Modi witnesses commencement of core loading at India’s first fast breeder reactor

Prime Minister Narendra (Photo:ANI)


In a milestone marking the country’s entry into the vital second stage of its three-stage nuclear programme, Prime Minister Narendra Modi on Monday witnessed the commencement of “core loading” at India’s first indigenous fast breeder reactor (500 MWe) at Kalpakkam in Tamil Nadu.

He took a tour of the reactor vault and the Control Room of the Reactor. He was briefed about the salient features of this reactor.

India has developed comprehensive capabilities spanning the entire spectrum of the nuclear fuel cycle. The government had approved in 2003, the creation of Bharatiya Nabhikiya Vidyut Nigam Ltd (BHAVINI) to construct and operate India’s most advanced nuclear reactor-Prototype Fast Breeder Reactor (PFBR).

In line with the true spirit of Aatmanirbhar Bharat, PFBR has been fully designed and constructed indigenously by BHAVINI with significant contribution from more than 200 Indian industries including MSMEs. Once commissioned, India will only be the second country after Russia to have a commercial operating Fast Breeder Reactor.

The Fast Breeder Reactor (FBR) will initially use the Uranium-Plutonium Mixed Oxide (MOX) fuel. The Uranium-238 “blanket” surrounding the fuel core will undergo nuclear transmutation to produce more fuel, thus earning the name ‘Breeder’. The use of Thorium-232, which in itself is not a fissile material, as a blanket is also envisaged in this stage. By transmutation, Thorium will create fissile Uranium-233 which will be used as fuel in the third stage. FBR is thus a stepping stone for the third stage of the program paving the way for the eventual full utilization of India’s abundant thorium reserves.

In terms of safety, the PFBR is an advanced third generation reactor with inherent passive safety features ensuring a prompt and safe shut down of the plant in the event of an emergency. Since it uses the spent fuel from the first stage, FBR also offers great advantage in terms of significant reduction in nuclear waste generated, thereby avoiding the need for large geological disposal facilities.

Upon completion of the core loading, the first approach to criticality will be achieved, leading to generation of power subsequently.

Notably, despite the advanced technology involved, both the capital cost and the per unit electricity cost is comparable to other nuclear and conventional power plants.