CCA TESTER
Monday, December 28, 2020
Monday, December 21, 2020
Total Productive Maintenance ( TPM )
Total Productive Maintenance, or TPM, is a lean maintenance strategy that aims for zero breakdowns, zero defects and zero work accidents. We’ve already introduced TPM, what it is, who is responsible for it, its numerous advantages, and how it fits into Industry 4.0.
However, to succeed at such an ambitious plan, we need solid pillars. That brings us to the 8 pillars of TPM, or the 8 basic principles of TPM. Implementing them is not only key to enable TPM but also to ensure it will last.
What are the 8 Pillars of Total Productive Maintenance?
1. Focused Improvement
Focused improvement is the first pillar of TPM. The priorities are clear: improve, improve, and improve continuously. To avoid the loss of equipment, talent, raw materials, and energy, the whole team must share this vision. The team must be proactive, willing to try new methods, and eager to sit around the table to work out problems.
How to Use Kaizen for Continuous Improvement in TPM and Lean
If there’s something 2020 has proven to us, is that different and new work routines can yield the same results as the “traditional” ways. In fact, truth be told, some even proved to be more efficient than we’d previously thought. For all the challenges the pandemic brought, remote work showed it’s possible to improve the work-life balance and avoid endless hours in traffic jams. It was a learning curve, that’s for sure, but who knows if it isn’t the way forward?
What we’re trying to say is that everything can be improved, even if you’re set on your ways. You don’t know until you try. Some companies already do this with Kaizen. It’s not a tool, it’s not a methodology – it’s a culture. In Japanese, “kaizen” means “change for the better”, which some companies interpret as a synonym for continuous improvement. It’s closely associated with lean manufacturing and lean maintenance, as well as Total Productive Maintenance (TPM).
What is the Continuous Improvement Model?
Continuous improvement is essential under lean manufacturing models and TPM. Kaizen aims at finding processes that can become more efficient and more effective, usually in an organised and consistent manner.
Kaizen can be applied to anything, from management to the maintenance schedule of a specific piece of equipment, to logistics and even the supply chain. It also extends to everyone from operators to managers, a characteristic it shares with TPM. For lean manufacturing, or even lean maintenance, Kaizen takes another dimension. Improving or making activities more efficient implies eliminating waste.
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About “Point Kaizen” or “Kaizen Blitz”But, as we said, Kaizen is culture, not a tool. So what tools can you apply to reinforce this culture? There are four main tools to achieve continuous improvement, which we’ll see next.
Plan, Do, Check, Act (PDCA)
The PDCA cycle is one of the most popular tools to achieve continuous improvement. Originally designed as a quality control method, it can be used to establish new goals and processes (plan). Start small with a run-test (do). Then, compare the output/ results with your goals (check). If the new processes improve your performance, implement them (act). Of course, the trick with PDCA is setting measurable goals and tracking them accordingly.
- Take note: for single point Kaizen events, PDCA sometimes means Problem finding, Display, Clear, and Acknowledge.
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Root Cause Analysis (RCA)
Root Cause Analysis is a set of tools to find out what triggered a failure. Organisations searching for continuous improvement seek RCAs to improve processes and prevent failures from happening again. In fact, this is a topic we’ve already covered extensively. You can see our overview of 5 RCA tools, how to perform an FMEA, how to apply an FTA, how FMEA compares to FTA, and what’s a 5 Whys Analysis. The latter and Fishbone Diagrams are often used on PDCA cycles.
Kanban
Kanban is another lean tool. It means “signboard” or “billboard” in Japanese, and it’s a scheduling system for just-in-time manufacturing and lean processes. In essence, it’s a whiteboard to map every step of the process, divided between “requests”, “in progress” and “done”. Over time, this “visual workflow” has emerged as a way to promote improvement. Problems (such as interruptions or delays) are highlighted, so you can spot potential bottlenecks and act on them.
CMMS or equivalent software
This can’t come as a surprise. A CMMS or an equivalent intelligent software are incredible sources of data and insights into your operation. They will lend a hand not only to spot opportunities for change and improvement but also to track results. Of course, to keep it lean, you’ll want software that is user-friendly, easy to integrate with other tools, and able to generate reports and time-based work orders automatically.
What are the benefits of Kaizen?
It’s a fair question. When you’re taking on a lean approach, every change in the company culture needs to build up, instead of wasting time or human resources. However, if you’re already “all in” with TPM and lean maintenance, Kaizen is almost non-negotiable. Here’s a roundup of the changes you’ll notice when implementing the tools we’ve mentioned:
- improved product quality after successive PDCA cycles;
- minimising waste through continuous improvement of processes;
- shorter delivery times due to the elimination of production bottlenecks;
- increased safety, especially when RCA is applied in design processes;
- boost team morale, since workers feel more motivated and listened to;
- reduced costs and more effective management overall, as a consequence of all of the above.
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- Read more about using Kaizen for continuous improvement in TPM and lean manufacturing.
2. Autonomy
Autonomy is the second pillar of TPM, in the sense that every team is an autonomous “maintenance agent”. Everyone has the autonomy to clean, inspect, and contribute to the upkeep of the assets they work with. This ensures every piece of equipment is cared for, improves early fault detection, and frees maintenance technicians for heavier tasks. Learn more about autonomous maintenance and how to implement it.
3. Quality Maintenance
One of TPM’s biggest goals is manufacturing zero defective products, which, undoubtedly, also plays into customer satisfaction. Hence, quality management and implementing internal processes linked to quality control are another pillar. We recommend several root cause analysis tools to root out problems.
4. Planned Maintenance
Planned maintenance – whether it is planned reactive maintenance or preventive maintenance – is the best way to avoid downtime and breakdowns. Keep every asset up and running to ensure quality and avoid customer complaints (for B2C), and improved compliance (for B2B service providers). Programmed maintenance that requires machines to shut down should be done after regular work hours.
5. Early Equipment Maintenance
Early equipment maintenance is one of the 8 pillars of a well-succeeded TPM strategy. When it’s time to choose new equipment or develop new products, consider previous experiences to make maintenance easier. This can be as simple as choosing a washable paint for the walls (which makes cleaning easier), or as complex as picking a robot which can self-diagnose malfunctions (which improves production).
6. Training and Education
TPM requires investing in training and education. Otherwise, it’s impossible to trust each worker with routine maintenance or prevention. For TPM to work, basic maintenance knowledge about assets used daily is non-negotiable. Besides, when you think about how fast technology evolves, continuous training is the only way to make sure your technicians are familiar with new equipment and the state-of-the-art of the industry.
7. Safety, Health and Environment
TPM also aims at zero work accidents, zero pollution, and zero burnout. Good maintenance management not only avoids accidents during maintenance activities but also contributes to every worker’s well-being and safety.
Estimates suggest about 53% of all cancers in Europe are related to professional activities, usually due to exposure to asbestos, benzene (used in rubbers, lubricants, dyes, detergents, and pesticides, for example), chromium, nickel, silica powder (common in mining activities, quarries, glue and paint factories), radiation and fumes. Proper maintenance of equipment and buildings can help to reduce these statistics.
8. Office TPM
The last of the 8 pillars is office TPM. This means administrative workers and managers should also chip in, instead of leaving it to the “worker bees”. Everyone, without exception, must be proactive and focused on improvements, from logistics to scheduling.
Sunday, December 20, 2020
TRANSFORMER
Basic Working Principle Of An Induction Motor
In a DC motor, supply is needed to be given for the stator winding as well as the rotor winding. But in an induction motor only the stator winding is fed with an AC supply.
- Alternating flux is produced around the stator winding due to AC supply. This alternating flux revolves with synchronous speed. The revolving flux is called as "Rotating Magnetic Field" (RMF).
- The relative speed between stator RMF and rotor conductors causes an induced emf in the rotor conductors, according to the Faraday's law of electromagnetic induction. The rotor conductors are short circuited, and hence rotor current is produced due to induced emf. That is why such motors are called as induction motors.(This action is same as that occurs in transformers, hence induction motors can be called as rotating transformers.)
- Now, induced current in rotor will also produce alternating flux around it. This rotor flux lags behind the stator flux. The direction of induced rotor current, according to Lenz's law, is such that it will tend to oppose the cause of its production.
- As the cause of production of rotor current is the relative velocity between rotating stator flux and the rotor, the rotor will try to catch up with the stator RMF. Thus the rotor rotates in the same direction as that of stator flux to minimize the relative velocity. However, the rotor never succeeds in catching up the synchronous speed. This is the basic working principle of induction motor of either type, single phase of 3 phase.
Synchronous Speed:
The rotational speed of the rotating magnetic field is called as synchronous speed.
where, f = frequency of the spply
P = number of poles
Slip:
Rotor tries to catch up the synchronous speed of the stator field, and hence it rotates. But in practice, rotor never succeeds in catching up. If rotor catches up the stator speed, there wont be any relative speed between the stator flux and the rotor, hence no induced rotor current and no torque production to maintain the rotation. However, this won't stop the motor, the rotor will slow down due to lost of torque, the torque will again be exerted due to relative speed. That is why the rotor rotates at speed which is always less the synchronous speed.
The difference between the synchronous speed (Ns) and actual speed (N) of the rotor is called as slip.
buchholz relay
Transformer - 8: Captive Power Plant
Sr.No. Description Unit Details
1 Name of manufacturer Areva
2 Service and cooling Indoor/ONAN
3 Rated KVA 10000
4 Rated voltage/Current of primary (on noload) Volt/Amp 24000/240.6
5 Rated voltage/Current of secondary (on noload) Volt/amp 11000/524.8
6 Temperature rise by resistance of winding Deg C 50 (Restricted to class F)
7 Maximum Ambient Temperature Deg C 50
8 Rated Frequency Hz 50
9 Connections
High Voltage Star
Low Voltage Delta
10 Vector Group Reference YNd11
11 Tapping Double Wound
12 Type ON Load Tap Changer
13 Tap Range (+10% to -10% in step of 1.25%)
14 No load loss at rated voltage and frequency 9250(Max)
15 Load loss at rated current and 75 Deg C at particular tap 58500(Max)
16 Impedance voltage at rated current at 75 Deg C 8.11% Tolerance
17 Reactance at rated current and frequency % 8.09
18 Resistance at rated current and frequency % 0.557
19 Efficiency at 75 Deg C at UPF at full load % 99.38
20 Regulation at full load at 75 Deg. C
At Unity Power factor % 0.884
At 0.8 power factor (Lag) % 5.488
21 Class of insulation Class F
22 Material of winding Copper
23 Total Weight Kg 16150
24 Approximate overall Dimension
Length mm
Width mm
Height mm
25 Terimal Arrangement
High Voltage(Primary) Bus Duct
Low Voltage(Secondary) Bus Duct
26 Protection Class IP 32
27 Noise Level As per NEMA TR-1
28 Maximum Flux Density Tesla 1.72(max)
29 Referance Standards IS11171,IS 2026
30 Year of Manufacturer 2011
31 Sr.No. 622000198
OLTC details
Sr.No. Description Unit Details
1 Make: Ctr Manufacturer India Limited
2 Type EN 16
3 Serial No 2921447
4 Year of manufacture 2011
5 Rated current
OLTC Amp 300A Max, 149A Normal
TR Amp 240.6A / 524.8A
6 Rated step voltage Volt 313V
7 Transition resistance Ohm 2.2 Ohm
8 Rated insulation level Kv 70Kv RMS/Min,170 KVP1.2/50
9 Motor voltage / frequency 415V,50 Hz
10 Control voltage / frequency 110V,50Hz
11 No. of service taping position 16
12 Direction of power flow
13 Transformer rating MVA 10 MVA
14 Connection diagram:
Saturday, December 19, 2020
Fire Alarm System
Types
httpsps://youtu.be/cVjyDgFrb2g
Heat Detector 57deg.c
Smoke Detector
Wiring Diagram
What is a fire alarm system?
Per the definition in NFPA 72 : A system or portion of a combination system that consists of components and circuits arranged to monitor and annunciate the status of fire alarm or supervisory signal-initiating devices and to initiate the appropriate response to those signals
What are the Basic Components of a Fire Alarm System ?
- Control Panel
- Communications
- Initiating Devices
- Notification Appliances
What is Fire Control Panel ?
A component of the fire alarm system that receives signals from initiating devices and processes these signals to determine the fire alarm output functions.
What are the Communications types available in Fire Alarm System ?
- DACS – Digital Alarm Communications Systems
- POTS – (Plain Old Telephone System) Loop Start with line seizure from the point of demarcation prior to sending it.
- Cable Company Service – assuming you have no CODEC, Voice Compression or back up power issues.
- One Way/Two Way Radio – Mesh Radio and GSM
- IP Communicators with UL listings
- Sole Path Communicators with UL Listings
What are Initiating Devices in Fire System ?
A system component that originates transmission of a change-of-state condition. Examples are Smoke Detector, Heat Detector etc.
What are the Types of Sprinkler Systems ?
Wet Pipe:
Since water is always present in the pipes supplying the sprinkler heads, these types of sprinkler system are quick to react upon the operation of a sprinkler head in a fire scenario.
These are the most common systems and are used in buildings where there is no risk of freezing. Wet systems are required for multi-storey or high-rise buildings and for life safety systems.
Dry pipe:
The pipes are filled with air under pressure at all times and the water is held back by the control valve outside of the protected area. Should a sprinkler head open in a fire scenario, the drop in air pressure opens the valve and water flows into the pipe work and onto the fire. Dry pipe systems are used where wet or alternate systems cannot be used.
Alternate: Alternate systems have the pipes full of water for the summer period, then subsequently drained down and filled with air for the winter. This is typically for buildings that are not heated, e.g. underground car parks.
What are Notification Appliances in Fire System ?
A fire alarm system component such as a bell, horn, speaker, light, or text display that provides audible, tactile, or visible outputs, or any combination thereof. Example are Horn/Strobe, Speaker, Bell etc
What are the different types of fire alarms?
There are two major types of fire alarms: ionization fire alarms and photoelectric fire alarms. Ionization fire alarms detect flaming, fast moving fires – curtain fires, trash can fires, etc.
Photoelectric fire alarms are best for smoky, smoldering fires, such as electrical fires that start out behind walls.
There are also dual sensor fire alarms which, naturally, combine both types into one. To maximize your fire protection, you should install both types (or a combination of the two) to make sure you are completely covered.
What is the difference between conventional and addressable fire alarms?
Conventional fire alarms are ideal for small buildings such as homes, individual offices, or retail shops. Conventional fire alarms go off when they detect smoke in their immediate vicinity and are perfect for evacuating people from a small space.
Addressable fire alarms are more useful for large buildings or building complexes.
The biggest difference between addressable and conventional fire alarm systems is addressable fire alarms have an anunciator panel that shows you (or, more importantly, the fire department) exactly which devices are going off so you can get the proper resources to them as quickly as possible.
What is the difference between a real and false alarm?
None. All alarms are real and are caused by a break in the electrical current passing through the alarm system. Alarms can be sounded by someone activating a pull station, by something as simple as toast burning near a smoke detector, or by an actual fire.
If an alarm sounds, something caused it. It might not be a fire, but don’t bet your life on it. All alarms should be treated as though they were caused by fire until it can be determined otherwise by a competent authority, such as the responding Fire Department.
Over the years we have developed a dangerous complacency in response to fire alarms due to the overuse of the term “false alarm” to characterize an alarm not caused by actual fire.
What is fire alarm?
A fire alarm system is number of devices working together to detect and warn people through visual and audio appliances when smoke, fire, carbon monoxide or other emergencies are present.
These alarms may be activated automatically from smoke detectors, and heat detectors or may also be activated via manual fire alarm activation devices such as manual call points or pull stations.
What should you do if I hear a fire alarm?
Evacuate your building immediately and go to the area your supervisor has designated as a meeting point. For safety reasons, you should evacuate if you hear any alarm, even if it is not in your zone.
Why do we need NFPA 72 compliance?
NFPA 72 is a prescriptive standard that applies to Fire Alarm Systems. While the NFPA 72 standard makes no mention of gas detection, many clients are applying NFPA 72 standards and requirements to both fire and gas detection systems.
There are several advantages to NFPA 72 certified systems that include:
- Allows for the combining of both fire alarm and gas detection functions into a single safety system
- Ensures that local “authorities having jurisdiction” like fire marshals or fire authorities have assurance that the system complies with the applicable codes and standards
- Allows the end-user to lower their insurance costs because they are using a certified system
- A NFPA 72 certified solution ensures that you are complying with the best practices in the industry as drafted by the NFPA
When should we use a PLC vs. a Controller-based solution for F&G ?
The choice between a PLC and Controller-based system is primarily driven by the size of the application.
PLCs are best suited for medium to large size gas detection systems (25+ points of gas detection). For very large systems, PLCs have the advantage of scaling fairly inexpensively to accommodate large point counts. PLCs offer the added benefit of extensive connectivity options for communicating with other DCS or ESD systems.
Controller-based gas detection lends itself to small to medium sized systems very effectively. A controller-based gas detection system is relatively easy to implement, and does not require software programming tools. The hardwired nature of a controller-based solution makes it inherently simple to troubleshoot and support.
What is the difference between fail-safe operation and the supervision requirements of the fire codes and NFPA 72?
The underlying principle of fail-safe design assumes that a process or item of equipment can be designed to take the process to a safe status on equipment failure or power interruption.
This approach requires that the switch to “safe state” be possible without power and that the “normal operating state” of the equipment utilize energized control circuits.
Almost all detection, extinguishing and notification circuits of a Fire Alarm system are not normally energized and are not “fail-safe”.
In order to be sure these fire circuits are intact and ready for use when needed these circuits are “supervised”. Supervision is normally done using a small current or voltage passed through a field circuit device called an “end of line device”. This small current or voltage is continuously monitored to verify that the circuit is intact and ready for operation.
Fire Alarm systems in many cases need to activate suppression or notification equipment in the event of a hazardous condition and these systems require power be available to do so. This is the primary arguments behind the NFPA 72 requirements associated with backup power systems and batteries.
Should we take addressable fire alarm communications in to process areas?
Addressable fire alarm communication devices can be used in process areas when the operating specifications of the devices are compatible with the electrical and environmental conditions found in these process areas.
Most commercial addressable fire alarm equipment are normally rated for operation in general purpose environments with ambient temperatures between 0 and 50°C. Most process area environments have operating temperature ranges outside the 0-50°C range. Many process area environments require devices suitable for Division 1 or Division 2 areas.
When using commercial addressable fire alarm equipment we normally recommend that the addressable equipment be located only in environmentally controlled areas such as crew quarters, control rooms, office areas.
If devices to be connected to the addressable fire alarm system are to be located outside these environmentally controlled areas, we recommend the use of an addressable to conventional circuit converter to be installed inside the environmentally controlled area with a conventional circuit interface to the process area located device.
What is a ‘fire triangle’?
A fire triangle represents the three elements, which causes a fire in a combustible mixture. The three elements are fuel, air and ignition.
What is importance or a ‘hood’ on a gas turbine?
During a gas turbine normal running condition, a hood provides:
a.prevention of turbine high dB noise to outside areas
b.keeps the gas turbine clean from external dust
c.provides a draft for the gas leak to the exhaust through the hood fan
During a gas turbine shutdown condition a hood provides:
a.cooling the turbine body by way of the hood fan
b.During a fire shutdown it facilitates to put out the fire by confining the fire extinguishers on the gas turbine.
Why do we use ‘Halon’ as a fire extinguisher in a gas turbine hood?
Halon is stored in liquid form in a cylinder. When it is released in a hood during the occurrence of the fire, it discharges the halon in gas from. Halon does not act or react on electrical components.
What is the expansion from of B.C.F?
The expansion form of B.F.C is Bromo chloro floride.
In a Ruston gas turbine, why are there two Halon cylinders in each bank? How do they function?
The first bottle is the ‘first shot’ and the second bottle is ‘Extended shot’.
The first bottle discharges the Galon into the hood through a 1’’ pipe in approximately 15 seconds, where as the extended bottle discharges the Halon through a ¼’’ pipe for another ½’’hour period to maintain the inert atmosphere.
How many UV detectors are installed in Solar, Ruston TB-5000 and Ruston TA-1750 gas turbine hoods?
Solar gas turbine hood: 4 UV detectors
Ruston TA-1750 hood: 4 UV detectors
Ruston TB 5000 hood: 12UV detectors
What is voting Logic of UV detectors in Soar and Ruston gas turbines?
There are two voting logics, they are: 1 out of 4 UV s and 2 out of 4 UV s
What happens when UV detectors detect a fire?
1out of 4 UV s: creates annunciation, audible alarm on the control panel and siren in the field (refer to the station drawings for the exact function and operations).
2 out of 4 UV s: creates annunciation, audible alarm on the control panel, a siren in the field, shutdown of the turbine and release of the fire extinguisher (refer to the station drawings for the exact function and operations).
How much is the time delay between fire sensing by a UV detector and confirming with an alarm?
Generally it is set for 4 secs. The UV detectors initiates a fire alarm only when the UV is detecting the fire continuously for 4 secs (refer to the station drawings for the exact settings parameters).
What are the Halon manual release facilities available on a Solar gas turbine?
Auto Halon cylinder can be discharged manually from the fire & gas control panel in the control room. On initiating the manual release:
a.The unit shuts down.
b.The auto Helon cylinder gets discharged in the hood.
c.Auto halon discharge confirmation and the auto Halon cylinder pressure low alarm appears on the control panel.
d.Audible alarm in the control room and siren in the field occurs.
Manual Halon cylinder can discharged manually from the field through a pall string. On initiating the manual release:
a.The unit shutsdown.
b.The manual Halon cylinder gets discharged in the hood.
c.Manual Halon discharge confirmation and the manual Halon cylinder pressure low alarm appears on the control panel.
d.Audible alarm in the control room and siren in the field occurs.
Why are there ‘heat switches’ in side the hood, when there are UV detectors?
Heat switches are a mechanical type and they are considered to be a positive type of fire detection system.
The heat switch settings are much higher than the hood temperature.
What maybe the reasons if a unit shutdown on false heat detected alarm?
The reason could be:
a.Hood ventilation fan has failed or stopped.
b.Major hot gas leak inside the hood.
What happens when a heat switch actuates?
On detection of heat, the heat switch initiates the following.
Annunciation, audible alarm on the control panel, a siren in the field, shut down of the turbine and release of fire extinguisher (refer to the station drawings for the exact settings parameters).
Explain the operating principle of a gas monitor?
Gas monitor measures the imbalance in the current loop caused by its active and in-active filaments in the presence of a combustible gas.
Explain the calibration procedure of a gas monitor system.
- Gas sensor loop current or voltage at the sensor head is set as per the manufacturer’s recommended value.
- Gas monitor zero is adjusted to the instrument air.
- A test gas with a known quantity of combustion gas (Generally methane 2% by volume) is fed to the sensor and the span is adjusted to read 40% on the monitor scale (refer to the station drawings for the exact settings parameters).
- The calibration procedure is repeated until the zero and span reads correctly.
What are the alarm and shut down setting on a gas monitor?
Generally on the gas monitor, the alarm is set at 20%rising and the shut down is set at 60%rising (refer to the station drawing for the exact settings parameters)
What has to be done prior to entering a gas turbine hood?
Prior to entering a gas turbine, turn on the ‘ventilation defeat switch’.
What is a ventilation defeat switch?
On activating, the ventilation defeat switch inhibits the release of Halon in the auto mode and also the unit shutdown on ‘ventilation failure’.
How much is the delay between fire detection and Halon release? Why is the time delay required?
A time delay of 15 secs. Is set between the detection of fire and the initiation of Halon release.
This is to achieve effective fire extinguishing by allowing the hood fan to run-down to zero speed and the bleed valves to release the compressed air.
What does a hood ventilation fan do when a fire is detected? And why?
On detection of fire, the fire system initiates the hood fan shutdown. This is to minimize the presence of air the hood for releasing the extinguisher.
What is hydrostatic testing on a fire extinguisher?
The dry chemical contents inside your fire extinguisher are kept under pressure over long periods of time, which can eventually cause damage to the extinguisher shell.
To ensure the shell, hose, and nozzle have no defects, whether due to metal fatigue or other causes, the extinguisher shells are emptied, filled with colored water, and brought up to a specified pressure over a short period of time (typically 30 seconds).
The shell must be able to hold that pressure for one minute (or the time specified by manufacturer’s maintenance procedures) while the cylinder is inspected for signs of stress, leaks, bulging, and other indications of metal fatigue. Hoses on some extinguishers must also be hydro-statically tested.
How do fire sprinkler systems work?
Most conventional sprinkler heads use a small, liquid-filled bulb that acts as a plug to prevent water from escaping out of the sprinkler.Extreme heat causes this liquid to expand, eventually causing the bulb to burst and release the water behind it.
The liquid inside the bulbs comes in a variety of colors, and each color represents the temperature required to activate the sprinkler.
How does fire suppression work?
In order to burn, fire requires a chemical reaction involving heat, oxygen, and fuel. Fire suppression work by disrupting either the chemical reaction or one of the elements involved in the fire.
Numerous different fire suppression systems exist, each of which attacks a fire from a different angle and each of which has advantages and disadvantages in different environments.
What is a clean agent?
Clean agents extinguish fires using an electrically non-conductive gas. This makes them uniquely suited to protecting sensitive electronic equipment and other high-value assets present in your building.
Clean agent fire suppression systems are ideal for extinguishing fires in small spaces such as cabinets or the inside of equipment as well as for large-scale applications such as semiconductor facilities or data centers.
Clean agents do not leave behind a residue, eliminating the need for time consuming clean up.
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