Annunciator Alarm Systems Buyer`s Guide
Transcription
Annunciator Alarm Systems Buyer`s Guide
Annunciator Alarm Systems Buyer’s Guide An easy-to-digest overview of common capabilities and features of modular alarm annunciators Excellence in Monitoring & Measurement for Over 55 Years Table of Contents: Click on link to navigate to desired location Introduction and Focus …..…………………………………………………………………………………………………… 3 Size: Chassis type, Alarm Points and Dimensions ………………………………………………………………… 4 Networkable (communication) or Stand-alone (no communication) ………………………………….. 7 Software Configurability ……………………………………………………………………………………………………… 7 Event Recording ………………………………………………………………………………………………………………….. 7 Outputs ………………………………………………………………………………………………………………………………. 8 Field Contact Voltage ………………………………………………………………………………………………………….. 8 Source Voltage ……………………………………………………………………………………………………………………. 8 Display: LED and Window Lenses for Alarm Grouping ………………………………………………………… 8 Other Types of Annunciators ………………………….………………………………………………………………….. 9 Introduction and Focus This Annunciator Alarm Systems Buyer’s Guide aims to help in the initial research and selection of an alarm annunciator for the process control and power industries. In this guide, an annunciator will be defined as a device that is designed to alert operators of abnormal process conditions (i.e. low/high temperature alarms, pressure alarms, etc.) in plant/refinery/process operations. Annunciators can be found in control rooms, boiler rooms, power substations or just about any type of process or operational environment where conditions need to be personally monitored and status indication is necessary. This guide will only discuss integrated logic alarm annunciators - annunciators in which the alarm condition and responsive operator actions are dictated by a programmed logic sequence. A sequence, by definition, is “the chronological series of actions and states of an annunciator after an abnormal process condition or manual test initiation occurs” (ISA–18.1–1979 (R2004), Annunciator Sequences and Specifications). Basically, an annunciator alarm sequence defines the steps an operator would take in response to the alarm condition. Most annunciators are standardly equipped with the ISA (International Society of Automation) standard alarm sequences. Custom alarm sequences are often supplied by most manufacturers upon customer request. See ISA–18.1–1979 (R2004), Annunciator Sequences and Specifications for more detailed information on sequences. When choosing an annunciator, you need to determine which sequence is most suitable for the process. It is important to note that some annunciators have software programming capabilities which allow the sequence to be selected or changed in the field via computer. If you are only looking for an alarm display that will provide a visual status without logic, then you will want to direct your search to a “LED/lamp box” or “LED/lamp cabinet.” These types of alarm displays are driven by other devices such as PLCs or remote logic annunciators. LED lamp boxes by themselves do not have the function of flashing alarms or audible outputs. This guide will not discuss selection of LED/lamp boxes or cabinets. Let’s Begin… The following sections are meant to guide you step-by-step through the features you should consider when researching the suitable annunciator for your application. Annunciator Alarm Systems Buyer's Guide | 3 Size: Chassis type, Alarm Points and Dimensions Annunciators are sold in many different shapes and sizes but are typically modular in construction and designed as module cells high by module cells wide. Several factors contribute to the system’s size, dimensions and window display configuration. Those factors include: 1) The chassis needed for the installation 2) How many alarm points you need to monitor 3) The control panel, cabinet or field space you have available for the annunciator 1) Chassis The best place to start is to determine which chassis is needed for the annunciator’s installation. The most common types of annunciator chassis are panel-mount, surface-mount and rack-mount. A panel-mount chassis (also referred to as flush-mount) is designed to be mounted in a panel cut-out, typically in a control room type setting. Wiring can only be accessed from the back of the panel, therefore leaving only the alarm display (with or without pushbuttons) showing in the front of the panel. Depth dimensions of these panel-mount chassis can vary by manufacturer so it is important to request dimensions and drawings to be sure that the system fits in your installation setting. A surface-mount chassis is a cabinet-type enclosure whereby the alarm chassis is mounted on to a panel inside an enclosure that provides front door access to the annunciator’s terminal wiring. This type of chassis is suitable for applications where the annunciator system is to be in a NEMA or IP-type enclosure and terminals must be accessed from the front of the annunciator system. A rack-mount chassis is standardly manufactured in a 19” width and is designed to be slid into a vacant space in a pre-existing rack. The 19” width limits the number of horizontal windows for the alarm display but can be expanded vertically to accommodate the necessary amount of alarm points. Note: Special applications may call for NEMA 1, 12, 4, 4X enclosures or purge systems. Annunciator Alarm Systems Buyer's Guide | 4 2) Alarm Points Once you’ve selected the chassis type, then determine how many alarm points (or inputs) need to be monitored in your operation or process. The amount of points will dictate how many module cells you will need to display the alarm conditions. For example, if you need to monitor a high pressure level, low pressure level, high temperature level and low temperature level, you will need four points. You’ll also have to take into consideration how big you want the module cells and text legends to be and what will provide the operator with the best level of awareness for your environment. Example A: 2 module cells high x 2 module cells wide (Each point occupies one full “cell” or “module” space) HIGH PRESSURE LOW PRESSURE HIGH TEMP LOW TEMP Example B: 1 module cell high x 4 module cells wide HIGH PRESSURE E LOW PRESSURE HIGH TEMP LOW TEMP Example C: 1 module cell high x 2 module cells wide with 2 alarm points per module cell for a total of four alarm windows HIGH PRESSURE LOW PRESSURE HIGH TEMP LOW TEMP Note: Alarm points are typically configured left to right. 1 2 3 4 Annunciator Alarm Systems Buyer's Guide | 5 Pushbuttons: The number of module cells you need will also depend on the desired location of the pushbuttons. The three most common positions for the pushbuttons are either 1) occupying bottom right module cell space 2) on the bottom right trim of the chassis or 3) located remotely. The standard is to have the pushbuttons occupy the bottom right module cell. Below are two common examples of pushbutton location. The most common pushbutton options are Test, Acknowledge, Silence and Reset. Manufacturers may offer more pushbutton options (i.e. First Out Reset). Example D: 4 point system with integral pushbuttons – 1 module cell high x 5 module cells wide HIGH PRESSURE E LOW PRESSURE HIGH TEMP LOW TEMP TEST SIL ACK RES Example E: 4 point system with pushbuttons on trim – 1 module cell high x 4 module cells wide (Pushbuttons do not need to occupy one window space) HIGH PRESSURE E LOW PRESSURE HIGH TEMP LOW TEMP TEST SIL ACK RES 3) The control panel, cabinet or field space you have available for the annunciator The space that you have available for the annunciator is another large factor in the construction of the system and how many alarm points you can fit per module cell. For example, if you are limited by a 6” width cutout space but need to monitor 20 points, you could build your module cells vertically and divide each cell by 4 points. Example F to right: 20 point system with pushbuttons on trim – 5 module cells high x 1 module cell wide to accommodate limited cutout space in control room One module cell split into four points for a total of 20 windows (20 points) for the entire system 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 6 Networkable (communication) or Stand-Alone (no communication) Built-in Ethernet capability allows for communication between your annunciator system and plant control systems such as PLCs or other field instrumentation devices. There are a variety of network protocols (i.e. Modbus/TCP, DNP3, etc.) that can be used. You must decide if Ethernet communication is needed or desired, as well as make sure the annunciator you purchase has the proper protocols needed for your network. Ethernet communication also allows for features such as remote monitoring with annunciators or remote HMI displays, as well as distributed network connection with other Ethernet devices. Communication may not be desired or necessary. Some plants and companies prefer to keep their alarm systems as stand-alone (no communication) systems in an effort to protect their critical alarms from cyber network vulnerabilities. Software Configurability If you are seeking the ability to re-configure the annunciator features via computer or laptop in the field, you will need an annunciator with software configurability done through network or serial communication. WARNING: It is important to note that the use of network communication comes with the risk of vulnerability to cyber hackers. Should you select an annunciator that requires network connectivity, it is important to either 1) make sure your annunciator network is isolated from your operation’s main control network or 2) set up secure firewalls to help safeguard yourself from cyber hacking. Event Recording Annunciators with event recording capabilities can provide the operator with information about each alarm event such as: time of alarm (time-tagging), order of alarms, time of acknowledgement and more. The ability to time-tag alarm events to the nearest millisecond has become a popular feature in modern annunciator systems. Depending on your alarm needs, this may or may not be a necessary feature. Annunciator Alarm Systems Buyer's Guide | 7 Outputs Annunciators can be supplied with relay outputs and/or transistor outputs. Depending on the manufacturer, some relay outputs are standard while others are optional. Make sure the annunciator you choose has the necessary outputs you need for your operation. Common relay outputs include: Audible and visual signals: horn, beacon, bell Common Trouble Alarm (CTA) Relay: notification of any alarm within the system (commonly used for remote beacon or dial-up) Group CTA functions: for critical and noncritical groups Auxiliary Contact Repeat Relay: individual repeater output per input Reflash Alarm Relay: alarm counter Other relays may include: Diagnostic Relay, Ringback Relay, Loss of Power Relay, etc. For equipment needing under 24 volt inputs, transistor outputs of the annunciator are used. Field Contact Voltage Annunciators are standardly capable of accepting a wide range of DC or AC field contact voltages (dry or live contacts). Source Voltage Annunciators are standardly capable of accepting a wide range of DC or AC source voltages with integral or external power supplies. Display: LED and Window Lenses for Alarm Grouping Colored framing (or bezels) and colored cell filters or lenses allow for clustering or grouping of alarm functions. For example, if you have a set of temperature alarms that you want to separate from the rest of your alarms, you could put a yellow lens or filter on those windows with red framing (or bezels) to differentiate them from the rest. Example G: Grouping of four temperature alarms with red framing and yellow lens TEMP POINT TEMP POINT ALARM POINT ALARM POINT ALARM POINT ALARM POINT TEMP POINT TEMP POINT ALARM POINT ALARM POINT ALARM POINT ALARM POINT ALARM POINT ALARM POINT ALARM POINT ALARM POINT TEST SIL ALARM POINT ALARM POINT ALARM POINT ALARM POINT ACK RESET Annunciator Alarm Systems Buyer's Guide | 8 It is now standard for annunciators to utilize LED lights for window illumination. Some manufacturers may still provide lamp bulb lighting, but LEDs have proven to be the most preferable, sustainable and economic option. White LEDs are a common option, however, if you prefer different color illumination, check with your manufacturer to make sure the desired color is available. If you need colored lenses, framing or LEDs, be sure to make your manufacturer aware of this. Some manufacturers have a standard of all white windows and LEDs with black module cell framing. Other Types of Annunciators There are several other types of annunciators that have not been listed in this guide. For a more detailed explanation of the following annunciators, feel free to contact Ronan Engineering. Split architecture annunciator Split-architecture annunciators separate the display from the electronics containing the alarm logic, allowing the display to be a remote distance (range varies by manufacturer) away from the actual annunciator. This is a common option for reduced weight systems and applications with limited space for display. Explosion-proof annunciator Explosion-proof Annunciators are designed for hazardous locations. They provide maximum flexibility for use under specified operating conditions approved for National Electric Code Hazardous Locations such as: Class 1 Division 1, Groups B, C & D Class II, Division 1, Groups E,F, G Class III, Divisions 1 and 2 NEMA 7 C, D; NEMA 9 E, F, G Sequence of Events Recorder A Sequence of Events Recorder (SER) is a standalone microprocessor based system that typically monitors a high volume of inputs and records the time and sequence of alarm events. SERS are a helpful diagnostic tool for troubleshooting to minimize operational downtime. Redundant SER systems are often used in the nuclear and power industries as a back-up system for conventional PLC-based SCADA alarm systems. Relay logic annunciators Although relay logic-based annunciators utilize traditional relay contact technology, they continue to be a viable and widely used option for many plants. Relay annunciators do tend to be more costly due to the dedicated relays and wiring in the annunciator. The combination of proven reliability, noise immunity and simplicity of the logic circuits makes the relay systems ideally suited for oil platforms, desert or arctic environments, shipboard or any place with limited access to technical support. Annunciator Alarm Systems Buyer's Guide | 9 Thank you for reading the Annunciator Alarm Systems Buyer’s Guide. Finding and selecting the right annunciator to meet your specifications can be cumbersome without a roadmap. We hope that this guide will be a helpful resource as you continue your research and select the best product for your project requirements. If you have any questions about the steps or features discussed in this guide, feel free to contact Ronan Engineering Company. Excellence in Monitoring & Measurement for Over 55 Years Annunciator Alarm Systems Buyer's Guide | 10