Hooke's Law, three serial springs

Click For Summary
SUMMARY

This discussion focuses on the application of Hooke's Law to three serial springs, specifically how to derive the effective spring constant (K_eq). The formula for two springs in series, 1/K_eq = 1/K_1 + 1/K_2, can be extended to three springs by substituting the effective spring constant of the first two springs into the equation. Participants clarify that the total extension of the springs can be expressed as X_tot = X_1 + X_2 + ... + X_n, leading to the conclusion that the effective spring constant for multiple springs can be generalized as 1/K_eq = 1/K_1 + 1/K_2 + ... + 1/K_n. This method simplifies the understanding of spring systems in series.

PREREQUISITES
  • Understanding of Hooke's Law and spring constants
  • Basic algebra and manipulation of equations
  • Familiarity with the concept of forces in equilibrium (F_net = 0)
  • Knowledge of series circuits in electronics for analogy
NEXT STEPS
  • Study the derivation of Hooke's Law for two springs in series
  • Explore the concept of effective spring constant in multiple spring systems
  • Learn about the applications of Hooke's Law in real-world scenarios
  • Investigate the relationship between force, extension, and spring constants in mechanical systems
USEFUL FOR

Students studying physics, particularly those in VCE Physics or similar courses, as well as educators and anyone interested in the practical applications of Hooke's Law in mechanical systems.

Lore
Messages
7
Reaction score
0
Hello all, newbie here

Google led me to this thread:
https://www.physicsforums.com/showthread.php?t=70094"
which happens to be basically my question. I am doing an investigation on Hooke's Law for my VCE Physics class (Australian year 12, senior school).

Thanks to wikipedia's derivation and lots of blank staring, I finally understand how the 1/Keq = 1/k1+1/k2 formula shows up (excuse the cruddy layout).
I tried to find the relationship between three spring constants, but I failed my workbook and google failed me :(

Can anybody help me?
 
Last edited by a moderator:
Physics news on Phys.org
If you have the formula for two springs, use it for three. Take the first two, replace it by the effective spring constant. Now you're back to two "springs" in series--apply the formula again. See what happens.

Of course if you really understood the derivation for two springs, then you could apply the same logic directly to the three spring case.
 
Thanks :)

I did try what I think you mean (simply adding 1/k3 at the end of the previous equation) and got a similar result to my expected final value, but I wasn't sure if that mean't that it worked - using such small numbers.

Unfortunately my understanding doesn't cover logic, only the way the maths worked. When i tried doing the maths via the same method I found myself cancelling out k values that I needed :S

Thanks again :)
 
Since you are confident that the formula for two springs in series works, just use it twice. Replace k1 & k2 by their equivalent ke. Now you have ke and k3 in series and you can apply the formula again.
 
Just like electronics :smile:
 
Hello!
Isnt the formula derivation on wikipedia way too advanced than it needs to be? Isnt it just possible to do like this:
The springs S1, S2,...,Sn, has spring coefficients K1, K2,...,Kn and Keq, and with length extensions X1, X2,...,Xn, and Xtot being to total length extension. Then:
X_{tot}=X_1+X_2+...+X_n
but F_m=X_mK_m\rightarrow X_m=\frac{F_m}{K_m}
thus\frac{F_{eq}}{K_{eq}}=\frac{F_1}{K_1}+...+\frac{F_n}{K_n}
Feq being the reaction force on the whole spring from the force making to total extension. but if you neglect the springs masses, you will after some force investigation realize that Feq=F1=F2=...=Fn (since at each shift between two springs, the upper spring must hold all the lower springs+weight, which is the same force as only the weight). Thus:
\frac{1}{K_{eq}}=\frac{1}{K_1}+...+\frac{1}{K_n}
hm I am not sure my motivation is totally correct, please correct me then
 
Last edited:
...
Little wonder it felt like I was beating my head against a wall..

You're absolutely correct (I think your last explanation was looking for the statement 'Fnet = 0'

The derivation on wikipedia was simply for two springs, so I think it was more a matter of proving it using the equations for that, but your version works much better :D

Also explains why it just keeps on going for many springs

Thankyou very much
 
Lore said:
...
Little wonder it felt like I was beating my head against a wall..

You're absolutely correct (I think your last explanation was looking for the statement 'Fnet = 0'

The derivation on wikipedia was simply for two springs, so I think it was more a matter of proving it using the equations for that, but your version works much better :D

Also explains why it just keeps on going for many springs

Thankyou very much
in fact, it(the effective force constant) can be written as 1 over summation 1/k
 

Similar threads

Problem with when to use Force and Energy. What compresses spring/
  • · Replies 3 ·
Replies
3
Views
1K
Investigating Unexpected Results in Elementary Experiment
  • · Replies 35 ·
2
Replies
35
Views
4K
Hooke's Law Lab Spring Constant Calculation
  • · Replies 3 ·
Replies
3
Views
2K
Finding the Spring Constant: Angular Velocity vs Hooke's Law
  • · Replies 1 ·
Replies
1
Views
6K
No prefix: Understanding the Total Force on a Mass Attached by Two Springs
  • · Replies 4 ·
Replies
4
Views
2K
Problem of spring block system: force vs conservation of energy
  • · Replies 20 ·
Replies
20
Views
3K
Hooke's law vs. Elastic potential energy
  • · Replies 1 ·
Replies
1
Views
2K
Why does Hooke's law not work here?
  • · Replies 3 ·
Replies
3
Views
3K
How Does Young's Modulus Relate to Spring Constants in Motion Equations?
  • · Replies 3 ·
Replies
3
Views
3K
Hooke's Law. Does this spring
  • · Replies 4 ·
Replies
4
Views
24K