Skip to main content

IMPORTANCE OF ROUTINE CHECKS FOR MECHANICAL REPAIRS

BY BRYAN CHRISTIANSEN.

Mechanical components in a factory require the most attention from a maintenance perspective, as they have a high propensity to fail, making it a high priority for maintenance teams. In turn, it is always better to prevent failures than resort to reactive maintenance.

It is important to note that routine checks help in preventing mechanical troubles in the factory. Let’s look at some of the most prevalent mechanical failures experienced by machines in a factory. While also considering how routine checks have the potential to be an antidote to mechanical failures. Different forces act on mechanical components while they are in operation. They work in an environment where interaction with other components and people in the factory is necessary. Such factors cause mechanical failures.

Common mechanical failures and their causes

Wear and tear: The most common mechanical problem experienced in any machine is the wear and tear of components. When machines are in operation, there are frictional forces acting between components. This friction causes material degradation of components.

Materials degrade to an extent where they can no longer perform their functions. Another risk is the sudden failure of the component while it is in operation. Components experiencing wear and tear need to be replaced before they evolve into a larger failure.

Overheating: Mechanical components in operation generally produce heat. This is due to friction when two surfaces slide against each other. Machines are designed to factor in this heat due to frictional forces.

Overheating is an indication of some fault in the machine. The root cause could be improper installation, lack of lubrication, or leakage of coolant. You need to perform root-cause analysis to identify the underlying cause that is manifested as overheating and rectify it.

Mistakes from operators: Machine operators can perform their tasks erroneously, causing mechanical problems. This could be due to a lack of training or experience of the operator. The operations teams might not have standard operating procedures (SOP) in place, leading to errors from operators, damaging mechanical components. Establishing SOPs and enforcing them with checklists reduces the mistakes performed by operators. Increased automation is another way of eliminating the potential for operator mistakes.

Improper maintenance: Machines and machine components each have a limited life, which depends on regular maintenance and upkeep performed. Scheduled maintenance activities must be done to make sure machines and their components are utilized to their full potential. Regular maintenance and replacement of worn-out components is required to prevent mechanical failures and extend machine life.

Why perform routine checks?

Routine checks are performed to inspect machines and their components for any sign that could indicate a future failure. Routine checks are performed as a preventive measure.

Trained maintenance professionals and operators inspect machines in operation and in an idle state. They are looking for signs of material degradation. You also need to check for any anomalies such as odd sounds, bangs, sparks, and unexpected output.

The anomalies identified must be investigated to find their cause. Rectifying them avoids mechanical failures and the costs that damage could cause. Routine checks help to identify smaller faults that have not manifested to a noticeable scale. Rectifying such faults in a timely manner ensures potential large failures do not happen.



Positive impacts of routine checks include:

Downtime

Routine checks help to identify small faults before they grow large enough to cause machine failure. When such faults are identified, maintenance can be scheduled in such a manner that it does not affect factory operations.

Rectifying the problems eliminates the chance of unscheduled downtime. This will ensure that maintenance activities can be performed to cause minimal disruption to factory operations.

Maintenance frequency

Routine checks force the maintenance team to identify the root cause of any small faults that occur. When the faults are minor, they will be observed closer to the root cause. In operations where routine checks are not done, you will get to know of faults only when a large failure occurs.

The root cause of problems becomes difficult to identify. Reactive maintenance in most cases will be able to patch up problems at the surface level. The root cause will be the origin of more failures that will require regular maintenance and machine downtime. Routine checks will help to catch mistakes in the start, reducing the maintenance needs of machines.

Wastage

Mechanical faults cause wastage in many forms. Increased energy consumption for operations is a common effect of mechanical trouble. The consumed energy could be electrical energy or heat from the combustion of fossil fuels.

Similarly, mechanical faults can cause an increased consumption of raw materials, lubricants, and coolants. Wastage can be avoided with routine checks and rectifying even minor mechanical faults that are observed. This ensures sustainable plant operations and an increased utilization ratio of resources.

Machine life

Machine life depends on many factors in its operations. Minor faults are unavoidable in any machine operation. Sustaining the faults without any rectification damages the machine. Larger catastrophic failures could also happen due to the compounding of smaller faults. These factors adversely affect the life of the machine.

Routine checks help to catch smaller anomalies and defects before they become a larger failure. Routine checks help in performing preventive maintenance, making the machine more robust compared to its counterparts that undergo reactive maintenance.

Scheduling routine checks

Routine checks are indispensable for proper operations and the maintenance of machines in a factory. They come with many benefits that save a lot of time, energy, and money.

You need to incorporate routine checks as part of regular machine operations. Create a checklist of tasks that must be performed on a daily, weekly, and monthly basis to inspect the health of machines. Making these checklists accessible to all maintenance and operations teams is a wise idea.

This helps anyone interested in following and performing routine checks. A cloud-based computerized maintenance management system (CMMS) is ideal for maintaining the checklist for routine checks.

 

Bryan Christiansen is the Founder and CEO at Limble CMMS (a mobile CMMS software company). He can be reached at bryan@ limblecmms.com.

MROMAGAZINE.COM / SEPTEMBER 2022

Labels:

Comments

Post a Comment

Popular posts from this blog

Maintenance 4.0 Implementation Handbook (pdf)

WHAT IS MAINTENANCE 4.0? Industry 4.0 is a name given to the current trend of automation and data exchange in industrial technologies. It includes the Industrial Internet of things (IIoT), wireless sensors, cloud computing, artificial intelligence (AI) and machine learning. Industry 4.0 is commonly referred to as the fourth industrial revolution. Maintenance 4.0 is a machine-assisted digital version of all the things we have been doing for the past forty years as humans to ensure our assets deliver value for our organization. Maintenance 4.0 includes a holistic view of sources of data, ways to connect, ways to collect, ways to analyze and recommended actions to take in order to ensure asset function (reliability) and value (asset management) are digitally assisted. For example, traditional Maintenance 1.0 includes sending highly-trained specialists to collect machinery vibration analysis readings on pumps, motors and gearboxes. Maintenance 4.0 includes a wireless vibration sensor conne
Post a Comment
[Read more...]

John Crane's Type 28 Dry Gas Seals: How Does It Work?

How Does It Work? Highest Pressure Non-Contacting, Dry-Running Gas Seal Type 28 compressor dry-running gas seals have been the industry standard since the early 1980s for gas-handling turbomachinery. Supported by John Crane's patented design features, these seals are non-contacting in operation. During dynamic operation, the mating ring/seat and primary ring/face maintain a sealing gap of approximately 0.0002 in./5 microns, thereby eliminating wear. These seals eliminate seal oil contamination and reduce maintenance costs and downtime. John Crane's highly engineered Type 28 series gas seals incorporate patented spiral-groove technology, which provides the most efficient method for lifting and maintaining separation of seal faces during dynamic operation. Grooves on one side of the seal face direct gas inward toward a non-grooved portion of the face. The gas flowing across the face generates a pressure that maintains a minute gap between the faces, optimizing flui
Post a Comment
[Read more...]

Thermal growth: how to identify, quantify and deal with its effects on turbomachinery

Thermal growth, as used in the field of machinery alignment, is machine frame expansion resulting from heat generation. The generation of heat, of course, is caused by operational processes and forces. Materials subjected to temperature changes from heat generation will expand by precise amounts defined by their material properties. In turbomachinery, thermal growth results from the temperature differences occurring between the at-rest and running conditions. Generally speaking, the greater the temperature difference, the greater the thermal growth. The magnitude of the growth can be calculated from three variables: ∆ T (temperature difference) C   (coefficient of thermal expansion) L    (distance between shaft centerline and machine supports) When machinery begins to generate heat, the temperature difference between at-rest and running conditions will cause thermal expansion of the machine frame, thereby bringing about the movement of the shaft centerlines. This can produce changes in
Post a Comment
[Read more...]

Understanding the Causes of Pump Shaft Breakage

By NTS. Pump shafts are essential in many industrial and commercial applications, providing the necessary mechanical force to move fluids through pipelines and process systems. However, when a pump shaft breaks, it can cause significant downtime, production losses, and safety risks. In this article, we will explore the common causes of pump shaft breakage and how to prevent it from occurring. 1. Excessive Load  The most common cause of pump shaft breakage is excessive load. When a pump is overloaded, it places a significant amount of stress on the shaft, causing it to bend, warp, or break. Overloading can be caused by a variety of factors such as a clogged discharge line, worn impeller, or damaged bearings. Proper maintenance, regular inspections, and monitoring of the pump's performance can help prevent overloading. 2. Misalignment  If the pump and motor are not properly aligned, it can cause stress on the pump shaft and lead to breakage. Misalignment can occur due to improper ins
Post a Comment
[Read more...]

Technical questions with answers on gas turbines

By NTS. What is a gas turbine? A gas turbine is an engine that converts the energy from a flow of gas into mechanical energy. How does a gas turbine work? Gas turbines work on the Brayton cycle, which involves compressing air, mixing it with fuel, and igniting the mixture to create a high-temperature, high-pressure gas. This gas expands through a turbine, which generates mechanical energy that can be used to power a variety of machines and equipment. What are the different types of gas turbines? There are three main types of gas turbines: aeroderivative , industrial, and heavy-duty. Aeroderivative gas turbines are used in aviation and small-scale power generation. Industrial gas turbines are used in power generation and other industrial applications. Heavy-duty gas turbines are typically used in large power plants. What are the main components of a gas turbine? The main components of a gas turbine include the compressor, combustion chamb
Post a Comment
[Read more...]