001 Stand Alone Low Voltage - Garney Construction

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Section 3: Application Guidelines 9 solid-state logic and output circuits. If this protection is not part of the DC supplies for a system, a timing circuit external to the power supply can be added to delay the application of power to output devices. Removing all power or losing all power from a system simultaneously usually does not result in a hazard since the power for machine operation is also being removed. However, when power other than electrical power is being controlled, a power interlock circuit may be required to protect against unexpected machine motion. Power interlocks with automatic shutdown should be included if erratic or hazardous operation results due to loss of one power supply in a system with multiple supplies. Automatic power supply sequencing should be employed in systems that require the application or removal of power in a specific sequence. If the STOP or E-STOP sequence normally employs dynamic braking, alternative safeguards, such as automatic mechanical braking upon loss of power, should be provided if coasting stops are hazardous. If hazardous operation can result from unexpected restoration of power during a power outage or a system shutdown, the system should include a feature that requires a deliberate operator action before power is reapplied to the system. 3.1.3 Redundancy and Monitoring When solid-state devices are being used to control operations, which the user determines to be critical, it is strongly recommended that redundancy and some form of checking be included in the system. Monitoring circuits should check that actual machine or process operation is identical to controller commands; and in the event of failure in the machine, process, or the monitoring system, the monitoring circuits should initiate a safe shutdown sequence. Comments: 3.1.3 Redundancy and Monitoring The normal operating mechanism for solid-state components depends upon a deliberate electrical signal input altering the internal molecular structure of the semiconductor material. Unfortunately, spurious input signals may also alter the internal molecular structure without any means for external detection that this has happened. Therefore, solid-state devices are subject to malfunction due to random causes that are undetectable. Because of this, redundancy and monitoring are the most highly recommended means for counteracting this situation. When redundancy is used, dissimilar components not susceptible to common cause failure should be used for the redundant elements if a common cause could produce simultaneous failure of those elements in a dangerous mode. A “safe shutdown sequence” can involve much more than disconnecting electrical power for some machinery and processes. Examples include machines with high inertia and hazardous access points, processes that become unstable at shutdown unless a specific sequence is followed, etc. The control system for such applications should be configured to deal Publication SGI-1.1 - August 2009
10 Section 3: Application Guidelines with the particular hazard(s) through use of special features such as automatic transfer of control functions to redundant devices in the event of failure of primary controls; alarm circuits and diagnostics to signal and identify failures that require repair in order to maintain redundancy; emergency power sources with automatic transfer upon loss of primary power source; or other appropriate features. 3.1.4 Overcurrent Protection To protect triacs and transistors from shorted loads, a closely matched short circuit protective device (SCPD) is often incorporated. These SCPDs should be replaced only with devices recommended by the manufacturer. Comments: 3.1.4 —Overcurrent Protection Even a closely matched short-circuit protective device (SCPD) will generally protect a solid-state device only against shorted loads, an accidental short to ground, or a phase-to-phase short. Depending upon the application, additional protective measures may be needed to protect the solid-state devices against small to moderate overcurrents. Consult with the manufacturer if necessary. 3.1.5 Overvoltage Protection To protect triacs, SCRs and transistors from overvoltages, it may be advisable to consider incorporating peak voltage clamping devices such as varistors, zener diodes, or snubber networks in circuits incorporating these devices. Comments: 3.1.5 — Overvoltage Protection See section 2.7. 3.2 Circuit Isolation Requirements 3.2.1 Separating <strong>Voltage</strong>s Solid-state logic uses low level voltage (e.g., less than 32V DC) circuits. In contrast, the inputs and outputs are often high level (e.g., 120V AC) voltages. Proper design of the interface protects against an unwanted interaction between the low level and high level circuits; such an interaction can result in a failure of the low voltage circuitry. This is potentially dangerous. An input and output circuitry incorporating effective isolation techniques (which may include limiting impedance or Class 2 supplied circuitry) should be selected. Comments: 3.2.1 —Separating <strong>Voltage</strong>s For specifications of Class 2 circuitry, refer to Article 725 of the National Electrical Code, NFPA 70. Publication SGI-1.1 - August 2009
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A-2 Motor Cable Length Restrictions
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Index-2 Ungrounded Secondary, 2-3 D
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Index-4 Surge Protection MOV, 2-17
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Product Details and Certifications
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http://raise.rockwellautomation.com
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Yokogawa Corp. of America - Meter &
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Career │ Site Map │ Contact Us
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AMP-TRAP 2000 ® ATQR TIME DELAY/CL
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AMP-TRAP 2000 ® TIME DELAY/CLASS C
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9 KEY BENEFITS Unique protect
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Product Details Product Details Pro
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POTENTIAL TRANSFORMERS THREE PHASE
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PowerFlex 70/700 Production Test Pr
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PowerFlex 70/700 Production Test Pr
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TEST PROCEDURE Test No: TEST 5015-0
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TEST PROCEDURE Test No: TEST 5015-0
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Customer: The Reynolds Co. End User
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Harmonic Estimator Report - Summary
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Harmonic Estimator Report - Spectru
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SMC-Flex Bulletin 150 SMC-Flex Appl
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Bulletin 150 SMC-Flex Table of Cont
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Drives Support > Drive Maintenance
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Drives Support > Drive Maintenance
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SupportPlus For consultation on hig
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SERVICE & SUPPORT Contract Callout
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Table of Contents 1. Introduction 1
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1.2.1 Feeder Input Data Sheet ALL P
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2.1 Motor Starting Study Discussion
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WPS RVSS Study1 - RVSS - MTRI-WPSSW
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2.2.2 SKM TMS Solid State Voltage R
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2500 1250 100 Percent Voltage Study
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2.4 SKM TMS 80% Voltage Start This
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4. Information 30
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