Embodiments of an accumulator for charge management are described. A fluid compression system, comprising an accumulator fluidly connected to an evaporator via a spillover port. The spillover port directs working fluid received from the evaporator to be collected and stored in the accumulator, where the stored working fluid is stored and released from the accumulator in response to an operating condition of the evaporator.

High-efficiency cooling is performed in a data center in response to a cooling and/or humidity demand using a system having multiple cooling loops. The system includes a plurality of integrated cooling systems each comprising one or more specifically sized chillers and a liquid loop to address the cooling demand. A free cooling heat exchanger is coupled to the first liquid loop for use when a wet-bulb temperature surrounding the data center is at or below a free cooling set point of the first chilled liquid loop. The system isolates humidity control components to a second chilled liquid loop, and enables greater control of the first chilled liquid loop of the data center to meet specific IT loads.

High-efficiency cooling is performed in a data center in response to a cooling and/or humidity demand using a system having multiple cooling loops. The system includes a plurality of integrated cooling systems each comprising one or more specifically sized chillers and a liquid loop to address the cooling demand. A free cooling heat exchanger is coupled to the first liquid loop for use when a wet-bulb temperature surrounding the data center is at or below a free cooling set point of the first chilled liquid loop. The system isolates humidity control components to a second chilled liquid loop, and enables greater control of the first chilled liquid loop of the data center to meet specific IT loads.

The invention relates to a folding cooling rack for baking food, including the main frame and the cooling rack, the main frame as mentioned is equipped with legs and connecting rod component on its left and right ends, the legs as mentioned are equipped with first fixing rail at its front and back ends, the first fixing rail as described is connected respectively at both of its ends to the legs as mentioned by the first nut device, the legs as mentioned are also equipped with a chute. The connecting rod component is composed of two connecting rod, the two connecting rod component as described are flexibly connected at the center by rivet connection device, the connecting rod components as described are connected to pulley connecting rod below their front end, the pulley connecting rod as mentioned is equipped with plastic pulley at each end, the plastic pulley as mentioned is flexibly connected to the chute, using multiple connecting rod component and cooling rack, the efficiency of the use of cooling rack is greatly improved, while manpower, material and time are saved; by using height control groove and pulley connecting rod, the height can be flexibly adjusted according to the use of the rack, and the operation is simple, it can easily be operated and used by one person.

The invention relates to a folding cooling rack for baking food, including the main frame and the cooling rack, the main frame as mentioned is equipped with legs and connecting rod component on its left and right ends, the legs as mentioned are equipped with first fixing rail at its front and back ends, the first fixing rail as described is connected respectively at both of its ends to the legs as mentioned by the first nut device, the legs as mentioned are also equipped with a chute. The connecting rod component is composed of two connecting rod, the two connecting rod component as described are flexibly connected at the center by rivet connection device, the connecting rod components as described are connected to pulley connecting rod below their front end, the pulley connecting rod as mentioned is equipped with plastic pulley at each end, the plastic pulley as mentioned is flexibly connected to the chute, using multiple connecting rod component and cooling rack, the efficiency of the use of cooling rack is greatly improved, while manpower, material and time are saved; by using height control groove and pulley connecting rod, the height can be flexibly adjusted according to the use of the rack, and the operation is simple, it can easily be operated and used by one person.

A substrate processing system includes a multi-zone cooling apparatus to provide cooling for all or substantially all of a window in a substrate processing chamber. In one aspect, the apparatus includes one or more plenums to cover all or substantially all of a window in a substrate processing chamber, including under an energy source for transformer coupled plasma in the substrate processing chamber. One or more air amplifiers and accompanying conduits provide air to the one or more plenums to provide air flow to the window. The conduits are connected to plenum inlets at various distances from the center, to direct airflow throughout the window and thus address center hot, middle hot, and edge hot conditions, depending on the processes being carried out in the chamber. In one aspect, the one or more plenums include a central air inlet, to direct air toward the center portion of the window, to address center hot conditions.

A substrate processing system includes a multi-zone cooling apparatus to provide cooling for all or substantially all of a window in a substrate processing chamber. In one aspect, the apparatus includes one or more plenums to cover all or substantially all of a window in a substrate processing chamber, including under an energy source for transformer coupled plasma in the substrate processing chamber. One or more air amplifiers and accompanying conduits provide air to the one or more plenums to provide air flow to the window. The conduits are connected to plenum inlets at various distances from the center, to direct airflow throughout the window and thus address center hot, middle hot, and edge hot conditions, depending on the processes being carried out in the chamber. In one aspect, the one or more plenums include a central air inlet, to direct air toward the center portion of the window, to address center hot conditions.

A plenum, positioned beneath a first coil and above a window disposed on a top portion of a processing chamber, has side walls and a top surface covering an upper surface of the window and has a first air inlet positioned at a center portion to receive airflow from a first air amplifier. The first air inlet includes holes to distribute the air across the window within the side walls to reduce hotspots at a center portion of the window. The plenum includes a second air inlet at an edge portion of the top surface to receive the airflow from a second air amplifier to reduce hotspots at an edge portion of the window, and a third air inlet between the center and edge portions of the top surface to receive the airflow from a third air amplifier to reduce hotspots at a middle portion of the window.

A plenum, positioned beneath a first coil and above a window disposed on a top portion of a processing chamber, has side walls and a top surface covering an upper surface of the window and has a first air inlet positioned at a center portion to receive airflow from a first air amplifier. The first air inlet includes holes to distribute the air across the window within the side walls to reduce hotspots at a center portion of the window. The plenum includes a second air inlet at an edge portion of the top surface to receive the airflow from a second air amplifier to reduce hotspots at an edge portion of the window, and a third air inlet between the center and edge portions of the top surface to receive the airflow from a third air amplifier to reduce hotspots at a middle portion of the window.

A solar liquid-heating-and-cooling system (20) includes: 1. a hot-liquid storage-tank (22); 2. a hot-liquid manifold-tank (26); 3. a coaxial heating-and-cooling-tube (24) that connects downward from the hot-liquid storage-tank (22) to the hot-liquid manifold-tank (26); 4. a double layer heating-and-cooling collector-array-panel (32) located beneath the hot-liquid manifold-tank (26), the panel (32) including, connected to the hot-liquid manifold-tank (26): a. an upper layer of glazed heating-tubes (36); and b. a lower layer of unglazed cooling-tubes (56); 5. parabolic-trough mirror reflectors (64) that are located between the upper and lower layers of tubes (36, 56); 6. cold-liquid manifold-tank (92) located below the panel (32) connected to lower ends both of the glazed heating-tubes (36) and of the unglazed cooling-tubes (56); 7. a cold liquid storage tank (98); and 8. a coaxial heating-and-cooling-tube (96) that connects downward from the cold-liquid manifold-tank (92) to the cold liquid storage tank (98).