A check valve is a type of valve that allows fluids to flow in one direction but closes automatically to prevent flow in the opposite direction (backflow). Check valves are used in a wide variety of locations, but the focus of the discussion in this tutorial will be the installation of check valves at the steam trap outlet side.
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Questions are often asked about the need and purpose of check valves, such as:
Let’s discuss these two points.
Check valves are necessary if there is a risk of condensate backflow. For example, when a trap discharges into a common condensate collection line, there is the potential risk of backflow from condensate discharged from other traps, so as a rule a check valve should be installed. Preventing this backflow is important because it can not only diminish process heating efficiency, but can also damage steam traps. In contrast, when there is a single downward sloping pipe that is not submerged at any point, there is almost no possibility of backflow, so a check valve is not necessary.
If the trap is gravity drained through a downward sloping dedicated line that releases to atmosphere without being submerged at any point, there is usually no risk of backflow, so there is no need to install a check valve.
Note: Depending on piping configuration after the steam trap, back flow can also occur in open lines if equipment goes to vacuum or if there is positive pressure from a too small vent or pipe rise which can cause unwanted return line pressure. In such cases, installing a check valve may help prevent back flow.
If the trap outlet piping is connected to a common condensate collection line, condensate discharged from equipment in operation may backflow into equipment that is out of service unless there is a check valve installed at the trap's outlet.
Illustration C: No check valves at trap outletsIf a check valve is installed, even if the trap outlet piping is connected to a common collection line, the condensate discharged from equipment in operation will not backflow into equipment that is out of service.
Illustration D: Traps with check valvesThere are various mechanisms that generate water hammer. A principal cause of water hammer in condensate recovery lines is condensate flowing back down in vertical rises. The installation of a check valve at each of these locations is very effective in preventing water hammer due to backflow.
If the condensate discharge piping on a pump with intermittent operation (e.g. TLV PowerTrap® series or motorized pump with ON-OFF control) has a long horizontal run followed by a vertical rise, any condensate that falls back down the vertical rise becomes backflow that may collide with newly discharged condensate, resulting in water hammer. Similarly, in situations where a PowerTrap® discharges high temperature condensate, the combination of flash steam and backflow could be another possible cause for water hammer.
In such cases, water hammer may be prevented by installing a check valve at critical locations within the system (e.g. the beginning of a vertical rise).
Illustration F: Check valve on vertical riserCheck valves can also help prevent water hammer caused by a pulsating flow of low temperature condensate in condensate transport piping.
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When high pressure hot condensate is discharged through a steam trap to lower pressure, flash steam is generated. If this flash steam then flows into a return line that contains sub-cooled condensate at a much lower temperature, an instant collapse (condensing) of the flash steam will occur as it gives off its latent heat to the condensate, and water hammer may result. Installation of a check valve is generally not effective in this situation.
Check valves prevent backflow, but not back pressure. It is not possible to discharge low pressure condensate into a higher pressure line. Even if a check valve is installed after a steam trap, condensate will not flow if the pressure upstream of the trap is lower than the downstream (return) side.
Additionally, it should be noted that if a check valve is installed at the outlet of a trap operating under an extremely large operating differential pressure, the check valve itself becomes a point of resistance (i.e., the check valve has a pressure drop as well), which means that it is necessary to calculate pressure drop very carefully.
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A check valve is an automatic safety device designed to allow fluids and gasses to flow in one direction and prevent reverse flow. Under pressure, fluids enter the valve at the inlet where they force the disc off the seat of the valve and exit through the outlet.
Flow continues steadily as long as the pressure is maintained to keep the disc open. Once there is a pressure drop, the disc automatically returns to its seat to shut off the flow.
The pressure that opens the valve is referred to as cracking pressure, which can vary from 3 psi to 350 psi depending on the size, purpose, and function of the check valve.
Check valves ensures gasses or liquids are flowing in the right direction, and create tight seals to prevent leaks. By controlling the flow of liquids, check valves protect pumps and compressors from serious damage.
The names of check valves change according to their use and how they are manufactured. Their many names include clack, non-return (NRV), reflux, retention, and one-way valves. Regardless of the simplicity of their design and function, they are an essential factor in the protection of pumps, piping systems, and fluid movement.
The most common type of check valve, the swing valve, can be seen in the image below. It is a full port design where the disc is completely out of the way during fluid flow. The directional flow opens the disc. As the flow continues, the disc remains open. As the flow slows or stops, the disk moves, by the force of gravity, into the closed position.
The main function of a check valve is to prevent reverse flow, which can damage pumps and other mechanisms. When a check valve closes, there is a potential water hammer where the fluid in a system slams against a closed check valve. This aspect of a check valves operation requires that they be resilient and durable and be made of high quality materials.
Check valves can be noisy and need to have their noise suppressed. To that end, various forms of controls are added. To control surges and prevent the valve from slamming closed, springs, levers, or weights are designed into the valve’s structure.
There are endless varieties of check valves to fit multiple applications. There are industrial and commercial uses. In gardens, they control the flow of fertilizers and water in irrigation systems. The aerospace and aircraft industries use check valves to control corrosive fluids, hydraulic systems, and the fuel flow.
Though the function of check valves is the same regardless of where they are used, the types of check valves vary according to the flow rate, media gravity and temperature, line size, pressure, and velocity of the flow, which can be seen in the chart below.
Application of Check Valves Type Flow Media Type Velocity Range FPS(m/s) Recommended Check Valve Uniform With Insignificant Reversal Water Or Oil 1 to 6 (0.3 to 2) Swing Check w/ Lever and ctrl wt. Steam, Water, Gas 7 to 100 (2 to 30) Simple Swing Uniform Water Or Oil 5 to 10 Max (a.5 to 3) In-line Guided Disc Pulsating Air Or Gas 5 to 10 Max (a.5 to 3) In-line Guided Disc w/Cushion Chamber Uniform With Normal Reversal Water Or Oil 7 to 10 (2 to 3) Swing w/ Spring Assist To Close Uniform With Severe Reversal Water Or Oil 7 to 10 (2 to 3) Swing w/ Dashpot Uniform Or Pulsating Steam, Water, Or Gas 8 to 160 (2.5 to 50) Tee- Or Inclined- Pattern Lift Uniform Or Pulsating (Severe Revesal) Steam, Water, Or Gas 10 to 160 (3 to 50) Tee- Pattern Lift w/ Dashpot Uniform Steam, Water, Or Gas 12 to 250 (4 to 75) Tilting Disc Uniform Or Pulsating Steam, Water, Or Gas Or Oil 20 to 250 (6 to 75) Wye-Pattern Lift Uniform Or Pulsating (Severe Revesal) Wye-Pattern Lift w/ dashpotThe choice of a check valve has to fit the needs of an application. When engineers select a check valve, they adapt to fit the type of media, the size of the pipe, the pressure gradient, the velocity of the fluid, and the type of pumping mechanism. The examination of these factors are necessary to ensure the safe operation of an application or process and to protect equipment.
There is a wide range of check valves, with standard ones that can be purchased at a home improvement store to ones that are specially designed to fit the needs of unique applications. This wide variety makes it difficult to provide an all inclusive list of check valves since every day new ones are being developed. In the midst of the many check valves, descriptive factors are common to all types.
A swing check valve is a self actuated valve that serves as a backflow preventer or one direction valve. They have a disc that swings on a hinge off the seat of the valve to allow forward flow. When the flow stops, it swings back into position to stop reverse flow. The weight of the disc has to be sufficient to withstand the impact of the return flow. Swing check valves have less turbulence and low pressure drop.
Lever and weight swing check valves are used when there is a chance of water hammer while ones with lever and spring are used in high pressure and high flow velocity applications. Regardless of the type of swing check valve, their disc needs to be checked and cleaned regularly.
Wafer check valves have a thin disc that swings to block or allow flow. The flow of the media is allowed to flow in one direction, which lifts the disc off its seat. When the flow is in the opposite direction, the disc closes to create a seal to prevent backflow. In many cases, a spring or lever is attached to the disc for faster closing time and helps to reduce water hammer.
The thin, short, and compact design of wafer check valves makes them ideal for small pipe systems and systems that move solid or semi solid media.
A tilting disc check valve has its pivot point at the center of the disc so that the fluid flows over the top and bottom of the disc. They are often used where there is frequent flow reversal. When the disc is open, the flow keeps it open, which is different from a swing check valve where the velocity of the flow keeps it open. The disc is small and light with a center of gravity that is close to its pivot point. It has a low pressure drop with low flow rates and a higher pressure drop with high flow rates.
Ball check valves use a ball that moves up and down in the valve to block the flow. The seat of the valve is designed to fit the ball and has a conically shaped chamber that guides the ball to the seat. The weight of the ball can vary depending on the pump capacity and the possibility of water hammer.
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Reverse flow moves the ball back to the seat to seal off the flow. When there is enough pressure in the flow, the ball is lifted away from the flow. When the pressure decreases, it comes down and is guided to the seat.
A butterfly check valve is also known as a dual, folding disc, double disc, or splits check valve. The halves of the disc open toward the centerline, as seen in the diagram, during the forward flow of the fluid. With reverse flow, the halves open and seal the pipe. The short distance that the halves have to travel lessens the slamming effect on the discs. Butterfly check valves operate very quietly making them ideal for heating, ventilation, and air conditioning systems.
The flow for lift check valves enters below the seat of the valve. The pressure of the flow lifts the disc or ball off the seat. When the flow weakens, slows, reverses, or stops, gravity forces the disc or ball downward onto the seat. They are ideal for systems with high flow and velocity rates.
Silent check valves, also known as poppet check valves, avoid water hammer or shock by closing before fluid flow reversal. The benefit of a silent check valve is that they close quickly and smoothly, which prevents damage to surrounding materials.
Duckbill check valves are made of rubber or synthetic elastomer and have the shape of a duck‘s beak. The open end of the valve is stretched over the outlet to the supply line. The other end retains its normal shape. Upstream pressure forces the duckbill lips open allowing the flow. As the pressure increases, the lips open wider. As the pressure gets lower, the lips return to a flatten and close.
Diaphragm check valves have a rubber diaphragm or disk=c. The valve is centered in the seating area with the sealing surface on the inlet side of the valve and has an opening in the center. Backflow causes the rubber disk= to cover the sealing opening, which closes the opening to the inlet.
A foot check valve is at the bottom of a pipe connected to a pump. They act like a ball check valve with a screen to block debris. The opening of the valve is larger than the opening of the line. Foot valves keep the pump primed. When the pump is operating, suction pulls water up through the pipe and foot valve. When the pump is turned off, the water in the pipe is pulled back by the force of gravity. The foot check valve blocks the path of the water as it falls and is closed by the weight of the water.
Pneumatic check valves, or air check valves, control air flow from a compressor by letting air in and preventing it from going out. They are placed in pneumatic circuits that need air flow in one direction.
Since the invention of the self-sealing valve, at the beginning of the 20th Century, they have become the answer to backflow problems in a wide range of industries. Any industry that transports products through pipes has a check valve somewhere in their system.
Check valves are cost saving devices that prevent waste and protect equipment. Fluids that travel through a piping network need to be prevented from being lost due to poor handling. Check valves automatically stop liquid flow when pressure drops or the flow decreases by blocking backflow and containing the fluid.
Check valves in pumps is one of their more common uses.
Parallel Pump System – In a parallel pump system, a check valve prevents the duty pump from pumping into the standby pump.
Pressure Relief – Spring loaded check valves are used in gas applications for low pressure conditions. If the pressure in the system rises above the cracking pressure, the check valve safely releases the gas.
The pharmaceutical industry requires check valves for the movement of fluids. Check valves regulate the pressure in the fluid flow for product quality, efficiency, and production. Only sanitary check valves can be used for this process. They require easy cleaning, without the need for disassembly, and silent closing with a tight shut off.
Orifice check valves are used in the hydraulics of the landing gear actuator system. When the gear is raised, fluid flows to lift the gear. When the gear is lowered, the check valve stops the gear from dropping by controlling the flow out of the actuator. Aside from the landing gear, check valves on aircraft are used in other hydraulic systems as well as fuel and pneumatic systems.
In an irrigation system, check valves are located near the source of the system to prevent backflow, siphonage, of irrigation water back to the source.
Check valves are found in vehicles that were made before the invention of the electronic injection system. Old car fuel pumps have a check valve located at the pump‘s inlet and one at the outlet, They are designed to force the fuel to flow in the correct direction. When the check valve goes bad, the fuel pressure goes down.
Water in a home should only move from the supply line and out through a fixture or from a drain to the sewer. Check valves are located in homes to prevent cross connection or backflow. They come in several varieties including ball and swing check valves. Domestic check valves can be seen below on a diagram of a hot water system for a home.
Check valves on heating boilers prevent hot water from circulating when the thermostat is not calling for heat. They stop water from going back into the boiler, which would build up excessive pressure. In a home heating boiler, a check valve keeps boiler water from entering the domestic supply to keep it from being used for drinking, bathing, or cooking.
Liquid fuel check valves are designed to operate with several different types of fuels including jet fuels, hydraulic oil, synthetic oil, and air. They are designed to provide stable operation from the crack of the valve to full flow. An inverted spool is used that has a built in pressure sensor to ensure balance and stability and holds a specific delta pressure in the valve. The total design allows the valve to open uniformly.
When discussing how a check valve works, it is important to first understand how they are constructed. A basic check valve has four individual parts: body, seat, disc, and cover, which can be seen in the diagram below.
Springs, balls, stems, hinge pins, and other features can be added to the basic elements according to the purpose and design of the check valve.
Swing check valves have an unguided disc that moves into a fully open position when the pressure from the flow is applied. They come in several sizes and designs to fit different applications.
Lift check valves have a guided piston that lifts when the flow enters the check valve. The seat has a barrel design and is screwed on and sealed. The opening to the check valve is the same as the same size as the inlet and outlet.
The design of tilting check valves is to overcome some of the problems of swing check valves, which have been the most common type. They are capable of remaining open when the flow has a low velocity and close quickly when the flow stops. They perform well in applications with high velocity.
The folding disc check valve is a split disc design with a wafer body pattern that has a soft seat. The discs are secured by a pivot rod and open with the pressure of the flow. Springs on the discs help close the valve.
Vertical check valves are also known as spring check valves since a spring is used to keep the disc against the seat. The valve is held shut by the spring until a sufficient amount of pressure is applied to push the spring back and open the valve. Pressure keeps the valve open and the spring compressed. Once pressure drops, the spring forces the disc into the seat to shut off the flow. Vertical or spring check valves provide excellent backflow protection and are extremely reliable.
Most check valves are made from durable materials to be able to withstand high pressure conditions. Common materials used to make check valves include PVC, CPVC, bronze, brass, iron, and stainless steel.
Polyvinyl Chloride (PVC): PVC is corrosion resistant and flexible. The smooth surface of PVC allows the check valve parts to move easily.
Chlorinated Polyvinyl Chloride (CPVC): CPVC has the same qualities as PVC but is able to endure high temperature applications.
Bronze: Bronze can be used for low and medium pressure applications, be cast in complex configurations, and is corrosion resistant.
Brass: Brass has the same abilities as bronze as well as the same machinability and is less expensive than bronze.
Cast Iron:Cast iron check valves are used for hot and cold water, HVAC, steam, gas, and utility services due to its excellent corrosion resistance.
Ductile Iron:Ductile iron has more than 3% carbon so it can be bent and shaped easily. It is stronger than cast iron and is easier to form into check valves.
Iron: Iron is used for steam, water, oil, and gas applications. It can endure a wide range of temperatures and pressures. Its excellent performance balances its high cost.
Stainless Steel: Stainless steel is corrosion resistant, durable, and can be used in harsh conditions, including chemical applications.
Polypropylene (PP):PP is used to make check valves due to its exceptional resistance to corrosion, which is superior to CPVC and PVC.
Polyvinylidene Difluoride (PVDF):PVDF plastic is used in applications where exceptional purity and resistance to acids, solvents, and hydrocarbons are a necessity.
Cast Steel:Cast steel is used to produce check valves due to its sudden impact resistance without deforming, breaking, or bending. It can also be easily shaped to any type of check valve.
The major benefit of check valves is their ability to perform without having to be monitored or controlled. Their basic design allows them to be inserted into a pipe‘s flow and be able to control the flow without being managed.
Regardless of their many benefits, check valves are like any other type of mechanism and have drawbacks.
Water hammer is caused by a pressure surge when there is a sudden stop in the flow of a gas or fluid and the valve suddenly closes, which causes noise and vibrations. Water hammer can damage the system and lead to costly repairs.
Water hammer can be prevented by having faster closing check valves, which stops pressure surges and shock waves. Silent check valves are one possible solution.
Reverse flow is costly and can damage a pump by causing it to spin backwards. This problem can be corrected with tight fitting fast closing check valves. One of the benefits of spring assisted check valves is their ability to react quickly and prevent reverse flow.
Some check valve systems have chattering caused by repeated opening and closing of the valve. This is caused by oversizing of the check valve. When installing a check valve, it has to be sized to fit the application. The disc has to be stable in the open position and make a complete seal when closed, which can prevent repeated opening and closing, fluttering, and failure of the check valve.
Incorrect installation and assembly of a check valve can cause future problems. The first step is to choose the correct check valve for the application. Flow capacity, positioning, and orientation are crucial factors since installing a check valve too close to a pump can cause turbidity and possible damage to the check valve.
Check valves should be mounted several straight pipe diameters upstream from circulators, elbows, tees, and strainers to prevent turbulence and rattling of the disc against the seat.
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