Update Content - 2023-10-24

content/zettels/tuned_mass_damper.md

@@ -120,39 +120,40 @@ The following mass ratios are tested:
 mus = [0.01, 0.02, 0.05, 0.1];
 ```
 
-The obtained transfer functions are shown in Figure [1](#figure--fig:tuned-mass-damper-mass-effect).
+The obtained transfer functions are shown in Figure [3](#figure--fig:tuned-mass-damper-mass-effect).
 
 <a id="figure--fig:tuned-mass-damper-mass-effect"></a>
 
-{{< figure src="/ox-hugo/tuned_mass_damper_mass_effect.png" caption="<span class=\"figure-number\">Figure 1: </span>Effect of the TMD mass on its efficiency" >}}
+{{< figure src="/ox-hugo/tuned_mass_damper_mass_effect.png" caption="<span class=\"figure-number\">Figure 3: </span>Effect of the TMD mass on its efficiency" >}}
 
-The maximum amplification (i.e. \\(\mathcal{H}\_\infty\\) norm) of the transmissibility as a function of the mass ratio is shown in Figure [1](#figure--fig:tuned-mass-damper-effect-mass-ratio).
+The maximum amplification (i.e. \\(\mathcal{H}\_\infty\\) norm) of the transmissibility as a function of the mass ratio is shown in Figure [4](#figure--fig:tuned-mass-damper-effect-mass-ratio).
 This relation can help to determine the minimum mass of the TMD that will give acceptable results.
 
 <a id="figure--fig:tuned-mass-damper-effect-mass-ratio"></a>
 
-{{< figure src="/ox-hugo/tuned_mass_damper_effect_mass_ratio.png" caption="<span class=\"figure-number\">Figure 1: </span>Maximum amplification due to resonance as a function of the mass ratio" >}}
+{{< figure src="/ox-hugo/tuned_mass_damper_effect_mass_ratio.png" caption="<span class=\"figure-number\">Figure 4: </span>Maximum amplification due to resonance as a function of the mass ratio" >}}
 
 
 ## Manufacturers {#manufacturers}
 
-<https://vibratec.se/en/product/high-frequency-tuned-mass-damper/>
-<https://micromega-dynamics.com/products/vibration-control/passive-damping-devices/>
-<https://www.csaengineering.com/products-services/tuned-dampers-absorbers.html>
+-   <https://vibratec.se/en/product/high-frequency-tuned-mass-damper/>
+-   <https://micromega-dynamics.com/products/vibration-control/passive-damping-devices/>
+-   <https://www.csaengineering.com/products-services/tuned-dampers-absorbers.html>
 
 
 ## Ways to add damping {#ways-to-add-damping}
 
 Possible damping sources:
 
--   Magnetic (eddy current)
+-   Magnetic ([Eddy Current Damping]({{< relref "eddy_current_damping.md" >}}))
 -   Viscous fluid
+-   Elastomer ([example](https://www.dspe.nl/knowledge/dppm-cases/tuned-mass-damper-with-damped-mass-far-away-from-point-of-interest/))
 
 | Fuild                | Reference                                         |
 |----------------------|---------------------------------------------------|
 | Rocol Kilopoise 0868 | (<a href="#citeproc_bib_item_2">Verbaan 2015</a>) |
 
 <style>.csl-entry{text-indent: -1.5em; margin-left: 1.5em;}</style><div class="csl-bib-body">
-  <div class="csl-entry"><a id="citeproc_bib_item_1"></a>Elias, Said, and Vasant Matsagar. 2017. “Research Developments in Vibration Control of Structures Using Passive Tuned Mass Dampers.” <i>Annual Reviews in Control</i> 44 (nil): 129–56. doi:<a href="https://doi.org/10.1016/j.arcontrol.2017.09.015">10.1016/j.arcontrol.2017.09.015</a>.</div>
+  <div class="csl-entry"><a id="citeproc_bib_item_1"></a>Elias, Said, and Vasant Matsagar. 2017. “Research Developments in Vibration Control of Structures Using Passive Tuned Mass Dampers.” <i>Annual Reviews in Control</i> 44: 129–56. doi:<a href="https://doi.org/10.1016/j.arcontrol.2017.09.015">10.1016/j.arcontrol.2017.09.015</a>.</div>
   <div class="csl-entry"><a id="citeproc_bib_item_2"></a>Verbaan, C.A.M. 2015. “Robust mass damper design for bandwidth increase of motion stages.” Mechanical Engineering; Technische Universiteit Eindhoven.</div>
 </div>