Integration of active mems cooling systems into thin computing devices

1 . A cooling system, comprising: a heat transfer structure including: a heat spreader; a fin structure that transfers heat from the heat spreader to a fluid; and a differential pressure device including at least one actuator therein, the actuator configured to undergo vibrational motion that generates a low pressure region that draws the fluid from an ingress in a computing device through the fin structure and from the fin structure to the differential pressure device; wherein the heat transfer structure is in a chamber of the computing device, the chamber having the ingress and an egress. 2 . The cooling system of claim 1 , wherein the heat transfer structure restricts flow driven by the differential pressure device such that a pressure differential of at least a one hundred Pascals per cubic feet per minute (cfm) (100 Pa/cfm) is within the chamber. 3 . The cooling system of claim 1 , wherein the pressure differential device has a height not exceeding 3.5 millimeters. 4 . The cooling system of claim 1 , wherein the differential pressure device generates the low pressure region that draws the fluid from the ingress such that greater than 2 W of heat is ejected from the egress. 5 . The cooling system of claim 4 , wherein the differential pressure device generates the low pressure region such that greater than 6 W of heat is ejected from the egress of the computing device. 6 . The cooling system of claim 1 , wherein the differential pressure device further includes: a plurality of cells, each of the plurality of cells including a flow chamber having a vent, an actuator of the at least one actuator, and a plurality of orifices, the vibrational motion drawing the fluid into the flow chamber via the vent, directing the fluid around the actuator, and driving the fluid out of the flow chamber through the plurality of orifices; a top cover proximate to the vent and having at least one aperture therein; and a bottom plate proximate to the plurality of orifices and coupled with the top cover, the fluid being directed from the plurality of orifices toward the heat spreader. 7 . The cooling system of claim 6 , wherein the fluid flows through the differential pressure device and to the egress. 8 . The cooling system of claim 7 , wherein a top gap is between the top cover of the differential pressure device and a top of the chamber, the top gap being at least 0.5 mm and not more than 1 mm. 9 . The cooling system of claim 7 , wherein the differential pressure device has a height not exceeding 3.5 millimeters. 10 . A cooling system, comprising: a heat transfer structure including: a heat spreader; and a differential pressure device including at least one actuator, the at least one actuator undergoing vibrational motion that generates a low pressure region that draws fluid from an ingress in a computing device through the heat transfer structure, a heat-generating structure of the computing device being in a path between the ingress and the differential pressure device, the differential pressure device having a height not exceeding 3.5 millimeters. 11 . The cooling system of claim 10 , wherein the height of the differential pressure device does not exceed 3 millimeters. 12 . The cooling system of claim 10 , wherein the heat transfer structure resides in a chamber of the computing device having a chamber height of at least 2 millimeters and not more than 3.5 millimeters. 13 . The cooling system of claim 10 , wherein the heat transfer structure further includes: a fin structure that transfers heat from the heat spreader to the fluid, the low pressure region generated by the differential pressure device drawing the fluid through the fin structure, the fin structure being between the ingress and the differential pressure device. 14 . The cooling system of claim 13 , wherein the fin structure is between the heat-generating structure and the differential pressure device. 15 . The cooling system of claim 10 , wherein the differential pressure device generates the low pressure region such that greater than 2 W of heat is ejected from an egress of the computing device. 16 . The cooling system of claim 10 , wherein the differential pressure device generates the low pressure region such that greater than 6 W of heat is ejected from an egress of the computing device. 17 . The cooling system of claim 10 , wherein the differential pressure device further includes: a plurality of cells, each of the plurality of cells including a flow chamber having a vent, an actuator of the at least one actuator, and a plurality of orifices, the vibrational motion of the actuator drawing the fluid into the flow chamber via the vent, directing the fluid around the actuator, and driving the fluid out of the flow chamber through the plurality of orifices; a top cover proximate to the vent and having at least one aperture therein; and a bottom plate proximate to the plurality of orifices and coupled with the top cover, the fluid being directed from the plurality of orifices toward the heat spreader. 18 . A method, comprising: activating an active component in a differential pressure device to undergo vibrational motion, a heat transfer structure including the differential pressure device, a fin structure, and a heat spreader, the heat transfer structure being in a computing device, the fin structure transferring heat from the heat spreader to a fluid, the vibrational motion of the active component generating a low pressure region that draws the fluid from an ingress in the computing device through the fin structure and from the fin structure to the differential pressure device. 19 . The method of claim 18 , wherein the vibrational motion of the active component generates the low pressure region that draws the fluid from the ingress in the computing device such that greater than 2 W of heat is ejected from an egress of the computing device. 20 . The method of claim 18 , wherein the differential pressure device has a height not exceeding 3.5 millimeters.