advertisement
Mini Launcher
ME-6825B
Instruction Manual
012-15390A
800-772-8700 www.pasco.com
+1 916 462 8384 [email protected]
Mini Launcher Table of Contents
Contents
Equipment . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1
Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2
General Operation of the Mini Launcher . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3
Installation of the Optional Photogate Bracket. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4
Installing the 2-Dimensional Collision Accessory. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4
Expectations for the Mini Launcher . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5
Launch Positions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5
Experiments
1. Projectile Motion . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .7
2. Projectile Motion Using Photogates . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11
3. Projectile Range versus Angle . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15
4. Projectile Path. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 19
5. Conservation of Energy. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 23
6. Conservation of Momentum in Two Dimensions. . . . . . . . . . . . . . . . . . . . . . . . . 27
7. Varying Angle to Maximize Height on a Wall . . . . . . . . . . . . . . . . . . . . . . . . . . . 31
8. Demo: Do 30° and 60° Give Same Range . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 33
9. Demo: Shoot Two Balls Horizontally at Different Speeds. . . . . . . . . . . . . . . . . . 35
10.Demo: Shooting through Hoops . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 37
Technical Support . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 40
Warranty, Copyright, and Trademarks. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 40
Mini Launcher
ME-6825B
(8)
(1)
(2)
(3)
(4)
(7)
(6)
(5)
Included Items
(1) Safety Glasses
(2) Mini Launcher Stand
(3) Steel balls, 16 mm (2)
(4) Pushrod
Recommended Items*
Large C-clamp (SE-7285, pack of six)
45 cm Stainless Steel Rod (ME-8736
®
Included Items
(5) 2-D Collision Accessory
(6) Mini Launcher
(7) Metal Weight
(8) Lanyard
Large Table Clamp (ME-9472)
Launcher Spare Weights (ME-9868, 24-pack)
1
2
Mini Launcher Introduction
Other Items*
Smart Gate (PS-2180) or Photogate Head (ME-9498A)
Photogate Mounting Bracket (ME-6821A)
Time-of-Flight Accessory (ME-6810A)
Mini Launcher Ballistic Pendulum Accessory (ME-6829)
(*See the PASCO catalog or the PASCO web site at www.pasco.com for more information.)
Introduction
The PASCO Mini Launcher has been designed for projectile experiments and demonstrations. The only additional equipment required is a C-clamp for clamping the stand to a table or a Large Table
Clamp (ME-9472) for clamping the stand to a support rod. The features of the Mini Launcher include:
• LAUNCH AT ANY ANGLE Between -45° and 90°:
Protractor
The ball can be launched at any angle from 0 to 90 degrees measured above the horizontal. The mag netic piston holds the steel ball in position for launch at any angle from 0 to 45 degrees measured below the horizontal.
The angle is easily adjusted using the thumb screws.
The built-in protractor and metal weight on the side of the launcher give a convenient and accurate way of determining the angle of inclination.
• THREE RANGE SETTINGS:
Metal weight
0 0.5 m 1 m 2 m
There are three ranges from which to choose. They are approximately 0.5 meter, 1.0 meter, and 2.0 meters, when the angle is 45 degrees and measured from table top to table top.
012-15390A ®
ME-6825B General Operation
• FIXED ELEVATION INDEPENDENT OF ANGLE:
The Mini Launcher can be mounted so that the barrel pivots at the muzzle end and the elevation of the ball as it leaves the barrel does not change as the angle is varied.
• REPEATABLE RESULTS:
There is no spin on the ball since the piston keeps the ball from rubbing on the walls as it travels up the barrel. The sturdy base can be secured to a table with a C-clamp or a Large Table
Clamp (not included) so there is very little recoil. The trigger is pulled with a lanyard to minimize jerking.
• COMPUTER COMPATIBLE:
Ball center of mass
Outer edge of ball
A Smart Gate or Photogates may be attached with a Photogate Mounting Bracket (ME-6821A) to con nect the Mini Launcher to a computing device to measure the muzzle speed. You can also use a
Time-of-Flight Accessory and a Smart Gate or Photogate to measure the time of flight.
General Operation
Ready
Always wear safety goggles when you are in a room where the Mini Launcher is being used.
CAUTION: Never look down the front of the barrel because it may be loaded. Safety goggles are provided for use when operating the Mini Launcher. Always assume that the barrel is loaded!
The base of the Mini Launcher can be fastened to the edge of a table using a clamp of your choice.
See the Launch Position Examples section for mounting options. When shooting onto the floor, mount the launcher so that the muzzle is even with or slightly beyond the end of the table This will allow you to use a plumb bob to locate the point on the floor directly below the muzzle.
The Mini Launcher can be mounted to shoot onto a table such that the launch position of the ball is at the same height as the landing position on the table.
NOTE: To prevent the steel ball from denting the floor or table top, you may want to place a protective covering on the surface.
Aim
The angle of inclination is adjusted by loosening the thumb screws on the back of the stand and rotat ing the barrel of the Mini Launcher to the desired angle above or below the horizontal as indicated by the hanging weight and protractor on the side of the Mini Launcher. (See the Launch Position Exam ples section.) When the Mini Launcher is at the desired angle, tighten the thumb screws.
Load
Always cock the Launcher with a ball in the piston. NOTE : Use only 16 millimeter steel balls with the
Mini Launcher.
®
012-15390A
3
4
Mini Launcher Installing the Optional Photogate Bracket
Place a ball in the barrel. Push the ball down the barrel with the pushrod until the trigger catches a notch on the piston. One audi ble click indicates that the trigger is holding the piston at position 1, the shortest range setting. Two clicks indicate that the piston is cocked at position 2, the medium range setting. Three clicks indi cate that the piston is cocked at position 3, the long range setting.
Remove the pushrod and return it to its holder on the stand.
CAUTION : Do not push a ball down the barrel with your finger.
Your knuckle may get stuck.
Shoot
Before launching the ball, make certain that no person is in the way.
To shoot the ball, pull upward on the lanyard to release the trigger. It is only necessary to pull upward about a centimeter.
Storage
Store the Mini Launcher with the spring uncompressed. (Do not leave it in a cocked position.)
Installing the Optional Photogate Bracket
The Photogate Mounting Bracket is an optional accessory for mounting a Smart Gate or one or two
Photogates on the front of the Mini Launcher. Using a Smart Gate or Photogates and a computing device with a PASCO Interface and Data Collection Software is one way to determine the muzzle velocity of the ball.
Installation is as follows:
• Prepare the Photogate Mounting
Bracket by loosening the thumb screw near the end of the bracket that holds the square nut. Attach the Smart Gate or
Photogate(s) to the bracket by placing the Smart Gate or Photogate between the alignment ridges on the bracket and fastening them in place with the small thumb screw(s).
• Align the square nut with the T-slot on the bottom of the Mini Launcher barrel and slide the nut into the slot. Slide the bracket into the slot until the Smart Gate or Photogate closest to the barrel is as close as possible without blocking the infrared beam. Tighten the thumbscrew to secure the bracket.
Photogate
T-slot
Thumb screw
Mini Launcher barrel
Square nut Photogate Mounting
Bracket
Smaller thumb screws
• When storing the Mini Launcher, the photogate mounting bracket does not need to be removed.
Slide it back along the barrel with or without photogates in place, making the package as compact as possible.
012-15390A ®
ME-6825B Installing the 2-Dimensional (2-D) Collision Accessory
Installing the 2-Dimensional (2-D) Collision Accessory
The 2-D Collision Accessory consists of a thumbscrew, a square nut, and a molded plastic piece. The plastic piece has text on both sides. One side is “PASCO 2-D COLLI -
SION ACCESSORY” and the other side is “USE THIS
SIDE FOR MINI LAUNCHER”. (The item can be used with any PASCO Projectile Launcher.)
T-Slot
Assemble the 2-D Collision Accessory with the “USE
THIS SIDE FOR MINI LAUNCHER” facing up. Put the thumbscrew through the hole from the bottom and add the square nut from the top. Leave the thumbscrew slightly loose.
Square nut
Post
Thumbscrew
Align the square nut with the T-slot on the bottom of the
Mini Launcher barrel and slide the square nut into it. To
Plastic piece use the 2-D Collision Accessory, place a ball on the top of the post. Rotate the 2-D Collision Accessory to one side or the other until the ball on the post is in a position where it will be hit by a launched ball at the angle that you want (without causing the launched ball to bounce back against the barrel).
Expectations for the Mini Launcher
The following are helpful hints and approximate values you may find useful:
• The muzzle speed will vary slightly with angle. The difference between muzzle speed when shot horizontally versus vertically can be anywhere from zero to eight percent, depending on the range setting and the particular launcher.
• The scatter pattern is minimized when the Mini Launcher stand is securely clamped to a sturdy table. Any wobble in the table will show up in the data.
• The angle of inclination can be determined to within one- half of a degree with the protractor.
Launch Position Examples
The Mini Launcher barrel can be attached to the stand in more than one way. The square nuts in the
T-slot on the side of the barrel can slide from end-to-end of the T-slot. The plastic divider in the T-slot between the square nuts keeps the nuts in proper position relative to each other.
The stand has a lower pivot hole marked as upper pivot hole marked as
and an and an upper curved slot and a lower curved slot. The upper curved slot allows the Mini Launcher to shoot the ball at a positive or a negative angle. The lower curved slot allows launch angles from 0 to 90°.At the same height as the upper pivot hole and at the front edge of the stand is an align ment tab marked as .
-45 to 90° curved slot
0 to 90° curved slot When the barrel is mounted in the upper position, the muzzle end of the T-slot on the side of the Mini
Launcher barrel can slide forward to fit over the align ment tab ( ).
Upper pivot hole
Lower pivot hole
Allignment tab
®
012-15390A
5
Mini Launcher
• Example 1: Clamp the Mini Launcher stand to a table and mount the barrel in the lower position with the muzzle aligned with the pivot hole ( ). The Mini
Launcher will be able to shoot onto the table from the same level as the table. To do this, slide the square nut that the barrel pivots around to the front of the T-slot on the side of the launcher. The ball is launched with a positive angle at table level. When you change the angle of the launcher, the elevation of the launch position does not change.
• Example 2: Clamp the Mini Launcher base to a table and mount the barrel in the upper position on the stand using the upper pivot hole ( launcher fits over the alignment tab (
barrel forward so that the T-slot on the side of the
). Slide the
). Put the muzzle even with or slightly beyond the front edge of the stand when using the Mini Launcher Ballistic
Pendulum Accessory (ME-6829). In this position the launch angle is 0° to shoot the ball horizontally from a constant height.
• Example 3A: Clamp the Mini Launcher base to the side edge of a table. Mount the launcher in the lower position to shoot from the table onto the floor at a positive angle from the same elevation.
• Example 3B: Mount the launcher in the upper posi tion to shoot from the table onto the floor at a nega tive angle from the same elevation.
• Example 4: Mount the Mini Launcher stand on a vertical support rod. Put the barrel in any of the positions described above.
Launch Position Examples
Example 1
Example 2
Example 3A
Example 3B
Example 4
6 012-15390A ®
ME-6825B
Exp. 1: Projectile Motion
Equipment Needed
Item
Mini Launcher and ball
Meter stick
White paper
Item
Plumb bob and string
Carbon paper
Sticky tape
Exp. 1: Projectile Motion
Purpose
The purpose of this experiment is to predict and verify the range of a ball launched at an angle. The initial speed of the ball is determined by shooting it horizontally and measuring the range of the ball and the height of the muzzle of the Mini Launcher.
Theory
To predict where a ball will land on the floor when it is shot from the Launcher at some angle above the horizontal, it is first necessary to determine the initial speed (muzzle velocity) of the ball. That can be determined by shooting the ball horizontally from the Mini Launcher and measuring the vertical and horizontal distances that the ball travels. The initial speed can be used to calculate where the ball will land when the ball is shot at an angle above the horizontal.
Initial Horizontal Speed
For a ball shot horizontally from a table with an initial speed, ball is given by x = v
0 t , where t v
0
, the horizontal distance travelled by the
is the time the ball is in the air. (Neglect air friction.)
The vertical distance of the ball is the distance it drops in time t given by y =
.
1
2 gt
2
The initial speed can by determined by measuring using x and y . The time of flight, t , of the ball can be found t =
2 y g and the initial horizontal speed can be found using v
0
= t
.
Initial Speed at an Angle
To predict the horizontal range, x, of a ball shot with an initial speed, v
0
, at an angle, , above the horizontal, first predict the time of flight from the equation for the vertical motion: y = y
0
+ v
0 sin t –
1
2 gt
2 where y
0
is the initial height of the ball and component of the initial speed.
y is the position of the ball when it hits the floor. In other t and then use x = v
0 cos t where v
0
cos is the horizontal
® 012-15390A 7
Mini Launcher
8
Exp. 1: Projectile Motion
Setup
1. Clamp the Mini Launcher stand to a sturdy table or other horizontal surface with the launcher aimed away from the table.
1. Mount the Mini Launcher in the upper position with the T-slot at the muzzle end on the alignment tab.
• In this position the Mini Launcher will launch the ball horizontally.
Part A: Determining the Initial Horizontal Speed of the Ball
1. Put a ball in the Mini Launcher and use the push-rod to cock it at the long range position. Fire one shot to locate where the ball hits the floor. At that point, tape a piece of white paper to the floor.
Place a piece of carbon paper (carbon-side down) on top of the white paper and tape it in place.
• When the ball hits the carbon paper on the floor, it will leave a mark on the white paper.
2. Fire ten shots.
3. Measure the vertical distance from the bottom of the ball as it leaves the barrel to the floor. Record this distance in the Data Table.
4. Use a plumb bob to find the point on the floor that is directly beneath the release point on the barrel. Measure the horizontal distance along the floor from the release point to the leading edge of the piece of white paper. Record the distance in the Data Table.
5. Carefully remove the carbon paper and measure from the leading edge of the white paper to each of the ten dots. Record these distances in the Data Table and find the average. Calculate and record the total horizontal distance (distance to paper plus average distance from edge of paper to dots).
Bottom of ball
6. Using the vertical distance, y , and the total horizontal distance, the initial horizontal speed of the ball, v x , calculate the time of flight,
0
. Record the time and speed in the Data Table.
t , and
Part B: Predicting the Range of a Ball Shot at an Angle
1. Adjust the angle of the Mini Launcher to an angle between 30 and
60 degrees. Record this angle in the second Data Table.
2. Using the initial speed and vertical distance from the first part of this experiment, calculate the new time of flight and the new horizontal distance based on the assumption that the ball is shot at the new angle you have just selected. Record the predictions in the second Data Table.
3. Draw a line across the middle of a white piece of paper and tape the paper on the floor so that the line on the paper is at the predicted horizontal distance from the
Mini Launcher. Cover the white paper with carbon paper (carbon side down) and tape the carbon paper in place.
4. Shoot the ball ten times.
5. Carefully remove the carbon paper. Measure the distances to the ten dots and record the distances in the second Data Table.
012-15390A ®
ME-6825B Exp. 1: Projectile Motion
Data Table A: Determine the Initial Speed
Vertical distance = _____________ Horizontal distance to edge of paper = _________________
Calculated time of flight = ________________ Initial speed = _____________
Trial
7
8
5
6
3
4
1
2
9
10
Average
Total Distance
Distance
Data Table B: Predict the Range
Angle above horizontal = _____________ Horizontal distance to edge of paper = _________________
Calculated time of flight = ________________ Predicted range = _____________
Trial
7
8
5
6
3
4
1
2
9
10
Average
Total Distance
Distance
® 012-15390A 9
Mini Launcher Exp. 1: Projectile Motion
Analysis
1. Calculate the percent error between the predicted theoretical distance and the actual average distance when shot at an angle.
theoretical actual theoretical x 100
2. Estimate the precision of the predicted range. How many of the final 10 shots landed within this range?
Notes
10 012-15390A ®
ME-6825B Exp. 2: Projectile Motion Using Photogates
Exp. 2: Projectile Motion Using Photogates
Equipment Needed
Item
Mini Launcher and ball
Item
Plumb bob and string
Photogate Head ME-9498A (2) OR PASCO Smart Gate PS-2180
Photogate Mounting Bracket ME-6821A
PASCO Interface* and PASCO Data Collection Software* OR Smart Timer* ME-8930
Meter stick
White paper
Carbon paper
Sticky tape
*See the PASCO web site at www.pasco.com for information about PASCO interfaces, timers, and software.
Purpose
The purpose of this experiment is to predict and verify the range of a ball launched at an angle.
Photogates are used to determine the initial speed of the ball.
Theory
To predict where a ball will land on the floor when it is shot from the Mini Launcher at some angle above the horizontal, it is first necessary to determine the initial speed (muzzle velocity) of the ball. The speed can be determined by shooting the ball and measuring a time using photogates. To predict the range, x , of the ball when it is shot with an initial speed at an angle, the time of flight using the equation for the vertical motion:
, above the horizontal, first predict y = y
0
+ v
0 sin t –
1
2 gt
2 where y
0
is the initial height of the ball and quadratic equation to find the time, y is the position of the ball when it hits the floor. Solve the t . Use x = ( v
0 cos t to predict the range.
Setup
1. Clamp the Mini Launcher to a sturdy table or other horizontal surface. Mount the Mini Launcher near one end of the table.
2. Adjust the angle of the Mini Launcher to an angle between 30 and 60 degrees and record the angle.
3. Attach the photogate mounting bracket to the Mini Launcher and attach one Smart Gate or two Photogate Heads to the bracket. If you are using photogates, check that the distance between the photogates is 0.10 m (10 cm).
4. Plug the Smart Gate or the two Photogate Heads into an interface. If you are using a timer, plug the two Photogate Heads into the timer.
® 012-15390A 11
Mini Launcher Exp. 2: Projectile Motion Using Photogates
Procedure
Part A: Determining the Initial Speed of the Ball
1. Put a ball in the Mini Launcher and use the push-rod to cock it at the long range position.
2. Setup the software to measure the time between the ball blocking the Smart Gate or the two
Photogate Heads. [OR set up a timer to measure the time between the ball blocking the two Pho togate Heads.
3. Shoot the ball three times and calculate the average of these times. Record the data in the Data
Table.
4. Calculate the initial speed of the ball based on the distance and the time. Record the value.
Data Table: Part A
Table 1: Determine the Initial Speed
Trial
1
2
3
Average Time
Initial Speed
Time
Part B: Predicting the Range of a Ball Shot at an Angle
1. Keep the angle of the Mini Launcher at the original angle above horizontal.
2. Measure the vertical distance from the bottom of the ball as it leaves the barrel to the floor. Record this distance in the second Data Table.
3. Use the vertical distance, the angle, and the initial speed to calculate the time of flight. Record the value.
12 y = y
0
+ v
0 sin t –
1
2 gt
2
Bottom of ball
4. Use the time of flight, distance
(range, x = ( v
0 cos t t , angle, , and initial speed, v
). Record the predicted range.
0
, to predict the horizontal
5. Draw a line across the middle of a white piece of paper and tape the paper on the floor so the line is at the predicted horizontal distance. Cover the white paper with carbon paper and tape the carbon paper in place.
6. Use a plumb bob to find the point on the floor that is directly beneath the release point on the barrel. Measure the horizontal distance along the floor from the release point to the leading edge of the piece of white paper. Record the distance in the Data Table.
7. Shoot the ball ten times.
8. Carefully remove the carbon paper and measure from the leading edge of the white paper to each of the ten dots. Record these distances in the Data Table and find the average. Calculate and
012-15390A ®
ME-6825B Exp. 2: Projectile Motion Using Photogates record the total horizontal distance (distance to paper plus average distance from edge of paper to dots).
Angle above horizontal = ______________ Horizontal distance to edge of paper = _______________
Calculated time of flight = _________________ Predicted range = ________________
Data Table: Part B
Table 2: Confirm the Predicted Range
Trial
7
8
5
6
3
4
1
2
9
10
Average
Total Distance
Distance
Analysis
1. Calculate the percent error between the predicted theoretical distance and the actual average distance when shot at an angle.
theoretical actual theoretical x 100
2. Estimate the precision of the predicted range. How many of the final 10 shots landed within this range?
® 012-15390A 13
Mini Launcher
Notes
Exp. 2: Projectile Motion Using Photogates
14 012-15390A ®
ME-6825B Exp. 3: Projectile Range versus Angle
Exp. 3: Projectile Range versus Angle
Equipment Needed
Item
Mini Launcher and ball
Meter stick or measuring tape
White paper
Item
Plumb bob and string
Graph paper
Carbon paper
Purpose
The purpose of this experiment is to determine how the range of the ball depends on the launch angle.
The angle that gives the greatest range is determined for two cases: for shooting on level ground and for shooting off a table.
Theory
The range is the horizontal distance, projectile hits, given by x = ( v
0 cos x , between the muzzle of the Launcher and the place where the
t , where v
0
is the initial speed of the projectile as it leaves the muzzle, is the launch angle above horizontal, and t is the time of flight. See the figure.
υ
0
θ
x
Figure 3.1: Shooting on a level surface
For the case in which the projectile hits on a surface that is the same level as the level of the muzzle of the Launcher, the time of flight of the projectile will be twice the time it takes for the projectile to reach the peak of its trajectory. At the peak, the vertical speed is zero, so: v y
= 0 = v
0 sin – gt peak where v
0
is the initial speed of the projectile. Solving for the time gives an expression for the total time of flight as: t = 2 t peak
= 2 v sin g
For the case in which the projectile is launched at an angle above horizontal from a table onto the floor, the time of flight is found using the equation for vertical motion
: y = y
0
+ v
0 sin t –
1
2 gt
2 where y
0
is the initial height of the projectile in y is the vertical position of the ball when it hits the floor.
υ
0
θ y
0 x
Figure 3.2: Shooting from a table
® 012-15390A 15
Mini Launcher Exp. 3: Projectile Range versus Angle
Setup
1. Clamp the Mini Launcher stand to a sturdy table or other horizontal surface near one end of the table, but aim it toward the center of the table rather than away from the table.
2. Mount the barrel in the lower position on the stand. Align the muzzle with the lower pivot hole. Adjust the angle of the Mini
Launcher to 10 degrees.
3. Put a ball into the Mini Launcher and cock it to the medium or long range setting.
• Note: In general, the experiment will not work as well on the short range setting because the muzzle speed is more variable with the change in angle.
Figure 3.3: Shooting to a level surface
Procedure
Part A: Shooting to a Level Surface
1. Fire one shot to locate where the ball hits the table. Tape a piece of white paper on the table at this location. Tape a piece of carbon paper (carbon-side down) on top of the white paper.
• When the ball hits the carbon paper it will leave a mark on the white paper underneath.
2. Fire five shots.
3. Use a measuring tape to measure the horizontal distance from the muzzle to the leading edge of the paper. (If a measuring tape is not available, use a plumb bob to find the point on the table that is directly beneath the release point on the barrel and measure the distance along the table from the muzzle to the leading edge of the paper.) Record the distance in the Data Table.
4. Carefully remove the carbon paper. Measure from the leading edge of the paper to each of the five dots and record these distances in the Data Table.
5. Increase the launch angle by 10 degrees and repeat all the steps. Keep the muzzle at the same elevation.
6. Keep repeating for angles up to and including 80 degrees (the complementary angle of 10 degrees).
16 012-15390A ®
ME-6825B
Data Table: Part A
Exp. 3: Projectile Range versus Angle
Table 1: Shooting to a Level Surface
20 30 40 50 60 Angle
3
4
1
2
5
Average
Paper distance
Total distance
10
Part B: Shooting Off the Table
1. Turn the Mini Launcher so it will launch the ball to the floor.
2. Repeat the procedure and record the data in the Data Table.
Data Table: Part B
Table 2: Shooting off the Table
Angle
3
4
1
2
5
Average
Paper distance
Total distance
10 20 30 40 50 60
70
70
80
80
Analysis
1. Find the average of the five distances in each case and record the results in the Data Tables.
2. Add the average distance to the distance from the Mini Launcher to the leading edge of the white paper to get the total distance (range) in each case. Record the results in the Data Tables.
3. For each Data Table, plot the range versus the angle and draw a smooth curve through the points.
Questions
1. From the graph, what angle give the maximum range for each case?
2. Is the angle for the maximum range greater or less for shooting off the table?
3. Is the maximum range further when the ball is shot off the table or on the level?
® 012-15390A 17
Mini Launcher
Notes
Exp. 3: Projectile Range versus Angle
18 012-15390A ®
ME-6825B
Exp. 4: Projectile Path
Exp. 4: Projectile Path
Equipment Needed
Item
Mini Launcher and ball
Meter stick or measuring tape
Graph paper
White paper
Item
Movable vertical target board*
Sticky tape
Carbon paper
*The target board should be as tall as the distance from the muzzle to the floor.
Purpose
The purpose of this experiment is to determine how the vertical distance a projectile drops is related to the horizontal distance the projectile travels when the projectile is launched horizontally.
Theory
The range is the horizontal distance, the projectile hits, given by and t is the time of flight. x = v
0 x , between the muzzle of the Mini Launcher and the place where t , where v
0
is the initial speed of the projectile as it leaves the muzzle
If the projectile is launched horizontally, the time of flight of the projectile will be t = x
0
The vertical distance, y, that the projectile falls during time, t, is given by y =
1
2 gt
2 where g is the acceleration due to gravity. Substituting for t in the second equation gives y =
2 v
2
0
x
2
A plot of y versus x 2 will give a straight line with a slope equal to
2 v
2
0
Setup
.
1. Clamp the Mini Launcher to a sturdy table or other horizontal surface. Mount the Launcher near one end of the table with the
Launcher aimed away from the table.
2. Adjust the angle of the Mini
Launcher to zero degrees so the ball will be launched horizontally.
3. Fire a test shot on medium range to determine the
® 012-15390A
X
Target board
Figure 4.3: Launcher setup
Y
19
MiniLauncher Exp. 4: Projectile Path initial position of the vertical target board. Place the target board on the floor so that the ball hits the board near the bottom.
4. Cover the target board with white paper. Tape carbon paper over the white paper.
Procedure
1. Measure the vertical height from the floor to the muzzle and record the height in the Data Table.
Mark this height on the target.
2. Measure the horizontal distance from the muzzle of the Mini Launcher to the target board and record it in the Data Table.
3. Shoot the ball.
4. Move the target board about 10 to 20 cm closer to the Mini Launcher.
5. Repeat steps 2 through 4 until the height of the ball when it strikes the target board is about 10 to
20 cm below the height of the muzzle.
Data Table 4.1
Height of Muzzle = ____________________
Table 1: x, y Data
Horizontal (x) Vertical (y) x
2
20
Analysis
1. On the target board, measure the vertical distances from the muzzle level mark down to the ball marks and record them in Table 4.1.
2. Calculate x 2 for all the data points and record them in the Data Table.
3. Plot a graph of y versus x 2 and draw the best-fit light through the data points.
4. Calculate the slope of the graph and record it in Table 4.2.
5. From the slope of the graph, calculate the initial speed of the ball as it leaves the muzzle. Record the initial speed in Table 4.2.
012-15390A ®
ME-6825B Exp. 4: Projectile Path
6. Pick any
Calculate the initial speed using this time and the horizontal distance,
Table 4.2.
x , y data point from Table 4.1. Use the vertical distance, y , to calculate the time, t . x . Record the results in
7. Calculate the percent difference between the two initial speeds that were found using the different methods. Record the percent difference in Table 4.2. (To calculate the percent difference, let one of the initial speed values and let B be the other initial speed value.)
A be
------------------x 100
2
Data Table 4.2
Table 2: Compare Methods for Initial Speed
Value Item
Slope of graph
Initial speed from slope
Time of flight
Initial speed from x,y
Percent difference
Question
1. From the graph, was the best-fit line straight?
2. What does the shape of the best-fit line on the y versus x 2 y and x 2 ?
graph tell you about the relationship of
3. If you plotted a graph of y versus x, how would the graph differ from the y versus x 2 graph?
4. What shape is the path of the projectile?
® 012-15390A 21
MiniLauncher
Notes
Exp. 4: Projectile Path
22 012-15390A ®
ME-6825B
Exp. 5: Conservation of Energy
Exp. 5: Conservation of Energy
Equipment Needed
Item
Mini Launcher and ball
Meter stick or measuring tape
White paper
Item
Plumb bob and string
Sticky tape
Carbon paper
Smart Gate or Photogate Head (2) optional* Photogate Mounting Bracket ME-6821A optional*
*Use a Smart Gate or two Photogates and Photogate Mounting Bracket with a PASCO Interface or Timer to measure the initial speed of the ball directly (see Experiment 2).
Purpose
The purpose of this experiment is to confirm that the initial kinetic energy of a projectile shot straight up is transformed into an equal amount of gravitational potential energy.
Theory
The total mechanical energy of a projectile is the sum of its gravitational potential energy and its kinetic energy. In the absence of friction, total mechanical energy is conserved. When a projectile is shot straight up, the initial gravitational potential energy (GPE) can be defined as zero. The initial kinetic energy (KE) depends on the mass, the initial speed:
KE =
1
2 mv
0
2 m , of the projectile and
When the projectile reaches its maximum height, h , the speed of the projectile is zero and therefore the kinetic energy is zero. The gravitational potential energy depends on the mass of the projectile and the height:
GPE = mgh
V
0
Final height
Figure 5.1: Conservation of
Energy where g is the acceleration due to gravity. If friction in the form of air resistance is ignored, the initial kinetic energy should equal the final gravitational potential energy.
The initial speed of the projectile must be determined in order to calculate the initial kinetic energy. To calculate the initial speed, projectile is x = v
0 t where t v
0
, of a projectile fired horizontally, the horizontal distance travelled by the
is the time that the projectile is in the air.
The vertical distance that projectile drops in time, t , is given by y =
1
2 gt
2
υ
0 y
The initial speed of the projectile can be calculated by measuring x and y and using y to calculate the time, t.
The time of flight of the projectile can be found using t =
2 y g x
Figure 5.2: Find the initial speed
® 012-15390A 23
Mini Launcher Exp. 5: Conservation of Energy and then the initial speed can be found using v
0
= t
Setup
1. Clamp the Mini Launcher to a sturdy table or other horizontal surface. Mount the Mini Launcher near one end of the table with the launcher aimed away from the table.
2. Point the Launcher straight up and fire a test shot on medium range to make sure that the ball doesn’t hit the ceiling. (If it does, use the short range setting for this experiment or put the
Launcher closer to the floor.)
3. Adjust the angle of the Mini Launcher to zero degrees so the ball will be launched horizontally.
Procedure
Part A: Determine the Initial Speed (without photogates)
1. Put a ball into the Mini Launcher and cock it to the medium range setting. Fire one shot to locate where the ball hits the floor. At that position, tape a piece of white paper to the floor. Place a piece of carbon paper (carbon-side down) on top of the white paper and tape it in place
• When the ball hits the carbon paper, it will leave a mark on the white paper.
2. Fire ten shots.
3. Measure the vertical distance from the bottom of the ball as it leaves the barrel to the floor. Record this distance in the Table 5.1. Use the distance to calculate the time of flight and record it.
4. Use a plumb bob to find the point on the floor that is directly beneath the release point on the barrel. Measure the horizontal distance along the floor from the release point to the leading edge of the piece of white paper. Record the distance in Table 5.1.
5. Carefully remove the carbon paper. Measure from the leading edge of the white paper to each of the ten dots and record these distances in Table 5.1.
6. Find the average of the ten distances and record it.
7. Using the horizontal distance and the time of flight, calculate the initial speed of the ball. Record the speed.
24 012-15390A ®
ME-6825B
Data Table 5.1
Item
Vertical distance
Horizontal distance to edge of paper
Table 1:
Value
Exp. 5: Conservation of Energy
Item
Calculated time of flight
Initial speed
Value
3
4
1
2
5
Trial Distance Trial
8
9
6
7
10
Average
Total distance
Distance
Alternate Method for Determining the Initial Speed of the Ball (using photogates)
1. Attach a Photogate Mounting Bracket to the Mini Launcher and attach one Smart Gate or two
Photogate Heads to the bracket. .
2. Plug the Smart Gate into a PASCO interface, or plug the two Photogate Heads into a PASCO interface or a timer.
3. Adjust the angle of the Launcher to 90 degrees (straight up).
4. Put a ball in the Mini Launcher and use the push-rod to cock it at the medium range setting.
5. Setup the software or the timer to measure the time between the ball blocking the Smart Gate or the two Photogate Heads.
6. Shoot the ball three times and calculate the average of these times. Record the data in the Table
5.2.
7. Calculate the initial speed of the ball based on the time and the distance. Record the value.
Table 5.2
Table 2: Initial Speed Using Photogates
Trial
1
2
3
Average Time
Initial Speed
Time
® 012-15390A 25
Mini Launcher Exp. 5: Conservation of Energy
Part B: Measure the Height of the Ball
1. Adjust the angle of the Mini Launcher to 90 degrees (straight up).
2. Shoot the ball on the medium range setting several times and then measure the maximum height attained by the ball. Record the maximum height in Table 5.3.
3. Determine the mass of the ball and record it in Table 5.3.
Analysis
1. Calculate the initial kinetic energy and record it in Table 5.3.
2. Calculate the final gravitational potential energy and record it in Table 5.3.
3. Calculate the percent difference between the initial kinetic energy and the final gravitational potential energy and record it in Table 5.3
.
KE GPE x 100
2
Table 3: Results
Item
Maximum height of ball
Mass of ball
Initial Kinetic Energy
Final Potential Energy
Percent difference
Value
Questions
1. How does the initial kinetic energy compare to the final gravitational potential energy?
2. Does friction in the form of air resistance affect the result for the conservation of energy?
3. When the Mini Launcher is cocked, it has elastic potential energy. If energy is conserved, how should the elastic potential energy compare to the initial kinetic energy?
26 012-15390A ®
ME-6825B Exp. 6: Conservation of Momentum
Exp. 6: Conservation of Momentum
Equipment Needed
Item
Mini Launcher and 2 balls
Meter stick or measuring tape
White paper, large sheet
Protractor
Item
2-D Collision Accessory
Sticky tape
Carbon paper (2 or 3 sheets)
Plumb bob and string
Purpose
The purpose of this experiment is to confirm that momentum is conserved for elastic and inelastic collisions in two dimensions.
Theory
υ
1
A ball is shot toward another ball that is initially at rest, resulting in a collision after which the two balls move in different directions. In the system consisting of just the balls, both balls are falling under the influence of gravity so momentum is not conserved in the vertical direction. However, there is no net force in the horizontal plane (if air resistance is ignored), so momentum is conserved in the horizontal plane.
Before collision, since all the momentum is in the direction of Ball #1 ( m
1
), it is convenient to define the x-axis in this direction. Momentum before the collision is:
P before
= m
1 v
0 m
1
θ
1
υ
0 m
2
(
υ
= 0) m
1 m
2
(a)
θ
2
(a) before collision
(b)
(b) after collision
Figure 6.1: Conservation of Momentum
υ
2 where v
0
is the initial speed of Ball #1 and is the unit vector in the x-direction. The momenta of the after the collision is:
P after
= m
1 v
1 x
+ m
2 v
2 x
x + m
1 v
1 y
+ m
2 v
2 y
y where v
1 x
= v
1
cos
1
, v
1 y
= v
1
sin
1
. v
2 x
= v
2
cos
2
, and v
2 y
= v
2
sin
2
.
Since there is no momentum in the y-direction before the collision, there is zero net momentum in the y-direction after the collision. Therefore, t m
1 v
1 y
= – m
2 v
2 y
Equating the momentum in the x-direction before the collision to the momentum in the x-direction after the collision gives: m
1 v
0
= m
1 v
1 x
+ m
2 v
2 x
In a perfectly elastic collision, kinetic energy is conserved as well as momentum.
1
2 m
1 v
2
0
=
1
2 m
1 v
2
1
+
1
2 m
2 v
2
2
® 012-15390A 27
Mini Launcher Exp. 6: Conservation of Momentum
Also, when energy is conserved, the paths of two balls of equal mass will be at right angles to each other after the collision.
Setup
1. Clamp the Mini Launcher to a sturdy table near one end of the table with the barrel aimed inward toward the table.
Mount the Mini Launcher in the upper position on the stand.
• In this position, the Mini Launcher will launch the ball horizontally onto the table.
2. Cover the table with white paper (such as butcher paper).
NOTE: The paper must reach the base of the Launcher.
Target ball
3. Fire a test shot on the short range setting to make sure that the ball lands on the table. Tape a piece of carbon paper (carbon-side down) over the spot where the ball lands.
“tee”
4. Mount the 2-D Collision Accessory to the front of the Mini
Launcher. Put a target ball on the post (“tee”) of the accessory.
Figure 6.2: 2-D Collision Accessory
5. Loosen the thumbscrew and rotate the 2-D Collision Accessory slightly to one side.
• The “tee” must be located so that the launched ball does not bounce back into the Mini Launcher but does hit the target ball so that both balls land on the table at the same time.
• Tighten the thumbscrew to hold the accessory in place.
6. Load the Mini Launcher and fire a test shot to check that both balls hit the table at the same time.
Tape a piece of carbon paper on the white paper at each spot where the two balls land on the table.
Procedure
A. No Collision
1. Put “ball 1” into the Mini Launcher and cock it to the short range setting. Do not put a target ball on the “tee”.
2. Shoot the ball straight ahead and repeat the procedure five times.
B. Elastic Collision
1. Use two balls. Load Ball 1 into the Mini Launcher at the short range setting. Place Ball 2 on the
“tee” of the 2-D Collision Accessory.
2. Shoot Ball 1 so it collides with the target ball (Ball 2). Repeat the procedure five times.
C. Inelastic Collision
1. Use two balls. Load Ball 1 into the Mini Launcher at the short range setting. Put a small loop of sticky tape (sticky-side out) on Ball 2 and place it on the “tee”.
28
2. Orient the tape side of Ball 2 so that it will be struck by the launched ball (Ball 1), causing an inelastic collision.
012-15390A ®
ME-6825B Exp. 6: Conservation of Momentum
3. Fire a test shot to locate where the two balls hit the table. Tape a piece of carbon paper to the white paper.
4. Shoot Ball 1 and if the two balls stick together but miss the carbon paper, relocate the carbon paper and shoot once more.
• Since the tape does not produce the same inelastic collision each time, it is only useful to record this collision once.
5. Use a plumb bob to locate on the paper the spot directly below the point of contact of the two balls.
Mark this spot on the paper as the “point-of-contact” spot. Carefully remove the carbon paper from the white paper.
Analysis
The time of flight for each shot is the same because the vertical distance for each shot is the same.
Therefore, the horizontal length of each path is proportional to the speed of the ball. Since the masses are the same, the horizontal length of each path is also proportional to the momentum of the ball.
A. No Collision
1. Draw straight lines from the “point-of-contact” spot to each of the dots made by the ‘no collision’ shots.
2. Measure each straight line and record the length. Find the average of the five lengths and record the length as the “initial x-momentum” in Table 6.1 and Table 6.2. (For example, if the length is 65 cm, record “65” as the value for the “initial x-momentum” but do not include any units.)
B. Elastic Collision
1. Draw a straight line from the “point-of-contact” through the center of the group of dots made by the
‘no collision’ shots. (This is the center line from which all of the angles will be measured.)
2. Draw straight lines from the “point-of-contact” spot to each of the dots made by the ‘elastic collision’ shots. (There should be five lines on each side of the center line.)
3. Measure from the “point-of-contact” to each of the dots made by Ball 1. Find the average of the five lengths. Draw a straight line from the “point-of-contact” through the center of the group of dots made by Ball 1.
4. Measure the angle from the centerline to the straight line for Ball 1. Use this angle and the average length of the line for Ball 1 to calculate the x-component for Ball 1 and the y-component for Ball 1.
Record the values.
5. Measure from the “point-of-contact” to each of the dots made by Ball 2. Find the average of the five lengths. Draw a straight line from the “point-of-contact” through the center of the group of dots made by Ball 2.
6. Measure the angle from the centerline to the straight line for Ball 2. Use this angle and the average length of the line for Ball 2 to calculate the x-component for Ball 2 and the y-component for Ball 2.
Record the values.
7. Add the x-momentum for Ball 1 and the x-momentum for Ball 2 and record the result in Table 6.1 as “Final x-momentum”.
8. Calculate the initial kinetic energy of Ball 1 and the sum of the kinetic energy of Ball 1 and Ball 2 after the collision.
® 012-15390A 29
Mini Launcher Exp. 6: Conservation of Momentum
9. Calculate the percent differences.
Table 1: Data for the Elastic Collisions
Value Value Item
Initial x-momentum.
Ball 1
Final y-momentum,
Ball 1
Initial kinetic energy,
Ball 1
Item
Final x-momentum,
Ball 1 + Ball 2
Final y-momentum,
Ball 2
Final kinetic energy,
Ball 1 + Ball 2
Percent difference
C. Inelastic Collision
1. Draw straight lines from the “point-of-contact” spot to the dots made by the ‘inelastic collision’ shot.
(There should be two lines.)
2. Measure from the “point-of-contact” to each of the dots made by the ‘inelastic collision’ shot.
3. Measure the angle from the centerline to the straight line for each dot of the ‘inelastic collision’ shot.
4. Use the angle and the length of the lines for the shot to calculate the x-component and the y-component for each ball in the ‘inelastic collision’ shot. Record the values.
5. After the collision, add the x-momentum for Ball 1 and the x-momentum for Ball 2 and record the result in Table 6.1 as “Final x-momentum”.
6. Calculate the initial kinetic energy of Ball 1 and the sum of the kinetic energy of Ball 1 and Ball 2 after the collision.
7. Calculate the percent differences.
Questions
1. Was momentum conserved in the x-direction for each type of collision?
2. Was momentum conserved in the y-direction for each type of collision?
3. Was kinetic energy conserved for the elastic collision?
4. Was kinetic energy conserved for the inelastic collision?
30 012-15390A ®
ME-6825B Exp. 7: Vary the Angle to Maximize the Height
Exp. 7: Vary the Angle to Maximize the Height
Equipment Needed
Item
MIni Launcher and ball
Meter stick or measuring tape
White paper, large sheet
Plumb bob and string
Item
Board to protect wall
Sticky tape
Carbon paper (several sheets)
Purpose
The purpose of this experiment is to find the launch angle that will maximize the height on a vertical wall for a projectile launched at a fixed horizontal distance from the wall.
Theory
When the ball is shot at an angle at a fixed distance, x, from a target such as a vertical wall, the ball hits the wall at a height y given by: y = y
0
+ v
0 sin t –
1
2 gt
2 where y
0
is the initial height of the ball, of inclination above horizontal, due to gravity, and the horizontal distance,
Launcher and the place where the ball hits, given by x t
= x v g v
0
is the initial
is the angle
is the acceleration
is the time of flight. The range is
, between the muzzle of the
0 cos t
Solving this equation for the time of flight, t =
0 x cos t , gives v
X y
0
Figure 7.1: Maximizing Height y
Substituting for t in the equation for y gives y = y
0
+ x tan –
2 v
2 o gx
2 cos
2
To find the angle, , that gives the maximum height, set it equal to zero. Solve for the angle, . dy d
= x sec
2
–
2 y tan
, find the first derivative of the equation for
v
2
0 sec
2
= 0 y and
Solving for the angle, , gives: tan max
= v
0
2
Since the second derivative is negative for the ball, use the fixed distance, in the values for y max
, max x
, and max
, the angle is a maximum. To find the inital speed of
, and the maximum height, x .
y max
. Solve the y-equation for v
0
and plug
® 012-15390A 31
Mini Launcher Exp. 7: Vary the Angle to Maximize the Height
Setup
1. Clamp the Mini Launcher to a sturdy table near one end of the table. Mount the barrel in the upper position with the muzzle aligned with the upper pivot hole. Aim the barrel toward a wall about 2 meters from the table.
2. Use a vertical board to the protect the wall and cover the board with white paper.
3. Fire a test shot to see where the ball hits the board and tape a piece of carbon paper (carbon-side down) at that position.
Procedure
1. Shoot the ball at various angles and pinpoint which angle gives the maximum height by checking the marks on the white paper. (Move the carbon paper as necessary.)
2. Measure the angle that produces the maximum height and record its value in Table 7.1.
3. Measure the maximum height and record the value in the Data Table.
4. Measure the horizontal distance from the muzzle to the vertical board and record the value.
5. Measure the initial height of the ball where it leaves the muzzle and record the value.
Analysis
1. Calculate the initial speed by solving the y-equation for v
max
, and x from Table 7.1.
0
and substituting the values for y max
,
Table 1: Data and Results
Value Item
Measured Angle for Maximum Height
Maximum Height
Horizontal Distance
Initial Height
Calculated Initial Speed
Calculated Angle for Maximum Hight
Percent Difference between Angles
2. Calculate the angle for maximum height using the initial speed calculated in step 1 and the horizontal distance from the wall to the launcher.
3. Calculate the percent difference between the measured angle and the calcuulated angle. (Let A be one of the angles and B be the other angle).
Difference =
A B x 100
2
Questions
32
1. For the angle that gives the maximum height, when the ball hits the wall, has it already reached the peak of its trajectory?
2. For what distance from the wall would be height be maximized for a launch angle of 45°? What would the maximum height be in this case?
012-15390A ®
ME-6825B Exp. 8 (Demo): Do 30° and 60° Give the Same Range?
Exp. 8 (Demo): Do 30° and 60° Give the Same Range?
Equipment Needed
Item
Mini Launcher and ball
Purpose
The purpose of this demonstration is to confirm that the range of a ball launched at 30° is the same as one launched at 60° if the ball lands at the same height from which it was launched.
Theory
The range is the horizontal distance, the projectile lands, given by muzzle, x = ( v x , between the muzzle of the Mini Launcher and the place where cos ) t where v
is the launch angle above horizontal, and t
0
is the initial speed of the ball as it leaves the
is the time of flight.
If the ball lands on a target that is at the same height as the level of the muzzle of the launcher, the time of flight of the ball will be twice the time it takes the ball to reach the peak of its trajectory, when its vertical component of speed reaches zero. t = 2 t peak
=
2 v g sin
-------------------where g is the acceleration due to gravity. Substituting for t in the equation for x gives:, and t is the time x =
2 v
2
0 g
cos of flight. and using a trigonometry identity gives:
2 x = v
0 sin g
2
--------------------
The ranges for the angles 30° and 60° are the same since sin 60° = sin 120°.
Setup
1. Clamp the Mini Launcher to a sturdy table with the barrel mounted in the lower position on the stand. Mount the launcher near one end of the table with it aimed toward the middle of the table.
2. Adjust the angle of the Mini Launcher to 30°. Adjust the position of the barrel so that the muzzle is at the same level as the table top.
Figure 8.1: Set up to shoot on level surface.
3. Put the ball into the Mini Launcher and cock it to the medium range or long range setting.
• NOTE: In general, this demonstration will not work as well on the short range setting because the muzzle speed is more variable with the change in angle.
4. Fire a test shot to see where the ball hits.
® 012-15390A 33
Mini Launcher Exp. 8 (Demo): Do 30° and 60° Give the Same Range?
Procedure
1. Shoot the ball at 30° and mark where the ball lands on the table.
2. Change the angle of the Mini Launcher to 60° and shoot the ball again. Call attention to the fact that the ball again lands on the mark where the first ball landed (confirming that the ranges are the same).
3. Change the angle to 45° and shoot the ball again to show that the ball now lands further away, landing beyond the mark for the previous angles.
4. Ask the question: What other pairs of angles will have a common range? Will 20° and 70° have the same range? Will 35° and 55° have the same range?
• This demonstration can be done for any two angles that add up to 90°.
34 012-15390A ®
ME-6825B Exp. 9 (Demo): Simultaneous Shots at Different Speeds
Exp. 9 (Demo): Simultaneous Shots at Different Speeds
Equipment Needed
Item
Mini Launcher (2) and ball (2)
Purpose
The purpose of this demonstration is to confirm that regardless of the initial speed of projectiles fired horizontally, the projectiles will hit the floor at the same time.
Theory
Two projectiles are shot horizontally from the same height, are different. y.
The muzzle speeds of the two projectiles
The vertical and horizontal motions of a projectile are independent of each other. The horizontal distance, distance x , travelled by the projectile depends on the initial speed, v x = v
0 t.
0
, and the time of flight, t . The
The time of flight depends on the vertical distance that the projectile falls. t =
2 y g where g is the acceleration due to gravity. Since the vertical distance is the same fore each projectile, the time of flight is the same for each projectile.
Setup
1. Clamp two Mini Launchers adjacent to each other on a sturdy table. Mount the Mini Launchers near one end of the table with the Launchers aimed away from the table so the balls will land on the floor.
2. Adjust the angle of each Mini
Launcher to 0° so the balls will fire horizontally.
Procedure y
υ
0(short)
υ
0(long) x short x long
Figure 9.1: Shots fired simultaneously
1. Put a ball into each Mini Launcher. Cock one Mini Launcher to the short range setting and cock the other Mini Launcher to the long range setting.
2. Ask the class to be quiet and listen for the balls striking the floor.
• NOTE: If there is only one click, that means that the balls hit the floor simultaneously.
3. Put both trigger release lanyards in the same hand and pull them at the same time so that the balls are launched simultaneously.
4. After the balls hit the floor, ask the class if they heard one click or two.
® 012-15390A 35
Mini Launcher Exp. 9 (Demo): Simultaneous Shots at Different Speeds
36 012-15390A ®
ME-6825B Exp. 10 (Demo): Shooting Through Hoops
Exp. 10 (Demo): Shooting Through Hoops
Equipment Needed
Item
Mini Launcher and ball
Smart Gate OR Photogate Head (2) optional
Item
Ring clamp on stand (5)
Photogate Mounting Bracket optional
PASCO Interface and Software OR Smart Timer
Meter stick Two-meter stick
Purpose
The purpose of this demonstration is to confirm that the part of a projectile is parobolic.
Theory
The range is the horizontal distance, the projectile hits, given by: x , between the muzzle of a Mini Launcher and the place where x = v
0 t where v
0
is the initial speed of the projectile as it leaves the muzzle and t is the time of flight. The y , of the projectile at time t is given by: y = y
0
–
1
2 gt
2 where y
0
is the initial height of the projectile and g is the acceleration due to gravity.
Solving the x-equation for t and substituting the expression in the y-equation gives: y = y
0
–
1
2 g v x
2
= ax
2
+ b where “ a ” and “ b ” are constants. The y-equation ( y = ax 2
+ b ) describes a parabola.
Pre-Lab
Before the demonstration begins, find the initial speed of the ball.
• Attach a Photogate Mounting Bracket to the Mini Launcher. Use a Smart Gate with a PASCO
Interface or two Photogate Heads with an interface or a Smart Timer to measure the initial speed of the ball.
• Alternatively, shoot the ball horizontally and measure
See experiments 1 and 2.) x and y . (Use y to calculate the time of flight.
Setup
1. Clamp the Mini Launcher to a sturdy table near one end of the table with the Launcher aimed away from the table so the ball will land on the floor.
2. Adjust the angle of the Launcher to 0° so the ball will fire horizontally.
® 012-15390A 37
Mini Launcher Exp. 10 (Demo): Shooting Through Hoops
Procedure
1. Measure and record the initial height, y
0
, of the ball at muzzle level.
2. Calculate and record the horizontal and vertical positions of the ball each 1/10 second until the vertical position is zero.
Table 1: X- and y-positions t (sec) x = v
0 t (cm) y = y
0
- (1/2)gt
2
(cm)
0.1
0.2
0.3
0.4
0.5
3. Lay the two-meter stick on the floor in a straight line away from the Mini Launcher.
4. Starting at the muzzle of the Mini Launcher, measure off each set of x and y distances and place a ring clamp on a stand at each position corresponding to one-tenth of a second (see Figure 10.1).
5. Shoot the ball through the rings.
6. Ask the class: What shape of curve is formed by the rings? What is the path of the projectile?
38 012-15390A ®
ME-6825B Exp. 10 (Demo): Shooting Through Hoops
Figure 10.1: Demonstration setup
® 012-15390A 39
Mini Launcher
Technical Support
For assistance with any PASCO product, contact PASCO at:
Address: PASCO scientific
10101 Foothills Blvd.
Roseville, CA 95747-7100
Phone: +1 916 462 8384 (worldwide)
800-772-8700 (U.S.)
Web:
Email: www.pasco.com
Technical Support
For more information about the Mini Launcher and the latest revision of this Instruction Manual, visit the PASCO web site and enter ME-6825 into the Search window.
Limited Warranty For a description of the product warranty, see the PASCO catalog.
Copyright This PASCO scientific Instruction Manual is copyrighted with all rights reserved. Permission is granted to non-profit educational institutions for reproduction of any part of this manual, providing the reproductions are used only in their laboratories and classrooms, and are not sold for profit. Reproduction under any other circumstances, without the written consent of PASCO scientific, is prohibited.
Trademarks PASCO and PASCO scientific are trademarks or registered trademarks of PASCO scientific, in the United States and/or in other countries. All other brands, products, or service names are or may be trademarks or service marks of, and are used to identify, products or services of, their respective owners. For more information visit www.pasco.com/legal.
40 012-15390A ®
advertisement
* Your assessment is very important for improving the workof artificial intelligence, which forms the content of this project
Related manuals
advertisement
Table of contents
- 3 Equipment
- 4 Introduction
- 5 General Operation of the Mini Launcher
- 6 Installation of the Optional Photogate Bracket
- 6 Installing the 2-Dimensional Collision Accessory
- 7 Expectations for the Mini Launcher
- 7 Launch Positions
- 9 1. Projectile Motion
- 13 2. Projectile Motion Using Photogates
- 17 3. Projectile Range versus Angle
- 21 4. Projectile Path
- 25 5. Conservation of Energy
- 29 6. Conservation of Momentum in Two Dimensions
- 33 7. Varying Angle to Maximize Height on a Wall
- 35 8. Demo: Do 30° and 60° Give Same Range
- 37 9. Demo: Shoot Two Balls Horizontally at Different Speeds
- 39 10.Demo: Shooting through Hoops
- 42 Technical Support
- 42 Warranty, Copyright, and Trademarks