Sc6 2 setup

Manuals Brands Stober Manuals Controller SC6A062 Manuals and User Guides for Stober SC6A062. We have 3 Stober SC6A062 manuals available for free PDF download: Manual, Commissioning Instructions Stober SC6A062 Manual (219 pages) Drive controller Brand: Stober | Category: Controller | Size: 7.75 MB Table of Contents Sc6 Drive Controller Manual 2 Table of Contents2 1 Foreword 8 2 User Information 9 Storage and Transfer9 Described Product Type9 Timeliness9 Original Language9 Limitation of Liability9 Formatting Conventions10 Use of Symbols10 Markup of Text Elements11 Conventions for Cables12 Symbols, Marks and Test Symbols12 Trademarks13 3 General Safety Instructions 14 Directives and Standards14 Qualified Personnel14 Intended Use15 Transport and Storage15 Operational Environment and Operation16 Tab. 1 Maximum Symmetrical Nominal Short-Circuit Current of the Drive Controller16 Working on the Machine17 Decommissioning17 Disposal17 Firefighting17 4 System Configuration 18 Fig. 1 System Overview18 Hardware Components19 Drive Controllers19 Fig. 2 SC6A062 Nameplate19 Fig. 3 Sticker with MV and Serial Number20 Tab. 2 Meaning of the Specifications on the SC6 Nameplate20 Tab. 3 Meaning of the Specifications on the Sticker20 Tab. 4 Example Code for Type Designation21 Tab. 5 Meaning of the Example Code21 Tab. 6 Available SC6 Types and Sizes21 Controller22 Operating Motors, Encoders and Brakes22 Accessories23 Software Components27 Project Configuration and Parameterization27 Applications27 5 Technical Data 28 Drive Controllers28 General Technical Data28 Tab. 7 Device Features28 Tab. 8 Transport and Storage Conditions28 Tab. 9 Operating Conditions28 Tab. 10 Discharge Times of the DC Link Circuit29 Tab. 11 Control Unit Electrical Data29 Tab. 12: SC6 Electrical Data, Size 030 Tab. 13 SC6 Electrical Data, Size 0, for 4 Khz Clock Frequency30 Tab. 14 SC6 Electrical Data, Size 0, for 8 Khz Clock Frequency30 Tab. 15: Brake Chopper Electrical Data, Size 030 Tab. 16: SC6 Electrical Data, Size 131 Tab. 17 SC6 Electrical Data, Size 1, for 4 Khz Clock Frequency31 Tab. 18 SC6 Electrical Data, Size 1, for 8 Khz Clock Frequency31 Tab. 19: Brake Chopper Electrical Data, Size 131 Tab. 20: SC6 Electrical Data, Size 232 Tab. 21 SC6 Electrical Data, Size 2, for 4 Khz Clock Frequency32 Tab. 22 SC6 Electrical Data, Size 2, for 8

Khz Clock Frequency32 Tab. 23: Brake Chopper Electrical Data, Size 232 Tab. 24 X101 Electrical Data33 Tab. 25 X103 Electrical Data33 Fig. 4 Asymmetric Load on Double-Axis Controllers34 Tab. 26 Power Loss Data of the SC6 Drive Controller in Accordance with en 61800-9-235 Derating36 Tab. 27 Absolute Losses in the Accessories36 Dimensions38 Weight38 Fig. 5 SC6 Dimensional Drawing38 Tab. 28 SC6 Dimensions [MM]38 Tab. 29 SC6 Weight [G]38 Assignment of DL6B to SC639 Tab. 30 Device Features39 Tab. 31 Transport and Storage Conditions39 Tab. 32 Operating Conditions39 Tab. 33 Assignment of DL6B to SC639 Dimensions40 Fig. 6 DL6B Dimensional Drawing40 Tab. 34 DL6B Dimensions [MM]40 Weight41 Safety Technology41 Tab. 35 DL6B Weight [G]41 Tab. 36 X12 Electrical Data41 Operating Motors42 Tab. 37 Motor Types and Control Modes42 Evaluable Encoders43 Overview43 Signal Transmission43 Tab. 38 Overview of Encoder Connection43 Tab. 39 Endat 2.1 Digital Specification44 Tab. 40 Endat 2.2 Digital Specification44 Tab. 41 SSI Specification44 Tab. 42 Specification for TTL Differential Incremental Signals45 Tab. 43 Specification for Resolver Signals45 Tab. 44 Specification for HIPERFACE DSL45 X101 for Encoders46 X103 for Encoders46 Tab. 45 Encoder Models with Unsuitable Supply Voltage Range46 Tab. 46 Specification for Single-Ended HTL Incremental Signals and Single-Ended HTL Pulse Train Signals46 Tab. 47 Specification for Single-Ended HTL Incremental Signals and Single-Ended HTL Pulse Train Signals46 Controllable Brakes47 Evaluable Motor Temperature Sensors47 Tab. 48 Electrical Data of the Brake Output47 Braking Resistor48 Tubular Fixed Resistor FZMU, FZZMU48 Tab. 49 Assignment of FZMU, FZZMU Braking Resistor - SC6 Drive Controller48 Tab. 50 FZMU, FZZMU Specification48 Fig. 7 FZMU (1), FZZMU (2) Dimensional Drawing49 Fig. 8 FZMU, FZZMU Drilling Diagram49 Tab. 51 FZMU, FZZMU Dimensions [MM]49 Flat Resistor GVADU, GBADU50 Tab. 52 Assignment of GVADU, GBADU Braking Resistor - SC6 Drive Controller50 Tab. 53 GVADU, GBADU Specification50 Fig. 9 GVADU, GBADU Dimensional Drawing51 Fig. 10 GVADU, GBADU Drilling Diagram51 Tab. 54 GVADU, GBADU Dimensions [MM]51 6 Project Configuration 52 Drive Controllers52 DC Link Connection52 Information on Design and Operation53 Design54 Motors56 Mixed Operation57 Fig. 11 Grounding Concept in Mixed Operation with SI6 and SD6 with Powered SC6 Drive Controller57 Fig. 12

By becoming the first Korean battery materials company to secure North American spodumene concentrate (“SC6”), LG Chem began to strengthen its supply chain. SC6 is a high-purity material that processes lithium ore, which can extract lithium hydroxide that serves as a key material for batteries. On the 15th, LG Chem announced that it signed offtake agreements with an American mining company Piedmont Lithium Inc. (“Piedmont”) for a total of 200,000 metric tons of SC6. Starting in 3Q23, Piedmont will supply 50,000 metric tons per year of SC6 from a Canadian mine over a four-year term. LG Chem is expected to extract approximately 30,000 metric tons of lithium hydroxide, which is equivalent to the amount that goes into 500,000 high-performance electric vehicles. Piedmont has a 25% ownership interest in the North American Lithium (“NAL”) - Canadian mine in Quebec, and NAL is the only lithium mine in North America capable of commercial production this year. LG Chem plans to use the lithium mined in the region to produce cathode materials supplied to key North American customers. LG Chem became the first Korean battery materials company to secure SC6 from North America. With the use of North American lithium, LG Chem fulfills the US IRA (Inflation Reduction Act, passed by the US Congress) and expects to mitigate the regional concentration of key materials for secondary batteries. LG Chem also signed an agreement with Piedmont to make an equity investment of $75 million (KRW 94 billion), earning an approximately 6% stake in the company. LG Chem further stabilized its raw materials supply by obtaining priority negotiation rights for 10,000 tons of lithium hydroxide per year produced by Piedmont Lithium in the U.S. Established in 2016, Piedmont is a lithium mining company headquartered in North Carolina, USA. Piedmont is listed on both Nasdaq and Australian Securities Exchange, with lithium mine development and production projects underway in North Carolina and Tennessee. Piedmont also has stakes in lithium mine developers in Quebec, Canada, and Cape Coast, Ghana. Keith Phillips, CEO of Piedmont, said “We are pleased to partner with LG Chem to supply lithium resources produced in North America,” adding that “As LG Chem has a strong commitment to US electric vehicle battery manufacturing, Piedmont looks forward to discussing additional potential cooperation with LG Chem in North America.” LG Chem has been partnering with a wide range of global raw materials companies, including Piedmont, to secure stable raw materials supply and cost competitiveness. LG Chem also made a strategic equity investment in Tianqi Lithium, a company that owns a mine in Australia. Moving forward, LG Chem plans to continue its investment to secure key battery materials that satisfy criteria laid out in the US IRA and

Grounding Concept in Mixed Operation with SI6 with Powered SC6 Drive Controller58 7 Storage 59 Drive Controller59 Annual Reforming59 Reforming before Commissioning60 Fig. 13 Voltage Levels Dependent on Storage Time60 8 Installation 61 Safety Instructions for Installation61 Basic Assembly Instructions61 Drive Controllers61 Fig. 14 Fields for Equipment Identification on the Front of the Device61 Braking Resistor62 Minimum Clearances63 Fig. 15 Minimum Clearances63 Tab. 55 Minimum Clearances [MM]63 Drilling Diagrams and Bore Dimensions64 Drive Controllers64 Fig. 16 SC6 and DL6B Drilling Diagram64 Tab. 56 Drilling Dimensions for SC6 Drive Controller [MM]64 Length of Copper Rails65 Fig. 17 Determination of the Correct Length of the Copper Rails65 Tab. 57 Drilling Dimensions for Quick DC-Link DL6B [MM]65 Installing the Drive Controller Without a Rear Section Module66 Installing the DC Link Connection67 Mounting the Drive Controller on the Rear Section Module69 9 Connection 72 Safety Instructions for Connection72 Line Routing72 Protective Measures73 Power Grid Supply in Case of Parallel Connection73 Line Fuse74 Tab. 58 Recommended Maximum Line Fuse in Stand-Alone Operation74 Tab. 59 Recommended Line Fuse in Parallel Connection75 Grid Connection in Case of Parallel Connection76 Residual Current Protective Device76 Housing Grounding77 Fig. 18 Connection of the Grounding Conductor77 EMC Recommendations78 Tab. 60 Minimum Cross-Section of the Grounding Conductor78 Drive Controller79 Overview79 Fig. 19 Connection Overview Using the Example of the SC6A16279 X2A: Brake a80 Tab. 61 X2A Connection Description, Brake a80 Tab. 62 Maximum Cable Length of the Power Cable [M]80 X2A: Motor Temperature Sensor a81 X2B: Brake B81 X2B: Motor Temperature Sensor B81 Tab. 63 X2A Connection Description, Motor Temperature Sensor a81 Tab. 64 Maximum Cable Length of the Power Cable [M]81 X4A: Encoder a82 Tab. 65 X4A Connection Description for Endat 2.2 Digital Encoders and SSI Encoders82 Tab. 66 X4A Connection Description for Differential TTL and Differential HTL Incremental Encoders (HTL Via HT6 Adapter)83 Tab. 67 X4A Connection Description for Resolvers83 Tab. 68 X4A Connection Description for HIPERFACE DSL Encoders84 X4B: Encoder B85 X9: Ethernet Service Interface85 Tab. 71 AP6A00 Connection Description for Resolver (9-Pin to 15-Pin)85 Tab. 72 X9 Connection Description85 Tab. 73 Cable Length [M]85 X10: 400 V Supply86

Ive been using flash cs5 for sometime and I cant use the pen pressure at all. Everytime I use the pen pressure it creates a "Tampon" effect when I make a pen stroke. Idk how to fix this and I hope some flash veterans can help me with this. If it helps my tablet is a XP PEN12 and my operating system is WINDOWS 10. At 6/15/23 02:13 AM, BlackDingo86NG wrote:Ive been using flash cs5 for sometime and I cant use the pen pressure at all. Everytime I use the pen pressure it creates a "Tampon" effect when I make a pen stroke. Idk how to fix this and I hope some flash veterans can help me with this. If it helps my tablet is a XP PEN12 and my operating system is WINDOWS 10.In your tablet driver settings, make sure you have Windows Ink disabled for Flash.There are no settings on Flash's side that you can adjust.You need to rely on driver compatibility and make sure that you only use WinTab.I have no experience with non-Wacom devices, but as far as I know they should work.CS5 is OK, CS5.5 is better, and SC6 is the best.If you can, upgrade to CS6. At 6/15/23 04:31 AM, ntilcheff wrote:At 6/15/23 02:13 AM, BlackDingo86NG wrote:Ive been using flash cs5 for sometime and I cant use the pen pressure at all. Everytime I use the pen pressure it creates a "Tampon" effect when I make a pen stroke. Idk how to fix this and I hope some flash veterans can help me with this. If it helps my tablet is a XP PEN12 and my operating system is WINDOWS 10.In your tablet driver settings, make sure you have Windows Ink disabled for Flash.There are no settings on Flash's side that you can adjust.You need to rely on driver compatibility and make sure that you only use WinTab.I have no experience with non-Wacom devices, but as far as I know they should work.CS5 is OK, CS5.5 is better, and SC6 is the best.If you can, upgrade to CS6.I just got flash cs6 an hour