Dual purpose heating and cooling element for exhaust aftertreatment system

The invention claimed is: 1. A doser for injecting reagent into a stream of exhaust gas in order to enable chemical reaction of the exhaust gas to reduce nitrogen-oxides in the exhaust gas, the doser comprising a doser body including an outer doser housing defining an interior space, an inner doser conduit that extends through the interior space and defines a fluid passageway configured to conduct the reagent, and thermal insulation located in the interior space between the outer doser housing and the inner doser conduit, a valve system configured to selectively open the fluid passageway to allow the reagent to flow through the fluid passageway, and a temperature-management module including a module body thermally connected to the inner doser conduit, a heating element arranged within the module body that is configured to heat the module body and the inner doser conduit when active thereby raising a temperature of the reagent in the fluid passageway ahead of mixing with the exhaust gas, and a cooling element arranged within the module body that is configured to cool the module body and the inner doser conduit and, in turn, other parts of the doser to prevent damage to electronic components of the valve system. 2. The doser of claim 1 , wherein the valve system includes a valve door located in the fluid passageway and arranged to restrict flow of the reagent therethrough, an armature coupled to the valve door, and a coil in direct thermal communication with the temperature-management module configured to actuate the armature to displace the valve door and allow flow of the reagent through the fluid passageway. 3. The doser of claim 1 , wherein the heating element includes at least one conductive trace that extends through the module body in a plurality of directions. 4. The doser of claim 1 , wherein the heating element and cooling element are provided by a thermoelectric device that provides heat to the inner doser conduit when electrical current flows through the thermoelectric device in a first direction and removes heat away from the inner doser conduit when electrical current flows through the thermoelectric device in an opposite second direction. 5. The doser of claim 1 , wherein the temperature-management module extends circumferentially around the inner doser conduit uninterrupted and an inner surface of the temperature-management module faces toward an outer surface of the inner doser conduit. 6. The doser of claim 1 , wherein the inner doser conduit and the thermal insulation cooperate to form an annular space surrounding the inner doser conduit and the heating element is arranged to lie in the annular space. 7. The doser of claim 6 , wherein the heating element extends uninterrupted through the annular space formed cooperatively by the inner doser conduit and the thermal insulation. 8. The doser of claim 1 , wherein the inner doser conduit and the thermal insulation cooperate to form an annular space surrounding the inner doser conduit and the cooling element is arranged to lie in the annular space. 9. The doser of claim 8 , wherein the cooling element extends uninterrupted through the annular space formed cooperatively by the inner doser conduit and the thermal insulation. 10. The doser of claim 1 , wherein the cooling element is provided by at least one cooling passageway that extends through the module body to conduct cooling fluid to the heating element and cool the heating element. 11. The doser of claim 10 , wherein the at least one cooling passageway extends across the entire length of the module body. 12. The doser of claim 10 , wherein the heating element includes an electrically conductive trace and the at least one cooling passageway extends in transverse relation to the electrically conductive trace. 13. The doser of claim 12 , wherein the heating element includes two horizontally extending electrically conductive traces arranged to lie in spaced-apart parallel relation to one another and the at least one cooling passageway is arranged to extend downwardly in transverse relation to each of the two horizontally extending electrically conductive traces. 14. The doser of claim 1 , wherein the temperature-management module is located in a space formed between the thermal insulation and the inner doser conduit. 15. The doser of claim 14 , wherein the thermal insulation and the inner doser conduit cooperate to establish an annular module-receiving channel in the space and the temperature-management module is located in the annular module-receiving channel. 16. The doser of claim 15 , wherein the temperature-management module comprises four heating elements and four cooling elements. 17. The doser of claim 15 , wherein the temperature-management module has an annular shape. 18. The doser of claim 1 , wherein the doser comprises a plurality of temperature-management modules spaced circumferentially around the inner doser conduit. 19. The doser of claim 18 , wherein a first temperature-management module in the plurality of temperature-management modules includes a concave inner surface facing toward a convex outer surface of the inner doser conduit. 20. The doser of claim 18 , wherein each temperature-management module in the plurality of temperature-management modules includes a facing toward an exterior surface of the inner doser conduit. 21. The doser of claim 18 , wherein a first temperature-management module in the plurality of temperature-management modules includes a concave inner surface facing away from a concave inner surface of the thermal insulation. 22. The doser of claim 18 , wherein the plurality of temperature-management modules includes a second temperature-management module arranged to lie in spaced-apart relation to a first temperature-management module in the plurality of temperature-management modules to locate the inner doser conduit therebetween. 23. The doser of claim 22 , wherein the plurality of temperature-management modules includes a third temperature-management module arranged to lie in spaced-apart relation to a fourth temperature-management module in the plurality of temperature-management modules to locate the inner doser conduit therebetween. 24. The doser of claim 23 , wherein the second temperature-management module is positioned to lie in a space between the third temperature-management module and the fourth temperature-management module without touching the third temperature-management module and the fourth temperature-management module. 25. The doser of claim 24 , wherein the third temperature-management module lies in opposed spaced-apart relation to the fourth temperature-management module to surround the inner doser conduit and to cause a concave inner surface of the third temperature-management module to face toward a concave inner surface of the fourth temperature-management module. 26. An over-the-road vehicle comprising a combustion engine configured to combust fuel and air and produce exhaust gas, and an exhaust aftertreatment system configured to remove pollutants from the exhaust gas prior to the exhaust gas being released into atmosphere, the exhaust aftertreatment system comprising (i) a selective catalytic reduction unit (SCR), (ii) a doser located upstream of the SCR and configured inject reagent into the exhaust gas in order to enable chemical reaction of the exhaust gas with a catalyst in the SCR, and (iii) a temperature-management system confi