Integrated analysis of hydraulic PTOs in WECs

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Integrated analysis of hydraulic PTOs in WECs Conference on CeSOS Highlights and AMOS Visions Limin Yang 29 th May, 2013, Trondheim

Content Introduction Model description of wave energy converter (WEC) with hydraulic power take-off (PTO) Bond graph representations of pipelines Bond graph system modelling of the WEC Simulation results Conclusions Publications 2

WEC introduction Wear Fatigue Stochastic wave excitation Catastrophic failure Fatigue

Model description The studied wave energy converter can be characterized by several subsystems and each of which is based on basic physical laws. The electric generator used here is simplified as a dissipative element.

Model description wave-buoy Mass Assumptions and simplifications: Linear hydrodynamic theory Heave motion only Accelaration Velocity Position External force ( M m ) X K( t ) X ( ) d K X F ( t) F ( X, X, t) t 0 hstatic exc ext Radiation force Hydrostatic stiffness Excitation force wave-buoy interactions

Model description wave-buoy The governing equation of the buoy includes a convolution intergral term which can be approximated by a state space model: z( t) Az( t) BX ( t) t K( t ) X ( ) d Cz(t) The matrix coefficients A, B and C of the state space equations can be calculated by using Matlab function imp2ss.

Model description pump Applying the mass balance law to the respective chambers gives state space equations for the chamber pressures: PA ( QA Qli Ap X ) A L X p PB ( QB Qli Qle Ar X ) A L X r Assuming that the buoy and piston are rigidly connected by the rod, the external force defined in the buoy motion equation can be written as: F X, X, t A P A P F ( t) F ( t) ext r B p A f end

Model description motor Practical model: P Q D Q 1 in loss Vpf P D Q Q 2 out loss Vpb J P P D B T m 1 2 m L y Valve plate Here D is the volume displacement defined as: D NA R tan / p z Section A-A R x Piston A A Slipper Cylinder block Swash plate Swash plate axial piston motor z Shaft Pivot

Model description check valves Check valves are used to control the direction of the fluid flow. They can be considered as resistances that cause pressure drops when the fluid flows across them. They can be modelled by using Bernoulli s energy equation by combining a position dependent function:

P/gu Model description check valves Water hammer pressure waves can be created by check valves sudden closure or opening. 1 0-1 0 2 4 6 8 10 12 14 time (a/l)t

Model description water hammer pressure The magnitude of wate hammer pressure amplitudes can be approximated by Joukowski s equation for complete closure or opening of the valve. Example 10 0 10-1 For partial valve actuations, time dependent pressure transient amplitudes can be calculated by solving the basic partial differential equations of pipelines with the dynamic valve boundaries. P/gu 10-2 10 0 10 1 10 2 t c /T r

Model description pipelines The components of the hydraulic power take-off are connected by the hydraulic lines. The fluid pressure changes propagate with a speed of sound. Relatively long lines may introduce: A time delay for the pressures at the upstream and downstream sides. Strong pressure pulsations (water hammer) during the transition from one steady state to another. This is mainly induced by: Cyclic operation of check valves Sudden pump shut off Suddenly start or stop the system Failure of the valves

Model description pipelines Basic assumptions: Pipe wall is rigid; The flow is laminar; The motion in radial direction is negligible; Thermodynamic effects are negligible The model of the hydralic pipeline is found from the mass and momentum balance and can be written as partial differential equations:, Q x, t P x t t A x A 2 2 a a S Q x, t, A,, Q x t P x t F x t t x Fluid damping 1-D friction term 1 Q Ff Q Q wt d 2 t 2-D friction term t 0

Model description pipelines There are four possible sets of boundary conditions, corresponding to four input-output configurations, that lead to causal line models. Symmetric boundary conditions 1. [P up, P down ] as input e.g. the line is connected to volumes at both sides 2. [Q up, Q down ] as input e.g. the line is connected to valves at both sides Mixed boundary conditions 3. [P up, Q down ] as input 4. [Q up, P down ] as input e.g. the line is connected to a valve at one port and a volume at the other port.

Model description pipelines Partial differential equations (PDE) Time domain analysis Frequency domain analysis Discrete models Modal approximation method Have been studied here Method of characteristics Others Separation of variables (SOV) method Rational transfer function (RTF) method Others Using the modal approximation method, the pipeline dynamics can be characterised as a series of damped resonant modes. Each mode can be represented in a linear state space form.

Model description pipelines (SOV method) This method begins by assuming that the pressure P and flow rate Q can be separated into a product of mode shapes of x and a modal generate coordinate of time t., i i i1 P x t H x t, i i i1 Q x t G x t The mode shapes are given by the homogeneous solution of the pipeline equations. By using the orthogonality property of the mode shape, a set of decoupled ODEs can be obtained for each normal mode. The bond graph representations can then be obtained. The ODEs can be solved by numerical integration to find modal responses.

Model description pipelines (RTF method) The one-dimensional distributed transmission line model can be expressed by the fourpole equations that relate to different boundary conditions in the Laplace domain. The major obstacle to the distributed parameter model is that the terms of the transfer function are not in the form of a finite rational polynomial. The baisc idea of RTF method is to represent each of the transcendental function as finite sum approximations of low-order polynominal forms. T s Ti i s Transcendental transfer function Polynominal transfer function

Bond graph models A bond graph is: A graphical representation of physical dynamic system A multidisciplinary and unified approach Mainly used for modelling the systems in which power and energy interactions are important. Bond graph models include nine basic elements. A graphical model can be constructed by using these elements for a system.

Bond graph models pipelines (SOV method) The bond graph models by using SOV are directly shown in the figures. 1. [P up, P down ] as input (by Karnopp) 2. [Q up, Q down ] as input (by Karnopp) 3. [P up, Q down ] as input (By Yang et al.) 4. [Q up, P down ] as input (By Yang et al.)

Bond graph models pipelines (RTF method) The input-output behaviour governed by each polynonimal transfer function can be represented by using bond graph models. For different causalities, the suggested bond graph models are shown in the figures. 1. [P up, P down ] as input (by Yang et al.) 2. [Q up, Q down ] as input (by Yang et al.) 3. [P up, Q down ] as input (By Margolis) 4. [Q up, P down ] as input (By Margolis)

Pressure [Pa] Inlet Flow [m 3 /s] Pressure [Pa] Simulation results method comparison 2. 3. Pressure Flow rate pulsations variation at with the upstream side of the the pipeline configuration 1. Pressure with [Q up [P, Q up, P transient down down ] as ] input as input prediction with [P up, Q down ] as input 4 x 10-4 x 10 6 2 2 1 0 3 2 1 RTF RTFSOV Upstream Pressure SOV SOV RTF 0 0-2 -1 0 5 10 15 20 25 Normalized Time [(a/l)t] -1-4 0 1 2 3 4 6 7 8 0 1 2 3 Normalized 4 Time [(a/l)t] 5 6 7 Normalized Time [(a/l)t]

Pressure [Pa] Simulation results friction effect Pressure transient prediction with [P up, Q down ] as input 1-D friction term 1 Q Ff Q Q wt d 2 t t 0 2-D friction term 3 2 1 Upstream Pre Downstream Pre - Lossless Downstream Pre - 1D Downstream Pre - 2D 0-1 0 5 10 15 20 25 Normalized Time (at/l)

WEC model Interconnections of subsystems A sketch diagram which shows the input-output behaviour within each component

WEC model bond graph representation

Q [m 3 /s] P/H s 2 [kw/m 2 ] Pa [MPa] Pacc [MPa] Simulation results Under the sea state H s,des =3.5 m, T e =9.5 s 20 15 10 5 22 21 20 19 18 0 800 850 900 950 1000 1050 1100 1150 1200 1250 t [s] Pressure in pump cylinder 17 0 500 1000 1500 t [s] Pressure in HP accumulator 0.05 0.04 flow to HPacc 80 60 P pump P motor 0.03 0.02 0.01 0 780 800 820 840 860 880 900 920 940 t [s] Flow rate pumped into HP accumulator 40 20 0 800 900 1000 1100 1200 t [s] Power available to pump and motor

Conclusions Developed an integrated dynamic model for a wave energy converter with hydraulic PTO using inter-linked models of the related subsystems. Constructed bond graph models for transmission pipelines by using SOV and RTF for all the four possible input-output causalities. Comparisons were made for the pipeline responses by using the SOV and RTF with different causalities in time domain. It shows that the transient properties can be preserved well for both types of methods. Extended the pipeline bond graph models from 1-D friction model to 2-D friction model.

Relevant publications Yang, L., Hals, J. and Moan, T. Analysis of Dynamic Effects Relevant for the Wear Damage in Hydraulic Machines for Wave Energy Conversion. Ocean Engineering. 2010; 37 (13): 1089-1102. Yang, L. and Moan, T. Numerical Modeling of Wear Damage in Seals of a Wave Energy Converter with Hydraulic Power Take-Off Under Random Loads. Tribology Transactions. 2011; 54 (1): 44-56. Yang, L. and Moan, T. Dynamic Analysis of Wave Energy Converter by Incorporating the Effect of Hydraulic Transmission Lines. Ocean Engineering. 2011; 38 (16): 1849-1860. Yang, L., Hals, J. and Moan, T. Comparative Study of Bond Graph Models for Hydraulic Transmission Lines With Transient Flow Dynamics. Journal of Dynamic Systems, Measurement, and Control. 2012; 134 (3): 031005 (13 pages). Yang, L. and Moan, T. Bond Graph Representations of Hydraulic Pipelines Using Normal Modes with Dissipative Friction. SIMULATION, 2013, 89: 199-212. Yang, L. and Moan, T. Prediction of Long-term Fatigue Damage of a Hydraulic Cylinder of a Wave Energy Converter Subjected to Internal Fluid Pressure Induced by Wave Loads. International Journal of Marine Energy, Accepted.

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