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Listings as of Market Analysis Summary October 3, 2014 9:03 am Residential Sold # MLS # 1 A4101309 34219 11515 84Th COPPER Street E #102 STONE PH I M5842311 34219 11510 84Th COPPER Street E #104 STONE PH I A3992795 34219 11523 84Th COPPER Street E #104 STONE PH I T2702564 34219 11559 84Th COPPER Street E #105 STONE PH I M5900574 34219 11563 84Th COPPER Street E #106 STONE PH I M5844396 34219 11506 84Th COPPER Street E #106 STONE PH I M5900158 34219 11559 84Th COPPER Street E #101 STONE PH I M5843436 34219 11571 84Th COPPER Street E #101 STONE PH I M5846274 34219 7927 113Th COPPER Avenue E STONE PH I O5228750 34219 8119 112Th E COPPER STONE PH I T2602223 34219 7709 111Th E COPPER STONE PH 2 A4101809 34219 11245 82Nd COPPER E STONE PH I 2 3 4 5 6 7 8 9 10 11 12 Zip Address Subdiv WF WV WA WE Pool Gar P Style BR FB HB HSqFt LP/HSqFt List Price Sold Price SP/HSqFt Sold Dt LP/SP ADOM CDOM N Y N N Comm unity 1 Car Townho Garage use 3 2 1 1,396 $98 $136,900 $133,000 $95 09/12/14 0.97 19 19 N N N N Comm unity 1 Car Townho Garage use 3 2 1 1,396 $104 $145,000 $138,000 $99 05/05/14 0.95 91 91 N N N N Comm unity 1 Car Townho Garage use 3 2 1 1,396 $102 $141,900 $140,000 $100 08/29/14 0.99 166 166 N N N N Comm unity 1 Car Townho Garage use 3 3 0 1,375 $109 $149,900 $144,000 $105 09/26/14 0.96 10 10 N N N N Comm unity 2 Car Townho Garage use 3 2 1 1,375 $109 $149,900 $148,000 $108 09/15/14 0.99 32 32 Y Y N N Comm unity 2 Car Townho Garage use 3 2 1 1,551 $106 $164,900 $155,000 $100 05/27/14 0.94 83 83 N N N N Comm unity 2 Car Townho Garage use 3 2 1 1,551 $103 $159,900 $155,223 $100 09/25/14 0.97 50 50 N N N N Comm unity 1 Car Townho Garage use 3 2 1 1,700 $103 $175,500 $164,000 $96 07/15/14 0.93 111 157 Y Y Y N Comm unity 3 2 0 1,510 $122 $184,900 $185,000 $123 06/27/14 1.00 13 13 Y Y Y N Comm unity 3 2 0 1,511 $125 $189,000 $186,000 $123 08/12/14 0.98 84 84 N N N N Comm unity 3 2 0 1,481 $132 $194,990 $187,000 $126 04/15/14 0.96 114 114 N Y N N Comm unity 2 Car Single Garage Family Home 2 Car Single Garage Family Home 2 Car Single Garage Family Home 2 Car Single Garage Family Home 3 2 0 1,489 $124 $184,900 $189,000 $127 09/05/14 1.02 7 7 Presented By:
COPPER TAP WITH EVERY SINK SOLD DURING THE SALE Free Tap with any Sink Purchase Traditional single lever mixer with porcelain handle RRP $986 Limited Availability - Final Week flyer.html[21/02/2017 1:30:29 PM] *|MC:SUBJECT|* Copper Butler Sink Copper Farmhouse Sink Sizes:
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.
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DS-SFP-FC8G-SW-LEG Cisco DS-SFP-FC8G-SW Compatible 2/4/8Gbs Fibre Channel SW SFP+ Transceiver (MMF, 850nm, 150m, LC) DS-SFP-FC8G-SW GLC-BX-D-LEG Cisco GLC-BX-D Compatible 1000Base-BX SFP Transceiver (SMF, 1490nmTx/1310nmRx, 10km, LC, DOM) GLC-BX-D GLC-BX-U-LEG Cisco GLC-BX-U Compatible 1000Base-BX SFP Transceiver (SMF, 1310nmTx/1490nmRx, 10km, LC, DOM) GLC-BX-U GLC-EX-SMD-LEG Cisco GLC-EX-SMD Compatible 1000Base-EX SFP Transceiver (SMF, 1310nm, 40km, LC, DOM) GLC-EX-SMD GLC-FE-100FX-LEG Cisco GLC-FE-100FX Compatible 100Base-FX SFP Transceiver (MMF, 1310nm, 2km, LC) GLC-FE-100FX GLC-FE-100FXRGDLEG Cisco GLC-FE-100FX-RGD Compatible 100Base-FX SFP Transceiver (MMF, 1310nm, 2km, LC, Rugged) GLC-FE-100FX-RGD GLC-FE-100LX-LEG Cisco GLC-FE-100LX Compatible 100Base-LX SFP Transceiver (SMF, 1310nm, 10km, LC) GLC-FE-100LX GLC-GE-100FX-LEG Cisco GLC-GE-100FX Compatible 100Base-FX SFP Transceiver (MMF, 1310nm, 2km, LC) GLC-GE-100FX GLC-LH-SM-LEG Cisco GLC-LH-SM Compatible 1000Base-LX SFP Transceiver (SMF, 1310nm, 10km, LC) GLC-LH-SM GLC-LH-SMD-LEG Cisco GLC-LH-SMD Compatible 1000Base-LX SFP Transceiver (SMF, 1310nm, 10km, LC, DOM) GLC-LH-SMD GLC-LX-SM-RGD-LEG Cisco GLC-LX-SM-RGD Compatible 1000Base-LX SFP Transceiver (SMF, 1310nm, 10km, LC, DOM, Rugged) GLC-LX-SM-RGD GLC-SX-MM TAA-LEG Cisco GLC-SX-MM Compatible 1000Base-SX MMF SFP (mini-GBIC) Transceiver Module, TAA Compliant GLC-SX-MM TAA GLC-SX-MM-LEG Cisco GLC-SX-MM Compatible 1000Base-SX SFP Transceiver (MMF, 850nm, 550m, LC) GLC-SX-MM GLC-SX-MMD-LEG Cisco GLC-SX-MMD Compatible 1000Base-SX SFP Transceiver (MMF, 850nm, 550m, LC, DOM) GLC-SX-MMD GLC-SX-MM-RGD-LEG Cisco GLC-SX-MM-RGD Compatible 1000Base-SX SFP Transceiver (MMF, 850nm, 550m, LC, DOM, Rugged) GLC-SX-MM-RGD GLC-T-LEG Cisco GLC-T Compatible 1000Base-TX SFP Transceiver (Copper, 100m, RJ-45) GLC-T GLC-ZX-SM-LEG Cisco GLC-ZX-SM Compatible 1000Base-ZX SFP Transceiver (SMF, 1550nm, 80km, LC) GLC-ZX-SM ONS-SI-GE-SX-LEG Cisco ONS-SI-GE-SX Compatible 1000Base-SX SFP Transceiver (MMF, 850nm, 550m, LC, DOM, Rugged) ONS-SI-GE-SX QSFP-40G-SR4-LEG Cisco QSFP-40G-SR4 Compatible 40GBase-SR QSFP+ Transceiver (MMF, 850nm, 150m, MPO, DOM) QSFP-40G-SR4 SFP-10G-ER-LEG Cisco SFP-10G-ER Compatible 10GBase-ER SFP+ Transceiver (SMF, 1550nm, 40km, LC, DOM) SFP-10G-ER SFP-10G-LR-LEG Cisco SFP-10G-LR Compatible 10GBase-LR SFP+ Transceiver (SMF, 1310nm, 10km, LC, DOM) SFP-10G-LR SFP-10G-LRM-LEG Cisco SFP-10G-LRM Compatible 10GBase-LRM SFP+ Transceiver (MMF, 1310nm, 220m, LC, DOM) SFP-10G-LRM SFP-10G-SR-LEG Cisco SFP-10G-SR Compatible 10GBase-SR SFP+ Transceiver (MMF, 850nm, 300m, LC, DOM) SFP-10G-SR SFP-1GB-SX-LEG Cisco SFP-1GB-SX Compatible 1000Base-SX SFP Transceiver (MMF, 850nm, 550m, LC, DOM) SFP-1GB-SX SFP-GE-L-LEG Cisco SFP-GE-L Compatible 1000Base-LX SFP Transceiver (SMF, 1310nm, 10km, LC, DOM) SFP-GE-L SFP-GE-S-LEG Cisco SFP-GE-S Compatible 1000Base-SX SFP Transceiver (MMF, 850nm, 550m, LC, DOM) SFP-GE-S SFP-GE-T-LEG Cisco SFP-GE-T Compatible 1000Base-TX SFP Transceiver (Copper, 100m, RJ-45) SFP-GE-T WS-G5483-LEG Cisco WS-G5483 Compatible 1000Base-TX GBIC Transceiver (Copper, 100m, RJ-45) WS-G5483 WS-G5484-LEG Cisco WS-G5484 Compatible 1000Base-SX GBIC Transceiver (MMF, 850nm, 550m, SC) WS-G5484 WS-G5486-LEG Cisco WS-G5486 Compatible 1000Base-LX GBIC Transceiver (SMF, 1310nm, 10km, SC) WS-G5486 X2-10GB-LR-LEG Cisco X2-10GB-LR Compatible 10GBase-LR X2 Transceiver (SMF, 1310nm, 10km, SC, DOM) X2-10GB-LR X2-10GB-SR-LEG Cisco X2-10GB-SR Compatible 10GBase-SR X2 Transceiver (MMF, 850nm, 300m, SC, DOM) X2-10GB-SR XENPAK-10GB-SR-LEG Cisco XENPAK-10GB-SR Compatible 10GBase-SR XENPAK Transceiver (MMF, 850nm, 300m, SC) XENPAK-10GB-SR XFP10GLR-192SRLLEG Cisco XFP10GLR-192SR-L Compatible 10GBase-LR XFP Transceiver (SMF, 1310nm, 10km, LC, DOM) XFP10GLR-192SR-L XFP-10G-MM-SR-LEG Cisco XFP-10G-MM-SR Compatible 10GBase-SR XFP Transceiver (MMF, 850nm, 300m, LC, DOM) XFP-10G-MM-SR designed to be better.™ TRANSCEIVERS COMPATIBILITY CROSS REFERENCE HP® LEGRAND® PART NO.
SP Angel – Morning View – Tuesday 31 10 17 Copper is little changed despite weakening Chinese PMIs MiFID II - This note will move to FULL MiFID II compliant format come 3 January 2018 If you wish your company to be compliant so we can continue to write lovely things about you then please contact me If you don’t like what we write about your company, don’t worry, we will continue to write but it will be in a new MIFID 2 compliant format which is designed to make institutional investors pay for the insightful analysis which we provide.
BO08C28S1 SFP 1.25G RJ45 100M RoHS Compliant Copper Transceiver SFP 1.25G Copper RJ45 Transceiver Features Description The BlueOptics© BO08C28S1 SFP transceiver is a high performance, cost effective module supporting a data rate up to 1.25Gbps with 100 Meter link length on twisted pair Cat5E cable.
BO08C38S1 SFP 10/100/1000M RJ45 100 Meter RoHS Compliant Copper Transceiver SFP 10/100/1000Mbit Copper RJ45 Transceiver Features Description The BlueOptics© BO08C38S1 SFP transceiver is a high performance, cost effective module supporting a data rate up to 1.25Gbps with 100 Meter link length on twisted pair Cat5E cable.
Copper-based nitroimidazole complexes Copper has two main oxidation states, Cu(I) (Cu1+) and Cu(II) (Cu2+), and a relatively rare Cu(III) (Cu3+) state .
Dave Johannesen/Don Gehrls 2&1 Scr a mb le - La r ges t M a r gin of Victor y Tea m Scor e N/A Y ea r - Cou r s e 2015 - Jester Park 2015 - Jester Park Y ea r - Cou r s e I ndividu a l M a tch P la y - La r ges t M a r gin of Victor y I ndividu a l Scor e Y ea r - Cou r s e Don Gehrls defeats Alex Broderik 6&5 2015 - Tournament Club of Iowa Don Gehrls defeats Carson Tigges 6&4 2015 - Copper Creek Garrett Marshall defeats Matt Adamson 5&4 2015 - Tournament Club of Iowa Ryan Wies defeats Carson Tigges 5&4 2015 - Tournament Club of Iowa Alex Broderick defeats Ryan Wies 4&3 2015 - Copper Creek Matt Adamson defeats David Johannesen 3&2 2015 - Copper Creek Alex Ganske defeats Garrett Marshall 1-up 2015 - Copper Creek 1.
Stainless steel coil drapery Copper coil drapery Brass coil drapery BOEGGER Specifications ＆ Size ◆ BOEGGER Real measurement figure ●Material:
Gold, silver and other ores have been mined in Arizona for more than a century, but the state’s real claim to fame is copper.
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Magnetic heater inspired by energy www.emolio.com/MagneticHeater This is FREE document with much less informations and without technical drawings. For FULL document with technical drawings go to http://www.emolio.com/MagneticHeater This is FREE document with NO much details, like technical (CAD) drawings. For FULL document with technical drawings go to http://www.emolio.com/MagneticHeater Magnetic heater description The magnetic system is a multifunctional system designed for central heating. This means that it can be adapted to existing central heating systems, as well as different applications. One of the ways the system works is that it heats the water that heats your home. The other option is to heat thermal oil, which then heats the water in the buffer which then heats your home. It is the choice of the user, we must specify that the option of heating the thermal oil brings greater efficiency in spending the energy. The magnetic system is based on the principle of natural law (Lentz law) copper as non ferro metal reacts to magnetic induction by creating heat. This principle has long been used in the auto industry as well as on certain appliances such as air conditioners. Magnetic heating in this application is a new design (construction) for implementing lowenergyuse heating systems. The purpose of this document is to use this opportunity (open source) to share, help and encourage consumers to make their own magnetic system, which compared to others is the most effective heating of modern times. We have to state that you need professional help in the construction of the magnetic system. From us you can expect such support, information, training courses, books, parts as well as a complete magnetic heating machine. In our case it is handwork rather than mass production and all profit goes to developing this or any other energy systems that helps you as consumer to use less energy. The durability of the device is only limited to the replacement of certain parts (such as an electric motor), the durability of the other parts is very longterm. The basic machine is running smoothly with minimal maintenance. It is important to note that the current model of magnetic heating works on a threephase electrical energy motor, and that future systems will be adapted to single phase electromotor. The device is a noncomplicated magnetic heating device which has a steel construction to support all parts such as an electric motor (with a difference of power from 1 to 5 kw / h), aluminium disk, magnets, copper cauldrons and the necessary electronics that regulate the turning on and off and it is connected to a thermostat that measures the temperature of water or thermal oil. The principle of operation is based on magnetic induction, so the electric motor runs the aluminum disk in which a number of magnets has been integrated. The field of magnetic induction is created when the disk reaches a certain speed and the copper reacts on that with heating up. So the copper cauldron heats up due to the magnetic induction and the heat is transferred to water or thermal oil (as already stated in the document). The principle of operation is simple and all of the energy used is by electric motors. Use and efficiency of magnetic heating depends on the existing central heating system where you place the magnetic heating, as well as the square footage of space that is heated. The entire unit of the magnetic heating system runs on low power consumption and can be customized, for instance by adapting the distance between the disk with magnets and the copper cauldron. A larger distance, calls for less power consumption. The user can customize the temperature in relation to personal wishes as to minimal and maximal temperature in the home. Compared to existing systems, magnetic heating uses a minimal amount of electricity and is very efficient when it comes to saving electricity. In addition, please note that the magnetic heater does not require additional maintenance such as cleaning, neither does it create emission of CO2. In other words, the system is 100% functional with minimal maintenance costs and high financial benefits due to the lower electrical inputs . For more details about everything read on ... This is FREE document with NO much details, like technical (CAD) drawings. For FULL document with technical drawings go to http://www.emolio.com/MagneticHeater Foreword My personal experience I gained after purchasing our house (240 square meters) in which there was a warming system based on oil fuel. I want to use this opportunity to show you that choosing to install the magnetic heater pays off in one year.; The seller of the house informed us that 2,000 liters of heating oil on an annual basis would be enough to heat the house, but already the first winter season I realized that the heating needs more than double of that. Faced with this fact I reviewed all existing systems and came to the conclusion that it would be profitable to try to make a magnetic system that could reduce the consumption with at least 70%. An additional advantage, and in my opinion an important one, is that the magnetic system is much more healthy than using oil or gas. And so it all began … In the beginning it took me a long time to understand in what way I should address the basic issues, my experiments have led to the development of this heating unit. My search has resulted in a product that is ready for use and is currently the most efficient. Just to mention some of the main points / problems I encountered: copper parts should be professionally welded and safe to withstand the pressure of minimum 3 bar / the copper part that I use can work at 8 bar, finding out what electric motor (kw/h) is best for a certain output in relation to either heating water or thermal oil magnets should be placed under the rules of north / south and alternately, Disk needs to be precise the distance between the disk and the boiler is adjustable, and the same is dependent consumption, etc ... These are all points that you need to pay attention to when making or setting up the system. It is important to call for the support of a professional plumber and electro technician. For all your questions you can contact me … Everything has a beginning and an end, but this project has been one of which I am very glad that despite all the attempts we have managed to make a magnetic heater. And I hope that others will learn from my experience, therefore, do not have to start from scratch, will experience less failures and achieve greater efficiency. In this era of innovation, energy saving is increasingly represented as a major theme. Outdated technologies are replaced with new systems that are adapted depending on the existing suppliers. Users, understandably, are interested in whether an investment will be profitable and worthwhile. We are proud to say that the magnetic heating system is reliable and economical on the long run, plus easy to install and maintain. We can, from personal experience, say that the magnetic system meets all the requirements expected of modern technology era. We have already had our investment paid back, and each new winter is saving on heating. The system is installed by using the existing hot and cold water pipes. (I like to mention that it is profitable to think about changing to floor and/or wall heating instead of using radiators) , builtin electronics regulate automatic switching the motor on and off which helps save energy. in addition it is an builtin security that the system will not overheat. There is no need for maintenance and cleaning, nor is there exhaust gas in the house. In short we are satisfied, and we want you the have the same experience....
TDV Special Alert: Cascadero Copper (CCD.V) Ed Bugos, TDV Senior Analyst April 29, 2016 Cascadero Copper Corporation, Initiation Symbol: CCD: TSXV Shares Issued: 151,692,528 o/s, 188,521,694 f/d Last Trade: $0.05 CDN Yahoo Finance Quote/Chart/News Buy Cascadero Copper (CCD:TSXV) Below $0.10 we are adding CCD to the TDV portfolio today Dear subscriber, I am very excited to bring you this opportunity. It has been a while since I’ve felt so passionately bullish about anything in the speculative end of the exploration and mining markets. But the time is nigh for this story in particular for reasons that will become clear when you read more. Cascadero Copper is a special high risk and high reward situation. Although, the risk side is not nearly as stacked as as it would be for a typical exploration company because the flagship asset in Cascadero’s case (the Taron deposit) has already been discovered, and enough information is known to significantly reduce the uncertainty that accompanies an exploration stage company. Still, since it is not a going concern, and much work is required to prove the asset’s economic viability, we advise that you treat these shares as you would other speculative companies whose survival is reliant on their ability to fund the project. Ultimately, Cascadero’s survival does not depend solely on the state of the market even though those prospects are improving. It has enough assets to be able to rationalize and sell some in order to fund development of the current flagship (i.e., most advanced) asset: Taron, a completely new form of Cesium deposit. The investment offers a rare opportunity to gain from a coming supply shock in the production of the rare metal (Cesium), which is the primary element in Cascadero’s Taron, and the rerating of the shares as it develops the resource and completes an economic study. Taron is the only primary source of Cesium in the world large enough to fill the supply vacuum that has arrived. The cost of developing this asset (proving it up) is relatively low at around $2 million, and can be accomplished within a year. There are a number of large specialty chemical, plastics, and oil drilling companies that need the compounds Cesium can provide, and are watching with keen interest. Cascadero has signed confidentiality agreements with some of them already. I believe the asset is ultimately going to be worth between $200 and $500 million, assuming no other significant primary source of Cesium is found and developed sooner, and assuming they can establish its economic parameters under the preliminary economic assessment planned for later this year (after an indicated resource has been established with further drilling). If we are right that is a potential C$1 or C$2 per share target price over a one or two year time frame. Those kind of gains don’t happen overnight. They will take time and work to realize. Nevertheless, as you will see, there is even more meat to the story and several other properties that the company intends to explore, including five gold and silver projects. And you are getting in almost at the ground floor. As a bit of disclosure, I have been accumulating shares in this stock since 2014 from 3 to 5 cents, early in its restructuring, when it still had a lot of fleas and we weren’t sure it would survive. We have also earned options to buy more shares at 5c in exchange for advising the company on its restructuring and capital plan. I am biased and I believe in the deal. It was previously too risky for subscribers. In fact, we almost lost everything when the BC Securities Commission took it off the exchange in October. It took the company several months of pain to get reinstated, which just happened last month. It is a great story and not many people know about it yet even fewer understand it but please do not chase the stock past 10 cents per share for now. There will be more liquidity as time goes on but on the first day or two of this report the buying may be lopsided. If you chase it over ten cents chances are you will only be outbidding each other. The value is there but it will take some corporate development to realize it and I don’t think the shares can support a market cap that is too high until work on the properties starts. Finally, for accredited investors, there may be an opportunity to acquire shares directly from the company’s treasury at this price, with a warrant, as part of a capital raise that it is likely to announce. I will keep you posted but if you are accredited and are interested in the future financing of this company, let me know personally at firstname.lastname@example.org Summary of the Investment Features >> One of the world’s rarest metals Cesium (Cs) is in play as the world’s predominant source of supply to 85% of the market (Tanco mine) is likely almost depleted , and has recently been shut down over geotechnical and environmental issues. The mine has chosen to ration availability of cesium products to select consumers, and the industry may be headed for a supply shock. While above ground stockpiles still remain at the Tanco mine, no other large sources of Cesium exist around the globe capable of sustaining the presently growing demand other than the Taron deposit being developed by Cascadero Copper. Cascadero offers the only pure play on this story . >> The demand for Cesium compounds has been growing for two decades, but new applications are being discovered at an increasing rate . The most marketable compound is Cesium Formate, an environmentally friendly brine with stable viscosity at high temperatures and pressures used by oil & gas drillers to control reservoir back pressure and complete wells. >> in 2004, Cascadero Copper, discovered the Taron deposit, a completely unique (i.e., newly recognized) style of Cs deposit in Salta, Argentina; a sediment hosted epithermal polymetallic deposit containing significant quantities of Cesium, Thallium, Arsenic and Manganese, with subordinate values of copper, zinc, silver, barium, cobalt, lithium, and rubidium. Based on data from 7 core holes drilled in 2009 and thousands of metres of trenching and assays Cascadero management believes Taron is one of the largest known accumulations of Cesium on the planet. Importantly, it is a completely newly discovered way that Cesium is found to form. A huge milestone in itself. >> The extraction method for the Cesium compounds is patentable . On January 29th, 2016 Cascadero Copper Corporation applied for a United States Provisional Patent Application No.62/288,884 Filed January 29, 2016. "RECOVERY OF CESIUM FROM EPITHERMAL MINERAL DEPOSITS". If anyone discovers this type of Cesium deposit in the future within the jurisdictions that Cascadero’s patent is filed they will have to negotiate a use of recovery process with Cascadero involved. >> Cascadero plans to drill out a 1020 million tonne maiden resource (~50 holes) , complete a preliminary economic assessment (PEA), and to carry out a sampling and mapping program at five of its best 100% owned silver targets in Argentina at a cost of less than $2 million in 2016. >> Taron possesses several potential advantages in mining over its predecessor and only other competing mine: Tanco . Taron is open pittable while the Tanco mine (owned by Cabot Corp in Manitoba) is underground and under a lake. An underground operation involves sinking shafts and raises. Getting to the ore at Tanco requires drilling, blasting and tramming it from hard rock 60 metres below a lake. The remaining pillars at the Tanco mine are in question after 20 years of mining. Continued mining there has increasingly drawn environmentalist protests . Conversely, the Taron deposit sits atop a hill with minimal stripping required to extract the minerals. >> Metallurgical work conducted by UBC staff on Taron drill core samples demonstrated a high degree of confidence that the mineral and compounds can be extracted efficiently and cheaply. >> Several large conglomerates in the specialty chemicals and brines industries, which have been consolidating, have shown an interest in Taron and signed confidentiality agreements with Cascadero in order to share information. Cascadero has sent one a 28 kg sample of ore to confirm the results of metallurgical studies undertaken by Cascadero and the University of BC. >> Possibility of limited dilution going forward if First Quantum (FM) buys the La Sarita group of nine Au/Ag/Cu properties that have mineral potential, in which FM already has a 50% interest in two properties with Cascadero holding 50%, and a 100% interest in five properties. In addition to the mineral potential of the La Sarita group, which adjoins Taca Taca to the west, that Cascadero’s management believes is strategic to the development of First Quantum’s billion dollar Taca Taca base metal deposit in Argentina. In theory, Cascadero could get through its resource calculation and PEA on a very small financing given the existence of nearly 40 million options and warrants exercisable from 5 10 cents (approx. $2 million worth). However, the La Sarita properties, while prospective, are not core for Cascadero, and could be sold to First Quantum, ensuring that the company’s development needs are funded for some time going forward. >> Most of the company’s properties are located in Argentina , previously impoverished by the corrupt socialistperonist policies of the former government under Cristina Kirchner. Argentina’s new government has already scrapped the foreign exchange controls, which were crushing its farmers and other export oriented sectors, freed up trade again, fired a bunch of soul sucking bureaucrats, and is trying to liberalize energy prices and reverse capital controls to make the place attractive for foreign investment again. For almost a decade the previous government had sucked the life out of the nation’s economy, and when the resource bust came it devastated the prospects for many companies and businesses, including those of Cascadero Copper’s. It is one of the many factors behind the company’s fall in value after 2008, and especially after 2012. >> In Argentina, Cascadero subsidiaries are the registered owner of a 100% interest in 20 properties (47,692 Has); a 50% interest in two (2) properties (2,300 Has); and, a 33 1/3% interest in two (2) properties for a total of 24 properties. Cascadero also holds a 49% working interest in the Toodoggone property in central British Columbia (Canada) joint ventured with the Gold Fields Ltd. In addition to developing its flagship Taron Cesium deposit, Cascadero intends to map and sample three (3) of its goldsilver properties in the next few months. >> The 3 year long corporate restructuring is almost complete . The company was able to separate interests on all properties joint ventured with its previous Brazilian partner, which was unable to satisfy the requirements of its partnership in part owing to the downturn in the commodity and resource sector following 2012. This part of the restructuring took almost two and a half years. The second part of the restructuring resulted in the arrival of a new joint venture partner (Regberg Ltd.) for a 25% beneficial interest in the Taron project (i.e., SESA LLC) for an advance of $850,000 (plus the right to acquire an additional 5% for $175,000). >> While valuation is still speculative, based on Cabot Corp’s (the Tanco mine’s owner) financial statements and other information we can impute annual revenues of at least $100 million , and imagine a net present value somewhere north of that figure (the average S&P 500 company trades at 1.8 times sales these days), leaving lots of reward in relation to the risk at the present market capitalization of C$8 million (plus C$2 million in enterprise value including options and warrants). This excludes the Company’s many other prospects in Argentina or BC, the realizable value of its La Sarita group of properties, as well as the value of its patent on Cesium extraction. >> Catalysts include the completion of its restructuring (followed by a financing to develop its flagship Cesium asset: Taron), the shutting down of the Tanco mine in Manitoba that supplies 8090 percent of the market’s current needs for Cesium, the new government in Argentina, and a new resource cycle. The timing to develop these assets has rarely been better, and the time to buy this stock is unique as the market does not yet know about the Cesium story and still sees Cascadero as a defunct former prospect generator that has joined the TSX’s list of zombies. Management
--Instructions-1- Remove stock gpu and ram thermal pads and clean off any stock thermal paste 2- Use the sandpaper to polish copper contacts on the gpu and to remove gpu die print if desired 3- Apply thermal paste to the gpu copper contact on the heatsink 4- Install the shim in the corner of the copper contact exactly as shown in the picture 4- Place a thermal pad on each ram chip 5- Apply thermal paste to the gpu and cpu 6- Install the heatsink
Copper Millberry We the End Buyer INTER ASIA SEA TRADES PTE LTD hereby confirm with full corporate responsibility under penalty of perjury state that we are ready to purchase Copper Millberry wire scrap under the following terms and conditions here in:Commodity :
1/22/2017 Cascadero Copper Corporation Argentina Taron Cesium Project Sat Jan 21, 2017 TARON OUTCROP PHOTO LOOKING SOUTH EAST THE OUTCROP AREA SHOWN IS ONLY A FRACTION OF THE DEPOSIT AND SHOWS A RELIEF OF 70 METRES FOR SCALE. THE WHITE SPOTS SEEN AT THE MIDLATITUDE ARE GRAZING SHEEP.
The primary and most well-known conflict is over the copper deposits located under the forest reserve in the community of Junín, in the parish1 of Garcia Moreno.