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Plane Launcher
Get inspired with our Build Your Own Cardboard Plane Launcher.The47-piece kit contains everything you need to slot together and build thisincredible launcher.Follow the detailed instructions, press out the pre-cutparts, attach the elastic bands and you’re ready to fly your planes!Experiment with the 10 different fold ‘n’ fly paper planes.Follow the simpleinstructions to create your bespoke planes, then see how their performance canbe affected by combining the integrated power scale and changes to the plane’sflight dynamics.Which one will fly the furthest? How can adjusting the wingschange how it flies or loops?Who can land the closest to one of the 4 scoringtargets?Made using sustainable cardboards and no plastics, we have tried ourbest to create a product that is not only fun and engaging to use, but alsoenvironmentally responsible.Slot together mess free construction – no glueneeded.Perfect family time activity.
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EMMAS PLANE
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Chamfer Plane Woodworking Edge Plane with Auxiliary Locator Hand Plane Suitable for Quick Edge
Chamfer Plane Woodworking Edge Plane with Auxiliary Locator Hand Plane Suitable for Quick Edge
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Router Plane Handheld Woodworking Tool Router Plane High Configuration Hand Router Plane with Depth
Router Plane Handheld Woodworking Tool Router Plane High Configuration Hand Router Plane with Depth
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What is the support vector of another plane in the same plane?
The support vector of another plane in the same plane is the vector that is perpendicular to the plane. In other words, it is a vector that is orthogonal to the plane and lies entirely within the plane. This vector is important in defining the orientation and position of the plane in space.
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'How do you reflect a plane across the plane x1x3?'
To reflect a plane across the plane x1x3, you can first find the equation of the mirror plane x1x3. Then, for each point on the original plane, you can find its reflection across the mirror plane by using the formula for reflecting a point across a plane. This involves finding the perpendicular distance from the point to the mirror plane and then using that distance to find the reflected point. By applying this process to all points on the original plane, you can obtain the reflected plane across the x1x3 plane.
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How do you reflect a plane on the plane x1x3?
To reflect a plane on the plane x1x3, you would first find the equation of the plane you want to reflect. Then, you would substitute x2 with -x2 in the equation to reflect it across the x1x3 plane. This means changing the sign of the coefficient of x2 in the equation of the plane. The resulting equation will be the reflection of the original plane across the x1x3 plane.
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How do you determine a parallel plane to a given plane?
To determine a parallel plane to a given plane, you can use the normal vector of the given plane. If the normal vector of the given plane is (a, b, c), then the parallel plane will have the same normal vector. You can then use this normal vector to find the equation of the parallel plane. If the given plane has the equation Ax + By + Cz + D = 0, then the parallel plane will have the equation Ax + By + Cz + K = 0, where K is a constant. This will ensure that the two planes are parallel to each other.
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Stamina : A Journey of Renewal for Your Weary Soul
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Faithfull No.4 Plane and No.60.1/2 Plane
This Faithfull Plane Set comes in a wooden storage box and provides the essentials you need for planing wood: 1 x No.4 Smoothing Plane, designed for smoothing and final finishing. Made with a quality grey cast iron body for strength and stability with precision ground base and sides for flatness and squareness. Machined seatings eliminate movement and blade judder. A lever cap with a brass locking screw secures the blade assembly and enables easy release for sharpening. Wooden handles and guidance knobs maximise user comfort. A solid brass blade adjustment nut completes the appeal of these traditional tools. Cutter Width: 50mm.Overall Length: 250mm. 1 x No.60 1/2 Block Plane with plane iron set at 13.5°. It is particularly effective on end grain and plastic laminates. Block planes are designed for end grain work or in any situation where a single-handed operation is required. The low angle cutter and fully adjustable mouth, from wide for coarse work to narrow for the fine shaving of awkward grain. Cutter Width: 35mm.Overall Length: 160mm.Additional Information:• Plane Type: Set
Price: 48.95 € | Shipping*: 4.95 € -
Faithfull No.4 Plane and No.60.1/2 Plane
This Faithfull Plane Set comes in a wooden storage box and provides the essentials you need for planing wood: 1 x No.4 Smoothing Plane, designed for smoothing and final finishing. Made with a quality grey cast iron body for strength and stability with precision ground base and sides for flatness and squareness. Machined seatings eliminate movement and blade judder. A lever cap with a brass locking screw secures the blade assembly and enables easy release for sharpening. Wooden handles and guidance knobs maximise user comfort. A solid brass blade adjustment nut completes the appeal of these traditional tools. Cutter Width: 50mm.Overall Length: 250mm. 1 x No.60 1/2 Block Plane with plane iron set at 13.5°. It is particularly effective on end grain and plastic laminates. Block planes are designed for end grain work or in any situation where a single-handed operation is required. The low angle cutter and fully adjustable mouth, from wide for coarse work to narrow for the fine shaving of awkward grain. Cutter Width: 35mm.Overall Length: 160mm.Additional Information:• Plane Type: Set
Price: 48.95 € | Shipping*: 4.95 € -
Faithfull No.4 Plane and No.60.1/2 Plane
This Faithfull Plane Set comes in a wooden storage box and provides the essentials you need for planing wood: 1 x No.4 Smoothing Plane, designed for smoothing and final finishing. Made with a quality grey cast iron body for strength and stability with precision ground base and sides for flatness and squareness. Machined seatings eliminate movement and blade judder. A lever cap with a brass locking screw secures the blade assembly and enables easy release for sharpening. Wooden handles and guidance knobs maximise user comfort. A solid brass blade adjustment nut completes the appeal of these traditional tools. Cutter Width: 50mm.Overall Length: 250mm. 1 x No.60 1/2 Block Plane with plane iron set at 13.5°. It is particularly effective on end grain and plastic laminates. Block planes are designed for end grain work or in any situation where a single-handed operation is required. The low angle cutter and fully adjustable mouth, from wide for coarse work to narrow for the fine shaving of awkward grain. Cutter Width: 35mm.Overall Length: 160mm.Additional Information:• Plane Type: Set
Price: 48.95 € | Shipping*: 4.95 €
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How can one establish a plane parallel to the x1-x2 plane?
To establish a plane parallel to the x1-x2 plane, one can choose any point not on the x1-x2 plane. Then, draw a line perpendicular to the x1-x2 plane from that point. This line will intersect the x1-x2 plane at a single point. Finally, construct a plane that is parallel to the x1-x2 plane and passes through the point where the perpendicular line intersects the x1-x2 plane.
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How can one establish a parallel plane to the x1-x2 plane?
To establish a parallel plane to the x1-x2 plane, one can use the equation of the x1-x2 plane, which is typically written as z = 0. To create a parallel plane, one can simply add or subtract a constant value from the right-hand side of the equation. For example, to create a parallel plane that is 3 units above the x1-x2 plane, the equation would be z = 3. This will create a new plane that is parallel to the x1-x2 plane and shifted vertically by 3 units.
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How does the transition from an inclined plane to a horizontal plane occur?
The transition from an inclined plane to a horizontal plane occurs gradually as the angle of inclination decreases. As the angle decreases, the force of gravity acting on the object becomes more perpendicular to the surface, reducing the component of the force that acts parallel to the plane. Eventually, when the angle reaches zero degrees, the plane becomes horizontal, and the force of gravity acts entirely perpendicular to the surface, causing the object to move along the horizontal plane.
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How is the transition from an inclined plane to a horizontal plane made?
The transition from an inclined plane to a horizontal plane can be made using a curved surface called a transition curve. This curve allows for a smooth and gradual change in the slope of the plane, ensuring that there are no sudden changes in elevation that could cause discomfort or safety issues for users. The transition curve is carefully designed to provide a seamless connection between the inclined and horizontal planes, allowing for a smooth transition for objects or individuals moving between the two surfaces.
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