Thematic planning
2 hours per week, total - 70 hours.
Topic | Number of hours | Number of laboratory works | Number of tests |
Physics and physical methods of studying nature | |||
Initial information about the structure of matter | |||
Interaction of bodies | |||
Pressure of solids, liquids and gases | |||
work and power. Body energy | |||
Repetition | |||
Total | 70 | 9 | 5 |
Course content
I . Physics and physical methods of studying nature. (3 hours)
Subject and methods of physics. Experimental method of studying nature. Measurement of physical quantities.
Measurement error. Generalization of the results of the experiment.
Observation of the simplest phenomena and processes of nature with the help of the senses (sight, hearing, touch). Use of simple measuring instruments. Schematic representation of experiments. Methods of obtaining knowledge in physics. Physics and technology.
Demonstrations
Examples of mechanical, thermal, electrical, magneticand light phenomena.physical devices.
1. Determination of the scale division value of the measuring instrument.
Know the meaning of the concept of "substance". Be able to use physical instruments and measuring instruments to measure physical quantities. Express results in SI.
II . Initial intelligence about the structure of matter. ( 7 hours)
Hypothesis about the discrete structure of matter. Molecules. Continuity and randomness of motion of particles of matter.
Diffusion. Brownian motion. Models of gas, liquid and solid body.
Interaction of particles of matter. Mutual attraction and repulsion of molecules.
Three states of matter.
Demos: The structure of matter.Thermal motion of atoms and molecules. Brownian motion. Diffusion. Interaction of particles of matter. Models of the structure of gases, liquids and solids andexplaining the properties of matter based on these ICT models. Compressibility of gases.Preservation of the volume of the liquid when changing the shape of the vessel. Lead cylinder clutch.
Frontal laboratory work.
2. Measurement of the sizes of small bodies.
Requirements for the level of training of students.
Know the meaning of concepts: substance, interaction, atom (molecule). Be able to describe and explain a physical phenomenon: diffusion.
III . Phone interaction. (20 hours)
mechanical movement. Uniform and non-uniform movement. Speed.
Calculation of the path and time of movement. Trajectory. Rectilinear movement.
Phone interaction. Inertia. Weight. Density.
Measurement of body weight on the scales. Calculation of mass and volume by its density.
Strength.Forces in nature: gravity, gravity, friction, elasticity. Hooke's law. Body weight. Relationship between gravity and body mass. Dynamometer. The addition of two forces in the same straight line.Friction.
Elastic deformation.
Frontal laboratory work.
3. Measurement of body weight on a balance scale.
4. Measurement of the volume of a solid body.
5. Determination of the density of a solid.
6.Dynamometer. Graduation of the spring and measurement of forces with a dynamometer.
Requirements for the level of training of students.
Know:
phenomenon of inertia, physical law, interaction;
the meaning of the concepts: path, speed, mass, density.
Be able to:
describe and explain uniform rectilinear motion;
use physical instruments to measure the path, time, mass, force;
identify the dependence: path on distance, speed on time, force on speed;
express quantities in SI.
Know that the measure of the interaction of bodies is force. Be able to give examples.
Know:
determination of mass;
units of mass.
Be able to reproduce or write a formula.
Know the definition of the density of a substance, the formula. Be able to work with the physical quantities included in this formula.
Be able to work with instruments when finding body weight, with a beaker and scales.
Be able to work with the physical quantities included in the formula for finding the mass of a substance.
To be able to reproduce and find physical quantities: mass, density, volume of matter.
Know the definition of force, its units of measurement and designations. Know the definition of gravity.
Be able to schematically depict the point of its application to the body.
Know the definition of elastic force. Be able to schematically depict the point of its application to the body.
Working out the formula for the relationship between strength and body weight.
Be able to work with physical devices. Instrument scale graduation.
The ability to draw up diagrams of vectors of forces acting on a body.
Know the definition of friction force. Be able to give examples.
IV .Pressure of solids, liquids and gases. (21 hours)
Pressure.The Torricelli experience.
Aneroid barometer.
Atmospheric pressure at various altitudes. Pascal's law.Ways to increase and decrease pressure.
Gas pressure.Air weight. Air shell. Measurement of atmospheric pressure. Pressure gauges.
Piston liquid pump. Transmission of pressure by solids, liquids, gases.
The action of liquid and gas on a body immersed in them. Calculation of liquid pressure on the bottom and walls of the vessel.
communicating vessels. Archimedean strength. Hydraulic Press.
Swimming tel. Sailing ships. Aeronautics.
Frontal laboratory work.
7. Measurement of the buoyant force acting on a body immersed in a liquid.
Requirements for the level of training of students.
Know the definition of physical quantities: pressure, density of matter, volume, mass.
Know the meaning of physical laws: Pascal's law.
Be able to:
explain the transfer of pressure in liquids and gases;
use physical instruments to measure pressure;
express quantities in SI.
Know the meaning of physical laws: the law of Archimedes.
Be able to solve problems on the principle of Archimedes.
To be able to reproduce and find physical quantities according to the formula of the law of Archimedes.
V . work and power. Energy. (3 pm)
Job. Power. Energy. Kinetic energy. Potential energy. The law of conservation of mechanical energy. simple mechanisms. mechanism efficiency.
Lever arm. The balance of forces on the lever. Moment of power. Levers in technology, everyday life and nature.
Application of the law of balance of the lever to the block. Equality of work when using simple mechanisms. The "golden rule" of mechanics.
Frontal laboratory work.
8. Finding out the equilibrium condition of the lever.
9. Determination of efficiency when lifting the cart on an inclined plane.
Requirements for the level of training of students.
Know the definition of work, the designation of a physical quantity and the unit of measurement.
Know the definition of power, the designation of a physical quantity and the unit of measurement.
Be able to reproduce formulas, find physical quantities: work, power.
Know the device of the lever. To be able to depict the location of forces in the figure and find the moment of force.
Be able to:
conduct an experiment and measure the length of the arms of the lever and the mass of loads;
work with physical devices.
Know the device of the block and the golden rule of mechanics, explain with examples.
Know the definitions of physical quantities: work, power, efficiency, energy.
Know the definitions of physical quantities: the efficiency of mechanisms.
To be able to determine the force, height, work (useful and expended).
Know:
definition of physical quantities: energy, types of energy;
energy units;
law of energy conservation.
Know the meaning of the law of conservation of energy, give examples of mechanical energy and its transformation.
Be able to solve problems.
VI . Repetition. (2 hours)
Requirements for the level of training of students.
Know definitions, designations, finding the studied quantities. Know basic concepts
St. Petersburg
2014-2015
Name of program sections | Pages |
|
Explanatory note | ||
General characteristics of the subject | ||
Learning objectives | ||
General educational skills, skills and methods of activity | ||
Learning Outcomes | ||
Requirements for the level of knowledge of graduates | ||
Forms and means of control. | ||
Educational and thematic planning | ||
Training and metodology complex | ||
Calendar-thematic planning |
Explanatory note.
Document structure.
The work program in physics includes three sections: an explanatory note; the main content with an approximate distribution of teaching hours by sections of the course, the recommended sequence for studying topics and sections; requirements for the level of training of students.
1.1 General characteristics of the subject.
Physics as a science about the most general laws of nature, acting as a subject in the lyceum, makes a significant contribution to the system of knowledge about the world around. It reveals the role of science in the development of society, contributes to the formation of a modern scientific worldview. Familiarization of students with the methods of scientific knowledge is supposed to be carried out when studying all sections of the physics course, and not only when studying the special section “Physics and methods of scientific knowledge”.
For problem solving formation of the foundations of the scientific worldview, the development of intellectual abilities and cognitive interests of students in the process of studying physics, the main attention should be paid to familiarization with the methods of scientific knowledge of the world around us, the formulation of problems that require students to work independently to resolve them.
The study of physics as an integral part of general education lies in the fact that it equips students with the scientific method of cognition, which allows them to obtain objective knowledge about the world around them. .
Knowledge of physical laws is necessary for the study of chemistry, biology, physical geography, technology, life safety.
The course of physics in the exemplary program of basic general education is structured on the basis of physical theories: physics and physical methods of cognition of nature; mechanical phenomena; thermal phenomena; electrical and magnetic phenomena; electromagnetic oscillations and waves; quantum phenomena.
Work program of the subject physics designed for 7th grade students and compiled on the basis of:
Federal Law of December 29, 2012 No. 273-F "On Education in the Russian Federation"
Federal component of the state standard of basic general education, approved by order Ministry of Education of the Russian Federation dated 05.03.2004 No. 1089
the curriculum of GBOU Lyceum No. 226 for the 2014/2015 academic year;
the annual calendar academic schedule of the lyceum for the 2014/2015 academic year.
exemplary program of basic general education in physics.
1.2 Learning objectives
The study of physics is part implementation of the educational program Lyceum No. 226 is aimed at achieving the following goals:
learning about thermal, electromagnetic and quantum phenomena; quantities characterizing these phenomena; the laws to which they are subject; about the methods of knowledge of nature and formation on this basis of ideas about the physical picture of the world.
mastery of skills conduct observations of natural phenomena; describe and generalize the results of observations; use simple measuring instruments to study physical phenomena; present the results of observations or measurements using tables, graphs and identify empirical dependencies on this basis; apply the acquired knowledge to solve physical problems;
application of knowledge in physics to explain natural phenomena, the properties of matter, the principles of operation of technical devices, solve physical problems, independently acquire and evaluate the reliability of new information of physical content, use modern information technologies to search, process and present educational and popular science information in physics;
development of cognitive interests, intellectual and creative abilities in the process of solving physical problems and performing experiments; the ability to independently acquire new knowledge in physics in accordance with vital needs and interests;
upbringing confidence in the cognizability of the surrounding world; the spirit of cooperation in the process of joint implementation of tasks, respect for the opinion of the opponent, the validity of the expressed position, readiness for a moral and ethical assessment of the use of scientific achievements, respect for the creators of science and technology , providing the leading role of physics in the creation of the modern world of technology;
use of acquired knowledge and skills for solving practical life problems, ensuring the safety of human life and society.
1.3 General educational skills, skills and methods of activity
The exemplary program provides for the formation of schoolchildren's general educational skills, universal methods of activity and key competencies. In this direction, the priorities for the school physics course at the stage of basic general education are:
Cognitive activity:
use for knowledge of the surrounding world of various natural sciences
methods: observation, measurement, experiment, modeling;
the formation of skills to distinguish between facts, hypotheses, causes, consequences, evidence
evidence, laws, theories;
mastering adequate methods for solving theoretical and experimental
acquiring the experience of putting forward hypotheses to explain known facts and
experimental verification of put forward hypotheses
Information and communication activities:
possession of monologue and dialogic speech, development
the ability to understand the point of view of the interlocutor and to recognize the right to otherwise
use for solving cognitive and communicative tasks
various sources of information.
Reflective activity:
possession of the skills of monitoring and evaluating their activities, the ability to
anticipate the possible results of your actions:
organization of educational activities: goal setting, planning,
determination of the optimal ratio of goals and means.
1.4 Learning outcomes
The implementation of the calendar-thematic plan ensures the development of general educational skills and competencies within the framework of information and communication activities: the ability to convey the content of the text in a compressed or expanded form in accordance with the purpose of the task; create written statements (plan, theses, synopsis); the ability to use various sources of information, including encyclopedias, dictionaries, Internet resources and other databases; consciously choose the expressive means of the language and sign systems: text, table, diagram, audiovisual series, etc. Students are supposed to confidently use multimedia resources and computer technologies for processing, transmitting and systematizing information, presenting cognitive and practical activities.
2. REQUIREMENTS FOR THE LEVEL OF GRADUATE TRAINING
7 CLASS
EDUCATIONAL INSTITUTIONS OF THE BASIC GENERAL
EDUCATION
As a result of studying physics, the student should
know/understand
meaning of concepts: physical phenomenon, physical quantity, model, hypothesis, interaction, atom, atomic nucleus, ionizing radiation;
meaning of physical quantities: displacement, speed, mass, density, force, pressure, momentum, work, power, mechanical energy, kinetic energy, potential energy, moment of force, efficiency;
meaning of physical laws: Pascal, Archimedes, Newton, Hooke, the law of universal gravitation, the laws of conservation of energy, momentum;
contribution of Russian and foreign scientists , which had the greatest influence on the development of physics;
be able to
describe and explain the results of observations and experiments: uniform rectilinear motion, uniformly accelerated rectilinear motion, transfer of pressure by liquids and gases, floating of bodies;
use physical instruments and measuring instruments to measure physical quantities: distance, time interval, mass, force, pressure, temperature, air humidity;
give examples of the practical use of physical knowledge about mechanical and thermal phenomena;
apply the acquired knowledge to solve physical problems;
define: the nature of the physical process according to the schedule, table, formula;
to measure: speed, acceleration of free fall; body mass, substance density, force, work, power, energy, coefficient of sliding friction;
express the results of measurements and calculations in units of the International System;
present measurement results using tables, graphs and identify empirical dependencies on this basis: path from time, elastic force from the elongation of the spring, friction force from the force of normal pressure;
use the acquired knowledge and skills in practical activities and everyday life for:
ensuring life safety in the process of using vehicles, household electrical appliances, electronic equipment;
rational use of simple mechanisms;
radiation background safety assessments.
Psychological and pedagogical characteristics of the team of 7th grade
The work program is compiled taking into account the individual characteristics of students in the 7th grade and the specifics of the class team. There are 25 students in the class, of which 14 are boys and 11 are girls. A distinctive age-related feature of children is the increased interest in each other on the part of boys and girls, which should also be taken into account when organizing work in groups of permanent and shift composition and when seating children in a classroom.
There are fairly even, generally friendly relations between students. above baseline
Psychological and pedagogical characteristics of the team 7 b class
The work program is compiled taking into account the individual characteristics of students in grade 7b and the specifics of the class team. There are 25 children in the class, of which 17 are boys, and 8 are girls. class.
There are fairly even, generally conflict-free relations between students. There is a group of children who are distinguished by an extremely slow pace of activity, are hardly involved in collective (group or pair) work, are embarrassed to give answers orally, and do not differ in competent monologue speech. In working with these children, an individual approach will be applied both in the selection of educational content, adapting it to the intellectual characteristics of children, and in the choice of forms and methods of its development.
The bulk of the students in the class are children with a sufficiently high level of abilities and motivation for learning, who are able to master the program in the subject above baseline. They are distinguished by sufficient organization, discipline, responsible attitude to the implementation of educational, especially homework assignments.
With this in mind, the content of the lessons includes material of an increased level of complexity, differentiated tasks are offered both at the stage of working out ZUNs and at the stage of control. The organization of work with this group of students also takes into account the fact that they do not differ in a high level of independence in educational activities and are more successful in working according to the model than in performing tasks of a creative nature. These guys are often unsure of themselves, suspicious, afraid of making mistakes and have difficulty experiencing their own failures. In order to correct and level these features, the children will study individual topics on their own using individual educational programs (IEP).
Psychological and pedagogical characteristics of the team 7 in the class
The work program is compiled taking into account the individual characteristics of students in the 7th grade and the specifics of the class team. There are 16 students in the class, of which 5 are boys and 11 are girls. A distinctive age-related feature of children is the increased interest in each other on the part of boys and girls, which should also be taken into account when organizing work in groups of permanent and shift composition and when seating children in a classroom.
There are fairly even, generally conflict-free relations between students, but there is a child who stands out from the class team. In working with this child, an individual approach should be used both in the selection of educational content, adapting it to the intellectual characteristics of the child, and in the choice of forms and methods of its development, which should correspond to personal characteristics.
The bulk of the students in the class are children with a very average level of ability and low motivation for learning (most children come to school to communicate), who find it difficult master the program in the subject even at a basic level. They are characterized by poor organization, indiscipline, often irresponsible attitude to the performance of educational, especially homework assignments. They have insufficiently formed basic mental functions (analysis, comparison, highlighting the main thing), poor memory.
In the class, one can single out a group of students who quite often do not have everything they need for the lesson, do not do their homework. In order to include these children in the work at the lesson, non-traditional forms of organizing their activities, frequent changes in the types of work will be used, because these children are not able to force themselves to work by force of will.
In general, students in the class are very heterogeneous in terms of their individual characteristics: memory, attention, imagination, thinking, level of performance, pace of activity, temperament. This necessitated the use of different channels of perception of educational material, various forms and methods of work in working with them.
Forms and means of control.
The main methods for testing students' knowledge and skills in physics are oral questioning, written and laboratory work. Written forms of control include: physical dictations, independent and control work, tests. The main types of knowledge testing are current and final. The current check is carried out systematically from lesson to lesson, and the final check is carried out at the end of the topic (section), school course.
Distribution of written works by course
4. Educational and thematic plan
Grade 7: 102 hours per year, 3 hours per week
Number of hours | Section topic | Number of hours to study | List of labs |
/ 5 | Observation and description of physical phenomena . International System of Units (SI) | 1. Determination of the division value of the measuring instrument. 2. Determining the volume of a cuboid and a cylinder using a ruler |
|
Measurement errors | |||
/ 8 | The structure of matter. molecules | 3. Measurement of the dimensions of small bodies |
|
Diffusion in gases, liquids and solids | |||
Three states of matter. The difference in the molecular structure of solids, liquids and gases | |||
Interaction of bodies / 32 | four . Measurement of body weight on a balance scale 5. Measurement of body volume 6. Determination of the density of a solid body 7. Determination of the density of potatoes and the percentage of starch in it 8. Graduation of the spring and measurement of forces with a dynamometer |
||
The phenomenon of inertia | |||
Phone interaction. Mass and density of matter | |||
Phone interaction. Examples of forces in nature | |||
Pressure of solids, liquids and gases / 33 | Pressure. Pressure units | 9. Determination of the buoyancy force acting on a body immersed in a liquid 10. Finding out the conditions for floating a body in a liquid |
|
Pressure of gas and liquid. Pascal's law | |||
Air weight. Atmosphere pressure | |||
The action of liquid and gas on a body immersed in them. Archimedean force | |||
work and power. Energy/16 | Work and power | 11. Elucidation of the equilibrium condition for the lever 12. Determination of efficiency when lifting a body along an inclined plane |
|
simple mechanisms. efficiency | |||
Repetition / 8 | Repetition, problem solving |
Changes made to the sample program
The program was amended based on the curriculum of the GBOU secondary school No. 226 for the 2014/2015 academic year, according to which the lyceum implements an expanded program for studying physics in the 7th grade. At the same time, considerable time is allocated for the formation and development of the ability to solve qualitative, computational and experimental problems at workshops on solving problems of an increased and high level of complexity.
The comparison table is shown below.
Chapter | Number of hours in the sample program | Number of hours in the work program |
|
in the example program | in the work program |
||
Physics and physical methods of studying nature | Physics and physical methods of studying nature | ||
Initial information about the structure of matter | Initial information about the structure of matter | ||
Interaction of bodies | Interaction of bodies | ||
Pressure of solids, liquids and gases | |||
Power and work. Energy | Power and work. Energy | ||
Repetition | Repetition | ||
Total |
The introduction of these changes allows you to cover all the material studied in the program, increase the level of students' learning in the subject, and also more effectively implement an individual approach to students.
The work program provides for a reserve of free study time in the amount of 2 hours for the implementation of author's approaches, the use of various forms of organization of the educational process, the introduction of modern teaching methods and pedagogical
technologies.
1) Technology of modern project-based learning
2) Activity technologies
3) Culture-educating technology of differentiated education according to the interests of children (I.N. Zakatova).
4) Technologies of level differentiation. Model "Intra-class (intra-subject) differentiation" (N.P. Guzik)
5. EDUCATIONAL AND METHODOLOGICAL COMPLEX:
Student:
1. Textbook: Peryshkin A.V. Physics: a textbook for the 7th grade of general educational institutions - 10th ed., stereotype. - M.: Bustard, 2010. -192 p.: ill.
2. Physics. Grade 7: teaching aid / A.E. Maron, E.A. Maroon. – 6th ed., stereotype. - M.: Bustard, 2008.- 125 . \
Teacher:
3. Gutnik E.M., Rybakov E.V. Physics. Grade 7: thematic and lesson planning for the textbook by A.V. Peryshkin “Physics. 7th grade". – 3rd ed., stereotype. - M.: Bustard, 2005. - 93 p.
4 Physics. Grade 7/S.N. Domnina. - M: National Education, 2012. - 96s
5. Getting ready for the GIA. Physics grade 7. Final testing in the format of the exam / Ed.-ed.: M.V. Boydenko, O.N. Miroshkin. - Yaroslavl, 2010. 64s.
6. Calendar-thematic planning (educational-thematic plan)
№p \ n lesson | lesson numberon topic | § | Lesson type | Topic name | Requirements for the level of training | Number of hours | terms | Note(forms and methods of control) |
|
Learning new material | Safety precautions in the physics classroom. What does physics study. Observations and experiments. | Know: the meaning of the term "substance". Be able to: use physical instruments and measuring instruments to measure physical quantities. Express results in SI. | 1 .09 |
Combined lesson | Physical quantities. Measurement of physical quantities. Accuracy and error of measurements. | 3 .09 | Oral responses |
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Workshop Lesson | Laboratory work No. 1 "Determining the division value of a measuring device" | 5 .09 | |||||||
Workshop Lesson | Laboratory work No. 2 "Determining the volume of a rectangular parallelepiped and a cylinder using a ruler" | 8 .09 | |||||||
Combined lesson | Physics and technology | 10 .09 | Oral responses |
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Initial information about the structure of matter | |||||||||
Combined lesson | The structure of matter. Molecules. | Know the meaning of the concepts: substance, interaction, atom (molecule). Be able to: describe and explain the physical phenomenon of diffusion Acquisition of skills in working with equipment. Ability to draw conclusions | 12 .09 | Physical dictation |
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Workshop Lesson | Laboratory work No. 3 "Measuring the size of small bodies" | 15 .09 | |||||||
Combined lesson | Diffusion in gases, liquids and solids. | 17 .09 | |||||||
Lesson in application of knowledge | Mutual attraction and repulsion of molecules | 19 .09 | Training tasks |
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Knowledge control lesson | Three states of matter. The difference in the molecular structure of solids, liquids and gases. | 22 .09 | Independent work. Problem solving |
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Lesson-practice | Lesson workshop "The structure of matter" | 24 .09 | Compilation of the classification table "Structure of matter" |
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Lesson in application of knowledge | Repetitive-generalizing lesson on the topic "Initial information about the structure of matter" | 26 .09 | |||||||
A Lesson in Control | Test No. 1 "Initial information about the structure of matter" | 29 .10 | Problem solving |
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Interaction of bodies | |||||||||
Learning new material | mechanical movement. Uniform and uneven movement | Know: - phenomenon of inertia, physical law, interaction; The meaning of the concepts: path, speed, mass, density. Be able to: Describe and explain uniform rectilinear motion; Use physical instruments to measure distance, time, mass and force; Reveal the dependence: path on distance, speed on time, force on speed; Express quantities in SI | 1 .10 | Problem Solving Workshop |
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Learning new material | Speed. Speed units | 3 .10 | Theoretical survey on the material |
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Combined lesson | Calculation of the path and time of movement. | 6 .10 | Physical dictation |
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Workshop on problem solving. Calculation of path and time. | 8 .10 | Testing |
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A Lesson in Control | Workshop on problem solving. Graphical representation of movement. | 10 .10 | Problem Solving Workshop |
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Knowledge consolidation lesson | Workshop on problem solving. Average speed. | 13 .10 | Problem Solving Workshop |
Lesson in application of knowledge | 15 .10 | Verification work |
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Combined lesson | The phenomenon of inertia. | 17 .10 | Oral survey on the material |
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Combined lesson | Phone interaction. Body mass. Mass units. | Know, that the measure of any interaction of bodies is force, the definition of mass, units of mass. Be able to give examples | 20 .10 | Oral responses |
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Workshop Lesson | Laboratory work No. 4 "Measurement of body weight on a balance scale" | Skill work with devices while finding body weight | 22 .10 | ||||||
Workshop Lesson | Laboratory work No. 5 "Measurement of body volume" | Skill work with instruments when finding the volume of the body | 24 .10 | ||||||
Combined lesson | Matter density | Know determination of the density of a substance, formula. Be able to work with physical quantities included in this formula | 27 .10 | Theoretical survey on the material |
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Combined lesson | Calculation of the mass and volume of a body by its density. | 29 .10 | Theoretical survey on the material |
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Combined lesson | 31 .10 | Problem Solving Workshop |
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Lesson for assessing knowledge on the topic | Workshop on solving problems with the calculation of volume, finding the number of objects. | 10 .11 | Problem Solving Workshop |
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Workshop Lesson | Laboratory work No. 6 "Determination of the density of a solid substance" | Be able to | 12 .11 | ||||||
Workshop Lesson | Lab #7"Determination of the density of potatoes and the percentage of starch in it" | Be able to work with instruments (beaker, scales). | 14 .11 | ||||||
Lesson for assessing knowledge on the topic | Verification work with an experimental task. | Be able to work with physical quantities included in the formula for finding the mass of a substance | 17 .11 | Verification work |
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Learning new material | Strength. Units of power. | Know definition of force, its units of measurement and designations | 19 .11 | Theoretical survey on the material |
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Learning new material | The phenomenon of attraction. Gravity | Know determination of gravity. Be able to | 21 .11 | Theoretical survey on the material |
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Learning new material | Elastic force. Hooke's Law | Know determination of the elastic force. Be able to schematically depict the point of its application to the body. | 24 .11 | Theoretical survey on the material |
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Learning new material | Body weight. Weightlessness. | Know determination of body weight. Be able to schematically depict the point of its application to the body | 26 .11 | Theoretical survey on the material. |
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Knowledge consolidation lesson | Relationship between gravity and body mass | Explain and classify the acquired knowledge. Working out the formula between strength and body weight | 28 .11 | Problem Solving Workshop |
Workshop Lesson | Dynamometer. Laboratory work No. 8 "Calibration of a spring and measurement of forces with a dynamometer" | Be able to work with physical devices. Instrument scale graduation. | 1 .12 | ||||||
Learning new material | The addition of two forces in the same straight line. Resultant force | Know: rule of addition of forces. Be able to: draw diagrams of vectors of forces acting on a body | 3 .12 | Frontal survey |
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Learning new material | Friction force. Sliding friction. Friction of rest. | Know the concepts: friction forces. Be able to: give examples. | 5 .12 | Physical dictation |
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Combined lesson | Friction in nature and technology | 8 .12 | Theoretical survey on the material |
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Workshop Lesson | Lesson-practice “The study of the dependence of the force of sliding friction on the type of rubbing surfaces, the pressure force, the area of \u200b\u200bsupport. Comparison of static friction, sliding, rolling " | 10 .12 | |||||||
Knowledge consolidation lesson | General lesson on the topic "Movement and interaction of bodies" ("Here the city will be founded") | Be able to solve problems on the topic "Movement and interaction of bodies." | 12 .12 | Solving problems on the topic "Structure of the atom" |
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Knowledge consolidation lesson | Preparing for the test | 15 .12 | |||||||
lesson-control | Test No. 2 on the topic "Movement and interaction of bodies" | 17 .12 | Problem solving |
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Knowledge Correction Lesson | Be able to | 19 .12 | |||||||
Learning new material | Pressure. Pressure units | Know determination of pressure, density, substances, volume and mass | 22 .12 | Theoretical survey on the material |
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Learning new material | Ways to reduce and increase pressure | 24 .12 | Theoretical survey on the material |
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Combined lesson | Workshop on problem solving. (calculation of the pressure of a solid body, taking into account the formulas for body weight, density, volume of a rectangular parallelepiped) | 26 .12 | Problem solving |
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Combined lesson | 12 .01 | Problem solving |
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Combined lesson | Workshop on problem solving. (calculation of the pressure of a solid body, taking into account the formulas for the weight of the body, density, volume of a rectangular parallelepiped, taking into account the changing mass of the pressing body, calculation of the pressure of the plate (if only its thickness is given)) | 14 .01 | Problem solving |
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Knowledge consolidation lesson | Verification work with an experimental task | 16 .01 | Verification work |
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Combined lesson | Gas pressure. | Know: properties of gases, experiments proving gas pressure, conditions for increasing and decreasing gas pressure. | 19 .01 | Theoretical survey on the material |
Combined lesson | Pascal's law. Pressure in liquid and gas | Know meaning of physical laws : Pascal's law. Be able to: Explain pressure transfer in liquids and gases; Use physical instruments to measure pressure; Express quantities in SI | 21 .01 | Theoretical survey on the material |
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Combined lesson | Calculation of the liquid pressure at the bottom of the vessel. Pressure in liquid and gas | 23 .01 | Independent work with equipment |
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Knowledge consolidation lesson | Workshop on problem solving. Solving problems for calculating the pressure of a liquid on the bottom and walls of a vessel and determining the pressure force. | 26 .01 | Verification work |
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Combined lesson | Communicating vessels. The use of communicating vessels. | 28 .01 | Theoretical survey on the material |
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Knowledge consolidation lesson | Intermediate generalization of the topic "Pressure of solids, liquids and gases" "Physics in wildlife" | 30 .01 | Theoretical survey on the material |
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lesson-control | Examination No. 3 on the topic "Pressure". Pascal's Law" | 2 .02 | Problem solving |
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Combined lesson | Air weight. Atmosphere pressure. Why does the Earth's atmosphere exist? | Be able to: describe and explain the phenomenon of atmospheric pressure. Know: background | 4 .02 | Theoretical survey on the material |
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Combined lesson | Measurement of atmospheric pressure. The Torricelli experience. | Be able to: measure atmospheric pressure with a barometer. Know: historical Torricelli experience | 6 .02 | Problem solving. Verification work |
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Combined lesson | Aneroid barometer. Atmospheric pressure at various altitudes | Be able to: explain how atmospheric pressure changes with altitude | 9 .02 | Theoretical survey on the material |
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Lesson workshop | Lesson-practice.“Problem solving: rules of communicating vessels. Atmospheric pressure measurement» | Be able to: solve problems for calculating the pressure of a liquid in communicating vessels; measure atmospheric pressure | 11 .02 | Problem solving |
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Combined lesson | Pressure gauges. Piston and liquid pump. Hydraulic Press. | Know/Understand: application of hydraulic machines, piston and liquid pumps | 13 .02 | Theoretical survey on the material |
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Combined lesson | The action of liquid and gas on a body immersed in them. Archimedean force | Know/Understand: the meaning of the law of Archimedes | 16 .02 | Theoretical survey on the material |
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Workshop Lesson | Laboratory work No. 9 "Determination of the buoyant force acting on a body immersed in a liquid" | Know/Understand: how to determine the buoyant force acting on a body immersed in a liquid | 18 .02 | ||||||
Combined lesson | Workshop on problem solving. Determination of the Archimedes force, taking into account the formula for the volume of a rectangular parallelepiped, with mathematical transformations of the direct formula. | Be able to solve problems for calculating the force of Archimedes; be able to use reference books | 20 .02 | Problem solving |
Combined lesson | Be able to: -- solve problems for calculating the force of Archimedes; Use reference literature; Use formulas to calculate density and volume when determining the Archimedes force | 25 .02 | Problem solving |
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Combined lesson | Workshop on problem solving. Solving problems in which the density formula is used to find the volume of a body, tasks: “What force must be applied to ... to keep it under water?” | 27 .02 | Problem solving |
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Combined lesson | Swimming bodies | know/understand floating conditions of bodies; be able to solve problems on the use of navigation conditions | 2 .03 | Physical dictation |
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Workshop Lesson | Laboratory work No. 10 "Clarifying the conditions for swimming a body in a liquid" | Be able to describe and explain the conditions for floating bodies | 4 .03 | ||||||
Combined lesson | Sailing ships. Aeronautics | know/understand ship navigation conditions; principles of aeronautics | 6 .03 | Physical dictation |
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Combined lesson | Distance learning. | Be able to solve problems for calculating the carrying capacity and displacement of ships | 9 .03 | Problem solving |
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Combined lesson | Workshop on problem solving. Solving problems of load capacity, loading and unloading. | 11 .03 | Physical dictation. Problem solving |
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Combined lesson | Workshop on problem solving. Solving problems of load capacity, loading and unloading. | 13 .03 | Problem solving |
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intermediate control lesson | Verification work with an experimental task. | Be able to | 16 .03 | Problem solving Verification work |
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Combined lesson | Generalization of the topic: "Archimedean force, swimming of bodies, aeronautics." | Be able to use formulas to calculate the Archimedes force, the conditions for floating bodies and the principles of aeronautics | 18 .03 | Problem solving |
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lesson-control | Examination No. 4 on the topic “ Pressure of solids, liquids and gases» | Be able to apply the acquired knowledge in solving problems | 20 .03 | Problem solving |
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Knowledge Correction Lesson | Analysis of control work. Work on mistakes. | Be able to analyze mistakes made in solving problems | 1 .04 | ||||||
work and power. Energy | |||||||||
Learning new material | mechanical work | know/understand the meaning of the value "work", Be able to compute work for the simplest cases | Theoretical survey on the material |
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Lesson in application of knowledge | Problem Solving Workshop | Be able to solve problems on the calculation of mechanical work | Problem solving |
Learning new material | Power | know/understand the meaning of the quantity "power", Be able to calculate power for the simplest cases | Theoretical survey on the material |
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Lesson in application of knowledge | Problem Solving Workshop | Be able to solve problems on the calculation of work and power | 1 0 . 04 | Problem solving |
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Lesson workshop | simple mechanisms. Lever arm. The balance of forces on the lever | Know types of simple mechanisms and their application; Be able to derive the equilibrium condition for the lever | 1 3.04 | Theoretical survey on the material |
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Learning new material | Moment of power | Know formula for calculating the moment of force; be able to apply this formula to solve problems | 1 5.04 | Theoretical survey on the material |
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Workshop Lesson | Problem Solving Workshop | Be able to in practice to determine the equilibrium condition of the lever | Independent work |
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Workshop Lesson | Levers in technology, everyday life and nature. Laboratory work No. 11 "Clarification of the equilibrium condition of the lever" | know/explain where and for what blocks are used; distinguish between movable and fixed blocks | 2 0.04 | ||||||
58,59 | Learning new material | Blocks. Gate. Polyspast. Inclined plane. | know/understand the meaning of the "golden rule" of mechanics, apply this rule when solving problems | 2 2.04 | Theoretical survey on the material |
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Workshop Lesson | Lesson-practice“Comparison of mechanical work when moving a load horizontally and vertically”, “Calculation of the gain in strength of tools in which a lever is applied” | know/understand the meaning of efficiency, be able to calculate the efficiency of simple mechanisms | 2 4.04 | Problem solving |
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60,61 | Combined lesson | "Golden rule of mechanics" Efficiency of the mechanism. | know/understand the meaning of the efficiency of an inclined plane, be able to calculate the efficiency of an inclined plane | 2 7.04 | Theoretical survey on the material |
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Combined lesson | Problem Solving Workshop | Be able to In practice, determine the efficiency of an inclined plane, Describe ways to increase the efficiency of simple machines | Practical work |
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Workshop Lesson | Laboratory work No. 12 "Determining the efficiency when lifting a body along an inclined plane" | Be able to solve problems for calculating the efficiency of simple mechanisms and the "golden rule" of mechanics | |||||||
Learning new material | Energy. Potential and kinetic energy. Problem solving | know/understand the physical meaning of mechanical, kinetic and potential energy, know the formulas for their calculation | Theoretical survey on the material |
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Knowledge consolidation lesson | Examination No. 5 on the topic “Work and power. Energy." | know/understand physical meaning of the law of conservation of mechanical energy; applying it to solve problems | Problem solving |
Learning new material | The transformation of one type of mechanical energy into another. Law of conservation of total mechanical energy | Be able to apply the acquired knowledge in solving problems | 1 1.05 | Problem solving |
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Repetition. | |||||||||
A Lesson in Repetition and Generalization | Initial information about the structure of matter | 1 3.05 | |||||||
A Lesson in Repetition and Generalization | Interaction of bodies | 1 5.05 | |||||||
A Lesson in Repetition and Generalization | Pressure of solids, liquids and gases | ||||||||
A Lesson in Repetition and Generalization | work and power. Energy | ||||||||
Lesson in application of knowledge | Final control work. | Control and accounting of knowledge |
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Knowledge consolidation lesson | Analysis of the final test | ||||||||
Total hours |
Planned results of mastering the subject
Personal results:
The formation of cognitive interests based on the development of intellectual and creative abilities of students;
Conviction in the possibility of understanding nature, in the need for the reasonable use of the achievements of science and technology for the further development of human society, respect for the creators of science and technology, attitude towards physics as an element of human culture;
Independence in acquiring new knowledge and practical skills;
Willingness to choose a life path in accordance with one's own interests and capabilities;
Motivation of educational activity of schoolchildren on the basis of a personality-oriented approach;
Formation of value relations to each other, the teacher, the authors of discoveries and inventions, the results of learning.
Metasubject Results
Determine and formulate the purpose of the activity in the lesson.
Speak the sequence of actions in the lesson.
Learn to express your assumption (version) on the basis of working with a textbook illustration.
Learn to work according to the plan proposed by the teacher.
Learn to distinguish the right task from the wrong one.
To learn together with the teacher and other students to give an emotional assessment of the activities of the class in the lesson.:
Navigate in your system of knowledge: to distinguish the new from the already known with the help of a teacher.
Make a preliminary selection of sources of information: navigate in the textbook (on the spread, in the table of contents, in the dictionary).
Get new knowledge: find answers to questions using the textbook, your life experience and the information received in the lesson.
Process the information received: draw conclusions as a result of the joint work of the whole class.
Process the received information: compare and classify.
Transform information from one form to another: compose physical stories and tasks based on the simplest physical models (subject, drawings, schematic drawings, diagrams); find and formulate a solution to the problem using the simplest models (subject, drawings, schematic drawings, diagrams).
Communicate your position to others: formulate your idea in oral and written speech (at the level of one sentence or a short text).
Listen and understand the speech of others.
Jointly agree on the rules of communication and behavior at school and follow them.
Learn to play different roles in the group (leader, performer, critic).
Subject Results
The student will learn:
observe safety and labor protection rules when working with educational and laboratory equipment
recognizemechanical phenomena and explain, based on existing knowledge, the main properties or conditions for the occurrence of these phenomena: uniform and non-uniform rectilinear motion, inertia, interaction of bodies, pressure transfer by solids, liquids and gases, atmospheric pressure, swimming of bodies, equilibrium of solids;
describe the studied properties of bodies and mechanical phenomena using physical quantities: path, speed, body mass, substance density, force, pressure, kinetic energy, potential energy, mechanical work, mechanical power, efficiency of a simple mechanism, friction force; when describing, correctly interpret the physical meaning of the quantities used, their designations and units of measurement, find formulas that relate this physical quantity with other quantities;
recognize thermalphenomena and explain, on the basis of existing knowledge, the main properties or conditions for the occurrence of these phenomena: diffusion, changes in the volume of bodies during heating (cooling), high compressibility of gases, low compressibility of liquids and solids;
distinguish the main features of modelsstructures of gases, liquids and solids;
analyzeproperties of bodies, mechanical phenomena and processes, using physical laws and principles: the law of conservation of energy, the law of universal gravitation, the resultant force, Hooke's law, Pascal's law, Archimedes' law; at the same time, to distinguish between the verbal formulation of the law and its mathematical expression;
solve problems usingphysical laws (law of conservation of energy, Hooke's law, Pascal's law, Archimedes' law) and formulas relating physical quantities (path, speed, body mass, matter density, force, pressure, kinetic energy, potential energy, mechanical work, mechanical power, efficiency simple mechanism, sliding friction force): based on the analysis of the conditions of the problem, select the physical quantities and formulas necessary for its solution, and carry out calculations.
The student will have the opportunity to learn:
use knowledge about mechanical phenomena in everyday life to ensure safety when handling instruments and technical devices, to maintain health and comply with the norms of environmental behavior in the environment;
give examples of the practical use of physical knowledge about mechanical phenomena and physical laws;
methods of searching and formulating evidence for the hypotheses and theoretical conclusions based on empirically established facts;
find a physical model adequate to the proposed task, solve the problem on the basis of existing knowledge of mechanics using the mathematical apparatus,evaluate the reality of the obtained value of a physical quantity.
Content of training
Introduction (4 hours)
Physics is the science of nature. physical phenomena.
Physical properties of bodies. Observation and description of physical phenomena. Physical quantities. Measurements of physical quantities: length, time, temperature. physical devices. International system of units. Accuracy and error of measurements. Physics and technology.
1. Determination of the division value of the measuring instrument.
The structure of matter. Experiments proving the atomic structure of matter. Thermal motion of atoms and molecules.
Brownian motion. Diffusion in gases, liquids and solids. Interaction of particles of matter. Aggregate states of matter. Models of the structure of solids, liquids and gases. Explanation of the properties of gases, liquids and solids based on molecular kinetic concepts.
Frontal laboratory work
2. Determining the size of small bodies.
Interactions of bodies (23 hours)
mechanical movement. Trajectory. Path. Uniform and uneven movement. Speed. Graphs of the dependence of the path and the modulus of speed on the time of movement.
Inertia. Tel inertia. Phone interaction. Body mass. Measurement of body weight. The density of matter. Strength. Gravity. Elastic force. Hooke's law. Body weight. Relationship between gravity and body mass. Gravity on other planets. Dynamometer. The addition of two forces in the same straight line. The resultant of two forces. Friction force. The physical nature of the celestial bodies of the solar system.
3. Measurement of body weight on a balance scale.
4. Measurement of body volume.
5. Determination of the density of a solid body.
6. Graduation of the spring and measurement of forces with a dynamometer.
7. Elucidation of the dependence of the sliding friction force on the contact area of the bodies.
Pressure. Pressure of solids. Gas pressure. Explanation of gas pressure based on molecular kinetic concepts. Transmission of pressure by gases and liquids. Pascal's law. Communicating vessels. Atmosphere pressure. Methods for measuring atmospheric pressure. Barometer, manometer, piston liquid pump. Law of Archimedes. Sailing conditions tel. Aeronautics.
Frontal laboratory work
8. Determination of the buoyant force acting on a body immersed in a liquid.
9. Finding out the conditions for floating a body in a liquid.
Mechanical work. Power. simple mechanisms. Moment of power. Lever balance conditions. The "golden rule" of mechanics. Types of balance. Efficiency factor (COP). Energy. Potential and kinetic energy. Energy transformation.
Frontal laboratory work
10. Elucidation of the equilibrium condition for the lever.
11. Determination of efficiency when lifting a body along an inclined plane.
Final repetition (3h)
Calendar-thematic planning in physics
Class 7
Teacher Anokhina Galina Ivanovna
Number of hours according to the curriculum
Total: 70 hours; per week 2 hours
Scheduled control work 5
Scheduled laboratory work 11
Planning is made in accordance with the Federal State Educational Standard LLC, based on an exemplary Programbasic general educationin physics (2015),the author's program in physics for grades 7-9 (N.V. Filonovich, E.M. Gutnik, M., "Drofa", 2014)
Textbook_ Physics. Grade 7: textbook for educational institutions / A. V. Peryshkin - M. Bustard, 2015
№ p/p | Name of sections and topics of the program | Number of hours | the date holding |
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plan | fact |
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Introduction (4 hours) |
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1 | What does physics study. Some physical terms. Observations and experiments (§ 1-3) | |||||||||||||
2 | Physical quantities. Measurement of physical quantities. Measurement accuracy and error | |||||||||||||
3 | Lab #1 "Determination of the division value of a measuring instrument". | |||||||||||||
4 | Physics and technology (§ 6) | |||||||||||||
Initial information about the structure of matter (6 hours) |
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5 | The structure of matter. Molecules. Brownian motion (§ 7-9). | |||||||||||||
6 | Lab #2 "Determination of the size of small bodies". | |||||||||||||
7 | Movement of molecules (§ 10) | |||||||||||||
8 | Interaction of molecules (§11) | |||||||||||||
9 | Aggregate states of matter. Properties of gases, liquids and solids (§ 12, 13) | |||||||||||||
10 | Generalization on the topic "Initial information about the structure of matter" | |||||||||||||
Interaction of bodies | ||||||||||||||
11 | mechanical movement. Uniform and uneven movement (§ 14, 15) | |||||||||||||
12 | Speed. Speed units (§16) | |||||||||||||
13 | Calculation of the path and time of movement (§ 17) | |||||||||||||
14 | Inertia (§ 18) | |||||||||||||
15 | Interaction of bodies (§ 19) | |||||||||||||
16 | Body mass. Mass units. Measurement of body weight on a scale (§ 20, 21) | |||||||||||||
17 | Lab #3 "Measurement of body weight on a balance scale" | |||||||||||||
18 | The density of matter (§ 22 | |||||||||||||
19 | Lab #4 "Measurement of body volume". | |||||||||||||
20 | Lab #5 "Determination of the density of a solid body" | |||||||||||||
21 | Calculation of the mass and volume of a body from its density (§ 23) | |||||||||||||
22 | Solving problems on the topics: "Mechanical motion", "Mass". "Density of Matter" | |||||||||||||
23 | Test No. 1 on the topics: "Mechanical motion", "Mass", "Density of matter" | |||||||||||||
24 | Analysis of c/r. Strength (§ 24) | |||||||||||||
25 | The phenomenon of attraction. Gravity. Gravity on other planets (§ 25, 26) | |||||||||||||
26 | Elastic force. Hooke's law (§ 27) | |||||||||||||
27 | Body weight. Units of power. Relationship between gravity and body mass (§ 28-29) | |||||||||||||
28 | Dynamometer (§ 30).Lab #6 on the topic "Calibration of a spring and measurement of forces with a dynamometer" | |||||||||||||
29 | The addition of two forces in the same straight line. Resultant of forces (§31) | |||||||||||||
30 | Friction force. Friction of rest (§ 32, 33) | |||||||||||||
31 | Friction in nature and technology (§ 34).Lab #7 "Clarification of the dependence of the force of sliding friction on the area of contact of the bodies" | |||||||||||||
32 | Solving problems on the topic "Forces", "Resultant of forces" | |||||||||||||
33 | Examination No. 2 "Weight", "Graphic representation of forces", "Types of forces", "Resultant force | |||||||||||||
Pressure of solids, liquids and gases (21 h) | ||||||||||||||
34 | Analysis of c/r. Pressure. Pressure units (§ 35) | |||||||||||||
35 | Ways to reduce and increase pressure (§ 36) | |||||||||||||
36 | Gas pressure (§ 37) | |||||||||||||
37 | Transmission of pressure by liquids and gases. Pascal's law (§ 38) | |||||||||||||
38 | Pressure in liquid and gas. Calculation of liquid pressure on the bottom and walls of the vessel (§ 39, 40) | |||||||||||||
39 | Examination No. 3 Presentation on theme: "Pressure in Liquids and Gases. Pascal's Law" | |||||||||||||
40 | Analysis of c/r. Communicating vessels (§ 41) | |||||||||||||
41 | Air weight. Atmospheric pressure (§ 42, 43) | |||||||||||||
42 | Measurement of atmospheric pressure. Experience of Torricelli (§ 44) | |||||||||||||
43 | Aneroid barometer. Atmospheric pressure at various heights (§ 45, 46) | |||||||||||||
44 | Pressure gauges. Piston liquid pump (§ 47) | |||||||||||||
45 | Piston liquid pump Hydraulic press (§ 48, 49) | |||||||||||||
46 | The action of liquid and gas on a body immersed in them (§ 50) | |||||||||||||
47 | Law of Archimedes (§ 51) | |||||||||||||
48 | Lab #8 "Determination of the buoyant force acting on a body immersed in a liquid" | |||||||||||||
49 | Swimming bodies (§ 52) | |||||||||||||
50 | Solving problems on the topic "Archimedean force", "Conditions for floating bodies" | |||||||||||||
51 | Lab #9 "Clarifying the conditions for swimming a body in a liquid" | |||||||||||||
52 | Sailing ships. Aeronautics (§ 53, 54) | |||||||||||||
53 | Solving problems on the topics: "Archimedean force", "Floating bodies", "Aeronautics" | |||||||||||||
54 | Examination No. 4 on the topic “Pressure of solids, liquids and gases | 1 | ||||||||||||
work and power. Energy (13 h) | ||||||||||||||
55 | Analysis of c/r. Mechanical work. Units of work (§ 55) | |||||||||||||
56 | Power. Power units (§ 56) | |||||||||||||
57 | simple mechanisms. Lever arm. Balance of forces on the lever (§ 57, 58) | |||||||||||||
58 | Moment of force (§ 59) | |||||||||||||
59 | Levers in technology, everyday life and nature (§ 60).Lab #10 "Clarification of the conditions for the equilibrium of the lever" | |||||||||||||
60 | Blocks. "Golden Rule" of mechanics (§ 61, 62) | |||||||||||||
61 | Solving problems on the topic "Lever balance", "Moment of force" | |||||||||||||
62 | Center of gravity of the body (§ 63) | |||||||||||||
63 | Conditions for the equilibrium of bodies (§ 64) | |||||||||||||
64 | Efficiency of mechanismsLab #11 "Determination of efficiency when lifting a body along an inclined plane" | |||||||||||||
65 | Energy. Potential and kinetic energy (§ 66, 67) | |||||||||||||
66 | The transformation of one type of mechanical energy into another (§ 68) | |||||||||||||
Examination No. 5 on the topic "Work. Power, energy» | ||||||||||||||
Final repetition | ||||||||||||||
68 | Analysis of c/r.Solving problems "Mechanical and thermal phenomena". | |||||||||||||
69 | "I know I can..." | |||||||||||||
Physics and the world we live in | ||||||||||||||
Section name, topic | Scheduled date | Cause adjustments | Corrective actions | Actual date |
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Date _______________ Signature _________________/___ ____________
Explanatory note
The work program in physics for grade 7 is based onFederal component of the state standardsecondary (complete) general education. The federal basic curriculum for general educational institutions of the Russian Federation allocates 204 hours for the compulsory study of physics at the basic level in grades 7–9 (68 hours in each of the calculation of 2 hours per week). The program concretizes the content of subject topics, suggests the distribution of subject hours by sections of the course, the sequence of studying topics and sections, taking into account inter-subject and intra-subject connections, the logic of the educational process, and the age characteristics of students. A list of demonstrations, laboratory work and practical exercises is also defined. The implementation of the program is providednormative documents:
- The federal component of the state standard of general education (order of the Ministry of Defense of the Russian Federation of 05.03.2004 No. 1089) and the Federal BUP for general educational institutions of the Russian Federation (order of the Ministry of Defense of the Russian Federation of 09.03.2004 No. 1312).
- An exemplary program of basic general education: "Physics" grades 7-9 (basic level) and the author's program E.M. Gutnik, A.V. Peryshkin "Physics" grades 7-9. - Moscow: Bustard, 2009.
- textbook (included in the federal list):
- A.V. Peryshkin. Physics-7 - M .: Bustard, 2006.
- collections of test and text tasks to control knowledge and skills:
- IN AND. Lukashik Collection of questions and problems in physics. 7-9 cells. – M.: Enlightenment, 2006.
Goals course study -development of competencies:
- general education:
Ability to be independent and motivated organize their cognitive activity (from staging to obtaining and evaluating the result);
Skills to use elements of cause-and-effect and structural-functional analysis, determine essential characteristics of the object under study, expanded substantiate judgments, definitions, drive proof of;
Skills use multimediaresources and computer technologies for processing and presenting the results of cognitive and practical activities;
Skills evaluate and correcttheir behavior in the environment, fulfill environmental requirements in practical activities and everyday life.
- subject-oriented:
- understand the growing rolescience, strengthening the relationship and mutual influence of science and technology, turning science into a direct productive force of society: to be aware of the interaction of man with the environment, the possibilities and ways of protecting nature;
Develop cognitive interests and intellectual capabilities in the process of independent acquisition of physical knowledge using various sources of information, including computer ones;
Bring up conviction in the positive role of physics in the life of modern society, understanding of the prospects for the development of energy, transport, communications, etc.; master skills apply the acquired knowledge to obtain a variety of physical phenomena;
Apply acquired knowledge and skills tosafe usesubstances and mechanisms in everyday life, agriculture and production, solving practical problems in everyday life, preventing phenomena that are harmful to human health and the environment.
The program aims to implementpersonality-oriented, activity, problem-search approaches; development by students of intellectual and practical activities.
General characteristics of the subject
Physics as a science of the most general laws of nature, acting as a school subject, makes a significant contribution to the system of knowledge about the surrounding world. It reveals the role of science in the economic and cultural development of society, contributes to the formation of a modern scientific worldview. To solve the problems of forming the foundations of a scientific worldview, developing the intellectual abilities and cognitive interests of schoolchildren in the process of studying physics, the main attention should be paid not to transferring the amount of ready-made knowledge, but to getting acquainted with the methods of scientific knowledge of the world around us, posing problems that require students to work independently to resolve them. Familiarization of schoolchildren with the methods of scientific knowledge is supposed to be carried out in the study of all sections of the physics course, and not only in the study of the special section "Physics and physical methods of studying nature."
The humanitarian significance of physics as an integral part of general education lies in the fact that it equips the student with the scientific method of cognition, which makes it possible to obtain objective knowledge about the world around him.
Knowledge of physical laws is necessary for the study of chemistry, biology, physical geography, technology, life safety.
The course of physics in the exemplary program of basic general education is structured on the basis of consideration of various forms of motion of matter in the order of their complexity: mechanical phenomena, thermal phenomena, electromagnetic phenomena, quantum phenomena. Physics in the basic school is studied at the level of consideration of natural phenomena, acquaintance with the basic laws of physics and the application of these laws in technology and everyday life.
The goals of studying physics
The study of physics in educational institutions of basic general education is aimed at achieving the following goals:
Mastering knowledgeabout mechanical, thermal, electromagnetic and quantum phenomena; quantities characterizing these phenomena; the laws to which they are subject; methods of scientific knowledge of nature and the formation on this basis of ideas about the physical picture of the world;
Skill Masteryconduct observations of natural phenomena, describe and generalize the results of observations, use simple measuring instruments to study physical phenomena; present the results of observations or measurements using tables, graphs and identify empirical dependencies on this basis; apply the acquired knowledge to explain various natural phenomena and processes, the principles of operation of the most important technical devices, to solve physical problems;
Development cognitive interests, intellectual and creative abilities, independence in acquiring new knowledge in solving physical problems and performing experimental research using information technology;
Upbringing conviction in the possibility of understanding nature, in the need for the reasonable use of the achievements of science and technology for the further development of human society; respect for the creators of science and technology; attitudes towards physics as an element of human culture;
Application of acquired knowledge and skillsfor solving practical problems of everyday life, ensuring the safety of one's life, rational use of natural resources and environmental protection.
The place of the subject in the curriculum
The federal basic curriculum for educational institutions of the Russian Federation allocates 210 hours for the compulsory study of physics at the level of basic general education, including in grades VII, VIII and IX, 70 academic hours at the rate of 2 academic hours per week. The exemplary program provides for a reserve of free study time in the amount of 21 hours (10%) for the implementation of original approaches, the use of various forms of organizing the educational process, the introduction of modern teaching methods and pedagogical technologies, and taking into account local conditions.
As a result of studying physics in grade 7, the student must
know/understand:
- meaning of concepts Keywords: physical phenomenon, physical law, substance, interaction, atom, atomic nucleus;
- the meaning of physical quantities: path, speed, mass, density, force, pressure, impulse, work, power, kinetic energy, potential energy, efficiency;
- meaning of physical laws: Pascal, Archimedes, Newton, universal gravitation, conservation of momentum and mechanical energy.
be able to:
- describe and explain physical phenomena: uniform rectilinear motion, pressure transfer by liquids and gases, floating of bodies, diffusion;
- use physical instruments and measuring instruments to measure physical quantities: distance, time interval, mass, force, pressure, temperature;
- present the results of measurements using tables, graphs and, on this basis, identify empirical dependencies: distance from time, elastic force from the elongation of the spring, friction force from the force of normal pressure;
- express the results of measurements and calculations in units of the International System;
- give examples of the practical use of physical knowledge about mechanical phenomena;
- solve problems on the application of the studied physical laws;
- carry out an independent search for information of natural science content using various sources (educational texts, reference and popular science publications, computer databases, Internet resources), its processing and presentation in various forms (verbally, using graphs, mathematical symbols, drawings and block diagrams );
- use the acquired knowledge and skills in practical activities and everyday life:
- to ensure safety in the process of using vehicles;
- monitoring the health of the plumbing, plumbing and gas appliances in the apartment;
- rational use of simple mechanisms.
I. Physics and physical methods of studying nature. (3 hours)
Subject and methods of physics. Experimental method of studying nature. Measurement of physical quantities.
Measurement error. Generalization of the results of the experiment.
Observation of the simplest phenomena and processes of nature with the help of the senses (sight, hearing, touch). Use of simple measuring instruments. Schematic representation of experiments. Methods of obtaining knowledge in physics. Physics and technology.
1. Determination of the scale division value of the measuring instrument.
Know the meaning of the concept of "substance". Be able to use physical instruments and measuring instruments to measure physical quantities. Express results in SI.
II. Initial information about the structure of matter. (7 hours)
Hypothesis about the discrete structure of matter. Molecules. Continuity and randomness of motion of particles of matter.
Diffusion. Brownian motion. Models of gas, liquid and solid body.
Interaction of particles of matter. Mutual attraction and repulsion of molecules.
Three states of matter.
Frontal laboratory work.
2. Measurement of the sizes of small bodies.
Requirements for the level of training of students.
Know the meaning of concepts: substance, interaction, atom (molecule). Be able to describe and explain a physical phenomenon: diffusion.
III. Phone interaction. (20 hours)
mechanical movement. Uniform and non-uniform movement. Speed.
Calculation of the path and time of movement. Trajectory. Rectilinear movement.
Phone interaction. Inertia. Weight. Density.
Measurement of body weight on the scales. Calculation of mass and volume by its density.
Strength. Forces in nature: gravity, gravity, friction, elasticity. Hooke's law. Body weight. Relationship between gravity and body mass. Dynamometer. The addition of two forces in the same straight line. Friction.
Elastic deformation.
Frontal laboratory work.
3. Measurement of body weight on a balance scale.
4. Measurement of the volume of a solid body.
5. Determination of the density of a solid.
6.Dynamometer. Graduation of the spring and measurement of forces with a dynamometer.
Requirements for the level of training of students.
Know:
- phenomenon of inertia, physical law, interaction;
- the meaning of the concepts: path, speed, mass, density.
Be able to:
- describe and explain uniform rectilinear motion;
- use physical instruments to measure the path, time, mass, force;
- identify the dependence: path on distance, speed on time, force on speed;
- express quantities in SI.
Know that the measure of the interaction of bodies is force. Be able to give examples.
Know:
- determination of mass;
- units of mass.
Be able to reproduce or write a formula.
Know the definition of the density of a substance, the formula. Be able to work with the physical quantities included in this formula.
Be able to work with instruments when finding body weight, with a beaker and scales.
Be able to work with the physical quantities included in the formula for finding the mass of a substance.
To be able to reproduce and find physical quantities: mass, density, volume of matter.
Know the definition of force, its units of measurement and designations. Know the definition of gravity.
Be able to schematically depict the point of its application to the body.
Know the definition of elastic force. Be able to schematically depict the point of its application to the body.
Working out the formula for the relationship between strength and body weight.
Be able to work with physical devices. Instrument scale graduation.
The ability to draw up diagrams of vectors of forces acting on a body.
Know the definition of friction force. Be able to give examples.
IV. Pressure of solids, liquids and gases. (21 hours)
Pressure. The Torricelli experience.
Aneroid barometer.
Atmospheric pressure at various altitudes. Pascal's law.Ways to increase and decrease pressure.
Gas pressure. Air weight. Air shell.Measurement of atmospheric pressure. Pressure gauges.
Piston liquid pump. Transmission of pressure by solids, liquids, gases.
The action of liquid and gas on a body immersed in them.Calculation of liquid pressure on the bottom and walls of the vessel.
communicating vessels. Archimedean strength.Hydraulic Press.
Swimming tel. Sailing ships. Aeronautics.
Frontal laboratory work.
7. Measurement of the buoyant force acting on a body immersed in a liquid.
Requirements for the level of training of students.
Know the definition of physical quantities: pressure, density of matter, volume, mass.
Know the meaning of physical laws: Pascal's law.
Be able to:
- explain the transfer of pressure in liquids and gases;
- use physical instruments to measure pressure;
- express quantities in SI.
Know the meaning of physical laws: the law of Archimedes.
Be able to solve problems on the principle of Archimedes.
To be able to reproduce and find physical quantities according to the formula of the law of Archimedes.
V. Work and power. Energy. (3 pm)
Job. Power. Energy. Kinetic energy. Potential energy. The law of conservation of mechanical energy. simple mechanisms. mechanism efficiency.
Lever arm. The balance of forces on the lever. Moment of power. Levers in technology, everyday life and nature.
Application of the law of balance of the lever to the block. Equality of work when using simple mechanisms. The "golden rule" of mechanics.
Frontal laboratory work.
8. Finding out the equilibrium condition of the lever.
9. Determination of efficiency when lifting the cart on an inclined plane.
Requirements for the level of training of students.
Know the definition of work, the designation of a physical quantity and the unit of measurement.
Know the definition of power, the designation of a physical quantity and the unit of measurement.
Be able to reproduce formulas, find physical quantities: work, power.
Know the device of the lever. To be able to depict the location of forces in the figure and find the moment of force.
Be able to:
- conduct an experiment and measure the length of the arms of the lever and the mass of loads;
- work with physical devices.
Know the device of the block and the golden rule of mechanics, explain with examples.
Know the definitions of physical quantities: work, power, efficiency, energy.
Know the definitions of physical quantities: the efficiency of mechanisms.
To be able to determine the force, height, work (useful and expended).
Know:
- definition of physical quantities: energy, types of energy;
- energy units;
- law of energy conservation.
Know the meaning of the law of conservation of energy, give examples of mechanical energy and its transformation.
Be able to solve problems.
VI. Repetition. (2 hours)
As a result of studying physics in the 7th grade, the student must:
know/understand
The meaning of concepts: physical phenomenon, physical law, matter, substance, diffusion, trajectory of the body, interaction; center of gravity of the body;
The meaning of physical quantities: path, speed, mass, density, force, pressure, work, power, kinetic and potential energy;
The meaning of physical laws: Archimedes, Pascal;
be able to
Describe and explain physical phenomena: uniform rectilinear motion, transfer of pressure by liquids and gases, floating of bodies, diffusion;
Use physical instruments and measuring instruments to measure physical quantities: distance, time interval, mass, force, pressure;
Present the results of measurements using tables, graphs and, on this basis, identify empirical dependencies: distance from time, elastic force from the elongation of the spring, friction force from the force of normal pressure;
Express the results of measurements and calculations in units of the International System;
Give examples of the practical use of physical knowledge about mechanical phenomena;
Solve problems on the application of the studied physical laws;
To carry out an independent search for information of natural science content using various sources (educational texts, reference and popular science publications, computer databases, Internet resources), its processing and presentation in various forms (verbally, using graphs, mathematical symbols, drawings and structural diagrams );
use the acquired knowledge and skills in practical activities and everyday life for:
Ensuring safety in the process of using vehicles;
Rational application of simple mechanisms;
Monitoring the serviceability of plumbing, plumbing, gas appliances in the apartment.
Calendar-thematic plan. Physics. 7th grade
Name of the section, topic, lesson | Requirements for the level of preparation of students | Number of hours | Lesson type | Basic terms | D.z. | notes | the date holding | ||
Plan | Fact |
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Physics and physical methods of studying nature | |||||||||
TV in the office. Physics is the science of nature. The concept of a physical body, substance, matter, phenomenon, law | Physics is the science of nature. Observation and description of physical phenomena. physical devices. Physical quantities and their measurement. Physical experiment and physical theory. Physics and technology. Measurement error. International system of units. Physical laws. The role of physics in shaping the scientific picture of the world | Combined lesson | body, substance, matter | § 1, 2, 3. L. No. 5, 12 | |||||
Physical quantities. Measurement of physical quantities. Unit system | Combined lesson | Physical quantities. SI system. Measurement and measurement accuracy. Value of division | § 4, 5; L. No. 25; preparation to l.r. | ||||||
Laboratory work No. 1 "Determining the price of division of the scale of the measuring instrument" | Methods for determining the division price of measuring instrument scales | § 6, make a crossword puzzle | |||||||
Initial information about the structure of matter | |||||||||
The structure of matter. molecules | The structure of matter | Combined lesson | The structure of matter. Molecules and atoms | § 7, 8. L. No. 53, 54, prep. to l.r. | |||||
Laboratory work No. 2 "Measuring the size of small bodies" | Methods for measuring the size of small bodies | Formation of practical skills | |||||||
Diffusion in gases, liquids and solids. The speed of movement of molecules and body temperature | Diffusion. Thermal motion of atoms and molecules. Brownian motion | Combined lesson | Diffusion | § 9, task 2(1). L. No. 66 | |||||
Interaction of particles of matter | Combined lesson | Mutual attraction and repulsion of molecules | § 10, ex. 2(1). L. No. 74, 80 | ||||||
Three states of matter | Models of the structure of gases, liquids and solids | Combined lesson | § eleven | ||||||
The difference in the molecular structure of solids, liquids and gases | Models of the structure of gases, liquids, solids and explanation of differences in molecular structure based on these models | Combined lesson | Properties and differences in the internal structure of solids, liquids and gases | § 12. L. No. 65, 67, 77-79 | |||||
Examination No. 1 on the topic "Initial information about the structure of matter" | A Lesson in Control | ||||||||
Interaction of bodies | |||||||||
mechanical movement. The concept of a material point. What is the difference between travel and travel | mechanical movement. Trajectory. Path. Rectilinear uniform motion | Lesson learning new knowledge | mechanical movement | § 13, task number 4. L. No. 99, 101, 103 | |||||
body speed. Uniform and uneven movement | Speed of rectilinear uniform motion | Combined lesson | Uniform and uneven movement. Speed of rectilinear uniform motion. Speed units | § 14, 15. Ex. 4(1.4) | |||||
Methods for measuring distance, time, speed | Knowledge consolidation lesson | § 16. Ex. 5(2.4) | |||||||
Calculation of speed, distance and time of movement | Knowledge consolidation lesson | § 16 | |||||||
Inertia | Inertia. Uneven movement | Combined lesson | Inertia | Section 17 | |||||
Interaction of bodies | Interaction of bodies | Combined lesson | Interaction of bodies | § eighteen. L. No. 207, 209 | |||||
Body mass. Mass units | Body mass. The device and principle of operation of the scales | Combined lesson | Body mass. Mass units | § 19, 20, preparation for L.R. | |||||
Laboratory work No. 3 "Measurement of body weight on a balance scale" | Methods for measuring body weight | Formation of practical skills | Repeat §19, 20. Ex. 6(1.3) | ||||||
Matter density | Matter density | Combined lesson | Density. Matter density | Section 21. L. No. 265, preparation for l.r. No. 4, 5 | |||||
Laboratory work No. 4.5 “Measurement of V tv. bodies”, “Determination of ρ tv. body" | Methods for measuring body volume and density | Formation of practical skills | Repeat §21. Ex. 7(1,2) | ||||||
Calculation of the mass and volume of a body by its density, problem solving | Knowledge consolidation lesson | Section 22 | |||||||
Calculation of the mass and volume of a body by its density | Knowledge consolidation lesson | Ex. 8(3,4), repeat formulas, preparation for c.r. | |||||||
Strength. Force is the cause of the change in speed | Phone interaction. Strength | Combined lesson | Strength. Force units | Section 23 | |||||
The phenomenon of attraction. Gravity | Gravity | Combined lesson | Gravity. The phenomenon of attraction. Gravity on other planets | Section 24 | |||||
Elastic force. Body weight | Elastic force and weight | Combined lesson | Elastic force | § 25, 26. L. No. 328, 333, 334 | |||||
Units of power. Relationship between strength and body mass | Units of power. Relationship between force and mass. Body weight | Combined lesson | Hooke's law. Dynamometer | § 27, ex. 9(1,3), preparation for l.r. | |||||
Laboratory work No. 6 “Dynamometer. Spring graduation» | Force measurement method | Formation of practical skills | § 28, ex. 10(1.3) | ||||||
Graphic representation of strength. Addition of forces | Addition of forces | Knowledge consolidation lesson | Composition of forces. resultant force | § 29, ex. 11(2,3) | |||||
Friction force. Friction of rest. The role of friction in technology | Friction force | Lesson learning new knowledge | Friction force. Friction of rest. Friction in nature and technology. Bearings. | § 30-32, write an essay on the role of friction in everyday life and nature | |||||
Examination No. 2 on the topic "Interaction of bodies" | A Lesson in Control | ||||||||
Pressure of solids, liquids and gases | |||||||||
Pressure. Ways to reduce and increase pressure | Pressure | Lesson learning new knowledge | Pressure. Units of pressure. Ways to increase and decrease pressure | § 33, 34. Ex. 12(2,3), ex. 13, task 6 | |||||
Gas pressure | Pressure | Combined lesson | § 35. L. No. 464, 470 | ||||||
Gas pressure. Repetition of the concepts of "density", "pressure" | Pressure, gas density | Knowledge consolidation lesson | Gas pressure | § 35. L. No. 473 | |||||
Pascal's law | Pressure. Pascal's law | Combined lesson | § 36. Ex. 14(4), task 7 | ||||||
Calculation of liquid pressure on the bottom and walls of the vessel | Combined lesson | Pressure in liquid and gas. Calculation of liquid pressure on the bottom and walls of the vessel | § 37, 38. L. No. 474, 476. Ex. 15(1) | ||||||
Pressure. Pascal's law | Pressure. Pascal's law | Knowledge consolidation lesson | Transmission of pressure by liquids and gases. Pascal's law | Repeat § 37, 38. L. No. 504-507 | |||||
Communicating vessels, application. Arrangement of locks, water gauge glass | Communicating vessels. Application. The device of locks, water-gauge glass. hydraulic machines | Combined lesson | Communicating vessels | § 39 task 9(3) | |||||
Air weight. Atmosphere pressure. Causes of atmospheric pressure | Atmosphere pressure | Combined lesson | Air weight. Atmosphere pressure | § 40, 41. Ex. 17, 18, task 10 | |||||
Atmospheric pressure measurement | Methods for measuring atmospheric pressure. The Torricelli Experience | Combined lesson | Measurement of atm. pressure. The Torricelli Experience | § 42, additionally § 7, ex. 19(3,4), task 11 | |||||
Aneroid barometer. Atmospheric pressure at various altitudes | Methods for measuring atmospheric pressure | Combined lesson | § 43, 44, ex. 20, ex. 21(1,2) | ||||||
Pressure gauges. Hydraulic Press | Gauges and presses | Combined lesson | Barometers. Pressure gauges | § 45, additionally § 46, 47 | |||||
Law of Archimedes. The action of liquid and gas on a body immersed in them | Combined lesson | The action of liquid and gas on a body immersed in them | § 48, ex. 19(2) | ||||||
Archimedean force | Combined lesson | Archimedean strength. Legend of Archimedes. Law of Archimedes | § 49, preparation for l.r. | ||||||
Laboratory work No. 7 "Determination of the buoyant force acting on a body immersed in a liquid" | Law of Archimedes | Formation of practical skills | Repeat §49, ex. 24(2.4) | ||||||
Swimming bodies | Bodies floating condition | Combined lesson | § 50, ex. 25(3-5) | ||||||
Swimming bodies | Law of Archimedes | Knowledge consolidation lesson | Swimming bodies | L. No. 605, 611, 612 | |||||
Sailing ships | Combined lesson | Section 51 | |||||||
Aeronautics | Law of Archimedes | Lesson learning new knowledge | § 52. Ex. 26 | ||||||
Aeronautics | Knowledge consolidation lesson | Aeronautics | Ex. 28(2) | ||||||
Repetition of questions: Archimedean force, floating of bodies, aeronautics | Pressure. Pascal's law. Atmosphere pressure. Methods for measuring atmospheric pressure. Law of Archimedes | Iterative-generalizing lesson | Aeronautics and repetition of the theme | Task 16, preparation for k.r. | |||||
Examination No. 3 on the topic "Pressure of solids, liquids and gases" | A Lesson in Control | ||||||||
work and power. Body energy | |||||||||
Work | Work | Lesson learning new knowledge | Mechanical work. Fur. Job. Units of work | § 53. Ex. 28(3.4) | |||||
Power | Power | Combined lesson | § 54. Ex. 29(3-6) | ||||||
Power and work | Power and work | Lesson testing knowledge and skills | mechanical power. Power. Power units | ||||||
Levers | Types of levers, their application | Lesson learning new knowledge | Sections 55, 56. L. No. 736. Task 18 | ||||||
Moment of power | Moment of force, rule of moments | Combined lesson | Lever arm. Moment of power | § 57, preparation for l.r., ex. 30(2) | |||||
57 | Laboratory work No. 8 "Clarifying the conditions for the equilibrium of the lever" | Practical study of equilibrium conditions for a lever | 1 | Formation of practical skills | § 58, ex. 38(1,3,4) | ||||
58 |
| Blocks. The golden rule of mechanics | 1 | Combined lesson | Block. simple mechanisms. Block and block system | Sections 59, 60. Ex. 31(5) | |||
59 | The golden rule of mechanics | simple mechanisms. Efficiency | 1 | A Lesson in Repetition and Generalization | The golden rule of mechanics | Repeat § 59, 60. Prepare for L.R. L. No. 706 | |||
60 | Laboratory work No. 9 "Determining the efficiency when lifting a body along an inclined plane" | Using a body to determine the efficiency of an inclined plane | 1 | Formation of practical skills | Section 61 | ||||
61 | Energy. Potential and kinetic energy. Law of energy conservation | Kinetic energy. Potential energy of interacting bodies. | 1 | Combined lesson | Energy | Sections 62, 63. Ex. 32(1.4) | |||
62 |
| The law of conservation of mechanical energy. Methods for measuring work, power, energy | 1 | Combined lesson | Potential energy. Kinetic energy | § 64. L. No. 797 | |||
63 | The transformation of one type of mechanical energy into another | 1 | Lesson of repetition and generalization of material | Law of conservation of mechanical energy |
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64 | Preparing for the test | 1 | |||||||
65 | Examination No. 4 on the topic “Work and power. Energy" | 1 | A Lesson in Control | ||||||
66 | The structure of substances, their properties | Basic concepts | 1 |
| Analysis of control work, work on errors | ||||
VI | Repetition | 2 | |||||||
67 | Interaction of bodies | Basic concepts | 1 | Lesson of generalization and systematization of knowledge | Repetition § 13-64 | ||||
68 | Final control | 1 | A Lesson in Control | -digital educational resources. Technical teaching aids.
Physics, grades 7-9, work program. The work program in physics is compiled on the basis of an exemplary program for general educational institutions, the federal component of the state standard for basic general education with the calculation of 2 hours per week in grades 7-9 according to the basic curriculum and in accordance with the selected textbooks: The work program contains the distribution of teaching hours by sections of the course and the sequence of studying sections of physics, taking into account inter-subject and intra-subject communications, the logic of the educational process, the age characteristics of students, contains a minimum set of experiments demonstrated by the teacher in the classroom, laboratory and practical work performed by students. Main content. 2. Change in the state of aggregation of matter (13h) Table of contents
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