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Material characteristics of elevator guide rail components

Source:mingyuanliangpin.com      Release date: 2024年11月18日
Information summary:The elevator guide rail components mainly include guide rails and guide rail brackets, and their material characteristics are as follows: 1、 Material characteristics of elevator guide rails 1. The dominant position of steel materials The commonly used steel for T-shaped guide rails: Elevator guide rails mostly use excellent carbon structural steel or low-alloy high-strength structural ste
The elevator guide rail components mainly include guide rails and guide rail brackets, and their material characteristics are as follows:
1、 Material characteristics of elevator guide rails
1. The dominant position of steel materials
      The commonly used steel for T-shaped guide rails: Elevator guide rails mostly use excellent carbon structural steel or low-alloy high-strength structural steel. For example, common T-shaped guide rails such as T89/A and T90/A are mainly made of carbon steel. This type of steel has high strength and hardness, and can withstand the weight of elevator cars and counterweights, as well as various forces generated during operation, such as friction and impact forces. Its yield strength can generally reach over 235MPa, ensuring that the guide rail will not easily undergo plastic deformation when subjected to heavy loads for a long time.
      The adaptability required for high-precision machining: Steel material is conducive to high-precision machining. Because the elevator guide rail needs to ensure the smooth operation of the car and counterweight, the requirements for geometric accuracy such as straightness and flatness of the guide rail are relatively high. Carbon steel and low-alloy steel can achieve high precision through processes such as grinding and milling during mechanical processing. For example, the straightness of the guide rail can be controlled within a range of no more than 0.3mm-0.5mm per meter, which is crucial for ensuring the smoothness and comfort of elevator operation.
2. Surface characteristics
     Wear resistance: The surface of elevator guide rails needs to have good wear resistance. Due to the frequent up and down sliding of the elevator car and counterweight on the guide rail through the guide shoes, the surface of the guide rail will experience continuous friction. In order to reduce wear, the surface of the guide rail is usually subjected to heat treatment processes such as quenching and nitriding. The surface hardness of the quenched guide rail can reach around HRC45-55, greatly improving its wear resistance. At the same time, some guide rails also add wear-resistant coatings on the surface, such as using special polymer coatings, to further reduce the friction coefficient and extend the service life of the guide rails.
     Corrosion resistance: Elevator guide rails may be affected by environmental factors, such as damp basement environments or salt spray erosion in coastal areas. Therefore, the material of the guide rail itself or after surface treatment must have a certain degree of corrosion resistance. The common method is to galvanize the surface of the guide rail, and the zinc layer can form a protective film on the surface of the guide rail to prevent the steel from being oxidized and rusted. Moreover, when the zinc layer is slightly damaged, it can protect the base steel through electrochemical action, extending the service life of the guide rail.
3. Balance of rigidity and toughness
      Sufficient rigidity: The elevator guide rail must have sufficient rigidity to maintain its shape and dimensional stability. This is because during the operation of the elevator, the guide rail must resist various forces from the car and counterweight to prevent bending and deformation. If the rigidity of the guide rail is insufficient, the car will shake during operation, affecting the comfort and safety of passengers. The high elastic modulus of steel (usually around 200GPa for carbon steel) enables the guide rail to maintain small deformation when subjected to large forces, ensuring the stability of elevator operation.
     A certain degree of toughness: In addition to rigidity, the guide rail also needs to have a certain degree of toughness to prevent brittle fracture when subjected to unexpected impact forces (such as sudden stopping of the elevator car during high-speed operation). A rail material with good toughness can absorb a certain amount of energy and avoid fracture accidents caused by local stress concentration. Low alloy high-strength structural steel can provide good toughness through reasonable alloy composition and heat treatment process while ensuring strength, ensuring the safety and reliability of elevator guide rails under complex working conditions.
2、 Material characteristics of elevator guide rail bracket
1. Strength and bearing capacity
     Selection of metal materials: Elevator guide rail brackets are usually made of steel, such as channel steel, angle steel, or welded steel plates. These steels have high strength and can withstand the weight of the car and counterweight transmitted from the guide rails, as well as the dynamic forces generated during elevator starting and braking processes. Taking channel steel as an example, its cross-sectional shape and size can be designed based on factors such as the elevator's load capacity and operating speed. Generally, elevators with larger load capacity will choose channel steel with larger size and higher strength as the guide rail bracket to ensure sufficient load-bearing capacity.
     Calculation and design of bearing capacity: When designing guide rail brackets, it is necessary to calculate the bearing capacity based on the specific parameters of the elevator. This includes considering factors such as the load capacity of the elevator, the weight of the car and counterweight, and the safety factor. For example, for a passenger elevator with a load capacity of 1000kg, the design load-bearing capacity of its guide rail bracket should be much greater than 1000kg. Generally, a safety factor of 1.5-2 times is considered to cope with complex working conditions such as possible overload situations and dynamic forces during elevator operation.
2. Installation and connection characteristics
     Easy to install: The material of the elevator guide rail bracket should be easy to install. The machinability of steel allows the guide rail bracket to easily adapt to different installation environments through cutting, drilling, and other processes. For example, when installing guide rail brackets on elevator shaft walls, the brackets can be adjusted and fixed according to the actual situation of the shaft wall (such as concrete walls, brick walls, etc.). At the same time, steel can be connected by various methods such as welding and bolt connection, so that the guide rail bracket can be firmly connected to the wellbore wall and guide rail.
     Reliability of Connection: In order to ensure the safety of elevator operation, the connection between the guide rail bracket and other components must be firm and reliable. In terms of material, it is required that the steel has good weldability or bolt connection performance. For welding connections, it is necessary to ensure welding quality and prevent welding defects from causing a decrease in connection strength. For bolted connections, it is necessary to select appropriate bolt specifications and strength grades, and ensure that the bolt tightening torque meets the requirements during installation to ensure that the connection between the guide rail bracket and the guide rail can withstand various forces during elevator operation.
3. Environmental resistance
     Adapt to various environmental conditions: The elevator guide rail bracket needs to adapt to various environmental conditions inside the elevator shaft. In some humid environments, such as elevator shafts in underground parking lots, the guide rail brackets may be eroded by moisture. Steel materials can improve their corrosion resistance through surface coating, anti rust paint, and other methods. In buildings with fire protection requirements, the material of the guide rail bracket also needs to meet certain fire performance requirements. For example, fireproof coatings can be used for treatment, so that the bracket can maintain structural integrity for a certain period of time in the event of a fire, providing time for personnel evacuation and firefighting rescue.