meta data for this page
  •  

Differences

This shows you the differences between two versions of the page.

Link to this comparison view

Next revision		Previous revision
sensor:energy_harvesting [2025/02/19 16:53] – created vamsansensor:energy_harvesting [2025/04/27 20:27] (current) vamsan
Line 1: Line 1:
 ====== lamaPLC: Energy harvesting (EH) ====== ====== lamaPLC: Energy harvesting (EH) ======
  
-A Wheatstone bridge is an electrical circuit used to measure an unknown electrical resistance by balancing two legs of a bridge circuit, one leg of which includes the unknown component. The primary benefit of the circuit is its ability to provide extremely accurate measurements (in contrast with something like a simple voltage divider)Its operation is similar to the original potentiometer.+**Energy harvesting** (//EH//) – also known as power harvesting, energy scavenging, or ambient power – is the process by which energy is derived from external sources (e.g., //solar power, thermal energy, wind energy, salinity gradients, and kinetic energy, also known as ambient energy//), then stored for use by small, wireless autonomous devices, like those used in wearable electronics, condition monitoring, and wireless sensor networks.
  
-The Wheatstone bridge was invented by Samuel Hunter Christie (sometimes spelled //"Christy"//in 1833 and improved and popularized by Sir Charles Wheatstone in 1843. One of the Wheatstone bridge's initial uses was for soil analysis and comparison.+Energy harvesters usually provide a very small amount of power for low-energy electronics. While the input fuel to some large-scale energy generation costs resources (oil, coal, etc.), the energy source for energy harvesters is present as ambient background. For example, temperature gradients exist from the operation of a combustion engine and in urban areas, there is a large amount of electromagnetic energy in the environment due to radio and television broadcasting.
  
-{{ :sensor:wheatstone_bridge_wiring.png?300 |Wheatstone bridge sensor}}+One of the first examples of ambient energy being used to produce electricity was the successful use of electromagnetic radiation (EMR) to generate the crystal radio. 
 +===== LTC-3588 Features ===== 
 +**V<sub>IN</sub>:** –0.3V to 18V (has an internal 20V clamp) \\ 
 +**I<sub>SW</sub>:** 0A .. 25mA \\ 
 +**PZ1, PZ2:** 0V .. V<sub>IN</sub> \\ 
 +**D0, D1:** –0.3V .. [Lesser of (V<sub>IN2</sub> + 0.3V) or 6V] \\ 
 +**CAP:** [Higher of –0.3V or (V<sub>IN</sub> – 6V)] .. V<sub>IN</sub> \\ 
 +**V<sub>IN2</sub>:** –0.3V .. [Lesser of (V<sub>IN</sub> + 0.3V) or 6V] \\ 
 +**V<sub>OUT</sub>:** –0.3V .. Lesser of (V<sub>IN2</sub> + 0.3V) or 6V \\ 
 +**PGOOD:** –0.3V to Lesser of (V<sub>OUT</sub> + 0.3V) or 6V \\
  
-==== YR-3180 Intelligent weighting sensor module ==== +===== Pin functions =====
-{{anchor:yr_3180}} +
-The weighing acquisition module is a high-performance, multi-functional electronic weighing equipment. It adopts advanced weighing sensing technology and can measure the weight of items in real time and display it with a five-digit digital tube. It also has upper and lower limit alarm functions. capable of achieving precise weighing control and monitoring. At the same time, this product also has TTL communication interface and [[com:basic_modbus|Modbus RTU]] communication protocol, which can communicate with PLC, computers and other equipment conveniently and quickly to realize the transmission and remote control of weighing data. In addition, it also supports Type-C power supply and button debugging functions, improving the convenience and stability of use.+
  
-|< 100%>| +{{ :sensor:ltc_3588_6.png |LTC-3588 block diagram}}
-|{{ :sensor:yr_3180_1.png?200 |YR-3180 Intelligent weighing sensor module}}|{{ :sensor:yr_3180_2.png?200 |YR-3180 Intelligent weighing sensor module}}|+
  
 +  * **PZ1 (Pin 1):** Input connection for piezoelectric element or other AC source (used in conjunction with PZ2). 
 +  * **PZ2 (Pin 2):** Input connection for piezoelectric element or other AC source (used in conjunction with PZ1). 
 +  * **CAP (Pin 3):** Internal rail referenced to VIN to serve as gate drive for buck PMOS switch. A 1µF capacitor should be connected between CAP and VIN. This pin is not intended for use as an external system rail. 
 +  * **VIN (Pin 4):** Rectified Input Voltage. A capacitor on this pin serves as an energy reservoir and input supply for the buck regulator. The VIN voltage is internally clamped to a maximum of 20V (typical). 
 +  * **SW (Pin 5):** Switch Pin for the Buck Switching Regulator. A 10µH or larger inductor should be connected from SW to VOUT. 
 +  * **VOUT (Pin 6):** Sense pin used to monitor the output voltage and adjust it through internal feedback. 
 +  * **VIN2 (Pin 7):** Internal low voltage rail to serve as gate drive for buck NMOS switch. Also serves as a logic high rail for output voltage select bits D0 and D1. A 4.7µF capacitor should be connected from VIN2 to GND. This pin is not intended for use as an external system rail. 
 +  * **D1 (Pin 8):** Output Voltage Select Bit. D1 should be tied high to VIN2 or low to GND to select desired VOUT (see Table 1). 
 +  * **D0 (Pin 9):** Output Voltage Select Bit. D0 should be tied high to VIN2 or low to GND to select desired VOUT (see Table 1). 
 +  * **PGOOD (Pin 10):** Power good output is logic high when VOUT is above 92% of the target value. The logic high is referenced to the VOUT rail. 
 +  * **GND (Exposed Pad Pin 11):** Ground. The Exposed Pad should be connected to a continuous ground plane on the second layer of the printed circuit board by several vias directly under the LTC3588-1.
 +===== LTC-3588 Nanopower Energy Harvesting Power Supply =====
 +{{anchor:ltc_3588}}
 +{{ :sensor:ltc_3588_1.png|LTC-3588}}
 +The **LTC®3588-1** integrates a low-loss full-wave bridge rectifier with a high efficiency buck converter to form a complete energy harvesting solution optimized for high output impedance energy sources such as piezoelectric, solar, or magnetic transducers. An **ultralow quiescent current undervoltage lockout** (//UVLO//) mode with a wide hysteresis window allows charge to accumulate on an input capacitor until the buck converter can efficiently transfer a portion of the stored charge to the output. 
  
-Description[[https://www.yunzhan365.com/basic/83969503.html|YR-3180 Intelligent weighing sensor module]] \\+In regulation, the LTC3588-1 enters a sleep state in which both input and output quiescent currents are minimal. The buck converter turns on and off as needed to maintain regulation. Four output voltages, 1.8V, 2.5V, 3.3V and 3.6V, are pin selectable with up to 100mA of continuous output current; however, the output capacitor may be sized to service a higher output current burst.  
 + 
 +An input protective shunt set at 20V enables greater energy storage for a given amount of input capacitance. 
 + 
 +===== Typical application ===== 
 +{{ :sensor:ltc_3588_2.png |LTC-3588 typical application}} 
 +==== LTC-3588 with Solar-Powered 2.5V Supply ==== 
 +{{ :sensor:ltc_3588_3.png |LTC-3588 with Solar-Powered 2.5V Supply}} 
 +5V to 16V Solar-Powered 2.5V Supply with Supercapacitor for Increased Output Energy Storage and Battery Backup 
 +==== LTC-3588 with Thermoelectric ==== 
 +{{ :sensor:ltc_3588_4.png |LTC-3588 with Thermoelectric}} 
 +Thermoelectric Energy Harvester 
 +==== LTC-3588 with Piezoelectric ==== 
 +{{ :sensor:ltc_3588_5.png |LTC-3588 with Piezoelectric}} 
 +Piezoelectric Energy Harvester with ±3.3V Outputs 
 +\\ 
 +\\ 
 +More information: https://www.analog.com/en/products/ltc3588-1.html
  
 ===== Sensor topics on lamaPLC ===== ===== Sensor topics on lamaPLC =====
Line 22: Line 60:
 \\ \\
 \\ \\
-{{tag>communication modbus RTU sensor weight YR-3180 Arduino TTL }}+{{tag>communication Arduino sensor energy_harvesting energy ambient_power}}
 \\ \\
 This page has been accessed for: Today: {{counter|today}}, Until now: {{counter|total}} This page has been accessed for: Today: {{counter|today}}, Until now: {{counter|total}}