GE Industrial Solutions 6KCV301DGF User Manual
6kcv301dgf, Instructions
Table of contents
Document Outline
- Table of contents
- 1. GENERAL DESCRIPTION
- 2. DGF Overview
- 2.1 INTRODUCTION
- 2.1.1 Firmware organization
- 2.1.2 DGF application
- 2.1.2 Working of the DGF
- 2.1.3 Global organization of the DBASE
- 2.1.4 Parameters and variables
- 2.1.4.1 Initialization of the General variables
- 2.1.4.2 Data management inside the DBASE
- 2.1.4.3 Access to a parameter from the external world
- 2.1.4.4 Storage of the parameter and of the associated record
- 2.1.5 FVAR, IVAR and NUM
- 2.1.6 DPRAM organization
- 2.1.6.1 DPRAM hardware
- 2.1.6.2 DPRAM software organization
- 2.2 DGF status
- 2.3 Data formats
- 2.4 Interface
- 2.5 Drive parameters
- 2.6 Parameter description
- 2.7 How to configure the DGF
- 2.1 INTRODUCTION
- List of tables and figures
- 1. GENERAL DESCRIPTION
- Figure 1.2.1: 6KCV301DGF connections
- Figure 1.2.1.1: 6KCV301DGF memory map
- Figure1.2.1.2: 6KCV301DGF flash Eprom memory map
- Figure 1.2.2.1: RS-485 interface
- Figure 1.2.2.2: RS-485 single point comm. without signal isolation
- Figure1.2.2.3: RS-485 communications with signal isolation
- Figure 1.2.4.1: 6KCV301DGF Jumper Locations
- Figure 1.3.1: DGF Location
- 2. DGF Overview
- Figure 2.1.1: DGF block diagram
- Figure 2.1.1.1: Logical structure
- Figure 2.1.2.1: DGF Program Structure
- Figure 2.1.7.1.1: DPRAM Hardware
- Figure 2.2.1: Logic of DGF status
- Table 2.2.1: Leds status
- Table 2.2.2.1: DGF alarm codes
- Table 2.2.2.2: Alarm code 2 (AL_DPRAM)cause
- Table 2.2.2.3: Alarm code 6 cause
- Table 2.2.2.4: Alarm code 14 (AL_BRICKS_DP) cause
- Table 2.2.2.5: Alarm code 15 (AL_REGISTER) cause
- Table 2.2.2.6: Alarm code 16 (AL_CCZ) cause
- Table 2.2.2.7: Alarm code 22 (AL_DNET) cause
- Figure 2.4.1: DGF Communication