Skip to content

Metal Buildings

Metal Buildings for Industrial, Commercial and Agricultural

Read More

Metal Buildings Solution

Metal Buildings design from Havit Steel provides an optimized solution for your project. Our professional team is ready to serve any buildings. We can provide you with the most efficient design and construction plan, which is fast and smooth to complete construction for your steel building projects.

Metal Buildings
Steel Structure Buildings
Steel Structure Building
Industrial

Steel Structure Building

Steel structure building is a new building structure—the entire building is made of steel. The structure mainly comprises steel beams,…

Steel Workshop Building
Steel Workshop Building
Industrial

Steel Workshop Building

Steel workshop building used for industrial production. The industrial workshop includes production workshops, auxiliary production workshops, warehouses, power stations, and…

Steel Warehouse Building
Steel Warehouse Building
Industrial

Steel Warehouse Building

The steel structure warehouse building designed by Havit Steel provides customers with ideal storage and cargo management solutions. With the…

Prefab Metal Building
Prefab Metal Building
Industrial

Prefab Metal Building

Prefab metal building is customized steel structures according to customers' architectural and structural requirements. All components are produced in the…

Steel Aircraft Hangar Building
Steel Aircraft Hangar Building
Commercial

Steel Aircraft Hangar Building

Havit Steel manufactures customized Steel Aircraft Hangar Building, which protects and maintains small and large aircraft. Our metal structure building…

Steel Structure Frame Building
Steel Structure Frame Building
Commercial

Steel Structure Frame Building

The Steel Structure Frame Building is composed of steel beams and steel columns. The steel frame can withstand the vertical…

Metal Structure Garage Kits
Metal Structure Garage Kits
Commercial

Metal Structure Garage Kits

The garage is an essential part of your property. Now almost every family has a car. The durable Metal Structure…

Steel Structure Livestock Buildings
Steel Structure Livestock Buildings
Agricultural

Steel Structure Livestock Buildings

Many farmers choose steel structures to build livestock buildings. Because steel structure livestock buildings with the advantage of low maintenance…

Metal Structure Warehouse Buildings
Metal Structure Warehouse Buildings
Industrial

Metal Structure Warehouse Buildings

Metal Structure Warehouse Buildings can better meet the needs of cargo storage and logistics turnover because steel structure buildings have…

Steel Structure Workshop
Steel Structure Workshop
Industrial

Steel Structure Workshop

The steel structure workshop is a new type of building structure system. The kind of building structure system is a…

Steel Structure Warehouse
Steel Structure Warehouse
Industrial

Steel Structure Warehouse

The main load-bearing component of a steel structure warehouse is a steel frame, including steel columns and roof beams. After…

Steel Manufacturing Building
Steel Manufacturing Building
Industrial

Steel Manufacturing Building

The steel building design from Havit Steel is an effective solution for steel manufacturing buildings. Every manufacturing business requires a…

Metal Buildings Specification

The metal buildings uses steel to form a load-bearing structure. Generally, beams, columns, trusses, and other components made of section steel and steel plates constitute a load-bearing structure, which together with roof, wall, and floor, form a building.

Compared with traditional concrete buildings, metal structure buildings use steel plates or section steel instead of reinforced concrete, higher strength, and better seismic resistance. And because the components can be manufactured in factories and installed on-site, the construction period is greatly reduced. Due to the reusability of steel, it can greatly reduce construction waste and become more environmentally friendly. Therefore, it is widely used in industrial buildings and civil buildings all over the world.

Advantage
1. Greatly save construction time. Construction is not affected by the season
2. Increase the use area of buildings, reduce construction waste and environmental pollution
3. Building materials can be reused, stimulating the development of other new building materials industries
4. Good seismic performance, easy to transform, flexible and convenient in use, bringing comfort and so on
5. High strength, lightweight, high safety and wealth of components, and lower building cost

Disadvantages:
1. Heat-resistant and non-fire-resistant, fire-resistant coatings are required
2. It is susceptible to corrosion, and the surface needs to be coated with anti-corrosion coatings to reduce or avoid corrosion and increase durability

Metal Buildings

Metal Building Kits

Steel Building Kits design from Havit Steel with advantage of Fast and Simple Construction, Wide Range Of Uses, Reasonable Cost, lower price than concrete building structure.

Metal Buildings Cladding

Metal Cladding System

Metal cladding system includes wall and roof cladding, skylight sheet, trim and flashing, gutter and downspout, insulation, which are essential components of metal building.

Metal Buildings

Steel Building Specs

Steel Building Specification provide the basic information about the Prefab Steel Building, which include Steel Warehouse, Industrial Workshop, Shed, and Garage Building.

We Are Here To Serve Any Type Of Metal Buildings

Please contact us. There’s a lot we can do for your steel building projects, small or large. Our team will provide you with the best quality construction solution

+86-152-05426602 sale@havitsteelstructure.com

As a typical construction and treatment method for steel structures, the level of welding construction is constantly improving, but welding deformation often occurs. Studying steel structure welding deformation and correction can better improve the actual effect of steel structure construction. This paper begins the research of this subject by introducing the classification and causes of welding deformation of steel structures.

Steel Structure Welding Deformation

Classification and Causes of Steel Structure Welding Deformation

The main factors affecting steel structure welding deformation are the welding process, position, and method. For steel structures, combined with their deformed appearance, steel structure welding deformation can be divided into the following categories:

Steel Structure Welding Deformation can be divided into the following categories:

Steel Structure Welding Deformation

Corner deformation.


When welding steel structures, the plane welds affect the steel components, resulting in angular displacement. The reason is that shrinkage and deformation occur in the relevant welds along the plate thickness direction in the steel structure. In addition, if the welding sequence is incorrect Or the operator does not use a better welding method, it will lead to corner deformation.

Side deformation.

When the operator welds two steel structures because the specific heat received by the two is different, there will be a particular difference in the length and height of the two steel structures, resulting in misalignment, that is, misalignment. Because the rigidity of the two is different, the shrinkage deformation is also other, leading to misalignment deformation.

Bending


After the steel structure is welded, deformation occurs in adjacent welds, resulting in no identical deformation between adjacent welds, causing the steel structure to deflect in appearance. The specific material quality of the steel structure has a great relationship with this phenomenon.

Wave deformation.


If the steel structure needs to be welded, its thickness is relatively small, and it is a thin plate structure. After high temperature, expansion will occur. After the weld is pulled by internal stress, shrinkage, and deformation will happen because this deformation appears. The resulting shape is wavy, so it is called wave deformation.

Spiral deformation.


After the welding, the steel component undergoes distortion and deformation, which is spiral deformation. This phenomenon is because the weld angles are not evenly distributed, and there are misaligned edges in the longitudinal position.

Horizontal and longitudinal deformation.


After the steel structure is welded, if the shrinkage deformation of the steel structure happens to be in the relevant axial position of the welding seam, it is longitudinal deformation. If the shrinkage deformation occurs in the vertical direction of the weld seam, it is a transverse deformation.

The reason for the steel structure welding deformation is that the relevant welds of the steel structure are affected by temperature and expand to varying degrees, resulting in horizontal and longitudinal deformation in the steel structure.

Factors affecting steel structure welding deformation:

Influence of welding method and process specification


The general welding methods in manufacturing steel structures include submerged arc automatic welding, manual arc welding, and CO2 gas-shielded welding. Different welding methods generate extra heat and cause various deformations. Steel structure welding caused by other welding process specifications is also further in the same welding method. Before the steel structure is welded, a welding procedure qualification guide must be formulated to guide welding. At the same time, there are requirements for the temperature and humidity of the working environment.

Influence of structural stiffness


Rigidity refers to the ability of a weldment to resist deformation, which is related to the weldment’s material, the weldment’s cross-sectional shape and size, etc. The greater the structural rigidity, the stronger the ability to prevent thermal deformation of the weld and its vicinity, and the smaller the welding deformation. On the contrary, the smaller the rigidity of the weldment, the greater the welding deformation. When the stiffness of the steel structure is minor, the welded seams are symmetrically distributed.

Only linear shortening deformation will occur when the welding procedures are correct and reasonable. When the welded seams are asymmetrically distributed, there is a distance between the weld shrinkage and the center of gravity. The upward bending of the section will produce bending deformation; when the welding procedure is reasonable, the center of the weld section and the center of the joint team are in the same direction, and only linear shortening will occur; when the center of the weld section deviates from the center of the common area, angular deformation will occur.

Influence of welding sequence


Different assembly and welding sequences will produce various deformations after welding, so a reasonable arrangement should be adopted during assembly and welding. Try to use symmetrical welding; when the weld is asymmetrical, weld the side with fewer welds first. Especially for welding components with many welds, reasonable selection of the welding sequence can effectively reduce welding deformation, and the deformations of multiple weldings can offset each other.

Control measures to reduce welding stress

1. Selection of weld size


Due to thermal expansion and contraction in the welding area, welding stress is formed. Generally, the more minor the welding area, the less heat input, the smaller the welding deformation, and the smaller the welding stress. For example, small-angle grooves and thick plates should use double-sided tracks to reduce welding stress.

2. Suitable welding materials and welding parameters

The selection of welding materials has an essential impact on the plasticity, toughness, and crack resistance of the weld metal and can also appropriately reduce the formation of hardened structures and stress concentration in the weld.

Typically, the carbon content of the base metal is higher than the carbon content of the weld metal. The strength of the weld to reach the same power as the base metal is mainly achieved by increasing the silicon and manganese content in the metal. The welding line energy in the welding parameters is proportional to the welding deformation; the more significant the welding line energy, the greater the welding plastic deformation produced, the greater the welding stress, and the greater the post-weld deformation, and vice versa.

3. Reasonable process


Long welds are inevitable in welded steel structures. In this case, segmented welding should be used instead of continuous welding.


Attention should be paid to segmental welding:
(1) Pay attention to the joints to stagger and cover each other’s joints to avoid joint alignment problems; (2) Pay attention to the welding deformation. When the temperature is too high, you need to stop, slowly cool, or turn the back of the welding;
(3) Pay attention to the order of welding multiple components. Generally, parts with more remarkable restraint are welded first, followed by members with less restriction.

4. Heat treatment measures


Appropriate heat treatment measures can eliminate stress and deformation on the one hand and prevent cracks on the other. For example, thick plates need to be preheated before cutting and welding. If the thickness of the low alloy steel plate exceeds 100 mm, the preheating temperature needs to be higher than 100 degrees Celsius, and the preheating range is 150mm to 200mm on both sides of the cutting line or groove. After welding, slow cooling or post-heat treatment is required to avoid hydrogen escape and accumulation, causing stress.

Analysis of control method for steel structure welding deformation

1. Analysis of steel structure welding deformation control in design


Due to its inherent properties, steel structures are not easy to repair after they are finished. If there are deficiencies and defects in the steel material during the design process, welding deformation will be inevitable. The errors at this time can only be repaired manually. The steel material can only be remanufactured if the design has severe flaws. Lack of innovation will lead to uncontrollable welding deformation of steel materials, while reasonable and scientific methods will significantly reduce the difficulty of welding and minimize the deformation during welding.

2. Analysis of steel structure welding deformation control during construction


In the construction and welding process of steel materials, different forms of welds and other structures of nodes are the basis for the welding construction of steel materials. Welds should be constructed using symmetrical welding methods. For asymmetrical welds, the side with fewer welds must be welded first, and then the construction on the other side is carried out. The deformation angle produced after welding can be reasonably controlled through the anti-deformation method before welding. When the thickness of the T-shaped joint plate is relatively large, we usually use the bevel angle for weld butt jointing.

3. Heat treatment measures


The heat treatment process is essential in the welding process of steel materials. When steel materials are directly exposed to high temperatures, reasonable heat treatment measures can eliminate deformation and stress and prevent cracks during deformation. The commonly used method is preheating and thick plate blanking during welding. Preheating steel materials during welding will effectively reduce the conventional cooling rate of the heat-affected zone and weld metal, inhibiting martensite formation in the hardened structure, thereby reducing the considerable stress generated by the weld and avoiding gas-cutting edges. Heat treatment measures are one of the essential methods to control the welding deformation of steel structures.

Conclusion
We can find many factors affecting welding deformation through relevant research on the control and correction of welding deformation of steel structures. Appropriate personnel should proceed from the objective reality of steel structures, thoroughly combine welding construction methods and research, and formulate the most optimized Reasonable welding deformation control and correction scheme.

Back To Top