Integrating Sphere | Goniophotometer | Surge Generator | ESD Simulator - LISUN

The operation of a LISUN surge generator is based on the generation of high voltage, high current transients (surges) that simulate the electrical disturbances that can occur in electrical and electronic systems in real-world environments. These electrical disturbances can be caused by things like lightning, power outages, and other natural disasters. When testing the resistance of electronic equipment to electrical transients, such as those produced by lightning strikes, switching power lines, or electrostatic discharge, a surge generator is used to produce surges that are then utilized to simulate the effects of the transients. A high voltage generator, a waveform generator, a voltage amplifier, a coupling/decoupling network (CDN), and a control system are the main components that make up the LISUN surge generator . The initial high voltage for the surge waveform is derived from the surge waveform's high voltage generator. The surge waveform, which may be either a common mode,

The following procedures are required for conducting surge immunity testing on motors using a LISUN surge generator: In order to prepare for the surge immunity test, the motor that will be tested (also known as the MUT) has to have its control circuits and power supply correctly attached. In addition to this, it is essential to make certain that the MUT is in a secure state and that all safety precautions have been taken. The LISUN surge generator should be chosen in accordance with the voltage and current levels that are necessary for the test, as well as the sort of surge waveform that is to be created. Connections: A coupling/decoupling network (CDN) and a surge arrestor are required in order to link the LISUN surge generator to the MUT power supply and control circuits. Isolating the MUT from the surge generator and lowering the amounts of voltage and current that are supplied to the MUT are two of the functions that the CDN performs. The MUT need protection against high volta

An EMC surge generator , which stands for electromagnetic compatibility, is a specialized piece of testing equipment that is used to assess the functionality and dependability of electronic devices and systems when subjected to surge circumstances. It is designed to generate electrical surges that mimic the electrical transients that may occur in real-world environments, such as lightning strikes, power line surges, and electrostatic discharge. Its primary function is to protect the device from damage caused by these types of electrical transients (ESD). In order to validate the performance of electronic devices and systems and ensure that they are compliant with electromagnetic compatibility (EMC) standards and regulations, EMC surge testing is performed in order to determine any potential issues that may occur in electronic devices and systems when they are subjected to these surges. These regulations and standards are designed to ensure that electronic devices and systems do not c

There are several factors that may influence the pricing of a LISUN surge burst generator , and one of those factors is the number of variables. These components include the configuration of the generator as well as its features and technical specs. The price of a LISUN surge burst generator may be affected by a number of factors, including the maximum voltage level of the generator, its maximum current capacity, and the waveform generating capabilities of the generator. In general, surge burst generators that have greater voltages and higher currents tend to be more expensive than equivalent models that have lower voltages and currents . This is because higher voltages and currents need more power to produce. There is also the chance that the price of the generator may go higher as a result of the addition of more complicated features to it, such as programmable waveforms, real-time data gathering capabilities, and automated testing capabilities. However, the price of a LISUN surg

The functioning of a LISUN 10kV surge generator could be different based on the particular type of the generator and the configuration it has been given. Nonetheless, in order to familiarize you with the basics of using a LISUN 10kV surge generator, below is a rundown: Preparation: Before using the surge generator , be certain that the generator has been correctly installed and configured, and that the test equipment has been connected and calibrated in accordance with the specifications provided by the manufacturer. The first step in conducting the test is configuring the surge generator control software with the necessary test settings. These parameters include the voltage level, waveform, and test time. The first step of the test is to push the start button, which can be found on the control software or directly on the surge generator itself. This will get the test started. After that, the surge generator will produce the surge voltage that has been set and apply it to the apparat

Surge generators are only one of the products that LISUN, a producer of EMC testing equipment , produces. It is possible that the particular actions required to use a LISUN surge generator will change based on the type and configuration of the generator; nonetheless, the following is a basic description of how to operate a LISUN surge generator: Before utilizing the surge generator, be certain that it has been correctly installed and configured, and that the test equipment has been connected and calibrated in accordance with the guidelines provided by the manufacturer. The first step in conducting the test is configuring the surge generator control software with the necessary test settings. These parameters include the voltage level, waveform, and test time. The first step of the test is to push the start button, which can be found on the control software or directly on the surge generator itself. This will get the test started. After that, the surge generator will produce the surge

In a wide variety of testing and certification applications, a high voltage surge generator capable of producing 20 kV is required. These applications are typically designed to evaluate the functionality and dependability of electrical and electronic devices while subjected to extreme electrical disturbances. The following are some of the most popular applications for a high voltage surge generator rated at 20 kV: Electromagnetic Compatibility (EMC) testing : In order to simulate electrical disturbances such as lightning strikes, power supply transients, and electrical interference in order to test the performance of electronic devices and systems for compliance with EMC standards and regulations, a high voltage surge generator with a capacity of 20 kilovolts is used. Tests of lightning surges involve employing a high voltage surge generator of 20 kV in order to simulate the electrical effects of a lightning strike. The purpose of these tests is to evaluate the functionality and depe

The cost of an EMC (Electromagnetic Compatibility) surge generator may shift dependent on the presence or absence of a number of different factors. The characteristics and specifications of the generator, as well as its brand and model, as well as the retail establishment from which the surge generator is purchased are all included here. An EMC surge generator may range in price from a few hundred dollars for a model that is regarded to be simple to several thousand dollars for a device that is considered to be high-end and complex. In general, the price of an EMC surge generator can vary significantly. Configurable surge patterns, high-precision measurement capabilities, and a large number of channels are just some of the features that may be incorporated on more advanced surge generators. It is probable that when compared to the cost of the equipment that is being tested, the cost of an EMC surge generator may seem to be rather dear. This is because the cost of the item being te

A high voltage lightning surge generator is a device that can replicate the electrical disturbances that might occur in an electrical system as a result of lightning strikes. These electrical disturbances can be caused by lightning strikes. The following is a rundown of the standard procedures to be followed while operating a high voltage lightning surge generator: Get the apparatus for the exam ready: Make sure that you have access to all of the essential tools and components, such as the surge generator, the test object (such an LED power driver), and any required test leads. Connect the test object to the surge generator using appropriate test leads, then connect the test object to the test itself. Activate the surge generator by using the controls on the surge generator to program the required surge characteristics. These parameters include surge voltage, surge current, and surge duration. The norms and regulations that the test item is required to adhere to will determine which

Electrical testing uses the term " combined surge voltage ," which may also be referred to as "combined wave surge voltage," to refer to the composite waveform that is formed when a surge event takes place. This waveform may also be thought of as "mixed wave surge voltage." In the context of an electrical system, the term "surge event" refers to a rise in voltage or current that lasts for just a limited amount of time. Lightning strikes and the switching of power sources are two examples of the kinds of occurrences that might cause surges. The act of merging several surge waves into a single waveform is referred to as "combined surge voltage," and the phrase "combined surge voltage" refers to the resulting waveform. There is a possibility that both common mode and differential mode surges are included in these. Common mode surges are characterized by voltage waveforms that are equal and in the same phase on two conductors, w

As a result of the sensitivity of outdoor appliances to overvoltage surges, which may be caused by either lightning strikes or transients in the electrical power supply, surge testing is required to ensure the safety of these products. Lighting fixtures and streetlights are both examples of this kind of electrical equipment. These surges have the potential to cause damage to the electrical and electronic components that are included inside the appliances, which may subsequently lead to the equipment failing to work properly or not functioning at all. By carrying out a surge test, either the appliance's maker or the end user may verify the device's resilience and determine whether or not it is capable of withstanding the anticipated surge environment in which it will be put. The appliance is put through this test to guarantee that it can successfully be installed. This aids to boost the appliance's reliability and durability, as well as to decrease the possibility of unexp