What geometric figure is the base of an inclined cylinder. Reference abstract on geometry on the topic "cylinder". Cylinder side surface area

Cylinder (straight circular cylinder) a body is called a body consisting of two circles (cylinder bases) combined by parallel translation, and all segments connecting the corresponding points of these circles during parallel translation. The segments connecting corresponding points circumferences of the bases are called generators of the cylinder.

Here is another definition:

Cylinder- a body that is bounded by a cylindrical surface with a closed guide and two parallel planes intersecting the generators of this surface.

Cylindrical surface- a surface that is formed by the movement of a straight line along a certain curve. The straight line is called the generatrix of the cylindrical surface, and the curved line is called the guide of the cylindrical surface.

Lateral surface of the cylinder- part of a cylindrical surface that is bounded by parallel planes.

Cylinder bases- parts of parallel planes cut off by the side surface of the cylinder.

Fig.1 mini

The cylinder is called direct(Cm. Fig.1) if its generators are perpendicular to the planes of the bases. Otherwise, the cylinder is called oblique.

circular cylinder- a cylinder whose bases are circles.

Right circular cylinder (just a cylinder) is the body obtained by rotating a rectangle around one of its sides. Cm. Fig.1.

Cylinder radius is the radius of its base.

Cylinder generatrix- generatrix of a cylindrical surface.

cylinder height called the distance between the planes of the bases. Cylinder axis is called a straight line passing through the centers of the bases. The section of a cylinder by a plane passing through the axis of the cylinder is called axial section.

The axis of the cylinder is parallel to its generatrix and is the axis of symmetry of the cylinder.

The plane passing through the generatrix of a right cylinder and perpendicular to the axial section drawn through this generatrix is ​​called tangent plane of the cylinder. Cm. Fig.2.

Reaming of the side surface of the cylinder- a rectangle with sides equal to the height of the cylinder and the circumference of the base.

Cylinder side surface area- the area of ​​the development of the lateral surface. $$S_(side)=2\pi\cdot rh$$ , where h is the height of the cylinder, and r is the radius of the base.

Full surface area of ​​a cylinder- area, which is equal to the sum of the areas of the two bases of the cylinder and its lateral surface, i.e. is expressed by the formula: $$S_(full)=2\pi\cdot r^2 + 2\pi\cdot rh = 2\pi\cdot r(r+h)$$ , where h is the height of the cylinder, and r is the radius of the base.

Volume of any cylinder is equal to the product of the area of ​​the base and the height: $$V = S\cdot h$$ Volume of a round cylinder: $$V=\pi r^2 \cdot h$$ , where ( r is the radius of the base).

A prism is a particular form of a cylinder (generators are parallel to the side edges; the guide is a polygon lying at the base). On the other hand, an arbitrary cylinder can be viewed as a degenerate ("smoothed") prism with a very large number of very narrow faces. Practically the cylinder is indistinguishable from such a prism. All properties of the prism are preserved in the cylinder.

Category:Cylinders at Wikimedia Commons

Cylinder(other Greek. κύλινδρος - roller, skating rink) - geometric bodylimited by a cylindrical surface and two parallel planes intersecting it. Cylindrical surface - a surface obtained by such a translational movement of a straight line (generator) in space that a selected point of the generatrix moves along a flat curve (guide). The part of the surface of the cylinder bounded by the cylindrical surface is called the lateral surface of the cylinder. The other part, bounded by parallel planes, is the base of the cylinder. Thus, the border of the base will coincide in shape with the guide.

In most cases, a cylinder means a straight circular cylinder, in which the guide is a circle and the bases are perpendicular to the generatrix. Such a cylinder has an axis of symmetry.

Other types of cylinder - (according to the slope of the generatrix) oblique or inclined (if the generatrix does not touch the base at a right angle); (according to the shape of the base) elliptical, hyperbolic, parabolic.

A prism is also a kind of cylinder - with a base in the form of a polygon.

Cylinder surface area

Lateral surface area

To the calculation of the lateral surface area of ​​a cylinder

The area of ​​the lateral surface of the cylinder is equal to the length of the generatrix multiplied by the perimeter of the section of the cylinder by a plane perpendicular to the generatrix.

The lateral surface area of ​​a straight cylinder is calculated from its development. The development of the cylinder is a rectangle with height and length equal to the perimeter of the base. Therefore, the area of ​​the lateral surface of the cylinder is equal to the area of ​​its development and is calculated by the formula:

In particular, for a right circular cylinder:

, and

For an inclined cylinder, the lateral surface area is equal to the length of the generatrix multiplied by the perimeter of the section perpendicular to the generatrix:

Unfortunately, there is no simple formula expressing the lateral surface area of ​​an oblique cylinder in terms of base parameters and height, unlike volume.

Total surface area

The total surface area of ​​a cylinder is equal to the sum of the areas of its lateral surface and its bases.

For a straight circular cylinder:

Cylinder volume

There are two formulas for an inclined cylinder:

where is the length of the generatrix, and is the angle between the generatrix and the plane of the base. For a straight cylinder

For a straight cylinder , and , and the volume is:

For a circular cylinder:

where d- base diameter.

Notes


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Synonyms:

See what "Cylinder" is in other dictionaries:

    - (lat. cylindrus) 1) geometric body, bounded at the ends by two circles, from the sides by a plane enveloping these circles. 2) in watchmaking: a special kind of double wheel lever. 3) a hat shaped like a cylinder. Dictionary of foreign words, ... ... Dictionary of foreign words of the Russian language

    cylinder- a, m. cylindre m., German. Zylinder, lat. cylindrus gr. 1. A geometric body formed by the rotation of a rectangle around one of its sides. Cylinder volume. ALS 1. The thickness of a cylinder is equal to the area of ​​its base multiplied by its height. Dal… Historical dictionary gallicisms of the Russian language

    Husband, Greek straight stack, shaft; oblets, oblyak; a body bounded at the ends by two circles, and at the sides by a plane bent in circles. The thickness of a cylinder is equal to the area of ​​its base multiplied by its height, geom. A steam cylinder, a freebie, a pipe in which ... ... Dictionary Dalia

    Cylindrical surface, drum, shaft; cap, hat, roller, roll, mandrel, cylinder, point, tsarga, body, roll Dictionary of Russian synonyms. cylinder n., number of synonyms: 22 atactosteles (2) ... Synonym dictionary

    - (from Greek kylindros) in elementary geometry, a geometric body formed by the rotation of a rectangle around one side: the volume of the cylinder is V=?r2h, and the area of ​​the lateral surface is S = 2?rh. The lateral surface of the cylinder is part of the cylindrical ... ...

    A hollow piece with a cylindrical inner surface in which the piston moves. One of the main parts of reciprocating machines and mechanisms ... Big Encyclopedic Dictionary

    High men's hat made of silk plush with small hard brim ... Big Encyclopedic Dictionary

    CYLINDER, solid or a surface formed by revolving a rectangle about one of its sides as an axis. The volume of the cylinder, if we denote its height as h, and the radius of the base as r, is equal to pr2h, and the area of ​​the curved surface is 2prh ... Scientific and technical encyclopedic dictionary

    CYLINDER, cylinder, man. (from Greek kylindros). 1. A geometric body formed by the rotation of a rectangle about one of its sides, called the axis, and having a circle at the bases (mat.). 2. Part of the machines (motors, pumps, compressors, etc.) in ... ... Explanatory Dictionary of Ushakov

    CYLINDER, a, husband. 1. A geometric body formed by the rotation of a rectangle around one of its sides. 2. Columnar object, eg. piston machine part. 3. A tall hard hat of this shape with a small brim. Black c. | adj… … Explanatory dictionary of Ozhegov

    - (Steam cylinder) one of the main parts of piston machines. It is made in the form of a hollow round ring, in which the piston moves. C. steam engines are usually equipped with a steam jacket to heat its walls in order to reduce steam condensation. ... ... Marine Dictionary

Lesson topic: Cylinder, its elements.

The purpose of the lesson:

Consolidation of students' knowledge about the body of revolution - the cylinder (cylinder elements, formulas for the area of ​​​​the lateral and full surface of the cylinder).

Student goal: be able to solve typical tasks for a cylinder in UNT tasks.

Lesson objectives:

1. build decision skills typical tasks;

2. develop spatial representations on the example of round bodies;

3. continue the formation of logical and graphic skills.

Lesson type: combined.

Teaching methods: verbal, practical activity, work with a book, problematic.

Equipment: board, table number 3, a set of models.

During the classes

1. Organizational moment:

1. goal setting

2. psychological attitude.

2. Actualization of basic knowledge.

1) Work on cards.

Students are asked to complete a worksheet.

It is possible to work using copying (in this case, one copy is handed over to the teacher, and the second student checks during further work on the lesson).

Card.

1. Draw the main elements of the cylinder on the drawing.



2

.Depict a) the axial section of the cylinder; b) section of the cylinder by a plane passing perpendicular to the axis of the cylinder; c) section of the cylinder by a plane parallel to the axis of the cylinder. What figure is obtained in each case?

3. Write down the formulas for calculating the surface area of ​​a cylinder.

What can be found by these formulas? What should be known in these cases?

Students hand in worksheets.

3. Oral work on models. (in order to generalize knowledge and check the work done)

1) What shape is called a cylinder?

Cylinder is a geometric body consisting of two equal circles located in parallel planes and a set of segments connecting the corresponding points of these circles.

2) Why is a cylinder called a body of revolution?

A cylinder can be obtained by rotating a rectangle around one of its sides.

3) What are the types of cylinders?

Inclined cylinders, straight cylinders, cylindrical surfaces.

4) Name the elements of the cylinder.

Cylinder bases - equal circles located in parallel planes.

Cylinder height - This the distance between the planes of its bases.

Cylinder radius is the radius of its base.

Cylinder axis is a straight line passing through the centers of the base of the cylinder (the axis of the cylinder is the axis of rotation of the cylinder).

Cylinder generatrix - this is a segment connecting the point of the circle of the upper base with the corresponding point of the circle of the lower base. All generators are parallel to the axis of rotation and have the same length, equal to the height of the cylinder.

The generatrix of the cylinder during rotation around the axis forms lateral (cylindrical) surface of a cylinder .

5) What is a cylinder sweep?

The development of the lateral surface of the cylinder is a rectangle with sides H and C, where H is the height of the cylinder, and C is the circumference of the base.

6) How to find the lateral surface area of ​​a cylinder?

S b = H · C = 2 π RH

7) How to find the total surface area of ​​a cylinder?

S P = S b + 2 S = 2 π R (R + H ).

8) What are the main types of sections of the cylinder. What figure is obtained in each case?

Axial section of the cylinder - section of the cylinder by a plane passing through the axis of the cylinder (the axial section of the cylinder is the plane of symmetry of the cylinder). All axial sections of the cylinder are equal rectangles.

cross section plane parallel to the axis of the cylinder. The section is a rectangle.

Plane section perpendicular to the axis of the cylinder. Circles in cross section, equal to the base.

9) Give examples of the use of cylinders.

Cylindrical gastronomy. Cylindrical architecture. Cylinders of the pharaoh (student performance 1-2 minutes).

4. Fixing the material. Problem solving.

At Students see a list of tasks for classwork. If desired, students have the opportunity to decide ahead of the mark.

1. (task with practical content). Find the surface area (outer and inner) of the hat whose dimensions (in cm) are shown in the figure.

2 . The axial section of the cylinder is a square whose diagonal is 20 cm. Find: a) the height of the cylinder; b) So cylinder.

3 The area of ​​the axial section of the cylinder is 10 m 2, and the base area is 5 m 2. Find the height of the cylinder.

4 The ends of the segment AB lie on different bases of the cylinder. The radius of the cylinder is r, his high - h, the distance between the straight line AB and the axis of the cylinder is d. Find: a) height if r = 10, d= 8, AB = 13.

5* Two secant planes are drawn through the generatrix AA 1 of the cylinder, one of which passes through the axis of the cylinder. Find the ratio of the cross-sectional areas of the cylinder by these planes if the angle between them is equal to j.


5. Educational independent work. Independent work on options. (It is possible to organize pair work).

Plane g, parallel to the axis of the cylinder, cuts off the arc A from the circumference of the base m D with degree measure a. The radius of the cylinder is a, the height is h, the distance between the axis of the cylinder OO 1 and the plane g is equal to d.


Option 1. 1) Prove that the section of the cylinder by plane g is a rectangle. 2) Find AD if a =10 cm, a = 60°.
Option 2. 1) Make a plan for calculating the cross-sectional area from the data a , h, d.2) Find AD if a =8 cm, a = 120°. 6. Setting homework . Repeat formula 1 and solve number 25. 7. Reflective-evaluative block.Reflection. What new did you learn in the lesson?

What have you learned?

What is your mood at the end of the lesson?

Can you explain the solution to these problems to a classmate who missed class today?

The name of the science "geometry" is translated as "measurement of the earth." It was born through the efforts of the very first ancient land surveyors. And it happened like this: during the floods of the sacred Nile, streams of water sometimes washed away the boundaries of the plots of farmers, and the new boundaries might not coincide with the old ones. Taxes were paid by the peasants to the treasury of the pharaoh in proportion to the size of the land allotment. The measurement of arable land within the new boundaries after the spill was carried out by special people. It was as a result of their activities that a new science arose, which was developed in Ancient Greece. There she received the name, and acquired practically modern look. In the future, the term became the international name for the science of flat and three-dimensional figures.

Planimetry is a branch of geometry that deals with the study of plane figures. Another branch of science is stereometry, which considers the properties of spatial (volumetric) figures. The cylinder described in this article also belongs to such figures.

Examples of the presence of cylindrical objects in Everyday life enough. Almost all parts of rotation - shafts, bushings, necks, axles, etc. have a cylindrical (much less often - conical) shape. The cylinder is widely used in construction: towers, supporting, decorative columns. And besides, dishes, some types of packaging, pipes of various diameters. And finally - the famous hats, which have become a symbol of male elegance for a long time. The list is endless.

Definition of a cylinder as a geometric figure

A cylinder (circular cylinder) is usually called a figure consisting of two circles, which, if desired, are combined using parallel translation. It is these circles that are the bases of the cylinder. But the lines (straight segments) connecting the corresponding points are called "generators".

It is important that the bases of the cylinder are always equal (if this condition is not met, then we have a truncated cone in front of us, something else, but not a cylinder) and are in parallel planes. The segments connecting the corresponding points on the circles are parallel and equal.

The totality of an infinite set of generators is nothing but side surface cylinder - one of the elements of this geometric figure. Its other important component is the circles discussed above. They are called bases.

Types of cylinders

The simplest and most common type of cylinder is circular. It is formed by two regular circles acting as bases. But instead of them there may be other figures.

The bases of the cylinders can form (except for circles) ellipses and other closed figures. But the cylinder may not necessarily have a closed shape. For example, a parabola, a hyperbola, or another open function can serve as the base of a cylinder. Such a cylinder will be open or deployed.

According to the angle of inclination of the generatrices to the bases, the cylinders can be straight or inclined. For a right cylinder, the generators are strictly perpendicular to the plane of the base. If this angle differs from 90°, the cylinder is inclined.

What is a surface of revolution

A right circular cylinder is without a doubt the most common surface of revolution used in engineering. Sometimes, according to technical indications, conical, spherical, and some other types of surfaces are used, but 99% of all rotating shafts, axles, etc. made in the form of cylinders. In order to better understand what a surface of revolution is, we can consider how the cylinder itself is formed.

Let's say there is a line a placed vertically. ABCD is a rectangle, one of whose sides (segment AB) lies on a straight line a. If we rotate a rectangle around a straight line, as shown in the figure, the volume that it will occupy while rotating will be our body of revolution - a right circular cylinder with height H = AB = DC and radius R = AD = BC.

AT this case, as a result of rotation of a figure - a rectangle - a cylinder is obtained. Rotating a triangle, you can get a cone, rotating a semicircle - a ball, etc.

Cylinder surface area

In order to calculate the surface area of ​​an ordinary straight circular cylinder, it is necessary to calculate the areas of the bases and the lateral surface.

First, let's look at how the lateral surface area is calculated. This is the product of the circumference and the height of the cylinder. The circumference, in turn, is equal to twice the product of the universal number P to the radius of the circle.

The area of ​​a circle is known to be equal to the product P to the square of the radius. So, adding the formulas for the area of ​​determining the lateral surface with twice the expression for the base area (there are two of them) and performing simple algebraic transformations, we obtain the final expression for determining the surface area of ​​the cylinder.

Determining the volume of a figure

The volume of a cylinder is determined by the standard scheme: the surface area of ​​the base is multiplied by the height.

Thus, the final formula looks like this: the desired is defined as the product of the height of the body by the universal number P and the square of the base radius.

The resulting formula, it must be said, is applicable to solving the most unexpected problems. In the same way as the volume of a cylinder, for example, the volume of electrical wiring is determined. This may be necessary to calculate the mass of wires.

The only difference in the formula is that instead of the radius of one cylinder, there is the diameter of the wiring core divided in two and the number of cores in the wire appears in the expression N. Also, wire length is used instead of height. Thus, the volume of the “cylinder” is calculated not by one, but by the number of wires in the braid.

Such calculations are often required in practice. After all, a significant part of the water tanks is made in the form of a pipe. And it is often necessary to calculate the volume of a cylinder even in the household.

However, as already mentioned, the shape of the cylinder can be different. And in some cases it is required to calculate what the volume of the inclined cylinder is equal to.

The difference is that the surface area of ​​the base is multiplied not by the length of the generatrix, as in the case of a straight cylinder, but by the distance between the planes - a perpendicular segment built between them.

As can be seen from the figure, such a segment is equal to the product of the length of the generatrix by the sine of the angle of inclination of the generatrix to the plane.

How to build a cylinder sweep

In some cases, it is required to cut out a cylinder reamer. The figure below shows the rules by which a blank is built for the manufacture of a cylinder with a given height and diameter.

Please note that the figure is shown without seams.

Beveled Cylinder Differences

Let us imagine a straight cylinder bounded on one side by a plane perpendicular to the generators. But the plane bounding the cylinder on the other side is not perpendicular to the generators and is not parallel to the first plane.

The figure shows a beveled cylinder. Plane a at some angle other than 90° to the generators, intersects the figure.

This geometric shape is more common in practice in the form of pipeline connections (elbows). But there are even buildings built in the form of a beveled cylinder.

Geometric characteristics of the beveled cylinder

The slope of one of the planes of the beveled cylinder slightly changes the order of calculation of both the surface area of ​​such a figure and its volume.

Let's start online new theme, and when I arrive we will conduct a test and test on the topic "Movement and vectors".

  • We begin our acquaintance with a new class of geometric bodies - bodies of revolution. The first representative of this class, with which we are acquainted, is a cylinder.
  • Why is a cylinder called a body of revolution?

C cylinder, is obtained by rotating a rectangle around one of its sides.

  • The cylinder consists of two circles and many segments.
  • Cylinder- This is a geometric body consisting of two equal circles located in parallel planes and a set of segments connecting the corresponding points of these circles.
  • Cylinder element definitions:

Cylinder bases- equal circles located in parallel planes

Cylinder height- This the distance between the planes of its bases.

Cylinder axis is a straight line passing through the centers of the base of the cylinder (the axis of the cylinder is the axis of rotation of the cylinder).

Axial section of the cylinder- section of the cylinder by a plane passing through the axis of the cylinder (the axial section of the cylinder is the plane of symmetry of the cylinder). All axial sections of the cylinder are equal rectangles

Cylinder generatrix- this is a segment connecting the point of the circle of the upper base with the corresponding point of the circle of the lower base. All generators are parallel to the axis of rotation and have the same length, equal to the height of the cylinder.

The generatrix of the cylinder during rotation around the axis formslateral (cylindrical) surface of a cylinder.

Cylinder radiusis the radius of its base.

straight cylinder is a cylinder whose generators are perpendicular to the base.

Equivalent cylinder- a cylinder whose height is equal to the diameter (show an equal cylinder: button with the hand icon to switch the model back to interactive mode and change the value of the height and radius of the proposed model so that ).

  • Derivation of the lateral surface area formula.

    The development of the lateral surface of the cylinder is a rectangle with sidesH and C, where His the height of the cylinder, andCis the circumference of the base. We obtain formulas for calculating the areas of the lateralS b and complete S n surfaces: S b = H · C= 2π RH, S n = S b + 2 S= 2π R(R + H).

  • Anchoring

    Task number 1. Calculate the area of ​​​​the lateral and full surface of a cylinder whose radius is 3 cm and the height is 5 cm (pi and the answer are rounded to integers).

    2. The height of the cylinder ish, base radiusR. Find the cross-sectional area of ​​a plane drawn parallel to the axis of the cylinder at a distancea from her.

    Homework: 522, 524, 526.

  • Р.S/ for those who are interested, try to follow the link and see the electronic resource about the cylinder, first on the page, install the OMS module on your PC and download the module. On the pop-up table, click play. And then go through all the pages in order.
  • THANKS TO ALL.