Hey so im trying to make a waterslide. Can anyone knowledgeable with splines in NX help me figure out how to make these three sections

Your waterslide (and therefore the space curve) must consist of at least three sections:

the entry free-form section, (the parametric) serpentine section, and (the exit) convex

free-form section, as described below.

• The entry to the waterslide is a free-form (B-spline) section that must pass through

at least 4 non-coplanar points (i.e., they cannot all lie on the same plane); you

can use it to design a variation of a “toboggan” slide.

• The serpentine section must be created using an explicit parametric law curve.

The easiest way to do this is to pick any planar parameterized curve, such as

those that can be found at

http://mathworld.wolfram.com/topics/Roulettes.html

and add the third dimension by specifying z(t), where t is the parameter of the

planar curve. Recall what we did in class for the circular helix, and what you did

in the lab with the involute profile. Please do NOT use a circular helix for your

serpentine - pick a more interesting shape.

• The last section of the waterslide is a “convex” free-form section (holds water,

and is another B-spline). This is your exit flume.

• You must be able to perform a rough analytical estimate of the total length of

your slide, and later verify it using tools in NX. You can approximate the lengths

of the free-form sections but you must compute analytically the length of

the serpentine section - see below.

2. It may be easier to position the end of the exit flume at {0, 0, 0} in the absolute

coordinate system, the positive z-axis should point upwards, and the xy-plane should

be considered ground level.

]]>Your waterslide (and therefore the space curve) must consist of at least three sections:

the entry free-form section, (the parametric) serpentine section, and (the exit) convex

free-form section, as described below.

• The entry to the waterslide is a free-form (B-spline) section that must pass through

at least 4 non-coplanar points (i.e., they cannot all lie on the same plane); you

can use it to design a variation of a “toboggan” slide.

• The serpentine section must be created using an explicit parametric law curve.

The easiest way to do this is to pick any planar parameterized curve, such as

those that can be found at

http://mathworld.wolfram.com/topics/Roulettes.html

and add the third dimension by specifying z(t), where t is the parameter of the

planar curve. Recall what we did in class for the circular helix, and what you did

in the lab with the involute profile. Please do NOT use a circular helix for your

serpentine - pick a more interesting shape.

• The last section of the waterslide is a “convex” free-form section (holds water,

and is another B-spline). This is your exit flume.

• You must be able to perform a rough analytical estimate of the total length of

your slide, and later verify it using tools in NX. You can approximate the lengths

of the free-form sections but you must compute analytically the length of

the serpentine section - see below.

2. It may be easier to position the end of the exit flume at {0, 0, 0} in the absolute

coordinate system, the positive z-axis should point upwards, and the xy-plane should

be considered ground level.