Forging is an industry with high emissions and high energy consumption. Due to the constant increase in the international energy price and the negative impact on the world's environment, researchers have
ABSTRACT This research paper addresses the energy-efficient distributed hybrid flow-shop scheduling problem with forging technology (EEDHFSP-FT) in distributed manufacturing. A
Mar 5, 2024 · The paper focuses on the importance of energy conservation by considering the loads of a forging plant having a contract demand of 450 kVA with HT1 connection considering
Energy-Efficient Forging Machinery Mechanical presses are essential in forging operations, using systems like flywheels and cams to provide high-speed forging strokes. Their energy efficiency
H2 GreenForge Project Electrolysis with renewable energy for a green forging future 🔋. The operation of forging furnaces is very energy-intensive and historically been powered by natural
IMARC Group''s report on steel forging manufacturing plant project provides detailed insights into business plan, setup, cost, layout, machinery & requirements.
Oct 1, 2022 · Then, an energy management system for energy efficiency evaluation is developed based on IoT and data-driven. The energy consumption data are conceived for collection,
The paper focuses on the importance of energy conservation by considering the loads of a forging plant having a contract demand of 450 kVA with HT1 connection considering the energy
APPLICATION Jernberg had begun a conversion from its traditional batch forging and finishing processes to a lean manufacturing operation (where forging is accomplished in a continuous
Sep 4, 2024 · ABSTRACT This research paper addresses the energy-efficient distributed hybrid flow-shop scheduling problem with forging technology (EEDHFSP-FT) in distributed
ABSTRACT: The modern forging plant, due to heavy energy consuming equipment and critical working conditions requires minimum energy losses and sustainable development during
However, batch operation processes, such as forging furnaces and die ovens, often present challenges to the WHR due to both spatial and temporary mismatches between waste heat
Nov 30, 2020 · ABSTRACT: The modern forging plant, due to heavy energy consuming equipment and critical working conditions requires minimum energy losses and sustainable
May 2, 2013 · APPLICATION Jernberg had begun a conversion from its traditional batch forging and finishing processes to a lean manufacturing operation (where forging is accomplished in a
Oct 15, 2025 · Aiming at the problems of the fuzzy energy-using mode of equipment in forging workshop and the not obvious green value information, we have studied real-time acquisition,
Aiming at the problems of the fuzzy energy-using mode of equipment in forging workshop and the not obvious green value information, we have studied real-time acquisition, pre-processing,
Jul 5, 2025 · Energy-Efficient Forging Machinery Mechanical presses are essential in forging operations, using systems like flywheels and cams to provide high-speed forging strokes.
Innovations such as computer-aided design (CAD), simulation software, and automated forging systems enable manufacturers to optimize production efficiency, reduce lead times, and enhance product quality. The following aspects have been covered in the report on setting up a steel forging manufacturing plant:
In addition, the strength of the proposed method in this paper is a novel approach to energy efficiency evaluation and the development of an energy management system suitable for forging workshops. It can monitor the energy consumption of the whole workshop and track the energy consumption of each part of the production.
Forging is an industry with high emissions and high energy consumption. Due to the constant increase in the international energy price and the negative impact on the world's environment, researchers have begun to focus on transforming forging into information and sustainable development.
The forging process comprises blanking, heating, forging, heat treatment, cooling and cleaning, and machining. The billet goes through a series of processes to reach the requirements of size, shape, and mechanical properties. The energy consumption of the forging process mainly includes fuel and kinetic energy consumption.
Application of the proposed framework in a forging workshop. Fig. 8 shows some of the primary functional interfaces of the evaluation system. The general idea of the system design is to use energy flow as a carrier to provide data management, energy monitoring, energy efficiency analysis, and evaluation.
Commonly used fuels are electricity, natural gas, fuel oil (including diesel and heavy oil), and coal, primarily used for heating forging billets and heat treatment of forgings. Kinetic energy consumption refers to the energy consumed in driving the equipment and production process.
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