flow communication to the first open base ends of the plurality of additional third venting stacks and to the air venting path. 13. The method according to claim 11, comprising the further steps of: arranging a first base mesh fabric supporting the first open base end and overlying the air venting path and arranging a second base mesh fabric supporting the second open base end and overlying the air venting path. 14. The method according to claim 11 wherein the step of arranging the air venting path is further defined by arranging an air permeable open mesh fabric between the roof membrane and the insulation layer. 15. The method according to claim 14 wherein the air venting path has a width of between 9 and 12 inches. 16. The method according to claim 11, wherein the step of arranging the second venting stack is further defined in that the second venting stack comprises a wind-driven turbine for drawing air up the second venting stack from the second open base end. 17. The method according to claim 16, wherein the step of arranging the air venting path is further defined in that the air venting path extends from the second location away from the first location to a third location; and comprising the further step of arranging a third venting stack having a third open base end open to the area on the top of the insulation layer and below the roof membrane, the air venting path open at the third location to the third open base end of the third venting stack. 18. The method according to claim 17, wherein the steps of arranging the first and second venting stacks are further defined in that the first and second locations are adjacent opposite sides of the roof and the second location is in a central location of the roof.