As an important metal processing technology, forging is widely used in various industries. In the forging process, the correct control of the forging press energy is the key to ensure the strength and durability of the forging.

First of all, we need to clarify the concept of forging press energy. Forging press energy refers to the energy contained in the pressure applied to the forging. In the process of forging, the metal material will undergo plastic deformation through a reasonable impact energy, so as to obtain the desired shape and mechanical properties of the forging. However, too much or too little energy can lead to undesirable consequences.

To ensure the strength and durability of forging parts, we need to pay attention to the following aspects.

First of all, the striking energy in the forging process must be precisely controlled to avoid cracks and defects caused by excessive deformation or stress concentration.

Secondly, according to the material and shape characteristics of the forgings, the appropriate impact energy range is selected to enable the forgings to achieve the expected mechanical properties.

Finally, by optimizing the mold design and process parameters, to ensure that the strike energy is evenly distributed, avoid the local area of the energy is too high or too low. When solving the energy problem of the forging press, we can take the following measures.

First, precise numerical simulations and experimental studies are carried out to understand the optimal range of strike energy required for forgings of different materials and shapes. Secondly, by adjusting and controlling the process parameters, such as forging speed, holding time, to adjust and control the impact energy.

In addition, the advanced monitoring and feedback system is used to monitor the impact energy changes in the forging process in real time, and the parameters are dynamically adjusted to ensure continuous and stable impact energy.

In addition, effective die design is also the key to ensure the impact energy control in the forging process. Reasonable design and selection of mold structure can achieve better energy transfer and distribution, avoid energy waste and local excessive deformation. At the same time, improve the automation level of the equipment, through the automatic control system to achieve accurate impact energy regulation, can further improve the forging quality and production efficiency.

To sum up, to ensure the strength and durability of forging parts, it is necessary to pay attention to the energy of forging press during forging. By precisely controlling the impact energy, selecting the appropriate parameter range, optimizing the die design and process parameters, and improving the level of equipment automation, this problem can be effectively solved to ensure the quality of forging parts and improve production efficiency.