Shah Bhogilal Jethalal & Bros (AAAG) We are the Fire Safety Equipment and Fire Protection Equipment Manufacturers and Dealers In India
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Double Outlet
Single Outlet
FM Approved
Special Designs
Screwed Inlet

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Shah Bhogilal Jethalal & Bros (AAAG) We are the Fire Safety Equipment and Fire Protection Equipment Manufacturers and Dealers In India
HYDRANT VALVES
Double Outlet
Single Outlet
FM Approved
Special Designs
Screwed Inlet
Gunmetal, ISI Marked
Gunmetal,MMD Approved
Gunmetal
Stainless Steel, ISI Marked
Stainless Steel
Gunmetal
Stainless Steel
Underground Fire Hydrant
Standpipe, Single Outlet
Standpipe, Double Outlet
Hydrant Key with Bar, Aluminium
Hydrant Key with Bar, Carbon Steel
Standard Nozzles
Special Nozzles
Hose Reel Nozzles
Single Outlet Stand Post, Carbon Steel
Double Outlet Stand Post, Carbon Steel
Double Outlet Stand Post with Pumper Connection, Carbon Steel
LX Foam Branches, Non Self-Inducting
LX Foam Branches, Self-Inducting
LX Foam Branches, UL Listed
MX Foam Branches & Pourers
HX Foam Generators
Portable Inline Inductors
Portable Inline Inductors, UL Listed
Mobile Foam Trolleys
Hose Ramp, Rubber
Hose Washing Machine
Jet Type Water Ejector
Turbine Driven Water Ejector (1200 lpm), Aluminium
Turbine Driven Water Ejector (1200 lpm), Gunmetal
Hose Binding Machine, Manual
Hose Clamp, Aluminium
Hose Clamp, Canvas
Hose Bandage, Canvas
Hose Strap, Canvas
Hose Sling, Canvas
Fire Bell, Brass
Delivery Valve For Pump, Gunmetal
Delivery Valve For Pump, Aluminium
Delivery Valve For Pump, Stainless Steel
Fire Hook
Fireman Axe
Axe Belt & Pouch
Fireman Axe, Multi-Edge
Fire Beater
Basket Strainer
Canvas Fire Bucket
Handline Branch Adaptor
Q1. What is the difference between Wet risers and Dry riser systems?
Q2. Why are Air Release valves required in Building Riser systems?
Q3. When are orifice plates required to be installed with hydrant valves?
Q4. What is the purpose of providing Hose reels in buildings?
Q5. What is the difference between vertical and horizontal type hose reels?
Q1. What is the difference between Wet risers and Dry riser systems?
Dry Risers are normally installed in Low Rise buildings (those less than 23 M in height). The riser pipe is empty and does not have any water in them. In the event of a fire incident, water is pumped into the riser from Fire tenders using the Fire brigade inlets provided at the bottom of the riser.
Wet risers provided in high rise buildings (more than 23 M in height). In these systems, the riser pipe is always full of water, and is pressurized using gravity tanks, or dedicated fire pumps. Hence water is always available for fire fighting. Fire brigade inlets are also provided on wet riser systems, to provide water in case of failure of the system fire pumps.
Q2. Why are Air Release valves required in Building Riser systems?
Air Release valves are required in dry riser systems installed in buildings. When water is pumped into the riser through Fire Brigade inlets (using Fire Tender pumps), the air in the pipe should be released from the highest point in the piping to allow water to flow in (and prevent compression of the trapped air). Air release valves (installed at the top of the riser) allow the air to be released, but once water reaches the valve, it closes the valve, allowing build up of water pressure in the riser, and enabling fire fighters to use this water for fire fighting
Q3. When are orifice plates required to be installed with hydrant valves?
In high rise buildings, the pressure will vary at the different floors due to the difference in head at the different levels. This can result in vast difference in pressure from top of the building to the bottom. To ensure that the same standard pressure is available from hydrant valves at all levels, different size orifice plates are required to be fitted at the inlet of the hydrant valve. The orifice size will depend on the level of the hydrant and the running pressure required from the hydrant.
Q4. What is the purpose of providing Hose reels in buildings?
Fire Hose Reels provide a first line of defence for building occupants in the event of fire. Like fire extinguishers, these are considered first aid appliances. Due to a low flow rate, there is no problem of jet reaction, and being simple in operation, hose reels can be safely used by occupants to fight small fires in buildings.
Q5. What is the difference between vertical and horizontal type hose reels?
Vertical hose reels are standard fire fighting hose reels used in building applications. These are preferred in building applications due to low space requirement. The hose reel pipe is normally of ¾” to 1” diameter size, with 30 mtrs length.
Horizontal hose reels are larger (in width) as compared to vertical hose reels (and can thus accommodate longer lengths of hose), but have similar applications. As it is possible to mount larger diameter hoses (typically 1 to 1¼”), these are preferred in industrial fire fighting applications, and for use on Fire Tenders.
Q1. What is purpose of providing fire fighting monitors?
Q2. Are Water Monitors different from Foam Monitors?
Q3. Is it possible to convert a Water Monitor to Foam monitor by changing the monitor nozzle?
Q4. What is the difference between Solid Jet nozzle and Master Stream nozzle fitted on monitors?
Q5. What is the ‘range’ and ‘effective range’ of a Monitor?
Q6. How is the location of a monitor decided?
Q7. What are HVLR monitors, and what are its applications?
Q8. What are Remote Control Monitors (RCM), and what are its applications?
Q9. Is it possible to operate RCMs in the event of power failure?
Q10. What are the applications of Portable monitors?
Q11. What is the application of Oscillating monitors?
Q12. What are the normal installation requirements for monitors?
Q13. What are the normal maintenance requirements for monitors?
Q1. What is purpose of providing fire fighting monitors?
There are limitations on the amount of water that can be discharged from handheld branches, (typically 1000 lpm), as higher flows have very high back thrust, which makes it impossible for firefighters to handle them safely. Due to this, handline nozzles/ branches have limited range, and hence limited effectiveness.
To fight bigger fires, which give out large amount of radiation, it is necessary to throw water/ foam in sufficient quantity from a safe distance. As explained above, it is impossible to do this using handline branches. Fixed monitors provide the solution as they can project water/ foam further due to the higher quantity of agent, and their design and installation allows the back thrust to be handled safely.
Q2. Are Water Monitors different from Foam Monitors?
Monitors can be used to project water or fire fighting foam (or in some cases, even Dry chemical powders). Water monitors typically project only water, while Foam monitors can be used to project water as well as foam.
The monitors projecting foam require special nozzles which allow for induction of foam concentrate (and in the case of aspirated foam nozzles, aereation of the foam solution). Thus water and foam monitors differ mainly due to the nozzles which are fitted on the monitor body (while the monitor body remains common for both).
Q3. Is it possible to convert a Water Monitor to Foam monitor by changing the monitor nozzle?
Technically, the monitor nozzle is the part where the foam induction & aeration (in case of primary aspirated foam) takes place. Hence it is possible to convert a water monitor to a foam monitor by changing the water nozzle to a foam nozzle (aspirated or unaspirated).
However, it is important to ensure that the capacity of the foam nozzle is matching to the capacity of the water nozzle to get required performance. Contact the monitor supplier to check suitability. Note : Connecting a Foam branch e.g. FB 10X (450 lpm capacity), at the outlet of a 75 mm waterway monitor (which typically has a flow of around 2800 lpm) will produce only a limited foam range i.e. the range of the FB10X branch only. Such arrangements are not recommended.
Q4. What is the difference between Solid Jet nozzle and Master Stream nozzle fitted on monitors?
Solid jet nozzles are the most commonly used nozzles on fixed monitors in the country. These nozzles project the water in the form of a solid jet stream for long range firefighting, and it is not possible to alter or change this pattern.
Master stream nozzles project water in the form of a hollow jet, which has a better range as compared to solid jet streams, hence these are being preferred nowadays. The other advantage is that the pattern can be changed from hollow jet to narrow fog (for vapour dispersal/ cooling) or wide fog (radiant heat protection).
Q5. What is the ‘range’ and ‘effective range’ of a Monitor?
The range of a Monitor is measured from its installation point to where the majority of the water/ foam discharge falls. However, some standards/ practices measure the distance to the farthest point of the discharge. Range will be mentioned in the data sheet of the monitor.
The ‘effective range’ is not an official definition but gives the actual range of the monitor in real conditions (taking into consideration factors such as unfavourable wind conditions). For e.g. a monitor with a 60 M range would actually be installed at a distance between 35 to 45 M from the hazard, to cater for unfavourable wind conditions, and ensure effective performance.
Q6. How is the location of a monitor decided?
When deciding the location of a monitor, factors such as the range of the monitor, expected wind direction/ speed, radiation from the fire hazard, site conditions, etc, need to be considered. For better coverage, it may be necessary to provide more than one monitor at different locations – this takes care of fluctuating wind directions and problems of accessibility during actual emergencies. For hazards at a height (e.g. process columns), or at jetties, monitors are also required to be installed at a height (tower mounted) to provide effective coverage.
Q7. What are HVLR monitors, and what are its applications?
HVLR (High Volume Long Range) monitors are special application monitors, suitable for high volume applications from a safe distance, ensuring safety of personnel. HVLR monitors find applications where risk of radiant heat from severe fire hazards is high, especially Oil & Gas facilities, flammable liquid storage and processing, ports, etc.
While the monitors can be used for any situation where the application of water or fire fighting foam on the hazard area is required, it is specifically useful for flammable liquid large spills and tank fires. The high application rates from HVLR monitors are more effective in controlling such fires, resulting in lower extinguishing times.
Q8. What are Remote Control Monitors (RCM), and what are its applications?
Remote Control Monitors (RCM) are standard monitors fitted with arrangements to operate the same from a remote location. RCMs normally employ Electric or hydraulic motors to operate the swivel joints for vertical/ horizontal movement of the monitor, as well as to adjust the discharge pattern of the nozzle.
RCMs find application in industries/ operations having severe fire hazards, such as Oil & Gas facilities, flammable liquid storage and processing, Ports, etc, where exposing personnel to the high radiant heat/ smoke and gases during fire incidents is not an option. RCMs provide the ideal solution to such problems as they can be operated from a safe and remote location.
Q9. Is it possible to operate RCMs in the event of power failure?
In the event of power failure, it is not possible to operate the RCM remotely. However, RCMs are provided with manual standby arrangement to operate the same manually. In this case, the operator has to stand near the monitor to operate the handwheels for the horizontal and vertical movement, as well as or adjusting the discharge pattern of the nozzle.
Q10. What are the applications of Portable monitors?
Portable monitors are employed where far-reaching streams are required but fixed monitors are not available. Portable monitors are normally carried on Fire Trucks (or even smaller vehicles) and quickly assembled and deployed at the emergency scene. Fire hoses are connected to the monitor, and once the hoses are charged, the monitor provides an effective far reaching stream. These monitors are suitable for use with water and foam solution as appropriate to the hazard.
Q11. What is the application of Oscillating monitors?
Certain fire hazards require the cooling of large hazard areas using water application. Similarly, it may be required to apply foam over a large area in some situations, instead of specific point application. This can be achieved by using oscillating monitors, as the monitor oscillates in the horizontal plane, providing coverage to a large area instead of a specific location. Oscillating Foam/ Water Monitors use gear boxes and mechanical means to oscillate the monitor in a preset angle. The power for movement can be an external power source or can be aqua powered (i.e. using a small quantity of the water supplied to the monitor). Aqua powered units are preferred as they do not require any external power source. These are also recommended where unmanned operation is necessary in view of severe fire hazards
Q12. What are the normal installation requirements for monitors?
Location of monitors is dictated by operational requirements such as type of hazard, range of the monitor, wind direction and speed, unhindered ‘view’ of the hazard, etc. When installating monitors, the following should normally be considered –
The mounting arrangement is suitable to the back thrust from the monitor.
Ensure that the mating flange of the hydrant post is matching to the valve inlet flange.
Use approved gasket between flanges, and good quality nuts/ bolts.
Ensure that full rotation of the monitor is possible, and height of the monitor handwheels are at proper height.
Q13. What are the normal maintenance requirements for monitors?
When tested and maintained regularly, monitors will give effective service when called upon to do so in an emergency. Monitors require minimal maintenance, however problems can occur due to entry of stones/ debris into the lines. For foam monitors, the foam solutions used (especially AFFF) are corrosive in nature, and if monitor is not flushed properly after operation, this can cause development of corrosive flakes/ pieces, which may cause problems during operation. Normal maintenance activities include –
Periodic visual inspections (at least monthly)
Periodic operational tests (as mandated by manufacturer/ site requirement)
Proper flushing of foam monitors after operation.
Greasing of swivel joints at specified intervals.
Periodic replacement of rubber washers/ gaskets as required by site conditions.
Periodic painting of external body (as required by site conditions).
Q1. What is fire fighting foam and what makes it useful in fire fighting applications?
Q2. How is fire fighting foam classified in terms of expansion & fire fighting application?
Q3. What is the difference between primary aspirated (aspirated) and secondary aspirated (unaspirated) foam?
Q4. Are primary aspirated (aspirated) and secondary aspirated (unaspirated) foam used for different applications?
Q5. What are the standard capacities of Low expansion Foam branches? Can the capacities be identified from the model?
Q6. What is the difference between self-inducting Foam branches and those employing Inline inductors?
Q7. What are the standard capacities of Medium expansion Foam branches & pourers?
Q8. Can medium expansion foam be used instead of low expansion foam?
Q9. How is foam concentrate mixed with the water stream?
Q10. What are the limitations of Inline Inductors?
Q11. Can any type of Foam concentrate be used with a specific Foam equipment?
Q12. How is Jet Ratio Controller unit used alongwith Foam monitor?
Q13. Are there any specific installation requirements for Foam Monitors?
Q14. What are the operational requirements to be kept in mind for Foam equipment?
Q15. What are the maintenance requirements for Foam equipment?
Q1. What is fire fighting foam and what makes it useful in fire fighting applications?
Fire fighting foam is a collection of bubbles, formed by the mixing of water, foam concentrate (or foam compound) and air. The mixture of water and foam concentrate is called foam solution with water being 97% to 94% of the mixture, while 3% to 6% is the foam concentrate. The foam solution is mixed with air, the ratio of which can vary from 1:2 to over 1:1000 depending upon the type of foam equipment used and its application.
Fire fighting foam being lighter than water can float on flammable liquid (while water sinks below the liquid surface), hence is very effective in fighting flammable liquid (Class B) fires. It can also be used to cover flammable liquid spills and prevent fires. With higher expansion ratios (more than 1:500) it is also used to fight Class A fires, where it results in minimal water damage.
Q2. How is fire fighting foam classified in terms of expansion & fire fighting application?
Fire fighting foam is classified into three types of foam, based on expansion ratio (and consequently, its application). Most fire manuals use this classification –
Low expansion foam :expansion ratio from 1:2 to 1:20 (most commonly used between 1:3 to 1:10, useful for flammable liquid fires)
Medium expansion foam :expansion ratio from 1:21 to 1:200 (most commonly used between 1:30 to 1:60, useful for tackling spills/ spillfires)
High expansion foam :expansion ratio from 1:201 to 1:2000 (most commonly used between 1:400 to 1:1500, useful in Class A and LNG applications
Q3. What is the difference between primary aspirated (aspirated) and secondary aspirated (unaspirated) foam?
Nowadays, low expansion foam is again sub-divided into two types :
Primary aspirated foam :mixing of foam solution with air occurs inside the equipment, resulting in expansion ratios from 1:7 to 1:12 (e.g. foam branches, foam barrels)
Secondary aspirated foam :mixing of foam solution with air occurs after solution leaves the nozzle, resulting in comparatively lower expansion ratios i.e. 1:3 to 1:6 (e.g. Aqua foam nozzles, handline nozzles)
It may be noted that for secondary aspirated foam, only certain types of foam concentrates (AFFF, AR-AFFF, FFFP) will give proper results.
Q4. Are primary aspirated (aspirated) and secondary aspirated (unaspirated) foam used for different applications?
Though both aspirated and unaspirated foam are low expansion foams, and used for the same application, unaspirated foam can be projected further due to higher density as compared to aspirated foams. Hence unaspirated foam is increasingly being preferred for fighting large flammable liquid fires where large capacity foam monitors are employed in the attack.
Q5. What are the standard capacities of Low expansion Foam branches? Can the capacities be identified from the model?
Though the flow capacity of Low Expansion (LX) Foam branches can vary from manufacturer to manufacturer, standard foam branches are normally designed for the following capacities – 200/225 lpm (FB 5X) 400/450 lpm (FB 10X), 800/900 lpm (FB20X) (Note – all flows at 7 kg/cm2 inlet pressure).
Flow capacities for AAAG LX Foam branches can be identified from the model – the ‘5’ & ‘10’ in the FB5X and FB10X refer to flow of 50 and 100 Gallons (British) per minute. This converts to 225 lpm (for FB5X) and 450 lpm (for FB10X) using conversion of 1 Gallon (British) = 4.5 Litres. The ‘X’ in the model number refers to expansion ratio of the branch i.e. roman numerical ‘X’ indicates approximately 10 times expansion.
Q6. What is the difference between self-inducting Foam branches and those employing Inline inductors?
Self inducting foam branches allow induction to be carried out at the branch, while for foam branches employing inline inductors, induction takes place at the inductor. Normally, operation of foam branches using Inline Inductors is preferred where the fire risk is higher, and it would not be safe to do the induction at the branch (as it involves supplying foam concentrate containers near the branch, and may hamper the movement of the foam branch operator). Hence foam branches with inline inductors are preferred where there is a risk of combustible and flammable liquid fires.
Technically, there is little difference in both types of operation i.e. operating range, expansion, etc at the same inlet pressure at branch. Foam quality also can be expected to be the same whether using self inducting foam branches or those employing inline inductors.
Q7. What are the standard capacities of Medium expansion Foam branches & pourers?
Like LX Foam branches, Medium expansion (MX) Foam branches are also available in matching capacities i.e. 200/225 lpm and 400/450 lpm. Higher capacities are available for MX pourers i.e. 600 lpm, 900 lpm and 1100 lpm.
Q8. Can medium expansion foam be used instead of low expansion foam?
Medium expansion foam has a higher expansion ratio (1:30 to 60) as compared to low expansion foam, hence can cover spills quicker. However, due to larger size bubbles, it cannot withstand the heat from flames, and breaks down much more quickly as compared to low expansion foam. Hence, it is not possible to use MX foam for LX foam applications (such as pool/ spill fires).
Q9. How is foam concentrate mixed with the water stream?
Different methods are employed for mixing the foam concentrate into the water stream. Most commonly used methods include – Inline foam inductor (portable or fixed), Jet Ratio Controller unit, Around the pump proportioner, Bladder tank proportioning, Balanced Pressure proportioning, etc.
Q10. What are the limitations of Inline Inductors?
Inline inductors work on the venturi principle. Hence for the induction to be accurate, it is necessary that the outlet pressure be at least 65% of the inlet pressure. This puts a limitation on the length of hose/ piping that can be connected between the inductor and the discharge device. It also puts a limitation on the elevation of the discharge device. Also, varying pressures can result in inaccurate induction.
Q11. Can any type of Foam concentrate be used with a specific Foam equipment?
Different type of Foam concentrates have different applications, and require different levels of ‘working’ (or aeration and agitation). Hence foam equipment is normally designed for a certain type (or types) of foam concentrate. Listed or approved Foam equipment is also approved/ listed with a specific foam concentrate. It is recommended that suitability of foam concentrate with the equipment be checked before use.
Q12. How is Jet Ratio Controller unit used alongwith Foam monitor?
Jet Ratio Controllers (JRC) are high efficiency venturi devices that deliver a concentrated foam solution to the monitor. The advantage with JRCs is that it allows the foam concentrate mixing at some distance away from the monitor. Hence foam container deployment and handling can be at a safe distance away from the fire scene
A pressurized water supply using hose from a hydrant valve (or Pump) is connected to inlet of the JRC unit. A PVC suction tube with Dip tube is used to induct foam concentrate from the containers into the JRC unit. A hose (or hoses) connected from the JRC outlet to the Foam nozzle delivers a concentrated foam solution to the monitor.
Q13. Are there any specific installation requirements for Foam Monitors?
When installing Foam monitors, ensure the following –
Height of the monitor is not more than 3 m from grade level (for monitors where induction occurs at the monitor nozzle i.e. using pick up tube or hose).
The mounting arrangement is suitable to the back thrust from the monitor.
Ensure that the mating flange of the hydrant post is matching to the valve inlet flange.
Use approved gasket between flanges, and good quality nuts/ bolts.
Ensure that full rotation of the monitor is possible, and the height of the monitor handwheels is at proper height for operator use.
Q14. What are the operational requirements to be kept in mind for Foam equipment?
Quality of fire fighting foam produced by Foam equipment depends upon certain factors such as the quality of Foam concentrate, its proper induction in the water stream and mixing of foam solution with air (aeration). As foam equipment is designed for induction and aeration rates at a certain working pressure, it is important to ensure that the equipment is operated at or within the specified pressure range. Operation of the foam equipment at pressure that varies greatly from the working pressure can result in ineffective performance of the equipment (it may also be noted that working pressure normally refers to pressure at the inlet of the equipment, not the line or pump room pressure).
Foam equipment is also designed for use with a specific type of foam concentrate/s. Optimum performance of the equipment can be obtained only when used with recommended foam concentrates.
Q15. What are the maintenance requirements for Foam equipment?
Many of the commonly used foam concentrates are corrosive to carbon steel, and it is important to ensure proper flushing with fresh water after each use. Proper drainage in foam equipment or fixed systems is therefore, recommended. Bronze or Stainless steel (SS304/ SS316) is therefore, normally preferred for foam equipment.
Parts requiring replacement are usually rubber washers/ rings. When replacing them, remember to use original washers/ rings. If metal parts/ components are required to be replaced, use original spares, as material properties are important for foam equipment. Equipment may be painted externally once in 2/3 years depending upon atmospheric conditions – do not paint parts which are not originally painted.
Q1. What is the purpose of handline firefighting branches and nozzles?
Q2. What are the basic types of handline nozzles?
Q3. What are the shortcomings of short branch with nozzle?
Q4. What are the advantages and shortcomings of the basic spray (combination) nozzle?
Q5. How are constant flow nozzles different from Combination nozzles?
Q6. What are the advantages of using a selectable flow nozzle?
Q7. What are automatic nozzles and how do they function?
Q8. How is quality of fog improved by providing teeth on nozzle outlets?
Q9. As far as quality of fog is concerned, how do spinning teeth compare with solid teeth?
Q10. Which type of valves are provided on handline firefighting nozzles?
Q11. What are the factors to be considered when procuring firefighting handline branches?
Q12. What are the normal maintenance requirements for handline nozzles?
Q1. What is the purpose of handline firefighting branches and nozzles?
To fight small and medium size fires, it is necessary to direct water from a safe distance onto the fire area, in the required form (large/ small droplets). Pressurized water can be conveyed to the affected area using fire fighting hoses. However, to project it to the fire area, it is required to convert the pressure energy of the water into velocity energy. At the same time, it is necessary to project the water in the desired form i.e. jet, spray or fog, to ensure maximum effectiveness depending upon the situation. Handline firefighting branches and nozzles do the job of converting the pressure energy to velocity energy and projecting the water in the required form.
Q2. What are the basic types of handline nozzles?
There is no standard classification of handline nozzles, as they can be sub-divided into different types depending upon on pattern, flow quantity, etc. Normally they are classified as follows –
Solid bore nozzles (which discharge water in form of a solid jet only)
Combination or Spray nozzles (or Jet/Spray type nozzles) which discharge in form of a hollow jet, narrow fog or wide fog. These can be further sub-divided into –
Multipurpose nozzles (those discharging water in form of a solid jet as well as spray, even simultaneously).
Constant flow nozzles (those discharging same flow at a given pressure)
Variable flow nozzles (flow can be varied manually for a given pressure)
Automatic nozzles (flow varies depending upon pressure)
Q3. What are the shortcomings of short branch with nozzle?
In short branch with nozzle, the pattern of flow is only in form of a solid jet, which means that this branch is unable to project water in form of fog, or spray for protection. At the same time, due to the absence of a valve in the nozzle, it could not be shut off by the nozzle man, which means that he has no control over the branch.
Q4. What are the advantages and shortcomings of the basic spray (combination) nozzle?
The main advantage of the combination or spray nozzle is that it is provided with a pattern changeover mechanism as well as a shut off arrangement. The pattern changeover mechanism allows changing the pattern from jet to spray or vice-versa, while the shut-off mechanism allows the operator to shut down the flow, when required.
In the basic spray nozzle, the flow varies as the pattern changes from the hollow jet to the spray pattern (normally the flow in jet pattern is lesser and increases as the pattern changes to fog)
Q5. How are constant flow nozzles different from Combination nozzles?
In certain combination nozzles, the flow changes with pattern. However, in Constant flow nozzles (also known as Single gallonage nozzles), the flow remains constant throughout the different range of discharge patterns i.e the flow will remain same whether discharging in form of a jet or spray.
Q6. What are the advantages of using a selectable flow nozzle?
Selectable flow nozzles incorporate an arrangement to vary the outlet orifice size, hence the flow can be varied by changing this orifice size. The operator can set the flow without shutting down the line, depending upon the pressure available, and other operational considerations. This means that the nozzle can be used effectively even in varying pressure conditions by the operator himself, without any dependence on the pump operator.
Q7. What are automatic nozzles and how do they function?
An automatic nozzle maintains a relatively constant pressure over a wide range of flows. Such nozzles have an arrangement in the nozzle which controls the flow by restricting the orifice outlet to maintain pressure.
If the pressure is relatively low, the nozzle orifice will automatically restrict the flow, causing pressure buildup at the outlet, and consequently resulting in a good quality discharge pattern. Similarly, if the pressure increases, the orifice opens to allow more flow, again adjusting to a constant pressure at the outlet of the nozzle.
Q8. How is quality of fog improved by providing teeth on nozzle outlets?
Providing teeth on the nozzle outlet serves two purposes; first, in the narrow fog position, it deflects part of the water to the centre of the spray (which is otherwise hollow). Secondly, in the wide fog position, it caused the water curtain to break up into streams which then impinged on one another to create a better quality fog. A variety of different designs of teeth (fixed/ spinning/ flexible) can be used to create this fog.
Q9. As far as quality of fog is concerned, how do spinning teeth compare with solid teeth?
There is no clear research data to prove superiority of spinning teeth over solid teeth. Certain trials show that spinning teeth rotating in the fog position, cause the break up of the water curtain into fine droplets, which are ideal for fire gas cooling operations. It may be noted, however, that there is no conclusive evidence on the superiority of spinning teeth.
Q10. Which type of valves are provided on handline firefighting nozzles?
For a long time, manufacturers have been using the ball valve for controlling the flow in the nozzle, as it is a proven design, operates well at the pressures used, and is relatively maintenance free. The ball can be of metal, or polymer based materials.
Another type of valve used nowadays is the slide valve, in which a hollow cylinder moves back and forth along the central axis, and seals against a polymer seat. Due to the movement of the cylinder, it causes a variation in the orifice gap between the cylinder and the seat and hence controls the flow.
Q11. What are the factors to be considered when procuring firefighting handline branches?
When procuring handline nozzles, the following factors are normally considered –
Suitability to risk (whether the nozzle is suited to the type of fires likely to be encountered)
Pattern & Flow range (what are the discharge patterns available & whether nozzle flow is suited to risk and to the operators).
Material of construction
Maintenance and durability
Ergonomics (whether comfortable to handle for the type of operators present)
Q12. What are the normal maintenance requirements for handline nozzles?
Maintenance requirements can vary from one handline nozzle to another. Simple jet nozzles require virtually no maintenance, while new combination nozzles can require periodic replacement of components. Normal maintenance activities include –
Periodic visual inspections (at least monthly)
Periodic operational tests (as mandated by manufacturer)
Periodic replacement of rubber washers/ O rings (as mandated by manufacturer).
Periodic replacement of valve seats/ springs/ spinning teeth (as mandated by manufacturer).
Q1. What is the difference between Landing Valves and Hydrant Valves?
Q2. Are Hydrant valves available in different designs and sizes?
Q3. Are different Hydrant valves inlet connections available?
Q4. What is the difference between Double headed Hydrant valve and Double headed hydrant post with hydrant valves?
Q5. What are the pressure ratings for different Hydrant valves?
Q6. What are the flow requirements for different Hydrant valves?
Q7. What are the different materials of construction used for Hydrant valves?
Q8. Do Stainless Steel Hydrant valves offer any advantages as compared to Bronze (Gunmetal) Hydrant valves?
Q9. Are there any specific installation requirements for Hydrant valves?
Q10. What are operating requirements to be kept in mind for hydrant valves?
Q11. What are maintenance requirements for Hydrant valves?
Q12. Can I use hydrant parts of another company in hydrant of another brand?
Q13. Where are underground hydrants used?
Q1. What is the difference between Landing Valves and Hydrant Valves?
The name ‘Landing valves’ were used to describe valves for fire fighting provided on Risers in buildings, as these were typically located in Staircase landings to allow easy access to Fire fighters. Hence, the name ‘Landing valve’ came to be associated with these type of valves in buildings. As firewater systems for municipal/ industrial applications are typically called hydrant systems, the term ‘Hydrant valves’ was used to describe the valves fitted on the Hydrant stand posts in such systems. Both terms actually refer to the same type of valve, though the term ‘Landing valve’ is more associated with building applications.
Q2. Are Hydrant valves available in different designs and sizes?
Though the basic function of hydrant valves remains the same, depending upon application/ location/ code requirements, different designs and sizes are available. Typically, Hydrant inlets can be flanged or threaded (threaded being used for low pressure applications, typically upto 7 kg/cm2). Inlet sizes could vary from 100 NB (4”) size to 50NB (2”) size. Similarly outlets can be have instantaneous/ threaded/ storz couplings, and sizes can vary from 75 NB (3”) to 38 NB (1.5”).
Orientation of the outlet can also be different depending upon its mounting arrangement, with outlet angle varying from 90º (straight) to 45º (Oblique).
Q3. Are different Hydrant valves inlet connections available?
As mentioned above, hydrant valve inlets can be threaded or flanged. Present BIS standards do not specify threaded connections, however same are being commonly used in many regions and countries around the world.
Q4. What is the difference between Double headed Hydrant valve and Double headed hydrant post with hydrant valves?
A double headed hydrant valve consists of a common inlet and body with two outlets. This will have two bonnets, stems and wheels. Double headed hydrant valves were earlier being used where higher flows were required due to severe hazards i.e. you could connect two hoses from the double headed hydrant.
Single headed hydrant valves are standard hydrant valves with a single inlet and single outlet. A double headed hydrant post is fitted with two separate single hydrant valves, allowing two hoses to be connected from the same hydrant post.
Due to the larger body of double headed hydrant valves, there are safety concerns, and nowadays, double hydrant posts with two separate single hydrant valves are used instead.
Q5. What are the pressure ratings for different Hydrant valves?
Normally, fire fighting equipment to be connected to and operated from a hydrant valve is designed for 100 psi (approx 7 kg/cm2) pressure. Hence the normal operating pressure is approx 7 kg/cm2. However, this may vary for different applications for e.g. on large industrial complexes, the operating pressue may be in the range of 10-11 kg/cm2. Similarly, if small diameter hoses (38 mm e being used with hydrants, the pressure may be 4 to 5 kg/cm2.
Q6. What are the flow requirements for different Hydrant valves?
Flow requirements from hydrants depend on the type of application and the standard fire fighting equipment (branches) which will be connected to the hydrant. This could vary from approximately 2200 lpm (for a double headed hydrant) to 600 lpm for hydrants having 38 NB (1.5”) outlets.
Q7. What are the different materials of construction used for Hydrant valves?
Most standards around the world, including BIS, allow the use of different materials for construction for hydrant valves, which include Bronze, Aluminium, Stainless Steel. The main requirements are mechanical strength, corrosion resistance and suitability to application.
Q8. Do Stainless Steel Hydrant valves offer any advantages as compared to Bronze (Gunmetal) Hydrant valves?
Stainless steel (SS) has higher mechanical (tensile) strength as compared to Bronze, hence SS Hydrant valves can withstand higher working pressures as compared to Bronze valves. Stainless steel is non corrosive, and at the same time, can survive harsh industrial environments. Stainless steel, unlike Bronze, has a low resale value, and this reduces theft of the valve parts, which is common with Bronze valves. Cost of Stainless steel and bronze valves are comparable at present marketrates, however due to its durability and long life, the cost of Stainless Steel valves is actually much lower over its entire working life.
Q9. Are there any specific installation requirements for Hydrant valves?
When installing hydrant valves, ensure the following –
Ensure that the mating flange of the hydrant post is matching to the valve inlet flange.
Orientation of hydrant valve outlet should be as per standard practices and should allow easy connection of hoses.
Use approved gasket between flanges, and good quality nuts/ bolts
Ensure minimum height of 750 mm from grade level.
Ensure that the hydrant valve rated working pressure is matching to the hydrant system line pressure. If hydrant system pressure is higher, ensure that the hydrant valves are rated for a higher pressure, which matches system pressure.
If Orifice plates are required to be used, ensure that these are of standard size, and provided by the original supplier. Installation of orifice plates should be as per standard practices.
Q10. What are operating requirements to be kept in mind for hydrant valves?
Proper operation of hydrant valves will result in a long and useful life, and at the same time, will ensure that the valve gives effective service when required to do so in an emergency. Certain points to be kept in mind while operating hydrant valves –
Ensure that operators are familiar with operation of the hydrant i.e. direction for opening/ closing.
Open and close the valve slowly – this will prevent water hammer, and ensure safety of operator and equipment.
Do not overtighten the valve (or use spanners) when closing. If valve leaks after closing, it means that the seat washer is not sealing against its seat. This could be due to foreign objects, or wear and tear of washer. Overtightening may damage the threads, bonnet and result in failure of hydrant body.
Q11. What are maintenance requirements for Hydrant valves?
Hydrant valves, if well designed and manufactured as per quality standards, require little maintenance. Proper periodic cleaning and light greasing of stud threads, and light oiling of the lug will ensure proper operation. Normal parts which can require replacement are the rubber washer (hydrant outlet), seat washer and the gland packing. Use standard washers, if replacement is required.
Q12. Can I use hydrant parts of another company in hydrant of another brand?
Though marked/ approved/ listed hydrant valves may look similar in design/ shape, the component size and/ or thread types may differ for different brands. Using externally fabricated/ manufactured parts may also be unsafe, as they may not have the same material properties. Hence it is advisable to use spare parts from the same supplier of the hydrant valve.
Q13. Where are underground hydrants used?
Underground Fire hydrants or flush type hydrants are used in certain parts of the world, which experience extremely cold weather (and water in above ground hydrants can freeze). They are also suitable for areas like Air fields where installation of normal hydrants is not possible. The Hydrant outlet is just below the surface of the ground protected by a cover, which is flush with the pavement, and so does not interfere with the aboveground operations.
For operating these hydrants, stand pipes are connected to the outlet of the underground hydrants, and hoses can then be connected to the outlet of the stand pipes.
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Our esteemed clients have reposed their faith in us for quality and performance, and have been the major factor in our growth and success. AAAG has over a thousand clients, which includes large corporates as well as dealers all over the country. Our products have been exported to countries such as the USA, UK, Italy, Singapore and the Middle East. Within the country, our clientele is a veritable who’s who of the Indian Industry, and covers every major sector of commerce and industry, including Oil & Gas, Petroleum Refining and Storage, Petrochemicals, Chemicals & Fertilizers, Pharmaceuticals, Steel, Cement, Engineering/Consulting, Construction and Infrastructure.
Refinery & Petrochemicals
Bharat Petroleum Corprn. Ltd, Kochi
Bharat Petroleum Corprn Ltd, Mumbai
Bharat Oman Refinery Ltd.
Chennai Petroleum Corprn Ltd
Essar Oil Limited
Haldia Petrochemicals Ltd.
Hindustan Petroleum Corprn. Ltd, Vizag
Hindustan Petroleum Corprn. Ltd, Mumbai
HPCL Mittal Energy Ltd.
Indian Oil Corprn. Ltd. Baroda
Indian Oil Corp. Ltd. Panipat
Indian Oil Corp. Ltd. Mathura
Indian Oil Corp. Ltd. Guwahati
Indian Oil Corp. Ltd. Barauni
Indian Oil Corp. Ltd. Bongaigaon
Numaligarh Refinery
Oil India Limited
Oil & Natural Gas Corprn Ltd.
ONGC Mangalore Refinery & Petrochemicals
Reliance Industries Ltd, Baroda
Reliance Industries Ltd, Hazira
Reliance Industries Ltd, Nagothane
Steel, Heavy Engineering &Transport
Airport Authority of India
Ashok Leyland Ltd
Bharat Heavy Electricals Ltd
Essar Steel
Hindustan Shipyard Ltd
Hindustan Zinc Ltd.
National Aluminium Co Ltd
Shipping Corprn. of India
Tata Steel Limited
Original Equipment Manufacturers
Amar Rubber Works
Brijbasi Hi-Tech Vehicles Limited
Chhattariya Rubber & Chemicals
Jyoti Rubber Udyog
Newage Industries
Nirmal Rubber Industries
Kooverji Devshi & Co. Pvt. Ltd.
Supremax Equipments
Vijay Fire Vehicles & Pump Ltd.
Wadia Body Builders
Engineering Consultants
Aker Solutions
Engineers India Limited
Foster Wheeler India Pvt. Ltd.
Gannon & Dunkerly Co. Ltd
KSB Engineers
Mecon Ltd.
Mott Macdonald
Punj Lloyd Ltd.
Bridge & Roof Co. India Ltd.
Larsen & Tubro Ltd.
Spack Turnkey Proj. Pvt. Ltd.
Tata Projects Ltd., Hyderabad
Tecnimont ICB Pvt. Ltd.
Toyo Engineering India Pvt. Ltd.
Tata Consulting Engineers Ltd.
Chemicals & Fertilizers
Chambal Fertilizers & Chemicals Ltd
Deepak Nitrite Ltd.
Fertilizers & Chemicals Ltd
Gujarat Alkalies & Chemicals, Baroda
Gujarat Alkalies & Chemicals, Dahej
Gujarat Narmada Valley Fertilizers Co Ltd
Gujarat State Fertilizers & Chemicals Ltd
Indian Farmers Fert. Co-op. Ltd, Kalol.
Indian Farmers Fert. Co-op. Ltd, Bareilly
Krishak Bharati Co-op. Ltd, Hazira
Nagarjuna Fertilizers & Chemicals Ltd.
National Fertilizers Ltd.
Power
Adani Power Ltd
AP Power Generation Corprn Ltd
Coastal Gujarat Power Ltd (Tata Power)
Essar Power Ltd
Gujarat Power Corprn.Ltd
Gujarat Industrial Power Corprn. Ltd
Gujarat Urja Vikas Nigam Ltd
Madhya Pradesh Electricity Board
Maharashtra State Electricity Board
Maharashtra State Power Gen Co. Ltd
National Thermal Power Corp. Ltd.
Nuclear Power Corprn of India Ltd.
Rajasthan Vidyut Utpadan Nigam Ltd
Torrent Power
UP Rajya Vidyut Utpadan Nigam Ltd
Fire Protection System Contractors
B. S. Engineers
Bells Controls Ltd.
Chetan Engineers
CME Industries
DE’s Technico
Fire Float (India) Pvt. Ltd.
FMS Systems Pvt. Ltd.
HD Fire Protect Pvt. Ltd.
Jai Hind Projects
Mansh Engineering Pvt. Ltd.
Mather & Platt (India) Ltd.
Mehta & Associates.
MX System International Pvt. Ltd.
New Fire Engineers Pvt. Ltd.
Nitin Fire Protection Ind. Ltd.
Punj Lloyd Ltd.
Radiant Fire Prot. Engineers
Rajyog Fire Services Pvt. Ltd.
Reliance Fire & Safety Equip. Pvt. Ltd.
Spack Turnkey Proj. Pvt. Ltd.
Steelage Industries Ltd.
Techno Fire Controls Pvt. Ltd.
Tyco Engineering
UTC Fire & Security India Ltd.
Unitech Machines Ltd.
Kidde India Ltd.
The AAAG manufacturing house is certified to ISO 9001:2008 Quality Management System, and its reputation for Quality and Reliability is widely acclaimed. Its products’ quality meets various National and International standards, and is further endorsed by reputed certification agencies like –
Bureau Of Indian Standards (BIS)
Underwriters Laboratories (UL))
Factory Mutual (FM))
Engineers India Limited)
DGQA, Ministry of Defence)
Indian Registrar of Shipping)
Click on the Link below to view our certificates/approvals:
ISO 9001:2008 Certification BIS Certificate – Hydrant Valves BIS Certificate – Branch Pipe with Nozzle BIS Certificate – Stand Post type Monitor DGQA, Ministry of Defence Certificate Engineers India Limited – Enlistment Certificate FM Approval Certificate – Hydrant (Hose) Valve Indian Registration of Shipping – Type Approval Certificate UL Listing Certificate – Foam Monitors UL Listing Certificate – Foam Branches