Valves for Powders – Selecting The Right Valve

Solids and slurries have completely different flow characteristics than liquid and gases, so it’s important to choose a valve for powder applications carefully.

Taking a spherical disc valve as an example:

Related to a full-port ball valve, the spherical disc valve design uses a spherical disc section (segmented ball) to provide shutoff. Mounting arms are added to provide a pivot on shafts through the center axis of the original ball. A section of the spherical disc seals against the identical spherical radius of the seat while the rest of the shut-off surface is under-cut below the spherical radius.

Advantages of the spherical disc valve design:

• The spherical disc wipes the material away from the matching radius of the seat to provide sanitary sealing and longer seat life.
• The spherical disc rotates 90 degrees out of the material flow, to allow mass-flow through its full port.
• The under-cut disc segment provides clearance that prevents powder jamming between the disc and housing.

Factors to consider when choosing your spherical disc valve:

Materials of construction

The powders and/or solvents to be processed determine the product contact material. While cast iron, carbon steels, and aluminum can be used for many industrial applications; corrosive processes require the use of stainless steel. In some cases, material laden with solvents justify the extra expense of using Hastelloy or other high-nickel alloys to prolong valve life.

Seat materials

Very abrasive material tend to dictate the use of metal seats versus the commonly used reinforced Teflon seats (RPTFE). The metal seat is typical stainless steel coated with a Carbide in a Cobalt favorable environments (WC/CO) and will give longer life and can be used at higher temperatures than Teflon.

Cleanability

The sanitary requirements of a particular process govern surface finishes and other sanitary options.

No surface finish specified

Also referred to as “mill finish” or “as cast”. Fabricated valves will only have the internal welds ground smooth and flush. This finish is most often used in general industrial applications where cross contamination or cleanability are not a concern.

#2 finish – Ra 33 to 65 microinch – 150 to 180 grit: Also referred to as “buffed, blended or uniform appearance finish.” This finish is usually specified for the outside of equipment which will be washed down.

#4 polish – Ra 16 to 32 microinch – 180 to 240 grit: All fabrication and handling marks are removed and the surface is buffed to a uniform satin finish. The #4 polish is typical for the interior of equipment that needs to be cleaned between batches to prevent cross contamination.

#7 polish – Ra 10 to 15 microinch – 240 to 320 grit: All surface imperfections are repaired. Often referred to as “pit free” and “mirror finish.” Used for high purity applications such as processing potent pharmaceutical actives. This finish is also used for products that tend to adhere to surfaces.

Spray balls or jets should be considered for automatic cleaning. Another option is a valve that can be dismantled by hand for inspection and cleaning. For safety reasons, the size of such valves are typically limited to a 10” port diameter due to the weight of individual components.

Weight

The weight of a valve is especially important for mobile or rotating equipment. High performance and heavy- duty valve models will be heavier than regular duty valves. A valve that is dust tight, full vacuum, and 1 bar service, is considered to be regular duty service. Valves that can handle 90 PSI (6bar) to 150 PSI (10bar) are high performance. A higher performance valve can weigh four times as much as its regular-duty counterpart.

Mounting arrangements

The typical ANSI 150 # drilling is used as an industry standard for heavy duty and high performance models valves. Quick clamps can also be used for applications up to 15PSI (1bar) and port sizes up to 10″.

Some valves will include blind tapped holes, which might present a problem if the valve is mating with existing blind tapped holes. Another option is to choose oversized flanges, which allows for through holes. DIN and special drilling are engineered to order. However, for regular duty service valves, ANSI and DIN bolting can be overkill.

Actuation

When selecting an actuator one must consider the materials being processed, available air supply and failsafe operation. As with other quarter turn valves; levers, gear drives or chain operators are all options to consider. Pneumatic and hydraulic, operators are available in double acting or failsafe modes.

For price, reliability, and speed, pneumatic operation should be the first choice. When handling solids, a higher factor of safety is used to calculate seat torque requirements. The factor is typically 1.5 instead of the more commonly used 1.25 safety factor used for liquid and gas valve calculations.

For solids that “set-up” or harden, an oversized actuator and specially designed discs that can be incorporated to break through the hardened cake when the valve opens or closes is recommended. Actuators are typically sized for 5.3bar (80-PSI) pressure.

If the available supply air pressure is dependably higher 6.7 bar to 8 bar (100 to 120PSI) or lower 2.6 bar to 4 bar (40 to 60 PSI), you will need to consider this factor when sizing the valves actuator.

For fail-safe operation, spring return actuators are the norm. When a spring return type actuator is used, it is oversized to compensate for the spring as well as the unseating, run, and seating torque required for valve operation. This can lead to weight and space problems as well as extra cost.

Another fail-safe option to consider is to use a double-acting actuator in conjunction with a pneumatic accumulator sufficiently sized to close the valve. When there is a loss of pneumatic pressure, a pressure switch activates the accumulator and closes the valve.

Flow Control

Fast acting (1 to 5 seconds), quarter turn valves are ideal for flow control of solids. A pneumatic (200mbar to 1000 mbar/3 to 15 PSI) or electro-pneumatic (4 to 20 milli-amp) positioner can take a signal from a manual adjusted pressure regulator, or from a computer controller. The pneumatic positioner is often used in manually-operated filling stations, whereas the electro-pneumatic positioner is typically used for automatic loss-in-weight systems.

Spherical Valves for Powders – Examples:

Light Weight Valves for Powders:​

The versatile TLD valve is most often chosen for processing light density materials such as foods and pharmaceuticals, and on rotating and mobile equipment where weight is a concern. The valve is offered as dust tight, full vacuum, and low-pressure (1 bar) services. Common installations of the TLD valve include inlet/outlet ports on rotating or stationary blenders and Intermediate Bulk Containers (IBC’s).

Light Weight Valves for Powders:​

The versatile TLD valve is most often chosen for processing light density materials such as foods and pharmaceuticals, and on rotating and mobile equipment where weight is a concern. The valve is offered as dust tight, full vacuum, and low-pressure (1 bar) services. Common installations of the TLD valve include inlet/outlet ports on rotating or stationary blenders and Intermediate Bulk Containers (IBC’s).

Sanitary Valves for Powders:​

The sanitary K valve is designed to USDA and FDA guidelines, which eliminate threads, keyways, and crevices. The split body design means it can be completely disassembled by hand to allow for quick and easy inspection and cleaning. It is used for charging/discharging, commonly in food and pharmaceutical industries where cleanability is required.​​

Heavy Duty Valves for Powders:

The T valve is designed for heavy-duty service and comes with oversized flanges with through holes for mounting to blind flanges. Options include high temperature or pressure (3 bar) designs. This valve is commonly used for charging and discharging of hoppers, tanks, silos, conveying systems, and weighing systems processing slurries, abrasives, and heavy density materials.

Other Valve Combinations and Options:

Retractable Sleeves:

Retractable sleeves are designed for the dustless transfer of solids from one process to another. They are usually interlocked with the valve. A mobile vessel or container is located so the retractable sleeve engages and seals automatically.

Once the seal is confirmed, the valve opens to allow material transfer safely and efficiently. Options for retractable sleeves can include inflatable seals for hazardous environment, spring-return air cylinders for fail-safe operation, metal bellows for high-pressure applications, and “clean-in- place” fittings.

Diverter Valves: 

The diverter valve places the spherical disc valve in a ‘Y’ junction. This allows the valve to select a product feed stream from one of the two inputs, or to direct one incoming stream of material to either of the two outlets. Diverter valve use varies greatly from rock crushers to food processing.

Airlocks: 

Airlocks are designed to control the flow of material between two atmospheres. They typically consist of two valves connected by an intermediate chamber. Airlocks are often used instead of rotary feeders, which are prone to high maintenance and leakage of material and gases,

Summary

Choosing the best valve for your powder application results in many benefits including: better performance, lower maintenance costs, and better product quality over the life of the processing equipment. For more detailed information visit the “Design Principles” page at Gemco Valve Company.