MindTap Engineering for Garber/Hoel's Traffic and Highway Engineering, 5th Edition, [Instant Access], 1 term (6 months)
MindTap Engineering for Garber/Hoel's Traffic and Highway Engineering, 5th Edition, [Instant Access], 1 term (6 months)
5th Edition
ISBN: 9781305581159
Author: Nicholas J. Garber; Lester A. Hoel
Publisher: Cengage Learning US
Question
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Chapter 6, Problem 19P
To determine

The graph of average individual delay versus the repair period and use this graph to discuss the effect of the expected repair time on the average delay.

Expert Solution & Answer
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Explanation of Solution

Given:

We have been given the following information:

We have been given the following information:

Total number of lanes = 3,

  V=90%of6000,

  tinc=2hr,

Mean free flow speed of the highway = 55 mi/h,

Jam density = 135 veh/mi/ln,

  Cr=4000.

Following is the lay out of the given highway section:

  MindTap Engineering for Garber/Hoel's Traffic and Highway Engineering, 5th Edition, [Instant Access], 1 term (6 months), Chapter 6, Problem 19P , additional homework tip  1

Calculation:For the expected repair period of 1 hour.

We have the following formula for the determination of maximum queue length that will be formed:

  qmax=(VCr)tinc

Where, qmax is the maximum queue length,

  V is the total volume,

  Cr is the reduced capacity,

  tinc is the duration of the incident.

Considering 90 percent of the flow and that the capacity of each lane is 2000 Veh/ h

Substituting the values in the following equation, we have

  qmax=(VCr)tincqmax=(( 90%of6000)4000)2qmax=(( 6000× 90 100 )4000)2qmax=(( 60×90)4000)2qmax=(54004000)2qmax=2800Veh.

Themaximum queue length that will be formed is qmax=2800Veh.

Now, the total delay, we have the following formula

  dr=tinc2(VCR)(CCR)2(CV)

Where, CR is the reduced capacity and can be found as follows:

  CR=Numberoflanesinuse×capacityofeachlane.CR=2000×(31).CR=2000×2=4000Veh/h.

And C is the total capacity and can be found as

  C=Totalnumberoflanesinuse×capacityofeachlane.C=2000×3.C=6000Veh/h.

Now, substituting the values in the required equation, we have

  dr=t inc2( V C R )( C C R )2( CV)dr=12( 90%of60004000)( 60004000)2( 60005400)

  dr=(54004000)(2000)2(600)

  dr=( 1400)( 20)12dr=2333.33=2334hr.

The total delay is dr=2334hr.

The number of vehicles that will be affected by the incident.

To calculate the number of vehicles that will be affected by the incident can be foundusing the following formula:

Number of vehicles affected = V×tinc.

Substituting the values, we have

  =5400×1.=5400Veh.

The number of vehicles that will be affected by the incident is 5400Veh.

To calculate the average individual delay, we have the following formula:

Average individual delay =drNumber of vehicles affected 

Substituting the values, we have

  Averageindividual delay=drNumber of vehicles affected =23345400.=0.432hr.

The average individual is 0.432hr.

For the expected repair period of 1.5 hour.

We have the following formula for the determination of maximum queue length that will be formed:

  qmax=(VCr)tinc

Where, qmax is the maximum queue length,

  V is the total volume,

  Cr is the reduced capacity and,

  tinc is the duration of the incident.

Considering 90 percent of the flow and that the capacity of each lane is 2000 Veh/ h

Substituting the values in the following equation, we have

  qmax=(VCr)tincqmax=(( 90%of6000)4000)2qmax=(( 6000× 90 100 )4000)2qmax=(( 60×90)4000)2qmax=(54004000)2qmax=2800Veh.

Themaximum queue length that will be formed is qmax=2800Veh.

Now, the total delay, we have the following formula

  dr=tinc2(VCR)(CCR)2(CV)

Where, CR is the reduced capacity and can be found as follows:

  CR=Numberoflanesinuse×capacityofeachlane.CR=2000×(31).CR=2000×2=4000Veh/h.

And C is the total capacity and can be found as

  C=Totalnumberoflanesinuse×capacityofeachlane.C=2000×3.C=6000Veh/h.

Now, substituting the values in the required equation, we have

  dr=t inc2( V C R )( C C R )2( CV)dr= 1.52( 90%of60004000)( 60004000)2( 60005400)dr=2.25( 54004000)( 2000)2( 600)dr=2.25( 1400)( 20)12dr=5250hr.

The total delay is dr=5250hr.

The number of vehicles that will be affected by the incident.

To calculate the number of vehicles that will be affected by the incident can be found using the following formula:

Number of vehicles affected = V×tinc.

Substituting the values, we have

  =5400×1.5.=8100Veh.

The number of vehicles that will be affected by the incident is 8100Veh.

To calculate the average individual delay, we have the following formula:

Average individual delay =drNumber of vehicles affected 

Substituting the values, we have

  Averageindividual delay=drNumber of vehicles affected =52508100.=0.648hr.

Theaverage individualdelay is 0.648hr.

For the expected repair period of 2.5 hour.

We have the following formula for the determination of maximum queue length that will be formed:

  qmax=(VCr)tinc

Where, qmax is the maximum queue length,

  V is the total volume,

  Cr is the reduced capacity and,

  tinc is the duration of the incident.

Considering 90 percent of the flow and that the capacity of each lane is 2000 Veh/ h

Substituting the values in the following equation, we have

  qmax=(VCr)tincqmax=(( 90%of6000)4000)2qmax=(( 6000× 90 100 )4000)2qmax=(( 60×90)4000)2qmax=(54004000)2qmax=2800Veh.

The maximum queue length that will be formed is qmax=2800Veh.

Now, the total delay, we have the following formula

  dr=tinc2(VCR)(CCR)2(CV)

Where, CR is the reduced capacity and can be found as follows:

  CR=Numberoflanesinuse×capacityofeachlane.CR=2000×(31).CR=2000×2=4000Veh/h.

And C is the total capacity and can be found as

  C=Totalnumberoflanesinuse×capacityofeachlane.C=2000×3.C=6000Veh/h.

Now, substituting the values in the required equation, we have

  dr=t inc2( V C R )( C C R )2( CV)dr= 2.52( 90%of60004000)( 60004000)2( 60005400)dr=6.25( 54004000)( 2000)2( 600)dr=6.25( 1400)( 20)12dr=14583.33hr.dr=14584hr.

The total delay is dr=14584hr.

The number of vehicles that will be affected by the incident.

To calculate the number of vehicles that will be affected by the incident can be found using the following formula:

Number of vehicles affected = V×tinc.

Substituting the values, we have

  =5400×2.5.=13500Veh.

Therefore, the number of vehicles that will be affected by the incident is 13500Veh.

To calculate the average individual delay, we have the following formula:

Average individual delay =drNumber of vehicles affected 

Substituting the values, we have

  Averageindividual delay=drNumber of vehicles affected =1458413500.=1.0803hr.

The average individualdelay is 1.0803hr.

For the expected repair period of 2.75 hour.

We have the following formula for the determination of maximum queue length that will be formed:

  qmax=(VCr)tinc

Where, qmax is the maximum queue length,

  V is the total volume,

  Cr is the reduced capacity,

  tinc is the duration of the incident.

Considering 90 percent of the flow and that the capacity of each lane is 2000 Veh/ h

Substituting the values in the following equation, we have

  qmax=(VCr)tincqmax=(( 90%of6000)4000)2qmax=(( 6000× 90 100 )4000)2qmax=(( 60×90)4000)2qmax=(54004000)2qmax=2800Veh.

Therefore, the maximum queue length that will be formed is qmax=2800Veh.

Now, the total delay, we have the following formula

  dr=tinc2(VCR)(CCR)2(CV)

Where, CR is the reduced capacity and can be found as follows:

  CR=Numberoflanesinuse×capacityofeachlane.CR=2000×(31).CR=2000×2=4000Veh/h.

And C is the total capacity and can be found as

  C=Totalnumberoflanesinuse×capacityofeachlane.C=2000×3.C=6000Veh/h.

Now, substituting the values in the required equation, we have

  dr=t inc2( V C R )( C C R )2( CV)dr= 2.752( 90%of60004000)( 60004000)2( 60005400)dr=7.5625( 54004000)( 2000)2( 600)dr=7.5625( 1400)( 20)12dr=17645.83hr.dr=17646hr.

Therefore, the total delay is dr=17646hr.

The number of vehicles that will be affected by the incident.

To calculate the number of vehicles that will be affected by the incident can be found using the following formula:

Number of vehicles affected = V×tinc.

Substituting the values, we have

  =5400×2.75.=14850Veh.

The number of vehicles that will be affected by the incident is 14850Veh.

To calculate the average individual delay, we have the following formula:

Average individual delay =drNumber of vehicles affected 

Substituting the values, we have

  Averageindividual delay=drNumber of vehicles affected =1764614850.=1.188hr.

the average individual delay is 1.188hr.

For the expected repair period of 3.0 hour.

We have the following formula for the determination of maximum queue length that will be formed:

  qmax=(VCr)tinc

Where, qmax is the maximum queue length,

  V is the total volume,

  Cr is the reduced capacity and,

  tinc is the duration of the incident.

Considering 90 percent of the flow and that the capacity of each lane is 2000 Veh/ h

Substituting the values in the following equation, we have

  qmax=(VCr)tincqmax=(( 90%of6000)4000)2qmax=(( 6000× 90 100 )4000)2qmax=(( 60×90)4000)2qmax=(54004000)2qmax=2800Veh.

The maximum queue length that will be formed is qmax=2800Veh.

Now, the total delay, we have the following formula

  dr=tinc2(VCR)(CCR)2(CV)

Where, CR is the reduced capacity and can be found as follows:

  CR=Numberoflanesinuse×capacityofeachlane.CR=2000×(31).CR=2000×2=4000Veh/h.

And C is the total capacity and can be found as

  C=Totalnumberoflanesinuse×capacityofeachlane.C=2000×3.C=6000Veh/h.

Now, substituting the values in the required equation, we have

  dr=t inc2( V C R )( C C R )2( CV)dr= 3.02( 90%of60004000)( 60004000)2( 60005400)dr=9.0( 54004000)( 2000)2( 600)dr=9.0( 1400)( 20)12dr=21000.00hr.

The total delay is dr=21000.00hr.

The number of vehicles that will be affected by the incident.

To calculate the number of vehicles that will be affected by the incident can be found using the following formula:

Number of vehicles affected = V×tinc.

Substituting the values, we have

  =5400×3.00.=16200Veh.

The number of vehicles that will be affected by the incident is 16200Veh.

To calculate the average individual delay, we have the following formula:

Average individual delay =drNumber of vehicles affected 

Substituting the values, we have

  Averageindividual delay=drNumber of vehicles affected =2100016200.=1.30hr.

The average individual delay is 1.30hr.

Plot the graph of average individual delay versus the repair period is as follows:

  MindTap Engineering for Garber/Hoel's Traffic and Highway Engineering, 5th Edition, [Instant Access], 1 term (6 months), Chapter 6, Problem 19P , additional homework tip  2

Conclusion:

Therefore, for 1.0 hour : Themaximum queue length that will be formed is qmax=2800Veh, total delay is dr=2334hr ,number of vehicles that will be affected by the incident is 5400Veh and theaverage individual is 0.432hr.

For 1.5hour:

Themaximum queue length that will be formed is qmax=2800Veh ,total delay is dr=5250hr ,number of vehicles that will be affected by the incident is 8100Veh and the average individual is 0.648hr.

For 2.50hour:

Themaximum queue length that will be formed is qmax=2800Veh.

The total delay is dr=14584hr.

The number of vehicles that will be affected by the incident is 13500Veh.

The average individual delayis 1.0803hr.

For 2.75hour:

Themaximum queue length that will be formed is qmax=2800Veh.

The total delay is dr=9334hr.

The number of vehicles that will be affected by the incident is 10800Veh.

The average individual delay is 1.188hr.

For 3.0 hour:

Themaximum queue length that will be formed is qmax=2800Veh.

The total delay is dr=21000.00hr.

The number of vehicles that will be affected by the incident is 16200Veh.

The average individual delay is 1.30hr.

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