Geothermal
One of the major challenges in the energy sector, aside from its production, is the issue of energy transmission and adapting it to meet specific output needs. This challenge has two key cost-related components: the expense of transmission infrastructure and the energy loss during transmission. A well-established, practical, and sustainable solution to address this problem is shortening the energy transmission path.
However, from a different perspective, the question shifts: What type of energy do we need, and in what quantity, to perform a specific task? For instance, if the focus is on heating and cooling a greenhouse or the broader environment of an aquaponic system, what kind and amount of thermal regulation are required? Answering this question leads us to rethink the design of greenhouse structures.
Considering the relatively stable temperatures found underground or in water bodies such as rivers and seas at specific depths, the primary heating and cooling needs to keep the cultivation environment within safe limits can be provided passively and at minimal cost.
In extremely hot, arid, and desert regions, greenhouses may need to be partially or entirely built underground. This approach allows for the transfer of air through soil or along the walls, significantly meeting the thermal needs of the greenhouse. Additionally, using water pipes beneath the soil as a primary heat source for heat pumps can provide the required temperature for achieving ideal conditions.
Technical advancements in heat pumps, alongside modifications in their components, have enabled us to achieve significantly higher outputs with much lower electricity consumption compared to similar products worldwide. Our analyses and designs have revealed that, despite considerable progress in this industry globally, we are still at the early stages, and much of its potential remains untapped.
Our primary goal is to reduce costs, enhance quality and efficiency, and ensure sustainability in energy supply through this array of solutions.
