Top transformer lamination producing company: When is it not allowed to adjust the tap changer of the transformer on-load voltage regulating device? The on-load voltage regulating device is a common accessory equipment of the transformer, which is used to adjust the transformation ratio when the transformer is running, so as to achieve the purpose of adjusting the output voltage. When using the on-load pressure regulator, the following points need to be paid attention to: It is not allowed to operate under live conditions: because the transformer is working under live conditions, the tap changer of the on-load voltage regulating device will have an arc when it is adjusted, so it is not allowed to operate the tap changer under live conditions. Frequent adjustments are not allowed: frequent adjustments to the tap changer of the on-load tap changer may cause damage to the tap changer or poor contact, thereby affecting the normal operation of the transformer. Discover additional info on cut to length line manufacturers.

What is the capacity of the transformer related to? The capacity of the transformer refers to the maximum load electric power that the transformer can bear. The capacity of the transformer is related to the following factors: Input voltage and output voltage: The input voltage and output voltage of the transformer determine the transformation ratio of the transformer, which affects the capacity of the transformer. The higher the input voltage of the transformer and the lower the output voltage, the larger the transformation ratio and the larger the capacity. Load nature: Different loads have different power factors, harmonic content and other characteristics, which affect the capacity of the transformer. For inductive loads, the capacity of the transformer can be appropriately reduced; for nonlinear loads, the capacity of the transformer needs to be appropriately increased.

The metal laser cutting machine focuses the laser emitted from the laser into a laser beam with high power density through the optical path system. The laser beam irradiates the surface of the workpiece to make the workpiece reach the melting point or boiling point. At the same time, the high-pressure gas coaxial with the beam blows away the molten or gasified metal. With the movement of the relative position between the beam and the workpiece, the material will finally form a slit, so as to achieve the purpose of cutting. Laser cutting process uses invisible light beam to replace the traditional mechanical knife. It has the characteristics of high precision, fast cutting, not limited to the limitation of cutting pattern, automatic typesetting, material saving, smooth incision and low processing cost. It will gradually improve or replace the traditional metal cutting process equipment.Want to konw more about metal cutting machine, contact us, one of the most professional metal laser cutting machine manufacturers & suppliers in China.

Three-dimensional wound core transformer breaks through the traditional triangle plane structure, adopts three-phase symmetric vertical structure, magnetic circuit completely symmetrical three-phase core products, magnetic resistance is greatly reduced, excitation current, no-load loss, is a kind of using traditional materials, but lower operating noise, structure is more compact and efficient energy-saving oil type transformer. Its excellent performance in energy saving and energy saving and environmental protection is in line with China’s energy conservation policy.

A transformer coil winding machine is an intricate piece of machinery with an essential role in the manufacturing of transformers, combining modern technology and meticulousness to create high-quality products efficiently. The process starts with the feeding of copper wire into the machine, which passes through a line-up of calibrations guides and tensioners designed to secure alignment and prevent damage. An automated system then causes rotation, gradually looping copper wire around the transformer coil. A computerized system oversees variables such as speed, pitch control, layer count and insulation thickness for consistent turns. Moreover, for distinct transformer models or designs, these machines can be fitted with extra features such as automatic lead cutting and tapping mechanisms for increased versatility and productivity.

As a professional electrical equipment manufacturer in China, Canwin specialized in dry type transformers, electrical equipment for over 20 years. Canwin electrical products manufacturer adopts large-scale, intelligent electrical machinery equipment manufacturing mode, and strive to achieve high quality, high efficiency, low cost operation.Our electrical machinery products including cut to length lines, china slitting lines and foil winding machines.

A China slitting line produces longitudinal cuts in a master coil of steel to predetermined narrower widths. These smaller coils are then sent to downstream operations such as metal stampers, tube producers or roll forming houses that will use the material in their final product. Customized slitting line machine equipment mainly includes the following: Loading trolley, double support uncoiler, feeding device, traction leveling machine, trimming shearing machine, deviation correction feeding device, longitudinal shear line, waste edge winder, feed rack, pre separation device, tensioner, feeding roller, winding shearing machine, steering drum, rear axle, discharge trolley, winding auxiliary support, hydraulic system and electrical system, etc.

As a result of mutual inductance, a transformer produces a transformed voltage or current when the magnetic flux produced by one winding (primary winding) links with another winding (secondary winding). There is a magnetic coupling between these two windings, and they are electrically isolated. In addition, magnetic reluctance is also known as opposition to magnetic flux flow. If, for example, the magnetic flux produced by a primary winding passes through air or any nonferrous material in order to reach a secondary winding in a transformer, it would result in a reduction in magnetic flux. Due to the high reluctance of air or nonferrous materials, it will reduce magnetic flux. See even more details at https://www.canwindg.com/

The main pillar of the smart grid is the smart substation, which is not only an important hub for power transmission and distribution, but also directly affects the operational and monitoring capabilities of the smart grid through its operational safety and stability. Through the network, information can be exchanged, and the transformer can share information with the process layer and the station control layer. On the premise of ensuring product performance, the integration of monitoring, control, measurement, protection, and metering is designed to achieve the integration of transformer components with actuators, sensors, and transformers.

Dry-type transformers are widely used in local lighting, high-rise buildings, airports, dock CNC machinery and equipment, etc. Simply put, dry-type transformers refer to transformers whose iron cores and windings are not impregnated with insulating oil. The relevant technical parameters of dry-type transformers include: Rated capacity (kVA): The capacity that can be delivered during continuous operation at rated voltage and rated current. Rated voltage (kV): The working voltage that a transformer can withstand during long-term operation.

Power Quality and Distribution Transformers – The efficiency of distribution transformer substations is significantly affected by power quality. These transformers, which are critical components of the electrical distribution system, convert high-voltage electricity into lower voltage levels suitable for end-use applications. The performance and efficiency of these transformers largely depend on the quality of power they receive. Poor power quality, characterized by voltage sags, swells, harmonics, and flicker, can lead to increased losses in power distribution transformers. These losses can be categorized into two types: core losses and copper losses. Core losses occur due to variations in the magnetic field within the transformer’s core, while copper losses occur due to the resistance of the transformer’s windings. Both these losses are exacerbated under conditions of poor power quality, leading to decreased efficiency of the transformer.