Generally, users can cast up two sorts of requests, such as elastic requests that contain no delay constraints, and inelastic requests that take an inflexible delay constraint. The distribution of WSN's in multiple areas like, target tracking in battle fields, environmental control needs an optimization for communication among the detectors to serve information in shorter latency and with minimal energy consumption. Cooperative data caching emerged as a productive technique to accomplish these ends simultaneously. The execution of protocols for that network depends mainly on the selection of the sensors which will call for special roles in accordance to the procedure of caching and take forwarding decisions. A perception of Wireless content distribution was shown in which there are numerous cellular base stations, each of which encompass a cache for storing of content. Content is typically partitioned into two disjoint sets of inelastic as well as elastic content. Cooperative caching is shown to be capable to reduce content provisioning cost which heavily depends on service and pricing dependencies among several stakeholders including content providers, web service providers, and end consumers. Hither, a practical network, service, and economic pricing models which are then utilized for making an optimal cooperative caching strategy based on social community abstraction in wireless nets are broken. Inelastic requests are provided by means of broadcast transmissions and here we develop algorithms in support of content spread by means of elastic and inelastic requests. The developed framework includes optimal caching algorithms, analytical models, for evaluating the operation of the suggested scheme. The primary donations are: i) formulation of economic cost-reward flow models among the WNET stakeholders, ii) developing optimal distributed cooperative caching algorithms, iii) characterizing the impacts of network, user and object dynamics, and finally iv) investigating the impacts of user noncooperation,