started at the beginning of the day. (Do not round intermediate calculations. Round down your answer to the next smallest integer.) the supporter is not included in efficiency calculations. (Round your answer to 2 decimal places.) 2. When the assembly line designed by the engineers is running at maximum capacity, what is the efficiency of the line relative to its use of labor? Assume that 3. If the line were to be redesigned to operate at the initial 240 units per day target, assuming that no overtime will be used, what would be the maximum allowable cycle time? Develop an assembly line using the fewest possible workstations for the allowable cycle time (HINT: use the longest task time rule for values to the next smallest integer.) assigning the tasks). What would be the efficiency of the new design? (Round your "Efficiency" answer to 2 decimal places. Round down "maximum cycle time" day? (Round your answer to 1 decimal place.) 4. What about running the line at 300 units per day? If overtime were used with the engineers' initial design, how much overtime would be needed each rate? (Round down "maximum cycle time values to the next smallest integer.) 5. If the assembly line is to be redesigned to operate at 300 units per day without using overtime, what is the maximum cycle time to meet this production answer to 2 decimal places.) 6. Develop an assembly line layout with the fewest possible assembly line positions and the fewest possible workstations with labor to produce 300 units per day without using overtime (HINT: use the longest task time rule for assigning the tasks). What is the efficiency of this new assembly line layout? (Round your 7. In your new layout, how many workstations include labor? started at the beginning of the day. (Do not round intermediate calculations. Round down your answer to the next smallest integer.) the supporter is not included in efficiency calculations. (Round your answer to 2 decimal places.) 2. When the assembly line designed by the engineers is running at maximum capacity, what is the efficiency of the line relative to its use of labor? Assume that 3. If the line were to be redesigned to operate at the initial 240 units per day target, assuming that no overtime will be used, what would be the maximum allowable cycle time? Develop an assembly line using the fewest possible workstations for the allowable cycle time (HINT: use the longest task time rule for values to the next smallest integer.) assigning the tasks). What would be the efficiency of the new design? (Round your "Efficiency" answer to 2 decimal places. Round down "maximum cycle time" day? (Round your answer to 1 decimal place.) 4. What about running the line at 300 units per day? If overtime were used with the engineers' initial design, how much overtime would be needed each rate? (Round down "maximum cycle time values to the next smallest integer.) 5. If the assembly line is to be redesigned to operate at 300 units per day without using overtime, what is the maximum cycle time to meet this production answer to 2 decimal places.) 6. Develop an assembly line layout with the fewest possible assembly line positions and the fewest possible workstations with labor to produce 300 units per day without using overtime (HINT: use the longest task time rule for assigning the tasks). What is the efficiency of this new assembly line layout? (Round your 7. In your new layout, how many workstations include labor? started at the beginning of the day. (Do not round intermediate calculations. Round down your answer to the next smallest integer.) the supporter is not included in efficiency calculations. (Round your answer to 2 decimal places.) 2. When the assembly line designed by the engineers is running at maximum capacity, what is the efficiency of the line relative to its use of labor? Assume that 3. If the line were to be redesigned to operate at the initial 240 units per day target, assuming that no overtime will be used, what would be the maximum allowable cycle time? Develop an assembly line using the fewest possible workstations for the allowable cycle time (HINT: use the longest task time rule for values to the next smallest integer.) assigning the tasks). What would be the efficiency of the new design? (Round your "Efficiency" answer to 2 decimal places. Round down "maximum cycle time" day? (Round your answer to 1 decimal place.) 4. What about running the line at 300 units per day? If overtime were used with the engineers' initial design, how much overtime would be needed each rate? (Round down "maximum cycle time values to the next smallest integer.) 5. If the assembly line is to be redesigned to operate at 300 units per day without using overtime, what is the maximum cycle time to meet this production answer to 2 decimal places.) 6. Develop an assembly line layout with the fewest possible assembly line positions and the fewest possible workstations with labor to produce 300 units per day without using overtime (HINT: use the longest task time rule for assigning the tasks). What is the efficiency of this new assembly line layout? (Round your 7. In your new layout, how many workstations include labor? started at the beginning of the day. (Do not round intermediate calculations. Round down your answer to the next smallest integer.) the supporter is not included in efficiency calculations. (Round your answer to 2 decimal places.) 2. When the assembly line designed by the engineers is running at maximum capacity, what is the efficiency of the line relative to its use of labor? Assume that 3. If the line were to be redesigned to operate at the initial 240 units per day target, assuming that no overtime will be used, what would be the maximum allowable cycle time? Develop an assembly line using the fewest possible workstations for the allowable cycle time (HINT: use the longest task time rule for values to the next smallest integer.) assigning the tasks). What would be the efficiency of the new design? (Round your "Efficiency" answer to 2 decimal places. Round down "maximum cycle time" day? (Round your answer to 1 decimal place.) 4. What about running the line at 300 units per day? If overtime were used with the engineers' initial design, how much overtime would be needed each rate? (Round down "maximum cycle time values to the next smallest integer.) 5. If the assembly line is to be redesigned to operate at 300 units per day without using overtime, what is the maximum cycle time to meet this production answer to 2 decimal places.) 6. Develop an assembly line layout with the fewest possible assembly line positions and the fewest possible workstations with labor to produce 300 units per day without using overtime (HINT: use the longest task time rule for assigning the tasks). What is the efficiency of this new assembly line layout? (Round your 7. In your new layout, how many workstations include labor? started at the beginning of the day. (Do not round intermediate calculations. Round down your answer to the next smallest integer.) the supporter is not included in efficiency calculations. (Round your answer to 2 decimal places.) 2. When the assembly line designed by the engineers is running at maximum capacity, what is the efficiency of the line relative to its use of labor? Assume that 3. If the line were to be redesigned to operate at the initial 240 units per day target, assuming that no overtime will be used, what would be the maximum allowable cycle time? Develop an assembly line using the fewest possible workstations for the allowable cycle time (HINT: use the longest task time rule for values to the next smallest integer.) assigning the tasks). What would be the efficiency of the new design? (Round your "Efficiency" answer to 2 decimal places. Round down "maximum cycle time" day? (Round your answer to 1 decimal place.) 4. What about running the line at 300 units per day? If overtime were used with the engineers' initial design, how much overtime would be needed each rate? (Round down "maximum cycle time values to the next smallest integer.) 5. If the assembly line is to be redesigned to operate at 300 units per day without using overtime, what is the maximum cycle time to meet this production answer to 2 decimal places.) 6. Develop an assembly line layout with the fewest possible assembly line positions and the fewest possible workstations with labor to produce 300 units per day without using overtime (HINT: use the longest task time rule for assigning the tasks). What is the efficiency of this new assembly line layout? (Round your 7. In your new layout, how many workstations include labor? started at the beginning of the day. (Do not round intermediate calculations. Round down your answer to the next smallest integer.) the supporter is not included in efficiency calculations. (Round your answer to 2 decimal places.) 2. When the assembly line designed by the engineers is running at maximum capacity, what is the efficiency of the line relative to its use of labor? Assume that 3. If the line were to be redesigned to operate at the initial 240 units per day target, assuming that no overtime will be used, what would be the maximum allowable cycle time? Develop an assembly line using the fewest possible workstations for the allowable cycle time (HINT: use the longest task time rule for values to the next smallest integer.) assigning the tasks). What would be the efficiency of the new design? (Round your "Efficiency" answer to 2 decimal places. Round down "maximum cycle time" day? (Round your answer to 1 decimal place.) 4. What about running the line at 300 units per day? If overtime were used with the engineers' initial design, how much overtime would be needed each rate? (Round down "maximum cycle time values to the next smallest integer.) 5. If the assembly line is to be redesigned to operate at 300 units per day without using overtime, what is the maximum cycle time to meet this production answer to 2 decimal places.) 6. Develop an assembly line layout with the fewest possible assembly line positions and the fewest possible workstations with labor to produce 300 units per day without using overtime (HINT: use the longest task time rule for assigning the tasks). What is the efficiency of this new assembly line layout? (Round your 7. In your new layout, how many workstations include labor? started at the beginning of the day. (Do not round intermediate calculations. Round down your answer to the next smallest integer.) the supporter is not included in efficiency calculations. (Round your answer to 2 decimal places.) 2. When the assembly line designed by the engineers is running at maximum capacity, what is the efficiency of the line relative to its use of labor? Assume that 3. If the line were to be redesigned to operate at the initial 240 units per day target, assuming that no overtime will be used, what would be the maximum allowable cycle time? Develop an assembly line using the fewest possible workstations for the allowable cycle time (HINT: use the longest task time rule for values to the next smallest integer.) assigning the tasks). What would be the efficiency of the new design? (Round your "Efficiency" answer to 2 decimal places. Round down "maximum cycle time" day? (Round your answer to 1 decimal place.) 4. What about running the line at 300 units per day? If overtime were used with the engineers' initial design, how much overtime would be needed each rate? (Round down "maximum cycle time values to the next smallest integer.) 5. If the assembly line is to be redesigned to operate at 300 units per day without using overtime, what is the maximum cycle time to meet this production answer to 2 decimal places.) 6. Develop an assembly line layout with the fewest possible assembly line positions and the fewest possible workstations with labor to produce 300 units per day without using overtime (HINT: use the longest task time rule for assigning the tasks). What is the efficiency of this new assembly line layout? (Round your 7. In your new layout, how many workstations include labor