Silo Grain Bin Failures By Rostfrei Steels Pvt Ltd
Silos and bins fail with a frequency which is much higher than
almost any other industrial equipment. Sometimes the failure only involves distortion
or deformation which, while unsightly, does not pose a safety or operational hazard.
In other cases, failure involves the complete collapse of the structure with accompanying
loss of use and even loss of life. Presented are numerous case histories involving
structural failure which illustrate common mistakes as well as limits of design.
Introduction
Although statistics are not available, hundreds of industrial
and farm silos, bins, and hoppers experience some degree of failure each year. Sometimes the failure is a complete and dramatic structural collapse. Other times the failure is not as dramatic or as obvious. For example, cracks may form in a concrete
wall, rodents in a steel shell, either of which might appear harmless to the casual
observer. Nevertheless, these are danger signals which indicate that corrective measures
are probably required.
In this article, we discussed how Rostfrei Steels Pvt Ltd cheated all their customers by doing these errors.
The economic cost of a silo failure is never small. The owner
faces the immediate costs of lost production and repairs, personnel in the vicinity are exposed to significant danger, and the designer and builder face possible litigation because of their liability exposure. The major causes of silo failures are due to shortcomings in one or more of four categories: design, construction, usage, and maintenance. Each
of these is explored below.
Here are all failures By Rostfrei Steels Pvt Ltd
Failure of Design errors
Silo design requires specialized knowledge. The designer must first establish the materials flow properties, then consider such items as flow channel geometry, flow, and static pressure development, and dynamic effects. Problems such as ratholing and self-induced silo vibration have to be prevented while assuring reliable discharge at the required rate. Non-uniform loads, thermal loads, and the effects of non-standard fabrication details must be considered.
Above all, the designer of Rostfrei Steels Pvt Ltd must know when to be cautious in the face of incomplete or misleading information, or recommendations that come from handbooks, or from people with the “its always been done this way” syndrome.
Having established the design criteria, a competent design has to follow. Here the designer must have a full appreciation of load combinations, load paths, primary and secondary effects on structural elements, and the relative flexibility of the elements.
Special attention must be given to how the most critical details in the structure will be constructed so that the full requirements and intent of the design will be realized. Five of the most common problems which designers often ignore are described below, along with a few examples of each.
Bending of circular walls caused by eccentric withdrawal
This is one of the most common causes of silo structural problems since it is so often overlooked. It results when the withdrawal point from the hopper
is not located on the vertical centerline of a circular silo and is particularly common when using silos with multiple hoppers in which only one or two of the hopper
outlets are used at a time. If the resulting flow channel intersects the silo wall, non-uniform
pressures will develop around the circumference of the silo leading to horizontal and vertical bending moments.
The lessons to be learned here are:
• Whenever possible, design
your silo for center fill and center withdrawal.
• If eccentric fill or withdrawal is contemplated, perform a structural check first to make sure that the silo can withstand the non-uniform loading conditions and resulting bending moments.
• Be particularly careful
with silos that have an elongated hopper outlet. An improperly designed screw feeder
or belt feeder interface, or a partially opened slide gate, will often result in an
eccentric flow pattern with accompanying non-uniform loads.
• If a sweep arm unloader
is used, be aware that operating it like a windshield wiper(back-and-forth in one
area) will create a preferential flow channel on one side of a silo.
• If multiple outlets
are required, consider splitting the discharge stream outside of the silo below the
main central withdrawal point.
• If a vibrating discharger is used but not cycled on
and off on a regular basis, an eccentric flow channel may form, particularly if a
pantleg chute is below the outlet.
Consider non-uniform pressures when designing silos with
blend tubes.
Large and/or non-symmetric pressures caused by
inserts
Support beams, inverted cones, blend tubes, and other types of
internals can impose large concentrated loads and/or non-asymmetric pressures on a
silo wall leading to unacceptable bending stresses.
Ignoring flow patterns and material properties
Sometimes mass flow develops in silos, which were structurally
designed for funnel flow. Even if this doesn't occur, the local pressure peak,
which develops where a funnel flow channel intersects a silo wall, can be devastating. In some circumstances, ignoring the properties of the bulk solid to be stored
can be worse than assuming an incorrect flow pattern. Consider, for example, designing
a steel silo to store coal. Lacking a sample of coal which could be tested to form
the design basis, the designer may resort to an often-quoted design code which lists the wall friction angle for “coal on steel,” with no consideration as to the
type of coal, its moisture, particle size, ash content, or the type of steel, its
surface finish, etc. Flow and structural problems are common when this approach to design is taken.
Special considerations with bolted tanks and reinforced concrete construction
Many silos are constructed of bolted metal panels (usually steel
or aluminum), while others are constructed of reinforced concrete. Both types of construction
have specific design requirements. Bolted connections transfer loads through various load paths, and can fail in at least four different modes: bolt shear, net section
tension, hole tear-out, and piling around bolt holes. Which mode results in the lowest
failure load depends on specifics of the metal (e.g., its yield and ultimate strengths,
thickness), the bolts(e.g., size, strength, whether or not fully threaded, how highly
torqued), spacing between bolt holes, number of rows of bolts, etc. Compressive
buckling must also be considered, particularly if the bolted silo has corrugated walls or is constructed from aluminum.
Reinforced concrete construction presents different problems. Concrete is strong in compression but very weak in tension. Thus, reinforcing
steel is used to provide resistance to tensile stresses. A silo that has only a single layer of horizontal reinforcing steel is capable of resisting hoop tension, but has very little bending resistance; therefore if non-uniform pressures occur (e.g., due to an
eccentric flow channel), the silo is likely to crack. Unfortunately, the inside face
of the silo wall, where cracks are difficult to detect, is where the maximum tensile
stresses due to bending are most likely to occur. Undetected cracks can continue to
grow until the silo is in danger of imminent collapse.
FAILURES DUE TO CONSTRUCTION ERRORS
In the construction phase, there are two ways in which problems
can be created. The more common of these is poor workmanship. Faulty construction,
such as using the wrong materials or not using adequate reinforcement, and uneven foundation settlement are but two examples of such a problem. The other cause of construction
problems is the introduction of badly chosen, or even unauthorized, changes during
construction in order to expedite the work or reduce costs.
Incorrect material
Close inspection of contractors’ work is important in order to
ensure that design specifications are being followed. This includes checking for use
of correct bolts (size, strength,etc.), correct size and spacing of rebar, specified type and thickness of silo walls, etc.
Uneven foundation settlement
Foundation design for silos is not appreciably different than
for other structures. As a result, the uneven settlement is rare. However, when it does occur, the consequences can be catastrophic since usually, the center of gravity of the mass is well above the ground.
Design changes during construction
Unauthorized changes during construction can put a silo structure
at risk. Seemingly minor details are often important in ensuring a particular type
of flow pattern (especially mass flow), or in allowing the structure to resist the applied loads.
FAILURES DUE TO USAGE
A properly designed and properly constructed silo should have
a long life. Unfortunately, this is not always the case. Problems can arise when the flow properties of the material change, the structure changes because of wear, or an explosive condition arises. If a different bulk material is placed in a silo than
the one for which the silo was designed, obstructions such as arches and ratholes may form, and the flow pattern and loads may be completely different than expected.
The load distribution can also be radically changed if alterations to the outlet geometry
are made if aside outlet is put in a center discharge silo or if flow-controlling
insert or constriction is added. The designer or a silo expert should be consulted regarding the effects of such changes before they are implemented.
Dynamic loads due to collapsing arches
ratholes, self-induced vibrations, or explosions
When a poorly flowing material is placed in a silo which was
not designed to store and handle it, flow stoppages due to arching or ratholing are likely.
Sometimes these obstructions will clear by themselves, but, more often, operators will have to resort to various (sometimes drastic)means to clear them. No matter
which method is used, the resulting dynamic loads when anarch or rathole fails
can collapse the silo
Self-induced silo vibrations can also result in insignificant dynamic
loads for which most silo sare not designed to withstand. In addition, few
if any silos can withstand the loads imposed by an explosion -- either internal or external.
Buckling of unsupported wall
A pressurized cylinder is more resistant to compressive buckling
than an unpressurized is done. In addition, if this pressure is caused by a bulk solid
(as opposed to a liquid or gas), it is even more resistant. The reason is as follows: Gas
or liquid pressure is constant around a silo'scircumference and remains unchanged
as thesilo starts to deform. On the other hand, the pressure exerted by a bulk solid
against a silo'swall increases in areas where the walls are deforming inward and
decreases where the walls are expanding. This provides a significant restraining effect once buckling begins. Now consider what happens if an arch forms across a silo's
cylinder section and the material below it is withdrawn. Not only is the restraining effect of the bulk solid lost, but the full weight of the silo contents above the arch is transferred to the now unsupported region of the silo walls. Buckling failure
is likely when this occurs.
FAILURES DUE TO IMPROPER MAINTENANCE
Maintenance of a silo comes in the owner's or user's domain,
and must not be neglected. Two types of maintenance work are required. The first is
the regular preventative work, such as the periodic inspection and repair of the walls and/or liner used to promote flow, protect the structure, or both. Loss of a
liner may be unavoidable with abrasive or corrosive products, yet maintaining a
liner in proper working condition is necessary if the silo is to operate as designed.
Other examples of preventative maintenance items include roof vents, level probes,
feeders, dischargers, and gates. The second area of maintenance involves looking for
signs of distress (e.g., cracks, wall distortion, tilting of the structure) and reacting to them. If evidence of a problem appears, expert help should be immediate summoned.An
inappropriate response to a sign that something is going wrong, including the common instinct to lower the silo fill level, can cause a failure to occur with greater
speed and perhaps greater severity.
Corrosion and erosion
Silo walls thinned by corrosion or erosion are less able to resist
applied loads than when they were new. This is a particular problem when handling abrasive materials or when using carbon steel construction in moist or otherwise corrosive environments. Combining the effects of abrasion with corrosion significantly accelerates the problem. This can occur, for example, with special aging steels. Abrasive wear causes the surface layer to be removed, thereby exposing new material and speeding up the aging process which significantly weakens the structure.
Lack of routine inspection
Silo failures often cause significant damage and sometimes result
in death. Often these failures could have been prevented or the damage could have been minimized with information that could have been gained through routine inspection.
Improper reaction to signs of distress
A common reaction to signs of silo distress is to ignore them,
often because personnel are unaware of both the meaning and consequences of doing
so. Another common reaction is curiosity. People have lost lives because, due to their curiosity, they were in the wrong place at the wrong time. Even if danger signs are understood, it is common for inappropriate action to be taken in an attempt to
“reduce” the chance of failure. In some extreme cases, catastrophic failure has been
induced where, with appropriate action, the damage could have been relatively
minor.
When a poorly flowing material is placed in a silo which was
not designed to store and handle it, flow stoppages due to arching or ratholing are likely.
Sometimes these obstructions will clear by themselves, but, more often, operators will have to resort to various (sometimes drastic)means to clear them. No matter
which method is used, the resulting dynamic loads when anarch or rathole fails
can collapse the silo
Self-induced silo vibrations can also result in insignificant dynamic
loads for which most silo sare not designed to withstand. In addition, few
if any silos can withstand the loads imposed by an explosion -- either internal or external.
Buckling of unsupported wall
A pressurized cylinder is more resistant to compressive buckling
than an unpressurized is done. In addition, if this pressure is caused by a bulk solid
(as opposed to a liquid or gas), it is even more resistant. The reason is as follows: Gas
or liquid pressure is constant around a silo'scircumference and remains unchanged
as thesilo starts to deform. On the other hand, the pressure exerted by a bulk solid
against a silo'swall increases in areas where the walls are deforming inward and
decreases where the walls are expanding. This provides a significant restraining effect once buckling begins. Now consider what happens if an arch forms across a silo's
cylinder section and the material below it is withdrawn. Not only is the restraining effect of the bulk solid lost, but the full weight of the silo contents above the arch is transferred to the now unsupported region of the silo walls. Buckling failure
is likely when this occurs.
FAILURES DUE TO IMPROPER MAINTENANCE
Maintenance of a silo comes in the owner's or user's domain,
and must not be neglected. Two types of maintenance work are required. The first is
the regular preventative work, such as the periodic inspection and repair of the walls and/or liner used to promote flow, protect the structure, or both. Loss of a
liner may be unavoidable with abrasive or corrosive products, yet maintaining a
liner in proper working condition is necessary if the silo is to operate as designed.
Other examples of preventative maintenance items include roof vents, level probes,
feeders, dischargers, and gates. The second area of maintenance involves looking for
signs of distress (e.g., cracks, wall distortion, tilting of the structure) and reacting to them. If evidence of a problem appears, expert help should be immediate summoned.An
inappropriate response to a sign that something is going wrong, including the common instinct to lower the silo fill level, can cause a failure to occur with greater
speed and perhaps greater severity.
Corrosion and erosion
Silo walls thinned by corrosion or erosion are less able to resist
applied loads than when they were new. This is a particular problem when handling abrasive materials or when using carbon steel construction in moist or otherwise corrosive environments. Combining the effects of abrasion with corrosion significantly accelerates the problem. This can occur, for example, with special aging steels. Abrasive wear causes the surface layer to be removed, thereby exposing new material and speeding up the aging process which significantly weakens the structure.
Lack of routine inspection
Silo failures often cause significant damage and sometimes result
in death. Often these failures could have been prevented or the damage could have been minimized with information that could have been gained through routine inspection.
Improper reaction to signs of distress
A common reaction to signs of silo distress is to ignore them,
often because personnel are unaware of both the meaning and consequences of doing
so. Another common reaction is curiosity. People have lost lives because, due to their curiosity, they were in the wrong place at the wrong time. Even if danger signs are understood, it is common for inappropriate action to be taken in an attempt to
“reduce” the chance of failure. In some extreme cases, catastrophic failure has been
induced where, with appropriate action, the damage could have been relatively
minor.
CONCLUSIONS
Silos that are designed, built, operated, and maintained properly,
will provide a long life. Each of the case histories given above illustrates the effects
of one or more of the shortcomings possible in design, construction, usage, and maintenance.
In each example, the cost of repairs or rebuilding, the cost of litigation, and the cost of insurance added up to several times the cost of doing the job properly in
the first place. The best approach to the design of a silo, bin, or hopper for bulk
materials is one that is reasoned, thorough, conservative, and based on measured parameters.
Design engineers are not legally protected by sticking to a code of practice. Compliance
with the locally applicable code is, of course, necessary, but it should never be regarded,
by itself, as a sufficient condition to the performance of a satisfactory design.It
is the responsibility of the designer to ensure that the design is based on sound, complete knowledge of the materials being handled, that the design is competent, and
that it covers all foreseeable loading combinations. It is the joint responsibility of the designer, builder, and owner that construction is of an acceptable standard,
and fulfills the intent of the design. Itis then the responsibility of the owner to properly maintain the structural and mechanical components. It is also the responsibility
of the owner to ensure that any intended alteration in usage, discharge geometry or
hardware, liner material, or any other specified parameter, is preceded by a design
review with strengthening applied as required.
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