A press brake is a piece of manufacturing equipment that is used to bend sheet metal. A press brake is typically narrow and long so that large pieces of sheet metal can be bent by it. A press brake bends sheet metal by lowering a punch onto sheet metal that has been positioned on top of a die. The metal may be bent several times by a press brake until the desired form has been achieved. Press Brake,Cnc Press Brake,Metal Bending Machine,Hydraulic Press Brake Jiangsu Hoston Machine Tools Co., Ltd. , https://www.hosdunmachinetools.com
Figure 1 Working process of a thick layer stack manufacturing system 
1. Y stepping motor 2.X stepping motor 3. Support plate 4. Z stepping motor 5. Small turntable 6. Large turntable 7. U type connection plate 8. Large turntable support plate 9. Base plate 10. Cutting table Figure 3 Axis milling machine 
1. Cutting table 2. Backing plate 3. Machined workpiece single layer 4. Bolt Figure 4 Clamping scheme
Press brakes can make a variety of different bends on many different types of metals. When setting up a bending process, it is important to consider the metal type being bent, the die, the punch, and the bending force.
The metal type is important to understand because of the differing physical properties among metals. For instance, a high carbon steel will generally be less bendable by a press brake than many aluminum alloys because of the differences in ductility and strength. Metals typically have a recommended minimum bend radius that the material can be bent to without damaging it.
The die and the punch used on the press brake both have a large impact on the bending process. The die is hollow material that the metal is placed on top of prior to bending. It is a very hard and strong material that is near in shape to the desired shape of the metal being bent. The punch is a solid material that is lowered down onto the metal. Since the pressing action of the punch onto the metal and the die are what causes the metal to bend, both shapes must be accurately suited to the bending job. The correct metal shape following a press brake operation is dependent on the size and shape of the punches and dies. The dies and the punches are typically designed in such a way that they can be interchanged easily to accommodate a wide array of jobs.
An economical precision rapid prototype manufacturing technology
1 Introduction The most mature rapid prototyping technology (RP) is currently researched: Stereolithography (SLA), 3D-Printing, Laminated Manufacturing (LOM), Selective Laser Sintering (SLS), Melt Stacking Law (FDM). As far as the existing RP technologies are concerned, there are some problems that need to be researched and improved in engineering practice: Accuracy and resolution are limited to 0.1mm or more. Edge thermal damage and burrs caused by heat fusion during Laser Cutting result in poor contour accuracy and surface roughness of the formed parts. In order to improve this situation, it is necessary to increase the milling process. For example, in the "3D-Plotting" technology of Sanders Corporation, after the formation of each layer, the upper surface of the layer is milled to control the Z-direction dimension. The laser rapid prototyping technology at the Fraunhofer Institute of Technology in Germany, after forming a single layer of parts, uses a high-speed milling head to light up the part's contours. In this way, the entire forming system is made more complicated and its price is high. With the micro-hole injection and extrusion molding technology, the micro-holes are easy to be blocked, and the working reliability needs to be improved. Some processes using vertical cutting have to minimize the thickness of each layer in order to reduce the step effect and improve the accuracy, which limits the manufacturing speed. Most processes are limited to one or a few materials, for example: SLS limited to paraffin, plastics, metals, ceramics and other powdered thermoplastic materials: SLA limited to thermosetting photosensitive resin: LOM is limited to paper, metal foil, plastic film and other thin materials: FDM Limited to waxes, thermoplastic resins, low melting point metals, etc. 2 Thick-Layer Manufacturing Technology Principles and Features of Cut-Cutting-Cutting Contours These shortcomings hinder the commercial application of RP. Therefore, in the next few years, RP technology with high accuracy, low cost, and wide range of applicable materials will be the mainstream of research and development in this field. To this end, we started the study of thick-layer stack manufacturing technology based on the tangential cutting contour of the tool. The principle is to layer the three-dimensional CAD model of the part, then use the CNC Milling Machine to process the layers, and then stack, bond, and assemble the layers, after appropriate post-processing (such as hot pressing, roasting, etc.), and finally The formed parts not only have a precise geometry, but also a good functional structure (Figure 1). Compared with the general lamination manufacturing with laser cutting profiles and other rapid prototyping technologies, the thick layer manufacturing technology based on the tangential cutting contour of the tool we are studying has high accuracy, high production efficiency, low cost, and a wide range of materials. Etc. details as follows: