Ocean thermal energy conversion is a technology that converts thermal energy into electricity. Tropical and sub-tropical regions where the water temperature at the ocean surface is relatively high are best suited for its use. A special feature of this technology is its capability to generate a stable supply of electricity around the clock. It is thus well suited for meeting baseload demand.
In addition, the deep seawater used for power generation can be put to use in secondary applications that can contribute to local industry and promote the local economy in remote island communities.
An OTEC system is comprised of components such as an evaporator, condenser, turbine, generator, and pump. This system utilizes the temperature difference between warm surface seawater and deep seawater (taken from depths of 600 to 1000 meters) to generate electricity. This is done using a working fluid with the low boiling point that vaporizes as the result of heat transfer from the warm surface seawater in the evaporator.The vapor drives the turbine, which in turn drives a generator to produce electricity. The vapor then is passed through the condenser, where the transfer of heat energy to the cold seawater returns the vapor to a liquid state.
To maximize the efficiency of every part of this process, from water intake to heat exchange, power generation, and water discharge, this system relies on an integrated control and monitoring system, performance management software, safety instrumentation, wireless communications, and a variety of sensors. Optimizing the overall system will stabilize operation and increase the efficiency of power generation.
Okinawa Prefecture is promoting clean energy with the aim of becoming a low-carbon society in the 21st century. Ocean thermal energy conversion (OTEC) technology is particularly well suited for this purpose, and is expected to both reduce the environmental impact that power generation has in the prefecture and lessen the prefecture's dependence on imported fossil fuels.
Optimizing the maintenance cycle is not always straightforward. In some cases, cleaning once a week is sufficient and other processes may require every 8 hours.
Select the correct pH glass and reference type to improve your pH sensor lifetime and you can limit or even eliminate the effects of temperature and pressure on especially the reference sensor.
Learning these four lessons will help you improve your engineering skills and most importantly extend the life of your pH sensors.
The lifetime of a pH sensor has a significant impact on the overall annual costs of a pH measuring loop. Optimizing four key factors will decrease these costs and optimize process control and overall plant efficiency.
Kind of. Calibration itself will not extend the life of a sensor, however, a sensor that is not calibrated properly can cause unreliable measurements - that are often misdiagnosed leading to unnecessary replacements.
Looking for more information on our people, technology and solutions?Contact Us