Sponge attacks aim to increase the energy consumption and computation time of neural networks deployed on hardware accelerators. Existing sponge attacks can be performed during inference via sponge examples or during training via Sponge Poisoning. Sponge examples leverage perturbations added to the model's input to increase energy and latency, while Sponge Poisoning alters the objective function of a model to induce inference-time energy/latency effects. In this work, we propose a novel sponge attack called SpongeNet. SpongeNet is the first sponge attack that is performed directly on the parameters of a pre-trained model. Our experiments show that SpongeNet can successfully increase the energy consumption of vision models with fewer samples required than Sponge Poisoning. Our experiments indicate that poisoning defenses are ineffective if not adjusted specifically for the defense against Sponge Poisoning (i.e., they decrease batch normalization bias values). Our work shows that SpongeNet is more effective on StarGAN than the state-of-the-art. Additionally, SpongeNet is stealthier than the previous Sponge Poisoning attack as it does not require significant changes in the victim model's weights. Our experiments indicate that the SpongeNet attack can be performed even when an attacker has access to only 1% of the entire dataset and reach up to 11% energy increase.