freaking_out
Saddam's new life
A hole of radius r is bored through a sphere of radius R. Find the remaining volume if:
i) R=8, r=2
ii) R/r=2/1
i) R=8, r=2
ii) R/r=2/1
-
Looking for HSC notes and resources? Check out our Notes & Resources page
another volumes question (1 Viewer)
- Thread starter freaking_out
- Start date
underthesun
N1NJ4
- Joined
- Aug 10, 2002
- Messages
- 1,781
- Location
- At the top of Riovanes Castle
- Gender
- Undisclosed
- HSC
- 2010
My teacher used slicing method for example by subtraction of the cylinder "hole", and calculating the sphere volume with the poles "chipped off".. if you get what I mean.
I forgot, but I tried to use shell method. I forgot if it worked or not. Why don't you try it?
I forgot, but I tried to use shell method. I forgot if it worked or not. Why don't you try it?
freaking_out
Saddam's new life
hey, this question is under the slicing disks and washers section. we still not meant to know cylindrical shells yet....but anyway i tried it but got it wrong!!!! i atleast wanna know what answer you got...
Firstly draw up a nice big diagram of the sphere, with a cylindric hole bored thru it (don't be too artistic with the 3D toning & stuff, this just wastes time and can confuse you more). If you can visualise it in your mind, that's good enough.
Split this huge volume into smaller pieces. You have a sphere, minus a hole in the shape of a cylinder, minus two caps at each end of the hole.
First find the volume of the entire sphere including the hole, which is V = (4/3)*pi*R^3 (note the capital V)
Then find the volume of the cylindrical hole. To do this you have to find out where the bored hole starts & ends. You know the sphere has radius R, so the equation of the circle, which represents the sphere is: x^2 + y^2 = R^2
Also the cylindric hole has radius r, which means at y=r, the hole ends.
x^2 + r^2 = R^2
x = sqrt(R^2 - r^2) <-- This is where the cylindric hole ends. (ignore the -ve value for now, which is the beginning of the hole)
x = sqrt(R^2 - r^2)
so the volume of the cylinder is (note the lower case v):
v = pi*(r^2)*h
= 2*pi*(r^2)*sqrt(R^2 - r^2)
Now for the hardest part, to find the volumes of the caps. Let the volume of each cap be C. The cross section of volume C (the cap) is circular, and it's bounded by the large sphere, so you can find it's volume by slicing:
r = y
x^2 + y^2 = R^2
hence r^2 = R^2 - x^2
so dC = pi*(r^2)*dx
dC = pi*(R^2 - x^2)*dx
dC/dx = pi*(R^2 - x^2)
to find C, integrate with the limits sqrt(R^2 - r^2) to R (where the cap starts & ends)
C = pi * I{sqrt(R^2 - r^2) --> R} R^2 - x^2
= pi * (- (R^3)/3 + (Rr)^2 + {(R^2 - r^2)^(3/2)}/3)
Now the volume (U) of the final product (answer) is:
U = V - v - 2C
= pi * [({4R^3}/3 - 2*pi*(r^2)*sqrt(R^2 - r^2) + 2*((R^3)/3 - (Rr)^2 - {(R^2 - r^2)^(3/2)}/3)]
Now you have U in terms of R & r (that horrible mess up there )
Sub in R=8, r=2 to get the answer for i), and sub r = R/2 to get the answer for ii) (most probably in terms of R)
To make things easier, maybe you can sub R & r to find V, v, and C and then find U.
Split this huge volume into smaller pieces. You have a sphere, minus a hole in the shape of a cylinder, minus two caps at each end of the hole.
First find the volume of the entire sphere including the hole, which is V = (4/3)*pi*R^3 (note the capital V)
Then find the volume of the cylindrical hole. To do this you have to find out where the bored hole starts & ends. You know the sphere has radius R, so the equation of the circle, which represents the sphere is: x^2 + y^2 = R^2
Also the cylindric hole has radius r, which means at y=r, the hole ends.
x^2 + r^2 = R^2
x = sqrt(R^2 - r^2) <-- This is where the cylindric hole ends. (ignore the -ve value for now, which is the beginning of the hole)
x = sqrt(R^2 - r^2)
so the volume of the cylinder is (note the lower case v):
v = pi*(r^2)*h
= 2*pi*(r^2)*sqrt(R^2 - r^2)
Now for the hardest part, to find the volumes of the caps. Let the volume of each cap be C. The cross section of volume C (the cap) is circular, and it's bounded by the large sphere, so you can find it's volume by slicing:
r = y
x^2 + y^2 = R^2
hence r^2 = R^2 - x^2
so dC = pi*(r^2)*dx
dC = pi*(R^2 - x^2)*dx
dC/dx = pi*(R^2 - x^2)
to find C, integrate with the limits sqrt(R^2 - r^2) to R (where the cap starts & ends)
C = pi * I{sqrt(R^2 - r^2) --> R} R^2 - x^2
= pi * (- (R^3)/3 + (Rr)^2 + {(R^2 - r^2)^(3/2)}/3)
Now the volume (U) of the final product (answer) is:
U = V - v - 2C
= pi * [({4R^3}/3 - 2*pi*(r^2)*sqrt(R^2 - r^2) + 2*((R^3)/3 - (Rr)^2 - {(R^2 - r^2)^(3/2)}/3)]
Now you have U in terms of R & r (that horrible mess up there
)Sub in R=8, r=2 to get the answer for i), and sub r = R/2 to get the answer for ii) (most probably in terms of R)
To make things easier, maybe you can sub R & r to find V, v, and C and then find U.
theres are better ways to do this:
The volume is just rotating the area bounded by
y=sqrt(R^2 -x^2)
y=r
about the x axis.
you can either do this by method of cylindrical shells or annular slices. some necessary working are omitted in the following.
shells:
dV = 2*Pi*(2*sqrt(R^2 -y^2))*y dy
V = integral {r->R} 2*Pi*(2*sqrt(R^2 -y^2))*y dy
V = [-(4Pi)*(1/3)(R^2-y^2)^(3/2)] (R, r)
V = [(4Pi/3)(R^2 -r^2)^(3/2)]
annular slices:
the x values for intersections are:
a=-sqrt(R^2 -r^2) and b=sqrt(R^2 - r^2)
dV = Pi*(y^2 - r^2) dx
V = Integral {a->b} Pi*(y^2 - r^2) dx
V = Integral {a->b} Pi*(R^2- x^2 - r^2) dx
V = 2* Integral {0->b} Pi*(R^2- x^2 - r^2) dx
V = 2*Pi*(xR^2- (1/3)x^3 - xr^2) [0,b]
V = 2Pi*(sqrt(R^2 - r^2) *(R^2 -r^2) -(1/3)(R^2 - r^2)^(3/2))
V = (4Pi/3)*(R^2 - r^2)(3/2)
by the way, it has been assumed that the hole and the sphere share the same center in the textbooks and all solutions posted. as a challenge, try the same question but with the hole off center.
The volume is just rotating the area bounded by
y=sqrt(R^2 -x^2)
y=r
about the x axis.
you can either do this by method of cylindrical shells or annular slices. some necessary working are omitted in the following.
shells:
dV = 2*Pi*(2*sqrt(R^2 -y^2))*y dy
V = integral {r->R} 2*Pi*(2*sqrt(R^2 -y^2))*y dy
V = [-(4Pi)*(1/3)(R^2-y^2)^(3/2)] (R, r)
V = [(4Pi/3)(R^2 -r^2)^(3/2)]
annular slices:
the x values for intersections are:
a=-sqrt(R^2 -r^2) and b=sqrt(R^2 - r^2)
dV = Pi*(y^2 - r^2) dx
V = Integral {a->b} Pi*(y^2 - r^2) dx
V = Integral {a->b} Pi*(R^2- x^2 - r^2) dx
V = 2* Integral {0->b} Pi*(R^2- x^2 - r^2) dx
V = 2*Pi*(xR^2- (1/3)x^3 - xr^2) [0,b]
V = 2Pi*(sqrt(R^2 - r^2) *(R^2 -r^2) -(1/3)(R^2 - r^2)^(3/2))
V = (4Pi/3)*(R^2 - r^2)(3/2)
by the way, it has been assumed that the hole and the sphere share the same center in the textbooks and all solutions posted. as a challenge, try the same question but with the hole off center.
freaking_out
Saddam's new life
now that is confusing......
how would you go about doing it???
freaking_out
Saddam's new life
hey does these sorta questions appear in the exam????? if so hurry up with the solutions!
otherwise.....take your time coz i can't seem to do it.:mad1:Oh.. they wouldn't be that hard in the exams since this will involve many calculations, but you should be able to do it .
I am in the process of figuring out what my chemistry teachers mean by their questions(their questions do not corrospond to what they want you to write) so.. I might try it after the trials
. I am in the process of figuring out what my chemistry teachers mean by their questions(their questions do not corrospond to what they want you to write) so.. I might try it after the trials
Last edited: