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Form Factor Operating System Processor Memory Hard Drive Optical Drive Floppy Warranty (Parts/Labor/Onsite) AntiVirus (60 Days) Office Ready Vpro Certification Monitor Promo Price (RM) Pro 4000 Pro 3330 - Gen I *While Stock Last A9H55PA#UUF * B4K22PA#UUF (Price Revised) Pro 3330 Elite 8200 *New B6T21PA#UUF B6T22PA#UUF B6B27PA#UUF B6T20PA#UUF B6T23PA#UUF B6T24PA#UUF (New Promo SKU) (New Promo SKU) (New Promo SKU) (New Promo SKU) (New Promo SKU) (New Promo SKU) B0V43PA#UUF B0V44PA#UUF B0V45PA#UUF Small Form Factor Microtower Microtower Microtower Microtower Microtower Microtower Microtower Convertible Minitower Small Form Factor Convertible Minitower Windows 7 Professional 32-bit Windows 7 Professional 64-bit Windows 7 Professional 32-bit Windows 7 Professional 64-bit Windows 7 Professional 64-bit Windows 7 Professional 64-bit Windows 7 Professional 64-bit Windows 7 Professional 64-bit Windows 7 Professional 64-bit Windows 7 Professional 64-bit Windows 7 Professional 64-bit A/P A/P Intel Pentium E6600 Intel Pentium G630 Intel Pentium G630 Intel Pentium G630 Intel Core i3-2120 Intel Core i3-2120 Intel Core i5-2320 Intel Core i5-2320 Intel Core i5-2500 Intel Core i5-2500 Intel Core i7-2600 Processor Processor Processor Processor Processor Processor Processor Processor Processor Processor Processor 2GB PC3-10600 Memory (1x2GB) 4-GB PC3-10600 Memory (1x4GB) 4-GB PC3-10600 Memory (1x4GB) 4-GB PC3-10600 Memory (1x4GB) 4-GB PC3-10600 Memory (1x4GB) 4-GB PC3-10600 Memory (1x4GB) 4GB PC3-10600 Memory (1x4GB) 4GB PC3-10600 Memory (1x4GB) 4GB PC3-10600 Memory (1x4GB) 500GB 7200RPM SATA-3G 1st HD SuperMulti DVDRW 1st No 500GB 7200RPM SATA 1st HardDrive HP SuperMulti (JB) 1st No 500GB 7200RPM SATA 1st HardDrive HP SuperMulti (JB) 1st No 500GB 7200RPM SATA 1st HardDrive HP SuperMulti (JB) 1st No 500GB 7200RPM SATA 1st HardDrive HP SuperMulti (JB) 1st No 500GB 7200RPM SATA 1st HardDrive HP SuperMulti (JB) 1st No 500GB 7200RPM SATA 1st HardDrive HP SuperMulti (JB) 1st No 500GB 7200RPM SATA 1st HardDrive HP SuperMulti (JB) 1st No 1TB 7200RPM SATA 6G 1st Hard Drive HP SuperMulti (JB) 1st ALL No 1TB 7200RPM SATA 6G 1st Hard Drive HP SuperMulti (JB) 1st ALL No 1TB 7200RPM SATA 6G 1st Hard Drive HP SuperMulti (JB) 1st ALL No 1.1.1 3.1.1 1.1.1 1.1.1 1.1.1 1.1.1 1.1.1 1.1.1 3.3.3 3.3.3 3.3.3 Yes Yes Microsoft Office 2010 Home &
8 The Shared-Processor Pool ....................................................................................................... ... 15 Multiple Shared-Processor Pools (MSPP) ............................................................................
Computer Parts Comparison Websites Index SSD Comparison Websites Graphics Card (GPU) Comparison Websites Processor (CPU) Comparison Websites Motherboard Comparison Websites Memory (RAM) Comparison Websites Hard Drive (HDD) Comparison Websites Power Supply (PSU) Comparison Websites SSD Comparison Websites User Benchmark:
http://www.princeton.com.tw Echo Processor IC PT2399 DESCRIPTION PT2399 is an echo audio processor IC utilizing CMOS Technology which is equipped with ADC and DAC, high sampling frequency and an internal memory of 44K Digital processing is used to generate the delay time, it also features an internal VCO circuit in the system clock, thereby, making the frequency easily adjustable.
• All the other components - RAM, disk drives, the monitor - exist only to bridge the gap between you and the processor.
Free delivery when you shop online at www.atljamaica.com 1-888-ATL-SERV 3 PREMIUM UHD 55” QLED 4K FLAT SMART TV • SUHD Dimming • Q Viewing Angle • Quad-Core Processor • Motion Rate 240 • Q Color $269,799 WKLY $4,836 QN55Q7FAMPXP 4 1-888-ATL-SERV Free delivery when you shop online at www.atljamaica.com ENTERTA INMENT | K I T C H E N | A I R C O N D I T I O N I N G | L A U N D RY | C O MME R C I A L K I T C H E N | C O MMERCIA L LA UNDRY 55” UHD 4K CURVED SMART TV • Motion Rate 120 • UHD Dimming • Active Crystal Color • Built-In-Wi-Fi $137,799 WKLY $2,470 UN55MU6500FX 49” FLAT UHD 4K SLIM SMART TV • PurColor • Built-In Wi-Fi • Quad-Core Processor $143,899 WKLY $2,581 UN49MU6400PX 40” LED 4K UHD $74,799 SMART TV WKLY $ 1,341 • PurColor • Quadcore • Smart Hub 65” UHD 4K CURVED SMART TV SERIES 6 • PurColor • Quad-Core Processor • Kant-M Platform • Built-In Wi-Fi UN40MU6100PX $231,199 WKLY $4,143 UN65MU6500FX Authorised under Section 58 (3) of The Betting, Gaming &
Summary When a processor reaches a conditional branch in code (e.g.
CALIFORNIA POLYTECHNIC STATE UNIVERSITY Alternative Fuels Laboratory BRAE 434 Spring Quarter 2016 Instructor: Art MacCarley Solar Waste Vegetable Oil Processor June 03, 2016 Andrew Hostler Steven Schwartz Chris Chavez Nathanael DeBruno Abstract Every year, countless gallons of vegetable oil are used in the foodservice industry to make many different kinds of food. This vegetable oil can find a second life in the form of biodiesel. Currently in Yellowstone National Park, a fleet of buses runs on BioDiesel. This allows them to reuse much of the food waste from their millions of tourists every year. Similarly, Cal Poly Corporation on the CPSU campus feeds 20,000 students for most of the year producing excess food waste. The BioDiesel filtration shed made for our class, EE 434, allows Cal Poly’s excess food waste to be put to good use. Students at Cal Poly can aquire french fry oil by the barrel from Cal Poly Corporation. This fuel is then processed for use in the Future Fuels Club’s multi fuel tractor. Introduction The following report is a detailed account of the design, procedure, and materials used to complete the solar WVO processor located in the alternative fuels shed at Cal Poly. The goal of this project was to further improve upon the work of students from previous quarters by automating the WVO conversion process. Equipment and Materials ½ inch PVC pipe ½ inch copper pipe ⅜ inch copper tubing ½ inch flexible tubing ½ inch brackets Coolant reservoir tank Screws and anchors Brass, copper, PVC fittings 24 to 12V buck converter Temperature sensors Switches Custom Arduino board Hammer drill and accessories Propane torch Design Requirements The main requirement of the project was to implement an easy to use control system for the processor. First, the control system needed to control the filtering system with the flip of a switch. This means this one switch would turn on the 12 volt pump, controlling the coolant loop, and the 24 volt scooter motor, controlling the WVO loop. The control system also needed to decide when to run the WVO loop which was dependent on the temperature of the coolant entering the coil of the WVO barrel. Finally the control system needed to shut the system off when the process was complete. Along with the control system, the project hardware needed to be brought up to code. Therefore, all the existing piping needed to be ripped out. The ¾ inch PVC, used for the coolant loop, that ran from the solar thermal array to the shed was to be replaced by ½ inch PVC. The flex cable used in the WVO loop that was placed outside of the shed was to replaced with ½ inch hard copper pipe. Then, the ½ inch PVC and copper piping was to enter through the window of the shed. Once the piping was inside the shed, flexible pipes could be implemented. Finally, the system was to be controlled using four batteries wired up to be a 24 volt supply. Procedure First, we ripped out all the existing piping. Then, we connected ½ pvc to the solar thermal array using two brass fittings and two PVC connectors. Making only 90 degree angles we connected all the PVC, using primer and glue for all connections, for the up and down coolant loop on the roof. We proceeded to feed the PVC through the window at a 90 degree angle, this was only possible with ½ inch piping, anything larger would not have fit through the window. Then, we connected the pushing coolant loop directly to the 12 volt pump with all ½ inch PVC pipe, no flex tubing. On the bottom end of the pump, we connected flex tubing which was placed in the coolant reservoir. The falling coolant loop was hard piped to near the 12 volt pump. From there we switched to the coolant flex pipe which was connected the copper coil inside of the barrel. At the bottom of the copper coil, flex tubing was fed into the coolant reservoir. This completed the coolant loop. Next, we worked on the copper pipe for the WVO loop. For reference, all connections were cleaned on the inside and outside of the copper pipe with the designated brush, then flux was applied on the outside of the pipes before soldering the copper connections. The copper pipe ran from the 24 volt pump out of the box, was ran to be flush with the wall, the two copper lines ran sidebyside up to and through the window. Then the copper pipe ran down to the wall inside the shed. From there, we connected the copper tubing. For testing purposes we left the copper tubing unconnected from the barrel so we could visually see the WVO loop worked properly without having to use the barrel for testing. This completed the WVO loop. After the piping was completed, we used the hammer drill to drill holes on the roof and on the walls of the shed, both inside and outside. The holes were filled with all purpose anchors, and ½ inch brackets were screwed into the anchors. Brackets were used on the roof to secure the PVC, on the outside wall to secure the copper piping,and inside to secure both the PVC and copper piping. Then, the 12 volt pump was screwed into anchors. Finally, the coolant reservoir was screwed into the anchors in the walls directly under the 12 volt pump. Finally, we built in an automated sensing and control system for the shed. This was built using an Arduino opensource software base, integrating the sensors to an AtMega328 processor. First, the custom printed circuit board was designed in CadSoft Eagle. This application is used by many businesses and hobbyists alike to create their own robust microcontroller systems. The board was then exported to a manufacturing set of files, and sent to Bay Area Circuits for fabrication. Next, the board was assembled and programmed. This board was modeled after the Arduino Duemilanove (2009), an early prototype of the Arduino Uno. As such, you could program the processor in an Arduino Uno for testing, the “pop” the chip into the board once fully programmed. This board controlled four lowside switches in parallel with the manual pump switches. Finally, the processor with the Arduino code was tested with the switches and various sensor readings on the two temperature sensors. If the Arduino code needs to be edited in the future, the arduino code is in Appendix A. Any student wishing to reprogram needs only to swap the processor chip with an Arduino Uno, program it with modified code from the appendix, then swap the chips back. Testing The WVO loop consisting of copper pipe, copper tubing, and the 24 volt scooter motor was ran for five minutes, using water, with no problems detected. The coolant loop was tested using the buck converter for the 12 volt pump. Multiple problems arose, the coolant reservoir used was not large enough to supply the whole loop with enough water to pump through the whole system. We ran the system until the coolant reservoir was depleted and shut the pump off. While waiting for the water to return to the reservoir, the water returning to the reservoir was steaming. As we watched this process, the PVC pipe inside the shed was beginning to droop. The PVC pipe made its own 90 degree angle because the water that made it to the solar thermal array became too hot for the PVC to handle. We waited for the PVC to cool down and we tested it again. This time we used a larger bucket so there was enough water to fill the coolant loop. We ran this loop for ten minutes and by the end of it the PVC inside the shed on the return loop had drooped down about an inch. Therefore, the WVO loop and coolant loop work as planned;however, the PVC pipe just can’t handle the heat of the system. Conclusion While the system runs currently, further improvements still need to be made. Firstly, the PVC pipe used is not adequate for the near boiling water coming out of the solar array. Additionally, there needs to be a better way to transport oil to and from the processing barrel.
Package 1 Package 2 Package 3 Package 4 Package 5 Code RMG3220 TWRI36100 AMI54440 SYSI54670K GTI7354770K Processor Model Intel Pentium G3220 Intel Core i3 6100 Intel Core i5 4440 Intel Core i5 4670K Intel Core i7 4770K Processor Speed Dual Core 3.0GHZ 3MB 3.7GHz, 3MB 3.1GHz, 6MB 3.4GHz, 6MB 3.4GHz;
WAVE PROCESSOR 9335 Recorders Display, Convert, Calculate, and Print Waveforms with a PC Use Windows application software to display, convert, calculate and print large volumes of waveform data on a PC 8855 The WAVE PROCESSOR 9335 is application software for Windows that enables users to display, print, convert, and calculate on large volumes of waveform data that has been recorded and collected by instruments in the MEMORY HiCORDER Series.
list directive to define processor #include <p12f675.inc>
ZDD204A, ZDD208A, ZDD216A 4/8/16 Channel Compact 1U Digital Recorder 4/8/16 ChannelPenta-brid MHD 1080720P Intelligent Digital VideoVideo Recorder Features · Embedded processor · H.264+/H.264 video compression · Support HDCVI/CVBS/HDTVI/AHD video inputs · Max 6/12/24 channels IP camera inputs, each channel up to 5MP · Max 24/48/96Mbps Incoming Bandwidth · Smart Search and Intelligent Video System Technical Speci Audio and Video System HDCVI Camera Input 4/8/16 Channel Main Processor Embedded Processor IP Camera Input 4+2/8+4/16+8 Channel, each channel up to 5MP OperĂƟng System Embedded LINUX Audio In/Out 1/1 Two-way Talk 1 Channel Input, 1 Channel Output, RCA Display Interface 1 HDMI ,1 VGA Recording ResoluƟon 1920×1080, 1280×1024, 1280×720, 1024×768 Compression H.264+/H.264 MulƟ-screen Display 4CH:
$193,757.00 Selection Summary Barebone Intel® C612 Chipset - 24x SATA/SAS - Dual Intel® 1-Gigabit Ethernet (RJ45) - FDR InfiniBand (QSFP) - 2000W Redundant Power Processor 8 x Twenty-Two-Core Intel® Xeon® Processor E5-2699A v4 2.40GHz 55MB Cache (145W) Memory 64 x 64GB PC4-19200 2400MHz DDR4 ECC Registered Load-Reduced DIMM Boot Drive 128GB SATA 6.0Gb/s Disk on Module (MLC) (Vertical) Hard Drive 24 x 7.68TB Micron 5100 ECO 2.5"
DELUXE ESPRESSO MAKER BLACK ESPRESSO MAKER WITH PUMP UL FOOD PROCESSOR 500W UL UL HAND BLENDER, 150 W BLACK UL HAND MIXER, 120 W, 2 BEATERS HAND MIXER SS 6 SPEEDS HAND/STAND MIXER SS BOWL ETL 2 2,322 1,000 800 4 2 3,080 1,960 1,500 6 3,744 40HQ AMBIENTI 3,000 16 12,896 SMALL APPLIANCES UL ETL ETL IRONS PIV7147 PIV7157 PIV7167 PIV7177 1,800 SMALL APPLIANCES HAND MIXERS PHM425 PHM427 PHSM466 40HQ 40HQ 40HQ SMALL APPLIANCES HAND BLENDER PHB315 12,500 7,200 4,200 SMALL APPLIANCES FOOD PROCESSOR PFP500 8 6 4 SMALL APPLIANCES ESPRESSO MAKER PEM585 PEM615P 1,200 1,200 1,200 3,000 3,000 1,500 12 6 6 7,200 13,248 3,948 AMBIENTI SMALL APPLIANCES STEAM / DRY IRON, NON STICK, SPRAY FULL SIZE STEAM IRON,NON STICK, SPRAY DELUXE IRON STAINLESS STEEL SOLEPLATE STEAM IRON RETRACTABLE CORD, NON STICK ETL ETL ETL ETL 2,000 2,000 2,000 3,900 10 10 10 10 13,900 8,530 8,330 3,350 40HQ 40HQ 40HQ 20FT PREMIUM COSTS 2015 1-Oct-14 MODEL DESCRIPTION UL / ETL MEAT SLICER PMFS688 MEAT FOOD SLICER MINI FOOD PROCESSOR 100 W ETL PANINI MAKER CONTAINER QTY NOTES 700 2 1,600 40HQ AMBIENTI $ 33.00 $ 6.00 $ 19.00 SMALL APPLIANCES UL PANINI MAKER PPN17 MASTER CTN AJR Price FOB Miami (Dead Net) SMALL APPLIANCES MINI CHOPPERS PMC156 MOQ CONTAINER SIZE 5,000 12 18,000 40HQ SMALL APPLIANCES ETL 1,440 4 1,440 20FT AMBIENTI CE 3,000 20 9,920 40HQ $ 5.50 40HQ 40HQ 40HQ 40HQ AMBIENTI $ $ $ $ 15.00 18.00 21.00 39.00 AMBIENTI AMBIENTI $ $ $ $ $ 9.00 10.50 14.00 13.00 19.00 7.00 17.00 7.00 7.50 PERSONAL CARE PWS103 DIGITAL WEIGHT SCALE - GLASS PRESSURE COOKERS PPC1047 PPC1077 PPC1097 PPC1057E PRESSURE COOKER 4LT PRESSURE COOKER 7LT PRESSURE COOKER 9LT PRESSURE COOKER ELECTRIC 5LT S.S.