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Friday, December 14, 2012

Question on Principle of Moments


3. (a) Principle of moments

In equilibrium

sum of clockwise moment (about any point) is equal to sum of

anticlockwise moment (about that point)

2

(b)(i) Weight

Use of “width x thickness x length”

Use of “density = mass”

volume

Correct value 3

V = 1.2 × 0.6 × 200 (cm3) = 144 (cm3)

Using ρ = m/v

m = 8 (g cm-3) × 144 (cm-3) = 1152 g

Weight = mg = 1152 × 10-3 (kg) × 9.81 ( m s-2) = 11.3 (N) / 12

(N)

(ii) Force F

Correct substitution into correct formula

Correct value with correct unit

F × 60 (cm) = 11.3 (N) × 40 (cm) / 12 (N) × 40 (cm) / 11(N) × 40

(cm)

= 7.5 N / 8 N / 7.3 N

2

(iii) Force R

18.3 N / 18.8 N / 20 N

1

(iv) Sketch graph

Any line upwards

Correct shape for F [concave shaped curve]

2

Moments of Forearm





Mark Scheme Capacitor questions


1.       (a)     (i)      Cp = 2 + 4 = 6 μF                                                                                  A1

  (ii)   1/C = 1/2 + ¼                                                                                        C1
Cs = 4/3 =1.33 μF                                                                                 A1

  (b)   (i)      6.0 V                                                                                                    A1

  (ii)   Q = CpV                                                                                                C1
= 6 × 6 = 36 μC                                                                                    A1

  (c)   E = ½ CsV2                                                                                                    C1
= 24 × 10–6                                                                                                    A1

  (d)   (i)      The capacitors discharge through the voltmeter.                                   B1

  (ii)   V = V0et/CR
1/4 =et/(6×12)                                                                                        C1
ln 4 = t / 72                                                                                           C1
t = 72 ln 4 ≈ 100 s                                                                                A1

[12]

 

  2.     (a)     Qo = CV = 1.2 × 10–11 × 5.0 × 103; = 6.0 × 10–8; C (3)                                    3

  (b)   (i)      RC = 1.2 × 1015 × 1.2 × 10–11 or = 1.44 × 104 (s) (1)                              1

(ii)     I = V/R = 5000/1.2 × 1015 or = 4.16 × 10–12 (A) (1)                               1

  (iii)  t = Qo/I; = 6 × 10–8 / 4.16 × 10–12 = 1.44 × 104 (s)                                  2

  (iv)  Q = Qoe–1; Q = 0.37Qo so Q lost = 0.63Qo                                              2

  (c)   (i)      capacitors in parallel come to same voltage (1)
so Q stored α C of capacitor (1)
capacitors in ratio 103 so only 10–3 Qo left on football (1)                      3

  (ii)   V = Q/C = 6.0 × 10–8 /1.2 × 10–8 or 6.0 × 10–11 /1.2 × 10–11 or only 10–3
Q left so 10–3 V left; = 5.0 (V)                                                                2

[14]

 

  3.     (a)     (i)      Q = VC; W = ½ VC.V ( = ½ CV2) (2)

(ii)     parabolic shape passing through origin (1)
plotted accurately as W = 1.1 V2 (1)                                                       4

  (b)   (i)      T = RC; = 6.8 × 103 × 2.2 = 1.5 × 104 s = 4.16 h                                     2

(ii)     ΔW = ½ C(V12 –V22) = 1.1(25 – 16) ; = 9.9 (J)                                       2

  (iii)  4 = 5 exp(–t/1.5 × 104) ; giving t = 1.5 × 104 × ln 1.25 = 3.3 × 103 (s)    2

(iv)    P = ΔW/Δt = 9.9/3.3 × 103 = 3.0 mW            ecf b(ii) and (iii)                 1
allow P = Vav2 /R = 4.52/6.8 × 103 = 2.98 mW

[11]

 

  4.     (a)     29; 34                                                                                                               2


(b)     λ = 0.693/T = 0.693/(120 × 3.2 × 107) = (1.8 × 10–10 s–1) accept ln 2              1

  (c)   (i)      Q = CV = 1.2 × 10–12 × 90; evidence of calculation (= 1.1 × 10–10 C)    2

  (ii)   n = Q/e = 1.1 × 10–10/1.6 × 10–19; = 6.9 × 108 allow sig. fig. variations  2

(iii)    A = λN; N = 6.9 × 108/1.8 × 10–10; = 3.8 × 1018 using 7.0 gives 3.9       3

  (iv)  1 y is less than 1% of 120 y so expect to be within 1%/
using e–λt gives exactly 1% fall/ problem of random emission
or other relevant statement                                                                      1

[11]

 

  5.     (a)     (i)

capacitor
capacitance / µF
charge / µC
p.d. / V
energy / µJ
X
5
30
= Q/C
= 6 (V) (1)
= ½ CV 2(1)
= ½ × 5 × 62
= 90 (1)
Y
25
= CV
= 25 × 6
=150 (µC) (1)
= 6 (V) (1)
= 450 (1)
Z
10
30 + 150 =
180 (µC) (1)
= Q/C
= 180/10
= 18 (V) (1)
= 1620 (1)

         Each box correctly calculated scores (1) + (1) for ½ CV2                        9

  (ii)   1   18 V + 6 V = 24 (V) (1)

2   180 (µC) (1)

3   180 / 24 = 7.5 (1)

4   90 + 450 + 1620 = 2160 (µJ) (1)                                                        4

  (b)   (i)      Kirchhoff’s second law OR conservation of energy (1)                          1

(ii)     Kirchhoff’s first law OR conservation of charge (1)                               1

  (c)   (i)      time constant = CR (1)
= 7.5 × 10–6 × 200 000 = 1.5 (s) (1)                                                        2

  (ii)    (1)
Q/Qo = e–4 = 0.0183 (1)                                                                          2

[19]

 

  6.     (a)     (i)      5.0 (V) (1)                                                                                               1

(ii)     10.0 (V) (1)                                                                                             1


(b)     (i)      Q = CV;= 1.0 × 10–3 (C) (2)                                                                    2

(ii)     The total capacitance of each circuit is the same (namely 100 μF); (1)
because capacitors in series add as reciprocals/ in parallel add/
supply voltage is the same and Q = VC, etc. (1) max 2 marks                 2

  (c)   (i)      A1 will give the same reading as A2; because the two ammeters are (1)
connected in series /AW (1)                                                                    2
answer only in terms of exponential decrease for a maximum of 1 mark

  (ii)   A4 will show the same reading as A2 at all times; (1)
A3 will show half the reading of A2 initially;
and at all subsequent times (2)                                                                3

[11]

 

  7.     (i)      C = Q/V or gradient of graph / = 24 μC/3V; = 8.0 (μF)                                     2

(ii)     E = ½ CV2 / = ½ × 8 × 32; = 36 (μJ) ecf a(i)                                                      2
or ½ QV / = ½ × 24 × 3; = 36 (μJ)

  (iii)  T = RC = (0.04); R = 0.04/8.0μ = 5.0 × 103 (Ω) ecf a(i)                                    2

(iv)    idea of exponential/constant ratio in equal times; which is independent of
initial value/AW or argued mathematically in terms of Q/Qo = e–t/RC
give 1 mark for statement that time depends only on time constant/RC            2

[8]

 

  8.     (i)      Cp = C + C = 6 μF; 1/Cs = 1/2C + 1/C; = 3/2C giving Cs = 2C/3 = (2 μF)          3

(ii)     2 sets of (3 in series) in parallel/ 3 sets of (2 in parallel) in series                     2

[5]

 

 

Wednesday, December 05, 2012

Car Safety


Momentum and Safety

1 The car takes 4 seconds to stop. Calculate the force exerted by the brakes.
 2500 N
                   
2 The same car is driven into a wall. It is traveling at 20 m/s. The car comes to a halt in 0.006 s. Calculate the force exerted by the wall on the car.
F =  1 666 667N = 1.67MN
 
Compare this with the answer to the previous question. Very much larger
What affect does the time taken to stop have on the force applied to the car? The longer the time to stop the lower the acceleration the less force exerted

3  A human head has a mass of 4.5 kg.
If the person is not wearing a seat belt and the car what happens to the speed of the head? It will hit the windscreen at 15m/s  What is the speed of the head after it has hit the windscreen? 0m/s The head stops in 0.002 s. calculate the force exerted on the head.
F  =  33750 N 
 If the car had air bags fitted the head is brought to a halt in 0.15s. Calculate the force exerted on the head now. F =   450 N
  
4 A driver has a mass of 65kg she is not wearing a seat belt. In a crash her car stops and she hits the steering wheel which stops her in 0.05s. Calculate the force exerted on her by the steering wheel. F = 45 500 N
Had she been wearing a seat belt she would have come to a halt in 0.2s.
Calculate the force exerted on her body by the seat belt. . F = 11 375 N
 
 5 A car has a mass of 750 kg and a velocity of 15m/s. (a)Calculate its KE. ½ x 750 x 152 = 84375 J (b) What is the work done by the brakes to stop the car 84375 J The brakes exert a maximum force of 5600 N. (c) Calculate the distance travelled before the car stops. Work = F x d, so, d = work / F = 84375/ 5600 = 15m(d) Repeat this for a speed of 30m/s KE = ½ x 750 x 302 = 337 500 J               Work = F x d, so, d = work / F = 337 500/ 5600 = 60.3m