Slider Crank Mechanism with Joint Clearance

Joints between two components of a mechanical system are not always perfectly fitting. For the ease of assembly and to allow relative movement between the components, a small gap called clearance is provided between the joining components. The presence of clearance on joints can sometimes adversely affect the performance of the system by generating impact forces thus giving rise to noise and vibrations.

This model compares the performance of a slider crank mechanism with and without a joint clearance. All components of the mechanism are assumed rigid. Hinge Joint node is used when there is no clearance on a joint whereas Clearance Joint node is used to include clearance on a joint. A transient analysis is performed to analyze the effect of joint clearance on slider velocity, slider acceleration, and crank moment. In addition to this, the dynamics of journal within the bearing and the reaction force in the clearance joint are also analyzed.

Model Definition

As shown in Figure 1, the model geometry consists of four rigid components: support, crank, connecting rod, and slider.

Figure 1: Model geometry of a slider crank mechanism.

One end of the crank is connected to the fixed support and other end to the connecting rod. Connecting rod, in turn, is connected to the center of the slider, which can slide freely along x-direction.

The connection between the support and crank is modeled as a hinge joint with one rotational degree of freedom about y-axis. A similar hinge joint is used to model the connection between crank and connecting rod also. To model the connection between connecting rod journal and slider, two different cases are considered:

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In the first case, a perfect hinge joint without any clearance is assumed between journal and the slider.

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In the second case, a clearance of 0.5 mm is provided between journal and the slider. A clearance joint is used to model this connection, which allows the connected members to move within the provided clearance distance.

The mechanism is driven by the crank which rotates with an angular velocity of 5000 rpm. A time dependent study is performed for 0.025 s to analyze the effect of joint clearance on slider velocity, slider acceleration, and crank moment.

Results and Discussion

Figure 2 shows the displacement of components in the slider crank mechanism for hinge joint and clearance joint cases. To visualize the motion of connecting rod with respect to the slider, the relative displacement of connecting rod is plotted in Figure 3. For hinge joint case, the relative motion is purely rotational without any translation, however for clearance joint case, connecting rod journal exhibits both translational and rotational motion within the slider hole. This trajectory of the journal within the slider hole is plotted in Figure 7.

The time variation of slider velocity is plotted in Figure 4. It is observed that the velocity profile in hinge joint case is smoother compared to the clearance joint case. Unlike the continuous contact in hinge joint, the translation and the consequent impact of journal with the slider generate a step like velocity profile in clearance joint case. As shown in Figure 5 and Figure 6, the impact between journal and slider also causes sudden variations in slider acceleration and reaction moment in the crank.

Figure 8 shows the variation in clearance joint force as a function of time. The zero value of force at times denotes the intermittent contact within the clearance joint. The variation of gap distance with crank rotation is shown in Figure 9. When gap distance is negative (inside black circle), journal and slider are in contact and penalty force acts on the bodies to maintain the relative movement of journal within the specified clearance.

Figure 2: Displacement of slider crank mechanism for hinge joint and clearance joint cases respectively at t = 0.025 s.

Figure 3: Relative displacement of connecting rod journal with respect to the slider for hinge joint and clearance joint cases respectively at t = 0.025 s.

Figure 4: Variation of slider velocity, as a function of time.

Figure 5: Variation of slider acceleration, as a function of time.

Figure 6: Variation of crank reaction moment, as a function of time.

Figure 7: Journal trajectory within the slider hole for clearance joint case. Here blue color denotes the initial position and red color denotes the final position.

Figure 8: Variation of clearance joint force, as a function of time.

Figure 9: Variation of gap distance, as a function of crank rotation. Here blue color denotes the initial position, red color denotes the final position, and black dotted circle corresponds to the zero gap distance.

Notes About the COMSOL Implementation

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In this model, linkages are modeled as rigid elements using the nodes which can be created automatically using the button in the section at the physics interface.

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nodes between two respective components can also be created automatically using the button in the section at the physics interface. The automatic joint creation requires the geometry to be in assembly mode and nodes to be available in the . In case geometry doesn’t create an identity pair automatically because of a geometric clearance between the two sets of boundaries, then the identity pair can be created manually in order to create a joint between those two components.

Reference

P. Flores and J. Ambrosio, “Revolute Joints with Clearance in Multibody Systems”, Computers and Structures, vol. 82, pp. 1359–1369, 2004.

Multibody_Dynamics_Module/Tutorials/slider_crank_mechanism_with_clearance

Modeling Instructions

From the menu, choose .

New

In the window, click

Model Wizard

In the window, click

In the tree, select .

Click .

Click

In the tree, select .

Click

Global Definitions

Parameters 1

In the window, under click .

In the window for , locate the section.

Click

Browse to the model’s Application Libraries folder and double-click the file slider_crank_mechanism_with_clearance_parameters.txt.

If you do not want to import the geometry and create selections, you can load the geometry sequence from the stored model. In the window, under right-click and choose . Browse to the model’s Application Libraries folder and double-click the file slider_crank_mechanism_with_clearance.mph. You can then continue to the section below.

To import the geometry and create selections from scratch, continue here.

Geometry 1

Import 1 (imp1)

In the window, expand the node.

Right-click and choose .

In the window for , locate the section.

Click .

Browse to the model’s Application Libraries folder and double-click the file slider_crank_mechanism_with_clearance.mphbin.

Click .

Form Union (fin)

In the window, under click .

In the window for , locate the section.

From the list, choose .

In the toolbar, click

Support

In the toolbar, click

and choose .

In the window for , type Support in the text field.

On the object , select Domain 1 only.

Locate the section. From the list, choose .

On Windows, click the colored bar underneath, or — if you are running the cross-platform desktop — the button.

Click .

Set the RGB values to 128, 128, and 128, respectively.

Click .

Click or on the cross-platform desktop.

Click

Crank

Right-click and choose .

In the window for , type Crank in the text field.

Locate the section. Click

On the object , select Domain 2 only.

Locate the section. On Windows, click the colored bar underneath, or — if you are running the cross-platform desktop — the button.

Click .

Set the RGB values to 209, 255, and 28, respectively.

Click .

Click or on the cross-platform desktop.

Click

Connecting Rod

Right-click and choose .

In the window for , type Connecting Rod in the text field.

Locate the section. Click

On the object , select Domain 3 only.

Locate the section. On Windows, click the colored bar underneath, or — if you are running the cross-platform desktop — the button.

Click .

Set the RGB values to 255, 128, and 128, respectively.

Click .

Click or on the cross-platform desktop.

Click

Slider

Right-click and choose .

In the window for , type Slider in the text field.

Locate the section. Click

On the object , select Domain 4 only.

Locate the section. On Windows, click the colored bar underneath, or — if you are running the cross-platform desktop — the button.

Click .

Set the RGB values to 0, 255, and 255, respectively.

Click .

Click or on the cross-platform desktop.

Click

Connecting Rod Boundaries

In the toolbar, click

and choose .

In the window for , type Connecting Rod Boundaries in the text field.

Locate the section. Click

In the dialog box, select in the list.

Click .

Journal Boundaries

In the toolbar, click

and choose .

In the window for , type Journal Boundaries in the text field.

Locate the section. From the list, choose .

On the object , select Boundaries 33 and 37 only.

Select the check box.

Connecting Rod without Journal

In the toolbar, click

and choose .

In the window for , type Connecting Rod without Journal in the text field.

Locate the section. From the list, choose .

Locate the section. Click

In the dialog box, select in the list.

Click .

In the window for , locate the section.

Click

In the dialog box, select in the list.

Click .

The identity pair between connecting rod and slider is not added automatically because of the geometric clearance. Add it manually to allow automatic joint creation functionality to create a hinge joint between the two components.

Definitions

Identity Boundary Pair 3 (p3)

In the window, expand the node.

Right-click and choose .

Select Boundaries 31, 32, 37, and 38 only.

In the window for , locate the section.

Select the

toggle button.

Select Boundaries 42 and 43 only.

Multibody Dynamics (mbd)

Do as follows to generate nodes for all components.

In the window, under click .

In the window for , locate the section.

Select the check box. This automatically sets the density of all rigid domains to zero and adds a Mass and Moment of Inertia subnode to each Rigid Domain node.