Abstract: A contact disc of a contact element for a vacuum switch is provided, which includes predominantly of a first conductive material or composite material and has a plurality of inlets distributed over the circumference and made of a second material with a lower level of conductivity relative to the first material or composite material, which, during a switching process of the vacuum switch, bring about the formation of a magnetic field and thereby a movement of an arising arc on a predefined path and/or an extensive propagation of the arc. A production method for a contact disc of this type is also provided.

Abstract: A contact carrier of a contact element for a vacuum switch is provided, which includes predominantly of a first conductive material or composite material and has a plurality of inlets of a second material distributed over the circumference, which bring about the formation of a magnetic field and thereby a movement of an arising arc on a predefined path during a switching process of the vacuum switch, wherein the second material has a lower level of conductivity relative to the first material or composite material and is introduced into the first material during the shaping of the contact carrier basic form. A production method for a contact carrier of this type is also provided.

Abstract: Various teachings herein may be used to make a bearing bush for a rotating shaft, wherein a wall of the bearing bush has a wall thickness which amounts to less than 10% of the diameter of the bearing bush. In the axial direction, the bearing bush is made from a plurality of layers connected with a material bond. Each layer has a layer thickness between 10 ?m and 200 ?m and the wall has closed cavities which are filled with a powder.

Abstract: In a method for producing a material layer with a recess, a first suspension containing a binder is applied through a first opening in a first template and a second suspension containing a binder and solid particles is applied through a second opening in a second template. The first opening in the first template is completely contained within the second opening in the second template such that the second suspension completely surrounds the first suspension to produce a green body. The green body containing the first and second suspensions is sintered such that the first suspension is evaporated to provide the recess and permanent cohesion of the solid particles in the second suspension is achieved.

Abstract: Various embodiments of the teachings herein include a method for stencil printing a layer on or onto a printing surface with a stencil comprising applying a stencil with a first part and a second part to the printing surface and applying a layer of material to the printing surface through the stencil. The first part and the second part cover a non-continuous region of the printing surface.

Abstract: A process for producing a contact element for a vacuum switch is provided. In this process, a first powder-like mixture, including particles of a first and second conductive material, or a first pre-pressed, disc-shaped green body, is introduced into a pressing die. An inner pressing stamp is introduced into the die and a second powder of the first conductive material or a second powder-like mixture including, particles of the first conductive material or a second pre-pressed green body including the first conductive material, is introduced into an intermediate space. An outer pressing stamp is introduced into the intermediate space between the die and the inner pressing stamp. Pressing pressure is exerted on the outer and inner pressing stamps, forming a contact disc of the contact element, and a region forming a contact body or contact carrier of the contact element is created.

Abstract: Various embodiments include a method for producing a planar structure including: printing a green body of the structure using a screen printing process on a surface of a carrier substrate; generating a temperature gradient on the surface underneath the green body; removing the green body from the carrier substrate; and heat treating the green body in order to convert the green body into the planar structure. The temperature gradient is at least 0.5 K/mm along a plane of the surface and has an extent in the plane of at least 10 mm.

Abstract: A method for modifying a production process for a product wherein the production process can be qualified by means of at least one quality parameter for the product and includes a plurality of individual processes, in at least some of which no control is used. The method includes the following steps: a) capturing at least one measurement quantity of at least one individual process without control; b) determining a quality parameter corresponding to the at least one measurement quantity; c) comparing the determined quality parameter with a desired value, which results from the measurement-quantity-associated individual process with control; d) evaluating, on the basis of the comparison, whether the use of control for the at least one individual process leads to an improvement in the quality parameter.

Abstract: Various embodiments of the teachings herein include a rotor lamination comprising: a first material; and a second material. The first material is at least partially soft magnetic. The second material has a higher mechanical tensile strength than the first material. The first material and the second material are connected with a material bond.

Abstract: Various embodiments include a method for manufacturing a stack of magnetic laminations for a rotor and/or stator of an electric machine. The method includes: recording a respective physical property of each respective magnetic lamination from a plurality of magnetic laminations; determining a setpoint value for a physical variable of the stack of magnetic laminations; ascertaining a stacking sequence of the individual magnetic laminations of the plurality reducing a deviation of an actual value for the physical variable of the stack with the ascertained stacking sequence from a setpoint value in relation to stacks with other stacking sequences of magnetic laminations; and stacking the plurality of the magnetic laminations in the ascertained stacking sequence.

Abstract: Various embodiments of the teachings herein include a material layer. The material layer may include: a first ply including a first material adjoined along its planar extent by a second material, and integrally bonded along a first connecting section, the first having a lower relative permeability ?? than the second; a second ply integrally bonded to the first and at least partially covering the latter on a planar side, the second ply including a third and a fourth material connected along a planar extent along a second connecting section, the region of the third material or the fourth at least partially overlapping the first connecting section; and a third ply including a fifth and a sixth material, arranged on the first ply on a planar side opposite the second ply. The fourth material and the sixth material comprise a matching substance material different in relative permeability from the second material.

Abstract: A method for manufacturing an electric machine having a stack of magnetic laminations including a stack of green blanks. A first green blank of the stack is printed. A separating layer is applied to the first green blank. At least a second green blank of a magnetic lamination is printed onto the first green blank with the separating layer. The green blanks are jointly sintered.

Abstract: Various embodiments of the teachings herein include an electric machine. The electric machine may comprise a stator and/or a rotor with a stack of soft-magnetic laminations. Each lamination is close to an adjacent lamination on respective flat sides of the laminations. The laminations are electrically insulated from one another by a metal oxide formed on at least one of the flat sides.

Abstract: In a method for producing a material layer with a void, a first suspension containing a binder is applied through a first opening in a first template and a second suspension containing a binder and solid particles is applied through a second opening in a second template. The first opening in the first template is completely contained within the second opening in the second template such that the second suspension completely surrounds the first suspension to produce a green body. The green body containing the first and second suspensions is sintered such that the first suspension is evaporated to provide the void and permanent cohesion of the solid particles in the second suspension is achieved.

Abstract: Various embodiments of the teachings herein include an electric machine. The machine comprises a stator and/or a rotor with a stack of soft-magnetic laminations. The soft-magnetic laminations are disposed next to one another on flat sides of the laminations. At least one of the flat sides on which two adjacent laminations are close to one another is formed with a sintering skin.

Abstract: Various embodiments of the teachings herein include an electrical machine. The electrical machine may include a rotor and/or a stator with a stack of soft magnetic laminations. Each soft magnetic lamination has a first respective flat side and a second respective flat side facing away from the first one. Each soft magnetic lamination tapers from the first flat side to the second flat side. Each of the soft magnetic laminations in the stack are oriented with the respective second flat side in the same direction.

Abstract: In a method for correcting a portion, in particular a tooth, of a material layer of a dynamoelectric machine, with the material layer including a soft-magnetic material and having a layer thickness between 0.5 and 500 ?m, an actual geometry of the portion of the material layer is ascertained and compared to a target geometry. A deviation of the actual geometry from the target geometry is determined. Before the deviation is corrected by partially plastically deforming the material layer using a light source, the material layer is partially heated by a further light source.

Abstract: A material layer for a laminated core of an electric machine is made of iron-containing ferromagnetic material and includes an electrically insulating coating on at least one side of the material layer. The electrically insulating coating Includes an electrically Insulating material which Is produced through controlled oxidation of the ferromagnetic material of the material layer and contains iron monoxide and/or triiron tetraoxid. The material layer is produced from a green body, which Is sintered under a reducing atmosphere.

Abstract: The invention relates to adapting a process for producing components of a component assembly, wherein, during the production process of a first component of the component assembly, a real digital model (15) of the first component is provided with information regarding design, production, actual geometry (5), field usage, repair and/or recycling of the first component and is updated, comprising the steps of:—acquiring (S1) specifications (11) for the components of the component assembly;—creating (S2) a CAD model (12) for manufacturing the first component according to the specifications (11);—creating (S3) the real digital model (15);—adapting (S4) the real digital model (15) on the basis of first information obtained as a result of creating (S2) the CAD model (12);—manufacturing (S5, 13) the first component according to the CAD model (12);—adapting (S6) the real digital model (15) on the basis of second information obtained as a result of manufacturing (S5, 13) the first component;—comparing (S7) the real dig

Abstract: Various teachings herein may be used to make a bearing bush for a rotating shaft, wherein a wall of the bearing bush has a wall thickness which amounts to less than 10% of the diameter of the bearing bush. In the axial direction, the bearing bush is made from a plurality of layers connected with a material bond. Each layer has a layer thickness between 10 ?m and 200 ?m and the wall has closed cavities which are filled with a powder.