Combined heater and accumulator assemblies

What is claimed is: 1. An assembly comprising: an enclosure including a first portion, a second portion, and a divider between the first and second portions; an inlet through which a coolant may enter an interior of the second portion; an outlet through which the coolant may exit the interior of the second portion; a heat source operable for supplying heat for heating the coolant within the interior of the second portion; a baffle having one or more bleed holes, wherein the baffle is positioned generally between the divider and the second portion of the enclosure, the baffle configured to be operable for at least reducing application of pressure on the divider from the coolant flowing within the interior of the second portion; the divider is flexible, movable, and/or deformable in a direction away from the first portion towards the second portion for causing the coolant within the interior of the second portion to exit the interior of the second portion via the outlet; and whereby the assembly is configured to allow pressurizing of an interior of the first portion to thereby cause the divider to flex, move, and/or deform in the direction away from the first portion towards the second portion for causing coolant to exit the interior of the second portion via the outlet; and whereby the one or more bleed holes are configured to enable pressure changes due to flexing, moving, and/or deforming of the divider to be transmitted throughout the second portion while the baffle at least inhibits the divider from being directly affected by the flow of coolant through the second portion; and wherein: the assembly includes first and second ports and a symmetric design such that either the first port and the second port are usable as the inlet or the outlet; and/or the baffle comprises a plate having the one or more bleed holes, the plate configured to resist deforming due to force or pressure exerted by flowing coolant within the second portion and to resist the force or pressure caused by the flexing, moving, and/or deforming of the divider, whereby the plate is operable for at least reducing application of pressure on the divider from the coolant flowing within the interior of the second portion. 2. The assembly of claim 1 , wherein the assembly is a single integrated unit for a closed liquid circuit and operable as both a heater for the coolant and an accumulator for mitigating volume changes of the coolant due to temperature changes of the coolant. 3. The assembly of claim 1 , wherein the divider comprises a diaphragm such that the diaphragm and the first portion of the enclosure are operable as a diaphragm accumulator. 4. The assembly of claim 1 , wherein the assembly includes a charge valve operable for supplying a pressurized gas into the interior of the first portion to pressurize the first portion and thereby cause the divider to flex, move, and/or deform in the direction away from the first portion and towards the second portion for causing the coolant within the interior of the second portion to exit the interior of the second portion via the outlet. 5. The assembly of claim 1 , wherein the assembly includes a mechanism operable for applying a mechanical force to the divider to flex, move, and/or deform the divider in the direction away from the first portion and towards the second portion and cause coolant within the interior of the second portion to exit the interior of the second portion via the outlet. 6. The assembly of claim 1 , wherein the assembly further comprises one or more surfaces that protrude inwardly from an inner surface of the enclosure along the second portion into the interior of the second portion such that heat is transferrable from the one or more surfaces to the coolant within the interior of the second portion. 7. The assembly of claim 1 , wherein the assembly is configured for multiple pass flow of the coolant through the second portion to enable the coolant to traverse a length of the interior of the second portion at least three times including a first pass, a second pass, and a third pass of the coolant flow within the second portion. 8. The assembly of claim 1 , wherein the heat source comprises: one or more heat sources within the interior of the second portion; and/or one or more heat sources disposed along and thermally coupled to an exterior surface of the enclosure along the second portion. 9. The assembly of claim 1 , wherein: a plurality of fins inwardly protrude from an inner surface of the enclosure along the second portion into the interior of the second portion; the fins are spaced apart around a perimeter of the inner surface of the enclosure of the second portion; and the heat source comprises an electric foil heater disposed along and thermally coupled to an exterior surface of the enclosure along the second portion; whereby the electric foil heater is operable for supplying heat for heating the exterior surface of the enclosure and the plurality of fins, which heat is transferrable to the coolant as the coolant flows across the plurality of fins. 10. The assembly of claim 1 , wherein: the enclosure comprises a cylindrical tubular housing including a longitudinal axis, a first section defining the first portion, and a second section coupled to the first section and defining the second portion, the divider includes an O-ring between the first and second sections of the cylindrical tubular housing, and the divider is generally perpendicular to the longitudinal axis when the first portion is unpressurized; and/or the divider is positioned within the enclosure such that the first portion extends along about one-fourth of a length of the enclosure and such that the second portion extends along about three-fourths of the length of the enclosure. 11. A system comprising the assembly of claim 1 and a source of pressurized fluid for supplying pressurized fluid into the interior of the first portion, to thereby cause the divider to flex, move, and/or deform in the direction away from the first portion and towards the second portion for causing the coolant within the interior of the second portion to exit the interior of the second portion via the outlet. 12. A heater-accumulator assembly comprising: an enclosure including an accumulator portion, a heater portion, and a membrane between the accumulator portion and the heater portion; an inlet through which coolant may enter an interior of the heater portion; an outlet through which the coolant may exit the interior of the heater portion; and a heat source operable for supplying heat for heating the coolant with the interior of the heater portion; a baffle having one or more bleed holes, wherein the baffle is positioned generally between the membrane and the heater portion of the enclosure, the baffle configured to be operable for at least reducing application of pressure on the membrane from the coolant flowing within the interior of the heater portion; whereby the membrane is flexible, movable, and/or deformable in a direction away from the accumulator portion and towards the heater portion for causing the coolant within the interior of the heater portion to exit the interior of the heater portion via the outlet; and wherein: the assembly includes first and second ports and a symmetric design such that either the first port and the second port are usable as the inlet or the outlet; and/or the baffle comprises a plate having the one or more bleed holes, the plate configured to resist deforming due to force or pressure exerted by flowing coolant within the second portion and to resist the force or pressure caused by the flexing, moving, and/or deforming of the membrane,