Category: Services

What is a strength calculation?

Strength calculation is the process of analysing the ability of structures and materials to withstand different loads. This includes, but is not limited to, examining tensile strength, compressive strength, flexural strength and shear strength. Strength calculations can be used to predict how structures will behave under different conditions and ensure that they meet safety requirements.

Structural analysis is based on mathematics and physics, and uses a variety of calculation methods and software. These can be used to simulate the behaviour of structures and optimise their design. This makes strength calculation an indispensable tool for engineers and designers.

One of the key objectives of strength calculation is to prevent failure of materials and structures. This is achieved by analysing the loads and stresses that can cause fractures, deformations or other damage. This ensures that structures can withstand the intended service conditions and operate safely throughout their life cycle.

The importance of strength calculation in different industries

Strength calculations are an essential part of many industries, including construction, engineering, aerospace and automotive. In the construction industry, strength calculations ensure that buildings and bridges can withstand the loads they are subjected to, such as wind, snow and earthquake forces. This is particularly important when designing tall buildings or other large structures.

In the engineering industry, strength calculations help to design machines and equipment that can withstand the stresses of the operating conditions. This is important to ensure that machines operate reliably and safely, which in turn reduces downtime and maintenance costs. In the aerospace industry, strength calculation is critical to the design of aircraft and spacecraft, which must be able to withstand extreme conditions and loads.

In the automotive industry, strength calculations ensure that vehicles are safe and durable. This includes simulating crash tests and optimising structures to protect occupants in the event of an accident. Strength calculations also help reduce vehicle weight, which improves fuel efficiency and reduces emissions.

Basic tools and methods for strength of materials calculations

A wide range of tools and methods are used for strength calculations, the most important of which are analytical calculation methods, numerical simulations and experimental tests. Analytical methods are based on mathematical formulae and theories that allow the calculation of stresses and deformations in structures. These methods are often used for simple structures and basic calculations.

Numerical simulations, such as the finite element method (FEM), are powerful tools for analysing complex structures. The FEM method divides a structure into small parts, called elements, and calculates their behaviour separately. This allows accurate and detailed analyses, which is particularly useful for complex and irregular structures.

Experimental tests are also an important part of strength calculations. They can be used to verify the accuracy of calculations and simulations and to study the behaviour of materials and structures under real conditions. Experimental tests can include tensile tests, compression tests and fatigue tests to measure the strength properties of materials and structures.

Steps in the strength calculation

The strength calculation process usually starts with the definition of needs and requirements. This includes the identification of loads, operating conditions and safety requirements. Next, suitable materials are selected and structures are designed to meet these requirements. Analytical methods and numerical simulations are often used at this stage.

In the next stage, more detailed calculations and analyses are carried out to ensure the strength and durability of the structures. This may include, for example, stress analyses, deformation analyses and fatigue analyses. These calculations can be used to optimise the design of the structures and ensure that they meet all requirements.

In the final stage, experimental tests are carried out to verify the accuracy of the calculations and simulations. These tests also allow the behaviour of the structures under real conditions to be studied and ensure that they work as designed. If necessary, the results of the experimental tests can be used to modify the design of the structures and improve their strength and durability.

Hefmec has been involved in many successful projects where strength calculation has played a key role. For example, in the design of lifting equipment, strength calculations have helped to ensure that the equipment can withstand the loads placed on it and operate safely. This has improved our customers’ productivity and reduced downtime, resulting in significant economic benefits.

Contact us and tell us your needs, and together we can create a more productive tomorrow.

Strength calculation is a key factor in ensuring safety in various industries. It helps to predict and prevent potential damage and accidents to structures and machinery. Strength calculations help to ensure that structures can withstand the loads and stresses placed on them, which is essential for structural safety and overall safety.

Basics of strength of materials calculations

Structural analysis is a branch of engineering that focuses on the analysis of the strength of materials and structures. It is based on the laws of physics and mathematics, which can be used to calculate how much force and stress a given material or structure can withstand before fracture or deformation. Strength calculations can be used to design safe and durable structures that meet required standards and regulations.

Various methods and tools are used for strength calculations, such as elementary methods (FEM), which allow the analysis of complex structures and loading situations. These methods can be used to simulate and predict how structures will behave under different conditions, such as temperature variations, vibrations and impact loads.

A properly performed strength calculation helps to identify potential weaknesses and risks at the design stage, which significantly reduces the risk of accidents and damage. This is particularly important when designing critical structures such as bridges, buildings and industrial equipment.

Strength calculation in different industries

Strength calculations are an essential part of many industries, including construction, engineering and aerospace. In the construction sector, strength calculations ensure that buildings and infrastructure can withstand the loads they are subjected to, such as wind, snow and earthquake forces. This is essential for structural safety.

In mechanical engineering, strength calculations help design durable and safe machines and equipment. For example, when designing lifting and transport equipment, it is important to ensure that it can withstand the loads and stresses placed on it without damage. This improves safety in the working environment and reduces the risk of accidents.

In the aerospace industry, strength calculation is a critical part of aircraft and spacecraft design. Aircraft structures must be able to withstand extreme conditions such as high speeds, high temperatures and strong pressure differentials. Strength calculations help ensure that aircraft are safe and reliable in service.

The importance of strength calculation for safety

The importance of strength calculation for safety is undeniable. It helps to anticipate and prevent potential damage and accidents to structures and machinery. Correctly performed strength calculations ensure that structures can withstand the loads and stresses to which they are subjected, which is essential for structural and public safety.

Strength calculations can also be used to optimise the use of materials and reduce costs. By designing structures to withstand well-defined loads, the use of excess materials can be avoided, thus reducing costs. This is important both economically and environmentally.

In addition to safety, strength calculation also improves the reliability and lifetime of structures and machinery. When structures are designed to withstand the loads placed on them, they last longer and require less maintenance and repair. This improves production efficiency and reduces downtime.

How does Hefmec use strength calculation?

Hefmec uses strength calculation in a wide range of projects. Our experts use advanced calculation methods and tools to ensure that the structures and machines we design are safe and durable. Strength calculations allow us to anticipate potential risks and weaknesses at the design stage, significantly reducing the risk of accidents and damage.

For example, strength calculations play a key role in the design of lifting equipment. Lifting equipment must be able to withstand high loads and stresses without damage. Strength calculations help us to ensure that lifting equipment meets all safety requirements and is reliable in use. This improves safety in the working environment and reduces the risk of accidents.

Hefmec experts are also involved in many demanding production development projects where strength calculation is an integral part of the project. Strength calculations allow us to optimise production processes and improve production efficiency. This helps our customers to achieve better results and reduce costs.

Contact us and tell us your needs, and together we will design the perfect solution for your project.

Strength calculations are a key part of building design and have a major influence on the choice of building materials. It ensures that the materials selected can withstand the intended loads and conditions, ensuring the safety and longevity of the structure. Without accurate strength calculations, the selection of building materials would be based on guesswork, which could lead to serious structural problems and safety risks.

The importance of strength calculations in the selection of building materials

Strength calculation is the process of evaluating the ability of structures and materials to withstand various loads, such as weight, wind and earthquakes. This calculation is an essential part of building design, as it helps determine which materials are best suited to a particular building project. Without strength calculations, the choice of building materials could be arbitrary and lead to structural failures.

When choosing building materials, several factors need to be taken into account, such as strength, durability, cost and availability. Strength calculations provide an accurate and objective way to assess these factors and make informed decisions. This ensures that the materials selected meet all required standards and can withstand the intended loads.

In addition, strength calculation helps to optimise the use of materials, which can lead to cost savings and reduce material wastage. This is particularly important in large construction projects, where even small savings can add up to significant costs.

How is the strength calculation done?

The strength calculation starts with the determination of the structure and its loads. This includes both static and dynamic loads, such as forces due to weight, wind and earthquakes. These loads are used to calculate the stresses and deformations of the different parts of the structure.

The next step is to select the appropriate materials and their properties, such as tensile strength, compressive strength and modulus of elasticity. This information can be used to calculate how well the materials can withstand the designed loads. Computer programs are often used to simulate different loading conditions and give accurate results.

Finally, the results are analysed and compared with design standards and regulations. If the materials and structures meet the required criteria, they can be approved for use. If not, the calculations can be adjusted and optimised until the desired results are achieved.

The benefits of strength of field calculations

The main benefit of strength calculation is its ability to ensure the safety and durability of structures. This is particularly important in large and complex construction projects where even small errors can have serious consequences. Strength calculations also help to optimise the use of materials, which can lead to significant cost savings.

Another important benefit is the possibility to simulate different loading conditions and assess the behaviour of structures before they are built. This reduces risks and helps to make informed decisions on the choice of materials.

How to choose the right building material using strength calculations

Choosing the right building material starts with defining your needs and requirements. This includes the intended use of the structure, loads and environmental conditions. Based on this information, an initial selection of suitable materials can be made.

Next, a strength calculation is performed to assess the ability of the selected materials to withstand the designed loads. This step may involve several iterations of refining and optimising the calculations until the desired results are achieved.

Finally, the results are analysed and a final decision on the choice of materials is made. This decision is based on both technical and economic factors, such as the cost and availability of materials. The strength calculation ensures that the materials selected meet all the required criteria and offer the best possible performance and durability.

Hefmec experts are ready to help you choose the right building material and offer comprehensive strength calculation services. Contact us and tell us your needs, and together we will design the perfect solution for your project.

Structural analysis is a key part of engineering, especially in structural analysis and mechanics. Correctly performed strength calculations ensure that structures can withstand the loads placed on them and operate safely throughout their design life. In this article, we will go through how to perform strength calculations correctly.

What is a strength calculation?

Strength calculation is an engineering analysis used to determine the resistance of structures and materials under different loading conditions. It is an essential part of mechanics and structural analysis, and aims to ensure that structures can withstand the loads placed on them without damage or failure.

Strength calculations cover a wide range of analyses, including stress analyses, deformation analyses and stability analyses. These analyses can be used to predict how structures will behave under different loading conditions and ensure that they meet safety and performance requirements.

In engineering, strength calculations are an essential tool to help design durable and safe structures. It is particularly important in the construction industry, where the safety and durability of structures are of paramount importance.

Steps in the strength calculation

A strength of field calculation always starts with a precise definition of what you want to analyse. This includes the geometry of the structure, material properties and loading conditions. It is important that all input data is as accurate and comprehensive as possible to ensure that the calculation results are reliable.

The next step is the calculation itself, which may include various analyses and simulations. This step often requires specialised software and tools that allow complex calculations to be carried out efficiently and accurately. During the calculation, the stresses, deformations and other critical factors of the structure are considered.

Finally, the results are analysed and interpreted. This step is as important as the calculation itself, as the results are used to make decisions on the design of the structure and any changes. It is important that the results are presented in a clear and understandable way so that all parties involved can make informed decisions.

Main tools and software

A wide range of tools and software are used to perform strength calculations. One of the most common is the Finite Element Method (FEM), which allows complex structures to be analysed by breaking them down into small parts, or elements. FEM software such as ANSYS, Abaqus and SolidWorks Simulation are widely used in engineering.

In addition, various CAD software such as AutoCAD and SolidWorks are used to facilitate the modelling and preparation of structures for strength calculations. These software programs allow the creation of accurate 3D models, which is essential for accurate calculations.

Traditional calculation tools, such as Excel and various spreadsheets, are also still in use, especially for simpler calculations. These tools allow basic calculations and checks to be carried out quickly and efficiently.

The importance of strength calculation in the construction sector

In the construction industry, strength calculation is a key part of the design process. It ensures that structures can withstand the loads placed on them and operate safely throughout their design life. This is particularly important in large and complex construction projects where the safety and durability of structures are of paramount importance.

Strength calculations also help to optimise the design of structures and the use of materials. This can lead to significant cost savings and improved structural performance. Optimised design can also reduce material waste and improve the efficiency of the construction process.

Companies like Hefmec that offer expert strength calculation services can help their customers ensure that their structures are safe, durable and cost-effective. For example, when designing lifting equipment, strength calculations are essential to ensure that the equipment can withstand the loads placed on it and operate safely in all operating conditions.

A properly performed strength calculation is therefore an essential part of civil engineering. It ensures the safety and durability of structures, optimises design and improves the efficiency of the construction process. Hefmec’s experts are ready to help with all your strength calculation needs, so that together we can create sustainable and safe structures for the future.

Contact us and tell us your needs, and together we can create a more productive tomorrow.

Engineering computing is the process of using mathematical and computer methods to solve engineering problems. It is central to many industries, including mechanical engineering, manufacturing engineering and civil engineering. Engineering computation enables the analysis, design and optimisation of complex structures and systems, improving production efficiency and safety.

Basics of technical calculation

Technical computing is based on mathematical models and algorithms that describe physical phenomena and structures. These models are used in areas such as strength calculations, flow calculations and temperature distribution analysis. The models can be used to predict how structures and systems will behave under different conditions.

The basic principles of technical calculation include the use of numerical methods. Numerical methods allow the solution of complex equations that cannot be solved analytically. Computers and software play a key role in performing these calculations, as they are able to process large amounts of data quickly and accurately.

Technical computing also requires a deep understanding of physics and materials science. For example, in strength calculations it is important to understand how different materials behave under load. This knowledge is combined with mathematical models to make accurate predictions about the durability and safety of structures.

The importance of technical calculation in industry

In industry, technical calculation is essential for the design and optimisation of many processes and products. In mechanical engineering, for example, engineering calculation helps design durable and efficient machines that meet stringent safety and performance requirements. This improves production quality and reduces costs.

In civil engineering, technical calculation plays a key role in the design and analysis of structures. Strength calculations ensure that buildings and bridges can withstand the designed loads and environmental conditions. This is particularly important for safety, as incorrect calculations can lead to serious accidents.

Technical calculation is also important in production engineering. It allows you to optimise production processes and improve efficiency. For example, flow calculation helps to design optimal piping and air conditioning systems, which improves energy efficiency and reduces costs.

How does technical calculation work in practice?

In practice, technical calculation starts with defining the problem and collecting the necessary data. This can include, for example, measuring material properties, estimating loads and analysing environmental conditions. A mathematical model is then created to describe the key features of the problem.

Next, the model is solved using numerical methods. This step often requires the use of computer software capable of handling large amounts of data and performing complex calculations quickly. Software such as FEM (Finite Element Method) and CFD (Computational Fluid Dynamics) are commonly used for engineering calculations.

Finally, the results are analysed and interpreted. This stage is critical, as the results are used to make decisions on design and optimisation. It is important to ensure that the results are accurate and reliable in order to make the right decisions in terms of production and safety.

The most common tools in technical calculation

Technical calculation tools range from simple spreadsheets to complex computer software. One of the most common tools is the Finite Element Method (FEM), which allows the analysis of complex structures and systems. FEM software, such as ANSYS and Abaqus, is widely used in various industries.

Another important tool is Computational Fluid Dynamics (CFD), which is used for flow calculations. CFD software, such as Fluent and OpenFOAM, allows the analysis and optimisation of fluid and gas flows. This is particularly important in sectors such as aerospace and automotive, where aerodynamics is a key issue.

In addition, a variety of mathematical software such as MATLAB and Mathematica are used, providing a wide range of tools for numerical calculation and analysis. These software tools are particularly useful in research and development, where flexible and efficient computational tools are needed.

Technical calculation challenges and solutions

Technical computing faces many challenges, such as creating complex models and dealing with large amounts of data. Another key challenge is ensuring accuracy, as even small errors in calculations can have serious consequences. This is why it is important to use reliable and tested methods and software.

Another challenge is the efficiency of the calculation. Large and complex calculations can require a lot of computing time and resources. This can be overcome by using powerful algorithms and parallel computing, which allows calculations to be performed faster and more efficiently.

Hefmec offers solutions to these challenges by providing expert design and calculation services. For example, when designing lifting equipment, we use engineering calculations to ensure that our products meet stringent safety and performance requirements. This enables us to provide our customers with reliable and sustainable solutions that improve production efficiency and safety.

Contact us and tell us about your needs, and together we will design the perfect solution for you.

The basic principles of strength calculation are key to ensuring the durability and safety of structures and materials. These basic principles include understanding the properties of materials, mastering common calculation methods, and designing and optimising structures. These principles help to ensure that structures can withstand the loads placed on them and perform as designed.

Definition and meaning of strength of field calculation

Strength calculus is a branch of mechanics that focuses on analysing the strength of structures and materials. It can be used to assess how well structures can withstand a variety of loads, such as weight, temperature changes and other external forces. Strength calculations can be used to predict potential damage and design structures to safely withstand service conditions.

The importance of strength calculations is particularly highlighted in industry, where the safety and durability of structures and machinery are of paramount importance. For example, the lifting equipment that Hefmec designs and manufactures requires accurate strength calculations to ensure that it can withstand the loads placed on it and meet safety requirements.

Without strength calculations, the design of structures would be based on guesswork, which could lead to serious safety risks. Therefore, strength calculation is an essential part of engineering and structural design.

The most common calculation methods

Several different methods are used for strength calculations, the most common being analytical methods, numerical methods and experimental methods. Analytical methods are based on mathematical formulae and theories that allow the calculation of stresses and deformations in structures.

Numerical methods, such as the finite element method (FEM), are particularly useful for analysing complex structures. In the FEM method, the structure is divided into small parts whose behaviour is analysed separately. This allows a more accurate and detailed analysis than traditional analytical methods.

Experimental methods, on the other hand, are based on physical tests and measurements. These methods are often used to verify the results of computational methods and to assess the actual behaviour of structures under practical conditions.

Properties of materials

Understanding the properties of materials is a key part of strength calculations. Different materials behave differently under load and their properties, such as strength, stiffness and ductility, directly affect the durability of structures. For example, steel is a very strong and rigid material, while aluminium is lighter but less strong.

The properties of materials can be measured by various tests, such as tensile tests, compression tests and impact tests. These tests provide information on the behaviour of materials under different loading conditions, which is essential for strength calculations.

The choice of materials is an important part of structural design. Choosing the right material can improve the durability of a structure, reduce costs and extend its lifetime. Hefmec experts help customers choose the most suitable materials for their needs, while ensuring the safety and durability of the structure.

Design and optimisation of structures

Structural design and optimisation are key aspects of strength calculation. The design process takes into account the intended use of the structure, loads and environmental conditions. The aim is to create a structure that is both safe and cost-effective.

Optimisation means improving a structure so that it meets all requirements as efficiently as possible. This can mean, for example, reducing the amount of material, changing the shape of the structure or improving the efficiency of the manufacturing process. Hefmec’s experts use advanced calculation methods and software to optimise structures according to customers’ needs.

For example, optimisation is particularly important in the design of lifting accessories. Lifting equipment must be lightweight but durable to be used safely and efficiently. Hefmec experts design and manufacture lifting equipment that meets the most stringent safety and durability requirements.

In summary, the basic principles of strength calculation are essential to ensure the durability and safety of structures and materials. Hefmec’s experts are ready to assist customers with all their strength calculation needs, whether it is the design of lifting equipment or the optimisation of other industrial structures. Contact us and let us know your needs and together we will design the perfect solution.

Development of technical calculation

Technical computing has evolved significantly in recent decades, especially with the development of information technology and software. Originally, technical calculation was based on manual methods and simple calculation tools such as logarithmic tables and slide rules. Today, complex software and computer programs are used to perform highly accurate and complex calculations quickly and efficiently.

For example, Finite Element Method (FEM) and Computational Fluid Dynamics (CFD) are engineering computing methods that enable the modelling and analysis of complex physical phenomena. These methods are widely used in various industries such as aerospace, automotive and construction, where accuracy and reliability are of paramount importance.

Hefmec specialises in technical calculation and offers its customers solutions based on the latest technologies and methodologies. This enables complex technical problems to be solved efficiently and reliably.

Basics of traditional calculation

Traditional accounting covers a wide range of accounting tasks, often related to financial management, accounting and other business management functions. Traditional accounting often uses simpler methods and tools, such as spreadsheets and traditional accounting software.

Traditional accounting often focuses on processing, analysing and reporting numbers and financial data. This can include budgeting, cost accounting, tax planning and financial reporting. Accuracy and consistency are important in these tasks, but the computational tasks are often less complex than in technical accounting.

Although traditional accounting does not require as complex tools as technical accounting, it is still an essential part of business management and decision-making. Well-executed traditional accounting helps companies understand their financial situation and make informed decisions.

Main differences between technical and traditional calculation

One of the main differences between technical and traditional computing is their applications. Engineering calculations focus on solving complex engineering problems, such as structural strength calculations, flow dynamics analysis and modelling of temperature distributions. Traditional calculation, on the other hand, focuses on the processing and analysis of economic data.

Another important difference is the tools and methods used. Engineering calculations use advanced software and computer programs, such as FEM and CFD software, which allow accurate and complex calculations to be carried out. Traditional calculation often uses simpler tools such as spreadsheets and traditional accounting software.

The third difference is the expertise required. Engineering computing requires in-depth technical knowledge and understanding of complex physical phenomena. Traditional accounting, on the other hand, requires financial management and accounting skills, but not necessarily the same depth of technical knowledge.

How to choose the right calculation method for your needs?

The choice of the right calculation method depends largely on the type of calculation tasks and problems to be solved. For complex engineering problems, such as structural strength calculations or flow dynamics analysis, technical calculation is the right choice. In this case, it is important to use advanced software and methods that allow accurate and reliable results to be obtained.

But when it comes to processing and analysing financial data, traditional calculation is more appropriate. In this case, simpler tools and methods can be used, which are sufficient for the needs of financial management and accounting. It is important to ensure that the tools and methods used are appropriate for the task in hand and that they allow accurate and reliable results to be obtained.

Hefmec offers its customers a wide range of technical calculation services designed to meet complex technical needs. For example, the lifting accessories we design and manufacture are based on precise engineering calculations and analyses to ensure their safety and reliability. Contact us and together we can design and implement a solution that meets your specific needs.

Basics of technical calculation

Engineering computing covers a wide range of mathematical and physical methods used in engineering and industry. It includes strength calculation, flow calculation and temperature control. These calculations can be used to predict and optimise the performance of machinery and equipment, and ensure their safety and durability.

For example, strength calculation is an essential part of mechanical engineering. It can be used to determine how much load and stress a machine part can withstand before it breaks down. This is particularly important in the design of lifting equipment, where safety is paramount. Hefmec experts use engineering calculations to ensure that the lifting equipment they design meets all safety requirements and operates reliably.

Flow calculation, on the other hand, helps optimise the flow of liquids and gases in industrial processes. This can lead to energy savings and process efficiency. Engineering calculation also enables temperature control, which is critical in many industrial applications, such as metal processing and the chemical industry.

Challenges and solutions for industry

Industry faces many challenges, such as managing production costs, quality assurance and safety. Engineering calculation offers solutions to these challenges. For example, production costs can be reduced by optimising the use of materials and reducing wastage. Engineering calculation can also help to improve production quality by predicting and preventing potential defects and errors.

Security is another key challenge in industry. Engineering calculations help ensure that machinery and equipment are safe to use. This is particularly important in the design of lifting equipment, where a mistake can lead to serious accidents. Hefmec experts use engineering calculations to ensure that the lifting accessories they design meet all safety requirements and operate reliably.

In addition, technical calculation enables the development of innovative solutions. For example, new materials and manufacturing methods can be tested and optimised computationally before they are introduced. This reduces risks and speeds up product development. Hefmec’s experts specialise in developing tailor-made solutions that meet customers’ specific needs and improve their production efficiency.

The future of technical calculation in industry

The importance of technical computing in industry will continue to grow in the future. With the development of digitalisation and artificial intelligence, technical computing will become more accurate and efficient. This will enable more complex and demanding problems to be solved. Hefmec is at the forefront of exploiting these new technologies and offering innovative solutions to its customers.

For example, artificial intelligence and machine learning can improve the accuracy and speed of technical computing. These technologies can be used to analyse large amounts of data and find new optimised solutions. This can lead to significant improvements in production efficiency and quality. Hefmec’s experts are closely following these developments and using them to provide their customers with the best possible solutions.

The future of technical computing in industry is therefore promising. It offers new opportunities to improve production efficiency, quality and safety. Hefmec’s experts are ready to help their customers exploit these opportunities and improve their production. Contact us and tell us your needs, and together we will design the perfect solution just for you.

The lifting beam allows heavy and awkward objects to be moved safely and efficiently, reducing the need for manual work and minimising the risk of accidents. This leads directly to improved productivity and job satisfaction.

Safety at work

Safety at work is one of the most important factors when it comes to the use of lifting beams. Crane beams reduce the physical strain on workers and the risk of accidents, as heavy lifting and moving can be done mechanically. This also reduces the risk of work-related injuries and illnesses, which in turn reduces sickness absence and improves work efficiency.

The lifting beams designed by Hefmec meet all the necessary safety requirements and are CE marked. This ensures that they are safe to use and comply with the Machinery Directive and national regulations. A safe working environment is key to maximising productivity and employee well-being.

Ergonomics

Ergonomics is another key factor affecting work efficiency. A well-designed lifting beam reduces the physical strain on workers and improves working postures. This leads to fewer musculoskeletal disorders and improves the overall well-being of workers. Ergonomically designed work equipment, such as lifting beams, makes work smoother and less tiring.

Hefmec lifting beams are designed to be user-friendly and ergonomic. The design takes into account the needs of the user and the requirements of the working environment, making the use of the lifting beams easy and safe. Taking ergonomics into account from the design stage ensures that the lifting beams are efficient and comfortable to use.

Cleanability and chemical resistance

In many industrial environments, such as cleanrooms and hygienic conditions, the cleanability and chemical resistance of the lifting beams are important factors. Hefmec lifting beams are designed to be easy to clean and resistant to a variety of chemicals. This ensures that they remain in good condition and work reliably for a long time.

Cleanability and chemical resistance are particularly important in the food and pharmaceutical industries, where hygiene requirements are very strict. Hefmec lifting beams meet FDA and GMP requirements, making them an excellent choice for these environments. Highly cleanable and durable, these lifting beams reduce maintenance costs and improve the efficiency of production processes.

Comprehensive design and delivery

Hefmec offers turnkey design and delivery of lifting beams. This means that our customers receive a complete solution that includes everything needed for the installation and maintenance of the lifting beams. Our design process is ISO 9001 certified, ensuring high quality and reliability.

The delivery includes the design and delivery of a safe, efficient and user-friendly lifting beam. We also provide operating and maintenance instructions and, if required, a guided commissioning. This ensures that our customers can commission the lifting beams quickly and efficiently, improving work efficiency and reducing downtime.

Summary

Lifting beams are an integral part of many industrial production processes, and their use can significantly improve work efficiency. They increase safety at work, improve ergonomics, are easy to clean and resistant to chemicals. Hefmec lifting beams are designed to meet all the necessary requirements and provide a complete solution for our customers’ needs.

If you are interested in improving work efficiency with lifting beams, contact Hefmec. We will design and supply lifting beams to meet your specific needs, improving productivity and safety in your working environment. We have the ability to solve the most demanding industrial production problems and always take full responsibility for our work.