Types of mesh

An offshore crane shock absorber is a gas spring with hydraulic damping used to reduce dynamic loads during offshore lifting. The lifting capacity of the offshore crane can be increased significantly during lifting in high sea states if a shock absorber is fitted. ^[1]

Crane design load

Offshore lifting capacity is governed by classification society rules. The fundamental rule is that the design load should not be exceeded. The design load is given by:
${\displaystyle F_m=\psi m_{s}g}$

Where:
${\displaystyle F_m}$ - Crane design load
${\displaystyle \psi }$ - Dynamic coefficient
${\displaystyle m_s}$ - Safe working load
${\displaystyle g}$ - Acceleration of gravity

The classification societies require that ${\displaystyle \psi }$ ≥1.3 for offshore cranes. This means that ${\displaystyle m_s}$ cannot exceed ${\displaystyle \frac{F_m}{\psi g}}$ even for platform lifts. ^{[2] [3] [4]}

Dynamic load

To calculate the dynamic load the classification societies use energy equations. The kinetic energy of the load is expressed as:
${\displaystyle E_k=\frac{1}{2}{m}_s{v}_r^2}$

Where:
${\displaystyle E_k}$ - Kinetic energy of the load
${\displaystyle v_r}$ - Relative velocity between crane hook and load

Energy absorbed by the crane is given by:
${\displaystyle E_c=\frac{1}{2}k{y}^2}$

Where:
${\displaystyle E_c}$ - Spring energy stored in crane structure
${\displaystyle k}$ - Stiffness of offshore crane
${\displaystyle y}$ - Vertical displacement of crane hook

The pring force is given by:
${\displaystyle F_c=ky}$

Combining the two previous equations yields an alternative description of the energy stored in the crane structure:
${\displaystyle E_c=\frac{1}{2}k(\frac{F_c}{k}{)}^2=\frac{F_c^2}{2k}}$

During an offshore lift the crane does not start to absorb energy from the load before the force in the crane wire exceeds the static weight of the load, which means that we can write the energy absorption of the crane as:
${\displaystyle E_c=\frac{(m_s\psi g-m_{s}g{)}^2}{2k}}$

Setting ${\displaystyle E_c}$ equal to ${\displaystyle E_k}$: ${\displaystyle \frac{(m_s\psi g-m_{s}g{)}^2}{2k}=\frac{1}{2}{m}_s{v}_r^2}$

And solving for ${\displaystyle \psi }$:
${\displaystyle \psi =1+\frac{v_r}{g}\sqrt{\frac{k}{m}}}$


The dynamic factor will always be larger than 1 because there will always be a velocity difference between the crane hook and the load during offshore lifts. The value of ${\displaystyle \psi }$ determines the lifting capacity as a function of ${\displaystyle v_r}$ which is dependent on the significant wave height. If the offshore crane has a shock absorber mounted it will absorb energy according to:
${\displaystyle E_a=\eta \mu S{m}_{s}g(\psi -1)}$

Where:
${\displaystyle E_a}$ - Energy absorbed by shock absorber
${\displaystyle \mu }$ - Stroke utilization (safety factor), standard value 0.9
${\displaystyle \eta }$ - Efficiency of shock absorber, usually possible to get close to 0.9
${\displaystyle S}$ - Stroke length

Adding this to the energy balance yields:

${\displaystyle \frac{(m_s\psi g-m_{s}g{)}^2}{2k}+\eta \mu S{m}_{s}g(\psi -1)=\frac{1}{2}{m}_s{v}_r^2}$


Again solving for ψ:
${\displaystyle \psi =1+\frac{\sqrt{(\mu \eta Sk{)}^2+m_{s}k{v}_r^2}-\mu \eta Sk}{m_{s}g}}$


The plot to the right shows the effect of the shock absorber stroke length.

Estimating relative velocity

The relative velocity is defined by several classification societies as:
${\displaystyle v_r=\frac{1}{2}{v}_L+\sqrt{v_d^2+v_c^2}}$


Where:
${\displaystyle v_L}$ - Maximum crane lifting velocity at this SWL
${\displaystyle v_d}$ - Vertical velocity of the deck which the load is placed on
${\displaystyle v_c}$ - Vertical velocity of the crane tip due to wave motion

${\displaystyle v_L}$ has to be gathered from crane user manual or be measured. The deck velocity can be estimated from Table 1.

The crane tip velocity, ${\displaystyle v_c}$, can be estimated by Table 2.

These estimations are conservative and for large ships/rigs they may deviate significantly from reality. A plot of the dynamic factor versus significant wave height for a crane mounted on a semisubmersible and lifting from supply boat is shown above to the right.

References

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