The design of an electric energy meter based on a single-chip computer has many meanings: 1. ** For the improvement of the designer's own ability **: Through thinking and hands-on practice, it can greatly train the designer's self-learning ability, and at the same time improve the knowledge level of the single-chip computer, laying a solid foundation for subsequent related applications. 2. ** Understanding of signal conversion and function realization **: It helps designers to have a clearer understanding of the signal conversion process and function realization. 3. ** Research on the performance of the electric energy meter: It can test the stability of the 89C51 single-chip computer in the application of the electric energy meter, and evaluate the function and superiority of the electric energy meter. 4. ** From the perspective of the development and practical value of the electric energy meter: With the rapid increase in power demand, the electric energy meter is the main tool for measuring electricity. It is extremely important to design an electric energy meter based on a single-chip processor with more functions and higher accuracy to save electricity. This kind of electric energy meter has high precision and accuracy, and has a very good practical development value. It converted the continuous digital data into a non-continuous, scattered digital form and displayed it, combining the results of electronic technology, computing technology, and automated technology with precision electrical measurement technology, breaking the pattern of traditional electronic measuring instruments. The display was clear and intuitive, and the reading was accurate. It adopted advanced digital display technology, which greatly reduced the measurement error caused by human factors. Read more exciting novels for free
Single-chip computers could be used in the industrial field, while electric tools belonged to the industrial category. The 8-bit single-chip computer was a single-chip computer with an internal arithmetic unit that could process 8-bit binaries at a time. It could perform operations such as addition, reduction, multiplication, and division. The internal register was mostly 8-bit, so it could be regarded as a weak micro-computer system. Theoretically, an 8-bit single-chip processor could be used to develop and control functions related to power tools, but the specific application depended on the complexity of the power tool's function development. If the power tool needed to develop a simple function, an 8-bit single-chip processor might meet the demand. If more functions were needed, a single-chip processor with a higher number of digits might be needed. <a href="/?from=ask_words" style="color:red" target="_blank">Read more exciting novels for free</a>
If the single-phase meter current is 10 amps, this 10 amps may be the nominal current. The rated current was used to calculate the base current value of the load. The smaller the rated current, the smaller the starting current of the electric meter, and the more sensitive the electric meter was. For example, if the starting current of the meter is 0.5% of the nominal current, then the meter will start counting as long as the current in the meter circuit is higher than 0.05A, and the meter will not count if it is lower than this value. Single-phase electric meters often have different specifications such as 10, 20, 40, 60, 80, 100A, etc. When using an electric meter with 10A current, you need to consider its matching with the power consumption. The current parameters are neither the bigger the better nor the smaller the better. It should correspond to the power consumption. The maximum current of all electrical appliances should be calculated. If the current parameters of the electric energy meter are small, the electric energy meter may burn. Therefore, it is usually recommended to choose an electric energy meter with a slightly larger current parameters. <a href="/?from=ask_words" style="color:red" target="_blank">Read more exciting novels for free</a>
The following are the general steps and key points of the development of the single-chip electronic scale: ** 1. Hardwares ** 1. ** Main control chip selection ** - He could choose a more common chip like the 8051 single-chip computer. It had 4KB of internal program memory (Scalable), 128-Byte internal data memory (Scalable), multiple bi-directional parallel input/output ports, and other resources to meet the basic control and data processing needs of the electronic scale. - It also has the advantages of low working voltage, low power consumption, strong driving ability, etc. For example, its I/O port is bi-directional and the output circuit is a complementary push-pull output circuit. The external circuit is simple in driving the digital tube display, and its A/D is 10 bits to meet certain precision requirements. 2. ** Sensing and signal processing ** - The sensor was used to obtain physical quantities such as weight. For example, using a pressure sensor to detect the weight of an object usually required a special signal processing chip, such as the HX711 for processing pressure signals (range 0 - 5kg, accuracy 0.1 g). 3. ** display module ** - The 1602 LCD module was used to display the date, time, weight and other information. It was necessary to connect the single-chip computer to the 1602 liquid crystal, including the connection of the data port and the control port. The software programming was also used to initiate and write data into the 1602 liquid crystal. 4. ** Clock module (option)** - If you need to record time-related information, you can use the DS1302 clock chip. It could provide accurate date and time information for the electronic scale. The microchip needed to communicate with it through the corresponding interface circuit to read and set the time. 5. ** Communication module (option)** - If you want to upload the data to the PC display, you can use the 232 serial communication. The single-chip computer had to set up the serial port, including the configuration of baudrate, data bit, stop bit, and other parameters to achieve stable data transmission with the PC. 6. ** Power Circuit ** - It provided a stable power source for the entire system. It was necessary to design a suitable power supply circuit according to the voltage requirements of the selected chip and other electronic components. For example, a voltage stabilizing chip was used to convert the input voltage to a stable 5V or 3.3V voltage to meet the power supply requirements of the single-chip computer, sensor, display module, etc. ** 2. Software ** 1. ** Selection of programming language ** - If you use the 8051 single-chip computer, you can generally use assembly language or C language for programming. For beginners, C language was relatively easier to understand and write complex program logic. - For the PIC-based single-chip computer, you can also use the C language or its specific programming language, but you should pay attention to the differences between the 8051 single-chip computer and the 8051 single-chip computer in terms of instruction set and register usage. 2. ** Program Function Realization ** - ** Initialize settings **: Initialize the ports, timers, and interrupt of the single-chip computer. For example, set the port connected to the sensor to the input mode and the port connected to the display module to the output mode; Initialize the timer to meet the timing requirements (if there is a timing function requirement); Configure the interrupt (if the interrupt is needed to process the sensor data collection or other events). - ** Data Collection **: Obtain weight and other data from the sensor through programming. If the HX711 was used to process the pressure signal, it was necessary to read the processed pressure data (weight data) from the HX711 according to the communication protocol of the HX711 and convert it into an actual weight value. - ** Data processing **: To process the collected data, such as filtering to reduce errors caused by sensor noise. Simple arithmetic average filtering or other filtering algorithms can be used. - ** Show Function **: Show the processed weight, date, time and other data on the 1602 LCD. This required writing the corresponding display function according to the display specifications of the 1602 liquid crystal, converting the data into a format suitable for display and sending it to the liquid crystal display module. - ** Communication function (option)**: If there is a serial communication function, write a serial communication program to send the data to the PC in the agreed format. This included the packaging and verification of the serial port data to ensure the accuracy of the data transmission. <a href="/?from=ask_words" style="color:red" target="_blank">Read more exciting novels for free</a>
When the single-phase AC electric meter works, when the electric meter is connected to the circuit to be tested, the voltage of the circuit to be tested is added to the voltage coil. After the current of the circuit to be tested passes through the current coil, it will produce two alternating magnetic flux passing through the aluminum disk. These two magnetic flux are the same in time, and they will produce vortex currents on the aluminum disk. Due to the interaction between the magnetic flux and the vortex, a rotating moment was generated, causing the aluminum disk to rotate. The magnetic flux of the brake magnet also passes through the aluminum disk. When the aluminum disk is rotated, the magnetic flux is cut, and a current is induced on the aluminum disk. The interaction between the current and the magnetic flux of the brake magnet produces a brake moment opposite to the rotation direction of the aluminum disk, so that the rotation speed of the aluminum disk is uniform. Its main structure included a voltage coil, a current coil, a rotating disc (aluminum disc), a rotating shaft, a brake magnet, a gear, a meter, etc. These components worked together to achieve the power measurement function, but there was no detailed illustration of the single-phase AC electric meter circuit diagram. <a href="/?from=ask_words" style="color:red" target="_blank">Read more exciting novels for free</a>
The following are several examples of simulation circuits related to single-chip processors: - In the ESP32 and Arduino single-chip simulation (such as the website of the website, the simulation circuit that lights up the LED light needs to add an LED light and a current limiting resistance. The negative pole of the LED lamp was connected to the GND pin of the single-chip development board, the positive pole was connected in series with the current limiting resistance, and the other end of the current limiting resistance was connected to the No. 2 pin of the development board. - For the simulation circuit of the steering gear control, add the steering gear in the hardware circuit (the steering gear has three pins, namely, the voltage regulator, the voltage regulator, and the voltage regulator. The voltage regulator is connected to the negative pole of the power supply, and the voltage regulator is connected to the positive pole of the power supply). Then, connect the steering gear to the single-chip computer (if you use the Arduino single-chip computer, you can choose a pin with a "~" to output the voltage regulator signal. In this project, pin 3 is selected as the voltage regulator output pin). - If the simulation uses L298 to drive the direct current motor, the circuit includes the L298N chip (this is a dedicated driver integrated circuit, belonging to the H bridge integrated circuit), the display part uses the PG 160128A (the liquid crystal display dot matrix is 160X128), the input device is a 4X4 matrix keyboard, and it may also include measurement tools such as a virtual scope. The positive and negative rotation of the motor can be controlled by the P1.0 pin of the single-chip computer. <a href="/?from=ask_words" style="color:red" target="_blank">Read more exciting novels for free</a>
C Language for Single-Chip Microprocessors A single-chip computer was a small electronic device used to control and monitor various devices and systems. The C language was a common programming language used to write programs for single-chip processors. If you want to learn the C language, you first need to understand the basic principles and structure of the microchip. Then you need to learn the basic grammar and programming skills of the C language. Next, you can learn the instruction set and interrupt system of the microchip in order to write programs that can control and monitor the microchip. You can also expand your knowledge by learning about the memory and input and output ports of the single-chip computer. Finally, you can practice writing programs for the single-chip computer and try out different control and monitoring methods. Through practice, you can better understand the use of the C language and improve your programming skills. The single-chip C language innovation tutorial requires the comprehensive use of the basic principles of the single-chip computer, the basic grammar of the C language, the instruction set and interrupt system of the single-chip computer, and the practice of writing single-chip computer programs. Through learning and practice, you can become an excellent program developer and succeed in the electronic field.
Using the 51 development board as an example, connect the single-chip experiment box to the power supply, use the download cable to connect the single-chip experiment board to the computer, and connect the USB cable to the USB port on the board. This port can not only realize the power supply, but also the program burning function. <a href="/?from=ask_words" style="color:red" target="_blank">Read more exciting novels for free</a>
For a 24V motor with a high current, it could generally be controlled by a MOS tube or an IGBT. Relatively speaking, an mos was a more economical and practical choice. You can use a single-chip computer to build an H-bridge drive circuit to drive a 24V brush motor. First, draw the H-bridge drive circuit. In the protues, you can use a high-voltage driver chip like the ICR2101 (24V is considered low voltage compared to the voltage it can drive) to build the circuit. At the same time, you need to consider the addition of some other circuit components, such as the addition of a circuit. Because there was an interelectrode capacity (between the G and S poles) inside the MOS tube, the resistance coming out of the G pole and the interelectrode capacity of the GS formed an RC-charge and discharge circuit. By adjusting this resistance, the rise time of the MOS output from the low level to the high level of the dimming pulse could be adjusted. A parallel connection of the G-pole resistance with a second voltage could make the discharge time of the dimming pulse from the high level to the low level faster, thus affecting the fall time. In addition, when it came to the single-chip processor receiving the signal from the 24V passive switch, the 24V high frequency needed to be reduced to the single-chip processor pin frequency. In the motor control, by controlling the operation of turning on and off the MOS tube in the H-bridge circuit, the motor was controlled and started. For example, through the electromagnetic coil of the contactors in the control circuit, the power supply of the main circuit of the motor was switched on and off to start the motor. <a href="/?from=ask_words" style="color:red" target="_blank">Read more exciting novels for free</a>
There were two ways to download the STM32 program. One was based on JTAG (SWD). This method required an simulator (such as J-Link and U-Link) to efficiently and quickly debugged the STM32 single-chip system. The other was based on serial port. The entire STM32 series supported this method. This method could download the HEX file to the STM32 chip through a USB cable and the corresponding ISP download software. In order to download the circuit through the serial port, one must first understand the several boot modes of the STM32. If you want to download the code through the serial port, you need to set BOOT0 to 1 and BOOT1 to 0. If you want the STM32 to run the code as soon as it is reset, you need to set BOOT0 to 0 and BOOT1 to any value. A circuit could be designed to control the one-button download circuit through the serial port to USB chip CH340G's DTL #and RTS#pin signals, thereby indirectly controlling the STM32's RESET and BOOT0 pin signals, achieving the effect of one-button download and operation through the serial port. The serial port download software can choose MCUSP, which can automatically allocate the BOOT0 and RESET signals through the DTL and RTS signals of the serial port. The user does not need to manually switch the state. Open MCUIsp, click Search serial port, and it will automatically find the onboard serial port of the circuit board. Choose the baudrate of 460800 in the bit rate, select the low level reset of DTL in the lower left corner, and then load the burn file into BootLoader at RTS high level. Before the program was written, click to read the device information. If the relevant information appeared, it meant that the serial port connection of the circuit board was successful. Then click to start programming, and the program began to be written. After the program was successfully written, a message indicating that the program was successfully written would appear. The specific process was as follows: mcuisp controls the DTL output to be low, so DTL #output is high. Then RTS is set to high, so RTS#output is low, so Q3 is turned on and BOOT0 is pulled high. At the same time, Q2 will also be turned on, and the reset pin of STM32 will be pulled low to achieve a reset. Then, after a delay of 100ms, mcuisp controls DTL to be at high level, DTL #will output low level, RTS will remain at high level, RTS#will continue to be at low level. At this time, the reset pin of STM32 will become high level because Q2 is no longer connected. STM32 will end the reset, but BOOT0 will still remain at 1, thus entering the SP mode. Then mcuisp can start to connect to STM32 and download the code, thus realizing one-click download. <a href="/?from=ask_words" style="color:red" target="_blank">Read more exciting novels for free</a>
The electric welding machine was a device that could convert 220V and 380V alternating current into low-voltage direct current. Its main function was to carry out welding operations. It did not have the function of converting single-phase electricity into three-phase electricity, so the electric welding machine could not be used for single-phase to three-phase electricity. <a href="/?from=ask_words" style="color:red" target="_blank">Read more exciting novels for free</a>