Abstract: A cooling system is configured to adjust cooling fluid flow to various racks located throughout a data center based upon the detected or anticipated temperatures at various locations throughout the data center. In one respect, by substantially increasing the cooling fluid flow to those racks dissipating greater amounts of heat and by substantially decreasing the cooling fluid flow to those racks dissipating lesser amounts of heat, the amount of energy required to operate the cooling system may be relatively reduced. Thus, instead of operating the devices, e.g., compressors, fans, etc., of the cooling system at substantially 100 percent of the anticipated heat dissipation from the racks, those devices may be operated according to the actual cooling needs.

Abstract: A cooling system is configured to supply individually metered amounts of cooling fluid to heat generating components, e.g., processors, micro-controllers, high speed video cards, disk drives, semi-conductor devices, and the like, of an electronic system. The cooling system includes at least one variable speed fan, e.g., blower, configured to supply fluid through a centralized plenum and thereafter through a plurality of nozzles to the components of the electronic system. Each of the nozzles contains a valve to control the amount of fluid flow through the each of the nozzles. A controller is provided to control the operation of the variable speed fan and the operation of each of the valves is also controlled by a controller.

Abstract: An apparatus and method for monitoring memory system performance and controlling an operating parameter is provided. A plurality of digital events indicative of memory system operations is detected, from which a subset of digital events to count is periodically selected, the subset being those digital events occurring during a sampling window time interval. Responsive to each digital event of the subset, a transistor is switched on to conduct current from a power supply to a capacitor. The transistor is biased by the capacitor to operate in a constant current region providing a substantially fixed amount of charge added to the capacitor responsive to each digital event of the subset. The operating parameter is controlled responsive to the charge accumulated in the capacitor, representative of the count of digital events in the subset. In one embodiment, the sampling window time interval is selected pseudo-randomly within a periodic base time interval.

Abstract: An air cooled electronic system within an enclosure simultaneously provides different levels of cooling in response to the individual cooling needs of the various electronic components. In one embodiment, electronic system includes a plenum that has an inlet and a plurality of outlets with the inlet receiving air from outside the enclosure. A rate of airflow at the respective plenum outlets varies as a function of a static air pressure behind the plenum outlets and a shape of the respective outlets, the static air pressure being a function of the shape of a cavity within the plenum. The system also includes a plurality of air ducts respectively coupled to the plurality of plenum outlets, with each air duct having a length and an outlet characterized by an outlet size. A first one of the air ducts has an outlet that is disposed proximate a first subset of the electronic components and a second one of the air ducts has an outlet that is disposed proximate a second subset of the electronic components.

Abstract: A cooling arrangement facilitates the cooling of a plurality of integrated circuit elements disposed on a plurality of substrates that are substantially perpendicularly mounted on a main substrate. In an example embodiment, the cooling arrangement provides cooling for a plurality of integrated circuit elements disposed on a plurality of substrates that are substantially perpendicularly mounted on a main substrate. The cooling arrangement includes a plurality of U-shaped thermally conductive members, each having a set of leg portions connected with a top portion and an open end disposed over a respective one of the substrates. In addition, a first inner surface of at least one of the leg portions is in thermal contact with at least one of the integrated circuit elements. The cooling arrangement further includes a housing member containing therein the U-shaped members and includes a cooling plate arrangement in thermal contact with the housing and the top portions of the U-shaped members.

Abstract: A cooling device primarily for cooling, e.g., integrated circuits or other electronic devices during operation may include a heat sink portion having a plurality of cooling vanes and a heat pipe chamber. Both the cooling vanes and the heat pipe chamber may be integrally formed within the heat sink portion. Because the heat pipe chamber is integrally formed with the cooling vanes, no joints exist between the condensing surface of the heat pipe chamber and the cooling vanes. This, in turn, allows extremely rapid and efficient heat transfer between the heat pipe chamber and the cooling vanes. The cooling device may include extensions of the main heat pipe chamber which project into each of the cooling vanes. In this manner, the condensing surface of the heat pipe chamber is actually moved into the vanes at a position very close to the surface of the vanes where heat transfer into the atmosphere occurs.

Abstract: A disc drive system having a rotating disc storage device and a base housing with a sealed internal heat transport structure containing a working fluid. The rotating disc storage device is disposed on the base housing and has at least one heat-generating component in a heat exchange relationship with the base housing. The heat transport structure is formed as a cavity or at least one fluid passage arranged radially, in parallel, as a matrix, or a serpentine channel. Absorbed heat vaporizes the working fluid. The vapor transports the heat from a heat transport structure evaporator section near a relatively hot location of the base housing, to a heat transport structure condenser section near a relatively cooler location of the base housing, where the vapor condenses to liquid and releases the heat. The liquid working fluid is drawn by capillary action from the condenser section back to the evaporator section, aided by a wicking structure.

Abstract: A semiconductor chip cooling system configured with thermal inkjet type sprayers controlled by a control system. The control system can operate groups of the sprayers at different rates to controllably cool separate regions of a chip at different rates. A detection system is configured to separately detect the cooling regime occurring on the different regions of the chip by reflecting an optical beam off the chip in the region that is being sprayed.

Abstract: A multi-chip module (MCM) having a substrate including a first surface, a second surface and a multi-layer interconnection arrangement disposed between the two surfaces. A high-density thin-film circuit region is provided on the substrate first surface to interconnect a plurality of integrated circuit chips and the multi-layer interconnection arrangement. The integrated circuit chips are powered through the high-density thin-film circuit region, which receives power from the multi-layer interconnection arrangement. A plurality of discrete on-board voltage converter devices, mounted on at least one substrate surface, provide uniform power supply distribution to multi-layer interconnection arrangement power planes, converting an MCM input voltage and current to a relatively lower output voltage and a relatively higher output current.

Abstract: A system and method for reducing temperature variation among components in a multi-component system. In this respect, component temperatures are controlled to remain relatively constant (approximately within 5° C.) with respect to other components, while allowing for multiple fluctuating heat loads between components. A refrigeration system possessing a variable capacity (speed) compressor and a thermostatic expansion valve is utilized to control the flow of refrigerant through the refrigeration system. The temperatures of the components are reduced by metering the mass flow rate of the refrigerant cooling the components to compensate for the heat load applied to the refrigeration system. The temperature variation among the components is reduced by supplemental heaters independently providing heat to each respective component.

Abstract: An apparatus for cooling electronic components contained within a housing member is configured to be easily removed from the housing member. In one example embodiment, an apparatus for cooling an electronic component is coupled to a housing that contains an electronic component. The apparatus includes a heat conductive member having a first lateral edge shaped to slidably attach and retain the heat conductive member to a portion of the housing. A top surface of the housing includes a second edge shaped to slidably receive and retain the heat conductive member.

Abstract: System and method for reducing temperature variation among components in a multi-component system. In this respect, component temperatures are controlled to remain relatively constant (approximately within 5° C.) with respect to other components, while allowing for multiple fluctuating heat loads between components. A refrigeration system possessing a variable capacity (speed) compressor and an electronic valve is utilized to control the flow of refrigerant through the refrigeration system. The temperature of the components is reduced by metering the mass flow rate of the refrigerant cooling the components to compensate for the heat load applied to the refrigeration system.

Abstract: An air cooled electronic system within an enclosure simultaneously provides different levels of cooling in response to the individual cooling needs of the various electronic components. In one embodiment, electronic system includes a plenum that has an inlet and a plurality of outlets with the inlet receiving air from outside the enclosure. A rate of airflow at the respective plenum outlets varies as a function of a static air pressure behind the plenum outlets and a shape of the respective outlets, the static air pressure being a function of the shape of a cavity within the plenum. The system also includes a plurality of air ducts respectively coupled to the plurality of plenum outlets, with each air duct having a length and an outlet characterized by an outlet size. A first one of the air ducts has an outlet that is disposed proximate a first subset of the electronic components and a second one of the air ducts has an outlet that is disposed proximate a second subset of the electronic components.

Abstract: A semiconductor chip cooling system configured with thermal inkjet type sprayers controlled by a control system. The control system can operate groups of the sprayers at different rates to controllably cool separate regions of a chip at different rates. A detection system is configured to separately detect the cooling regime occurring on the different regions of the chip by reflecting an optical beam off the chip in the region that is being sprayed.

Abstract: A spray cooling system for semiconductor devices. An ink-jet type spray device sprays droplets of a cooling fluid onto the semiconductor devices. The devices vaporize the liquid, which gets passed through a roll bond panel, or other heat exchanger, and is pumped into a spring loaded reservoir that feeds the spray device.

Abstract: A cooling system for cooling one or more components that produce heat. The cooling system includes sprayers configured to spray cooling fluid toward the components. A detection system includes a radiation source and a radiation sensor that pass radiant energy in the vicinity of the component such that the radiant energy is affected by passing through the vaporizing spray coolant. A controller controls the flow rates of the sprayers in response to levels of radiant energy detected by the radiation sensor, allowing the controller to more accurately control the wall temperature and cooling regime achieved by the spray cooling. The source and sensor are aimable or otherwise configured for gathering information for different thermal zones of the component, providing the controller with information that is helpful in separately controlling the wall temperature and/or cooling regime in each zone.

Abstract: A semiconductor chip cooling system configured with thermal inkjet type sprayers controlled by a control system. The control system can operate groups of the sprayers at different rates to controllably cool separate regions of a chip at different rates. A detection system is configured to separately detect the cooling regime occurring on the different regions of the chip by reflecting an optical beam off the chip in the region that is being sprayed.

Abstract: A modular semiconductor chip cooling system having a readily openable enclosure defining a chamber configured to hold a printed circuit board carrying components to be cooled. The enclosure can include a reservoir, a condenser and a pump. Sprayers within the chamber are adjustably mounted on one or more brackets to allow each sprayer to be set for the individual height of its respective component. The enclosure can be readily removed from a computer system through a quick release connection. The computer system can include a condenser and pump to operate all its modular cooling systems, removing the condensing function from the individual modules.

Abstract: A modular semiconductor chip cooling system having a readily openable enclosure defining a chamber configured to hold a printed circuit board carrying components to be cooled. The enclosure can include a reservoir, a condenser and a pump. Sprayers within the chamber are set in an array to spray a target area, and a controller controls which sprayers are activated based on information delineating the locations of the components to be cooled. The enclosure can be readily removed from a computer system through a quick release connection. The computer system can include a condenser and pump to operate all its modular cooling systems, removing the condensing function from the individual modules.

Abstract: A modular semiconductor chip cooling system having a readily openable enclosure defining a chamber configured to hold a printed circuit board carrying components to be cooled. The enclosure can include a reservoir, a condenser and a pump. Sprayers within the chamber are adjustably mounted on one or more brackets to allow each sprayer to be set for the individual height of its respective component. The enclosure can be readily removed from a computer system through a quick release connection. The computer system can include a condenser and pump to operate all its modular cooling systems, removing the condensing function from the individual modules.