Logging system and method for evaluation of downhole installation

The invention claimed is: 1. A logging system for evaluation of a downhole installation, wherein the downhole installation comprises: a first pipe layer, a second pipe layer about the first pipe layer, an annulus between the first pipe layer and the second pipe layer, and a geological formation outside of the second pipe layer, the system comprising: a logging tool including an angled acoustic transmitter for exciting a flexural wave in the first pipe layer, and three or more angled acoustic receivers spaced apart along the tool such that, in use, the receivers are at different locations along the length of the pipe layers, the receivers each being for obtaining third interface echo data from the second pipe layer; and a processor arranged to process acoustic data from the receivers in order to: identify trends in the amplitude of the third interface echo as it propagates along the length of the pipes, calculate an estimated exponential decay for the third interface echo when reinforcement from other acoustic energy is disregarded, use this estimation to predict if the material behind the second pipe layer is fluid or solid, and analyse the third interface echo data in light of the determined material state in order to thereby evaluate material conditions in the annulus outside the second pipe layer. 2. A logging system as claimed in claim 1 , wherein the processor is arranged to identify trends in the amplitude of the third interface echo as it propagates along the length of the pipes by plotting the peaks in amplitude for the third interface echo received at each of the receivers, and fitting a curve to the peaks. 3. A logging system as claimed in claim 2 , wherein the processor is arranged to determine an estimated exponential decay curve based on the trends in amplitude, and to use a predicted/estimated attenuation from the estimated exponential decay curve to determine estimated impedance data for the second pipe layer and material outside the second pipe layer. 4. A logging system as claimed claim 1 , wherein the logging tool comprises five or more receivers. 5. A logging system as claimed in claim 1 , wherein the receivers are equally spaced. 6. A logging system as claimed in claim 5 , wherein the receivers are spaced apart by a distance in the range 5-15 cm. 7. A logging system as claimed in claim 1 , being a cement bond evaluation system for a downhole installation, wherein the processor is arranged to produce cement bond log data. 8. A downhole installation equipped with the system of claim 1 . 9. A method of evaluation of a downhole installation, wherein the downhole installation comprises: a first pipe layer, a second pipe layer about the first pipe layer, an annulus between the first pipe layer and the second pipe layer, and a geological formation outside of the second pipe layer, the method comprising: exciting a flexural wave in the first pipe layer using an angled acoustic transmitter; receiving third interface echo data using angled acoustic receivers at different locations along the longitudinal extent of the pipes, the acoustic receivers including at least two receivers spaced apart from the transmitter so as to be located beyond the location where a peak in third interface echo amplitude is expected; processing the received acoustic data in order to: identify trends in the amplitude of the third interface echo as it propagates along the length of the pipe layers, calculate an estimated exponential decay for the third interface echo when reinforcement from other acoustic energy is disregarded, use this estimation to predict if the material behind the second pipe layer is fluid or solid, and analyse the third interface echo data in light of the determined material state in order to thereby evaluate material conditions in the annulus outside the second pipe layer. 10. A method as claimed in claim 9 , wherein three or more angled acoustic receivers are used. 11. A method as claimed in claim 9 , wherein the processing step includes identifying trends in the amplitude of the third interface echo as it propagates along the length of the pipes by plotting the peaks in amplitude for the third interface echo received at each of the receivers, and fitting a curve to the peaks. 12. A method as claimed in claim 9 , comprising determining the expected location for the peak in third interface echo amplitude based on simulations and/or experimental data, and placing the angle acoustic receivers based on the determined expected location. 13. A method as claimed in claim 9 , being a method of cement bond evaluation for a downhole installation. 14. A computer programme product comprising instructions that, when executed, will configure a computer apparatus to implement a method comprising: receiving acoustic data for a downhole installation that comprises: a first pipe layer, a second pipe layer about the first pipe layer, an annulus between the first pipe layer and the second pipe layer, and a geological formation outside of the second pipe layer; wherein the acoustic data comprises third interface echo data received by angled acoustic receivers at different locations along the longitudinal extent of the pipe layers, the acoustic receivers including at least two receivers spaced apart from the transmitter so as to be located beyond the location where a peak in third interface echo amplitude is expected; and processing the received acoustic data in order to: identify trends in the amplitude of the third interface echo as it propagates along the length of the pipe layers, calculate an estimated exponential decay for the third interface echo when reinforcement from other acoustic energy is disregarded, use this estimation to predict if the material behind the second pipe layer is fluid or solid, and analyse the third interface echo data in light of the determined material state in order to thereby evaluate material conditions in the annulus outside the second pipe layer. 15. A logging system for evaluation of a downhole installation, wherein the downhole installation comprises: a first pipe layer, a second pipe layer about the first pipe layer, an annulus between the first pipe layer and the second pipe layer, and a geological formation outside of the second pipe layer, the system comprising: a logging tool including an angled acoustic transmitter for exciting a flexural wave in the first pipe layer, and angled acoustic receivers spaced apart along the tool such that, in use, the receivers are at different locations along the length of the pipe layers, the acoustic receivers including at least two receivers spaced apart from the transmitter so as to be located beyond the location where a peak in third interface echo amplitude is expected, the receivers each being for obtaining third interface echo data from the second pipe layer; and a processor arranged to process acoustic data from the receivers in order to: identify trends in the amplitude of the third interface echo as it propagates along the length of the pipes, calculate an estimated exponential decay for the third interface echo when reinforcement from other acoustic energy is disregarded, use this estimation to predict if the material behind the second pipe layer is fluid or solid, and analyse the third interface echo data in light of the determined material state in order to thereby evaluate material conditions in the annulus outside the second pipe layer.