Circuit board configurations facilitating operation of heat sensitive sensor components

What is claimed is: 1. A thermal-isolation assembly, comprising: a multilayer circuit board, including: first and second conductive layers; a middle dielectric layer located between the first and second conductive layers; a metal-free region formed in the first conductive layer; and a heat-emitting component and a heat-sensitive component being mounted on top of the multilayer circuit board and horizontally separated by at least a portion of the metal-free region, wherein the heat-sensitive component is electronically coupled to the first conductive layer and the heat-emitting component is electrically coupled to the second conductive layer; wherein the middle dielectric layer thermally insulates the heat-sensitive component by resisting vertical heat flow from the second conductive layer; wherein the metal-free region thermally insulates the heat-sensitive component by resisting horizontal heat flow from the first conductive layer. 2. The thermal-isolation assembly of claim 1 , further comprising: a plurality of through holes vertically extending through the metal-free region wherein the through holes resist horizontal heat flow from the first conductive layer. 3. The thermal-isolation assembly of claim 1 , further comprising: a plurality of metal-plated vias vertically extending through the first and second conductive layers, wherein the metal-plated vias provide thermal paths away from the heat-sensitive component. 4. The thermal-isolation assembly of claim 1 , further comprising: a silicon rubber sleeve fitted around a portion of the heat-sensitive component, the silicon rubber sleeve thermally isolates the heat-sensitive component by resisting heat transfer by radiation to the heat-sensitive component. 5. The multilayer circuit board of claim 1 , wherein the heat-emitting component is an LED and the heat-sensitive component is a PIR sensor, both installed in a combined smoke detector and carbon monoxide device. 6. The thermal-isolation assembly of claim 1 , wherein the metal-free region is free of metal ground planes but includes metal ground, power, or signal traces. 7. A multilayered circuit board, comprising: a first conductive layer lying generally parallel to a horizontal plane; a metal-free region extending along a vertical axis through at least a portion of the first conductive layer; and a first outer surface being located along the vertical axis above the first conductive layer, lying generally parallel to the horizontal plane, and supporting a heat-emitting component and a heat-sensitive component, the heat-emitting component and the metal-free region being spaced along the vertical axis and the horizontal plane, the heat-sensitive component and the metal-free region being spaced along the vertical axis and generally aligned along the horizontal plane, wherein the metal-free region thermally isolates the heat-sensitive component by resisting heat flowing generally parallel to the horizontal plane towards the heat-sensitive component. 8. The multilayered circuit board of claim 7 , wherein the metal-free region includes inner and outer peripheries, and the heat-sensitive component is aligned along the horizontal plane inside the inner periphery such that the metal-free region provides a thermal-isolation barrier along the horizontal plane between the heat-sensitive and heat-emitting components. 9. The multilayered circuit board of claim 7 , wherein the metal-free region is free of metal ground planes but includes metal ground, power, or signal traces. 10. The multilayer circuit board of claim 9 , further comprising: a second conductive layer being located along the vertical axis below the first conductive layer and lying generally parallel to the horizontal plane; a second metal-free region extending along the vertical axis through at least a portion of the second conductive layer, the first and second metal-free regions being spaced along the vertical axis and the horizontal plane, the first and second metal-free regions being spaced along the vertical axis and generally aligned along the horizontal plane. 11. The multilayer circuit board of claim 7 , further comprising: a first connector extending generally parallel to the vertical axis and electrically coupling the heat-emitting component to the first conductive layer; a second connector extending generally parallel to the vertical axis and electrically coupling the heat-sensitive component to the second conductive layer; and a middle dielectric layer being located along the vertical axis between the first and second conductive layers and thermally resisting heat flow from the first conductive layer to the second conductive layer, thereby limiting return heat flow through the second connector to the heat-sensitive component. 12. The multilayer circuit board of claim 7 , further comprising: a plurality of through holes extending along the vertical axis through the metal-free region and being spaced around the heat-sensitive component, wherein the through holes resist heat flow generally parallel to the horizontal plane towards the heat-sensitive component; and a plurality of metal-plated vias extending along the vertical axis and being located outside the metal-free region, wherein the metal-plated vias provide thermal paths away from the heat-sensitive component. 13. The multilayer circuit board of claim 7 , further comprising: a silicon rubber sleeve fitted around a portion of the heat-sensitive component that projects away from the first outer surface, the silicon rubber sleeve thermally isolates the heat-sensitive component by resisting heat transfer by radiation to the heat-sensitive component. 14. The multilayer circuit board of claim 7 , wherein the heat-emitting component is an LED and the heat-sensitive component is a PIR sensor. 15. The multilayer circuit board of claim 14 , wherein the multilayer circuit board is part of a hazard detector. 16. The multilayer circuit board of claim 7 , wherein the second metal-free region is part of the metal-free region. 17. A multilayered circuit board, comprising: first conducting means being located along a vertical axis; a metal-free region extending along a vertical axis through at least a portion of the first conducting means; and a first surface being located along the vertical axis above the first conducting means and supporting a heat-emitting means and a heat-sensitive component, the heat-emitting means and the metal-free region being vertically and laterally spaced apart, the heat-sensitive component and the metal-free region being vertically spaced apart and laterally aligned, wherein the metal-free region thermally isolates the heat-sensitive component by resisting radial heat flow towards the heat-sensitive component. 18. The multilayered circuit board of claim 17 , further comprising: a second conducting means being located along the vertical axis below the first conducting means; a first coupling means electrically coupling the heat-emitting means to the first conducting means; and a second coupling means electrically coupling the heat-sensitive component to the second conducting means, a middle insulating mean being located along the vertical axis between the first and second conducting means, the middle insulating means thermally resisting heat flow towards the second conducting means, thereby limiting return heat flow through the second coupling means to the heat-sensitive component. 19. The multilayered circuit board of claim 17 , wherein the metal-free region is fre