Public buildings. Catalog of typical projects for construction Projects of public buildings with dimensions in drawings

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Plan- This is an image of a section of a building, dissected by an imaginary horizontal plane passing at a certain level (Fig. 10.3.1).

According to GOST 21.501 - 93, this plane should be located at 1/3 of the height of the depicted floor or 1 m from the depicted level for industrial buildings. For residential and public buildings, an imaginary cutting plane is located within the door and window openings of each floor.

The plan of the building gives an idea of ​​its configuration and dimensions, reveals the shape and location of individual rooms, window and door openings, main walls, columns, stairs, partitions. The contours of the building elements (walls, piers, pillars, partitions, etc.) that fall into the cut and are located below or above the secant plane are drawn on the plan.

As a rule, invisible structural elements are not shown on plans. But if it is impossible to show this element as visible in other drawings, it is depicted on the plan with strokes. In this case, the depicted element can be located both below the secant plane (niche for heating batteries), and above it (mezzanine) (Fig. 10.3.2). Building plans usually show plumbing fixtures (bathtubs, toilets, sinks, etc.). If stove heating is used in the building, then the location of the stoves, as well as smoke and ventilation ducts, is indicated on the plan. These channels are also depicted on the plans of buildings with central heating.

Sanitary equipment is drawn on the building plan on the same scale as the building plan, the dimensions of the most common sanitary equipment, as well as kitchen stoves in accordance with GOST 21.205-93, are given in Fig. 10.3.3.

On the floor plan of residential and public buildings, the placement of furniture or other equipment is sometimes shown (Figure 10.3.4, a). The layout of industrial buildings can show the location technological equipment influencing the design decision. Equipment outlines are drawn to scale (sometimes dimensioned) and outlined in thin lines. The name of the equipment is indicated in the explication, the positions of which correspond to the numbers affixed on the plan.

The layout of technological equipment can be given separately (Figure 10.3.4, b). In this case, the contours of the plan are drawn with thin lines 0.2-0.3 mm thick, and the contours of the equipment - with lines 0.6 mm thick. Detailed dimensions, graphic designations and inscriptions related to the construction part are not given on this plan. On the plans of industrial buildings, solid lines with a thickness of 0.4-0.6 mm depict normal and narrow track tracks.

Crane tracks, bridge cranes, girder cranes, underground channels intended for power supply lines, sanitary pipelines, etc., overlapping with removable plates is drawn with dashed lines (Figure 10.3.5). If necessary, indicate the coverage area of ​​the crane. All these images can be accompanied by explanatory inscriptions.

On the plans of household premises of industrial buildings, they show the location of cabinets, hangers, benches and other equipment (Figure 10.3.6).

If sites and mezzanines in industrial buildings are located at a height of more than 2 m from the floor level, they are shown with intersecting dashed lines (see Fig. 10.3.5) with two dots.

Extensions to an industrial building on the main plan can be omitted, confining themselves to drawing break lines (see Fig. 10.3.5). Built-in and attached auxiliary premises, platforms, mezzanines and some areas of industrial buildings can be shown schematically on the plan, but then separate drawings are made for these elements of the plan, most often on a larger scale, and on the main plan they give a link to these drawings (see Fig. . 10.3.6).

If the floor plans differ from each other only by the arrangement of individual sections of the outer walls, you should draw a plan of one floor, and only along its perimeter should be placed plans (ribbons) with some different sections of the walls. With a two-tier arrangement of windows in the room, the openings of the lower tier are shown on the main plan. The plans of wall sections with openings of the second tier are placed along the perimeter of the main plan in the form of separate ribbons (Figure 10.3.7). When implementing plans for civil and industrial buildings on a small scale, complex areas should be depicted in fragments. A fragment is a separate section of any part of the plan, made on a larger scale and with a greater degree of detail. All the necessary dimensions and designations are applied on it. In the drawings of the plans, the place that will be given in the future on the fragment should be indicated by a curly brace. The image, from where the fragment is taken out, and near it, the name assigned to the fragment is applied according to the type "Plan Fragment 1" (Fig. 10.3.8). In the inscription of the plan, the sheet on which it is located may be indicated: "Fragment of the plan 1, sheet 7". On sections of plans that are detailed on fragments, private dimensions are not put down. In such cases, they are limited to basic and anchor ones.

Individual sections of the plans that cannot be shown in sufficient detail on a small scale and which are not included in the drawings of the fragments are shown in detail; the plans for them must be referenced (Fig. 10.3.9). For residential (premises) buildings, both industrial and non-industrial construction, plans of individual sections, made on a larger scale, can be drawn.

The plans for sectional houses are long and are drawn on a small scale, therefore they are supplemented with drawings of section plans.

The residential section consists of several apartments with different numbers of living rooms located near the staircase. Depending on the position of the section on the building plan, it has an appropriate name and marking. The end section is called the end section and has a T mark.

The intermediate section is called an ordinary one and has a brand P. Types of apartments that differ in the size of the area are marked A and B. The number of living rooms is indicated by numbers, So, the end section, consisting of one one-room apartment and three two-room apartments, will have the following marking: T-1A , 2B, 2B, 2B.

In fig. 10.3.10, and a plan of a typical floor of a five-story residential building is shown. The main purpose of the plan is to give a general idea of ​​the shape and size of the house, the number of sections, the layout of apartments and the technical and economic characteristics of apartments and sections. In fig. 10.3.10b shows section T-1A, 2B, 2B, 2B.

For buildings assembled from large elements (panels, large blocks), plans can be drawn up in the form of layouts of elements of prefabricated structures.

Typically, wall panels are delivered to the construction site with window and door units installed. In this case, the plan does not indicate the dimensions of the panels and openings.

It is allowed to depict the panels schematically with rectangles (Fig. 10.3.11).

In fig. 10.3.11, and the plan of a typical floor of a large-panel building is shown.

The plan of a panel residential building is shown in Fig. 10.3.11, b.

On the plan of such buildings, abbreviated or full brands of panels are given (H - external wall panels, B - internal, P - partitions), floor numbers, node marks, the distance between the coordination axes.

An example of the graphic design of the layout is given in Fig. 10.3.11, c.

When starting to draw the plan, it should be remembered that the image of the building plan must be placed with the long side along the sheet, the side of the plan corresponding to the main facade of the building is recommended to be turned to the lower edge of the sheet. The building plan on the sheet should be located, if possible, in the same way as on the master plan. It is not allowed to draw a mirror image of the plan relative to its position on the general plan. Building plans are placed on the sheet in ascending order of floor numbering from bottom to top or from left to right.

When determining the composition of the various elements of the building plan, one should take into account the applied dimensions and the marking of the coordination axes. Therefore, the plan drawing should be located approximately 75-80 mm from the sheet frame. In specific cases, these dimensions may vary.

After determining the location of the plan on the sheet and its scale, they begin to draw.

1. Apply coordination axes, first longitudinal, then transverse (Fig. 10.3.12, a). These axes are conventional geometric lines. They are used to tie the building to the construction coordination grid and benchmarks. master plan, as well as to determine the position of supporting structures, since these axes are drawn only along the main walls and columns. In some cases, they may not coincide with the symmetry axes of the walls.

In fig. 10.3.13 shows an example of the design of the second floor plan of a residential building.

The coordination axes of buildings and structures are applied with dash-dotted lines with long strokes 0.3-0.4 mm thick. It is allowed, after the outline of the drawing, to leave the axes only at the intersections of the walls. On the plans, the alignment axes are displayed outside the contour of walls and marches.

nodding. For marking axes on the side of the building with a large number of them, use Arabic numerals 1, 2, 3, etc. Most often, the largest number of axles are across the building.

To mark the axes on the side of the building with a smaller number of them, use the letters of the Russian alphabet A, B, C, etc. As a rule, the axes along the building are marked with letters. At the same time, it is not recommended to use the letters: Ё, 3, Y, O, X, Ц, Ч, Щ, Ы, Ь, Ъ, .d. The axes of the elements located between the alignment axes of the main supporting structures can be marked with the fraction B / 1, B / 2, 1/1, 2/1, etc.

In this case, the numerator indicates the designation of the previous coordination axis, and in the denominator - the ordinal number of the additional axis within the area between adjacent coordination axes (Fig. 10,3,14). Such elements are half-timbered columns, built-in structures, installed equipment.

To designate the coordination axes of the block sections of residential buildings, use the index "c" (Fig. 10.3.15, a).

On the plans of residential buildings, composed of block sections, designations are applied to the extreme coordination axes of block sections without an index (Figure 10.3.15, b).

Marking starts from left to right and bottom to top. Gaps in the ordinal numbering and alphabet when using letter designations are not allowed. Typically, marking circles (their diameter is 6-12 mm) are located on the left and bottom sides of buildings (Figure 10.3.16). If the location of the axes on the right and upper sides of the plan does not coincide with the breakdown of the axes of the left and lower sides of the plan, then the coordination axes are marked on all sides of the plan or on those two sides where there is no coincidence of the axes (Figure 10.3.17).

In the image of an element tied to several coordination axes, these axes represent:

• with the number of coordination axes no more than three - as shown in Fig. 10.3.18;
• with the number of coordination axes three or more - as shown in Fig. 10.3.19.
• if necessary, the orientation of the coordination axis, to which this element is attached, in relation to the adjacent axis, the direction is indicated by an arrow (Fig. 10.3.20).

2. Draw thin lines (0.3-0.4 mm thick) the contours of longitudinal and transverse external and internal capital walls and columns (see Fig. 10.3.12, b).

Capital external and internal walls, columns and other structural elements are tied to the coordination axes, i.e. determine the distances from the inner or outer plane of the wall or the geometric axis of the element to the coordination axis of the building.

In buildings with load-bearing longitudinal and transverse walls, the binding is carried out in accordance with the following instructions.

In external load-bearing walls, the coordination axis passes from the inner plane of the walls at a distance equal to half the nominal thickness of the internal load-bearing wall (Fig. 10.3.21, Fig. 10.3.22, a), a multiple of the modulus or its half. In brick walls, this distance is most often taken equal to 200 mm, or equal to the modulus, i.e. 100 mm. It is allowed to carry out the coordination axes along the inner plane of the outer walls (Figure 10.3.22, d). If the floor elements rest on the outer wall throughout its entire thickness, the modular coordination axis is aligned with the outer edge of the wall (Figure 10.3.22, c).

In the inner walls, the geometric axis of symmetry is aligned with the coordination axis (see Fig. 10.3.21). A derogation from this rule is allowed for staircase walls and for walls with ventilation ducts.

In external self-supporting and curtain walls, their inner edge is often aligned with the coordination axis (see Fig. 10.3.22, d), but if floor panels or coverings partially go into the wall or completely overlap it, then the coordination alignment axis is aligned with the outer edges of the cover or overlap (Fig. 10.3.22, d).

When the beams of purlins or trusses are supported on the inner pilasters of the outer walls, the face of the pilaster at the level of the upper part of the wall is taken as the inner face of the wall (Fig. 10.3.22r b). In brick walls, it is allowed to adjust the binding value taking into account the size of the brick.

In frame buildings, the geometric center of the section of the column of the inner row coincides with the intersection of the modular coordination axes (Fig. 10.3.23, Fig. 10.3.24).

In the extreme rows of columns of frame buildings, the coordination axis can pass:

• on the outer edge of the column, if the girder, beam or truss overlaps the column;
• at a distance equal to half the thickness of the inner column, if the girders rest on the column consoles or the floor panels rest on the girder consoles;
• at a distance that is a multiple of the modulus or its half from the outer edge of the columns in a one-story building with heavy crane loads (see Fig. 10.3.24).

Modular alignment axes perpendicular to the direction of the columns in the outermost row should be aligned with the geometric axis of the columns.

3. Draw the contours of the partitions with thin lines (Fig. 10.3.12, c). Attention should be paid to the difference in the connection of external and internal capital walls and capital walls and partitions (Fig. 10.3.25, a, b, c).

4. Carry out a breakdown of window and door openings and outline the contours of the main walls and partitions with lines of appropriate thickness (see Table 9.5.2).

The conventional designation of window and door openings with and without filling is depicted in accordance with GOST 21.501-93. When drawing a plan at a scale of 1:50 or 1: 100, if there are quarters of them in the openings conventional image give on the drawing.

Quarter- this is a protrusion in the upper and side parts of the openings of brick walls, which reduces the airflow and facilitates the fastening of the boxes (Fig. 10.3.26, a-c).

When choosing the thickness of the outline lines, it should be borne in mind that non-load-bearing structures, in particular, the contours of partitions, are outlined with lines of a lesser thickness than the load-bearing capital walls and columns.

5. Draw the symbols of stairs, sanitary and other equipment, and also indicate the direction of opening the doors (Fig. 10.3.12, d). Axes are plotted on the plans of industrial buildings. rail tracks and monorails.

When making drawings of building plans, the graphic designation of stoves or sanitary equipment should be drawn to the scale adopted for this plan.

6. Draw extension, dimension lines and marking circles (Fig. 10.3.12, e).

The first dimension line, both inside the outline of the plan and outside it, should be located at least 10 mm from the outline of the drawing. However, due to the fact that marks of various building elements are often placed in front of the first dimension line behind the plan dimensions, this distance is increased to 14-21 mm or more. Subsequent dimension lines are spaced at least 7 mm apart. Sizes that go beyond the outline are most often applied in the form of three or more dimensional "chains" (see Fig. 9.5.5). The marking circles of the coordination axes are located at a distance of 4 mm from the last dimension line.

7. Put down the required dimensions, marks of axles and other elements (see Fig. 10,3.13). The dimensions of the plan indicate the dimensions of the premises, the thickness of the walls, partitions, the binding of the internal walls to the coordination axes, the partitions to the internal and external walls or to the coordination axes. The dimensions of openings in internal walls, in brick partitions are applied, as well as their binding to the contour of the walls or to the coordination axes. The dimensions of the doorways in the partitions are not shown on the plan. Also indicate the dimensions of the holes in the walls and partitions and their attachment, or refer to the corresponding drawings. On the plans of industrial buildings, the slopes of the floors, the dimensions and binding of channels, trays and ladders arranged in the floor structure are applied.

Behind the outline of the plan, usually in the first chain, counting from the outline of the plan, there are dimensions indicating the width of window and door openings, piers and protruding parts of the building with their reference to the axes. The second chain contains the dimension between the axes of the main walls and columns, In the third chain, the dimension is put down between the coordination axes of the outermost walls. With the same arrangement of openings on two opposite facades of a building, it is allowed to apply dimensions only on the left and bottom sides of the plan. In all other cases, the dimensions are set on all sides of the plan. On the plans of industrial buildings, with repeated repetition of the same size, you can indicate it only once on each side of the building, and instead of the rest of the dimensional numbers, give the total size between the extreme elements in the form of the product of the number of repetitions by the repeated size (see Fig. 9.5.6 ). The plans of industrial buildings also indicate the types of openings for gates and doors (in circles with a diameter of 5-6 mm), brands of jumpers and transoms, numbers of partitions schemes, etc. If the area of ​​the premises is put down on the plan, then it is better to place the number of its size in the corner of the drawing of each room, preferably in the lower right, and emphasize it. The area of ​​the premises, most often, is given on the plans of civil buildings.

When drawing plans of buildings made of large blocks or panels, the number of dimensions behind the outline of the plan, as a rule, is reduced. Most often, only the dimensions are indicated between all the coordination axes and between the extreme axes (Figure 10.3.12, a, b). In more detail, the position of window and door openings is shown on the block or panel layout diagrams.

When drawing up a plan drawing, the numbers and letters of the axes marks and the numbers indicating the area of ​​\ u200b \ u200bthe premises or their marking should be written in a larger font than the dimensional ones.

8. Carry out the necessary inscriptions (see Fig. 10.3.13).

On the plans of industrial buildings, the names of premises or technological areas are written with an indication of the category of production for explosive, explosion-fire and fire hazard. It is allowed to place the names of premises and categories of industries in the explication with the numbering of the premises on the plan in circles with a diameter of 6-8 mm. The name of the premises can also be indicated on the drawings of the plans of civil buildings. An inscription is made above the plan drawing. For industrial buildings, this will be an indication of the floor level of the industrial premises or site of the type “Plan at elev. 2,350 ". The word "mark" is written in abbreviated form.

For civil buildings in the inscription, you can write the name of the floor according to the type "Plan of the 1st floor", or "Plan of the 3rd floor in axes 3-7". For multi-storey buildings, plan drawings are drawn up separately for each floor. But if a number of floors have the same layout, then a plan of one of them is drawn, and all floors with a similar layout are indicated in the inscription. For example, "Plan of the 2nd and 3rd floors". If the building is one-story, then the floor is not indicated. The inscription is not underlined.

In the main inscription, the name of the plans is recorded according to the type of "Technical underground plan".

9. Designate the cutting planes of the cuts (see Fig. 10.3.13). On the plans, horizontal traces of the imaginary planes of the section are also applied, along which images of the sections of the building are then built. These traces are thick open strokes (1 mm thick) with arrows (Fig. 10.3.27). If necessary, the imaginary plane of the cut can be depicted with a thickened dash-dotted line.

The direction of the arrows, i.e. direction of gaze, it is recommended to take from bottom to top or from right to left. However, if necessary, you can choose another direction. Thick strokes with arrows should not go through the outline of the plan or come close to it. Depending on the position of the dimension chains and the workload of the drawing, they can be placed near the outline of the plan or behind the extreme dimension chain (see Fig. 10.3.13). Two or more cutting planes should be avoided. The cutting planes of the cuts are designated by letters of the Russian alphabet or numbers.

Floor plan drawings are accompanied by specifications of structural elements (joinery, etc.); wardrobe equipment specifications; explication of premises (and in the explication for residential and public buildings, the column "Category of production for explosive, explosion and fire hazard" is excluded); interior finishing sheets, in which the number of columns is determined by the presence of interior elements to be finished; a list of door openings and lintels, etc. The shape and dimensions of the tables are shown in Fig. 10.3.28 and fig. 10.3.29.

Special-purpose plans can also be implemented if necessary. So, for structural elements of industrial buildings (Fig. 10.3.30), assembly plans of the walls are drawn.

The assembly plans should show:

• the coordination axes of the building, the distances between them and between the extreme axes;
• structural elements of the building with reference to coordination axes or structures and marking;
• window and doorways;
• stairs within a floor (schematically);
• designation of cutting planes of nodes and fragments;
• floor marks (when the floors are located at the same level, their marks are not put down);
• the thickness of walls and partitions, their binding to the coordination axes or to the surfaces of the nearest structures.

For buildings made of bricks or small blocks, masonry plans are made.

Masonry plans should contain:

• dimensions of window and door openings, walls with their reference to the centerline axes or to the building structures;
• section of columns, pillars and other elements;
• place of laying and marking of jumpers;
• openings, channels, niches, chimneys, chimneys, ventilation ducts, openings for ventilation ducts (on the attic plan) with reference to the coordination axes or building structures.

On masonry plans of buildings, reinforced sections of walls or piers are also indicated or reference is made to reinforcement drawings. For complex parts of the plan, fragments should be developed. Window and door blocks or schemes for filling openings on the plans of public buildings are marked.

The name and area of ​​the premises are indicated on the plan. If the size of the image does not allow making an inscription on the drawing, then the rooms are numbered, and their names and areas are given in an explication, which can be combined with the list of finishing the rooms. Marking numbers are placed in circles with a diameter of 6-8 mm. On the plans of public buildings, lintels are marked by the type and number of elements included in the lintel, as well as by their location in the section. Data on the marked jumpers are given in the statement.

If necessary (due to the strong image saturation), the jumper plan can be performed separately.

Plans can be drawn separately for residential and public buildings finishing works... This plan indicates the areas of premises, brands of window and door blocks, built-in wardrobes, mezzanines, etc. with an assembly or masonry floor plan, and for public buildings - with a schematic floor plan. With simple finishing methods, these plans can be combined. The plan drawings are accompanied by a statement of finishing the premises.

Types of design of public buildings

Design of public buildings - time consuming process, which requires the involvement of many specialists.

Over the years, architects and engineers have gained extensive experience and knowledge in the following areas:

• Commercial real estate design
• Design of administrative buildings
• Design of office buildings
• Design of sports facilities
• School design
• Polyclinics design
• Hotel design
• Museum design
• Theater design
• Restaurant design

The creation of a project for any of the listed objects requires compliance with certain requirements, norms and rules at each design stage.

Stages and features of the design of public buildings

Before starting to create a project for a residential building, the time spent by people in the building is determined. Taking this factor into account, the functional and interconnection of the premises of the future construction object is included in the technical task and the stage-by-stage design is started.

Stage 1. Terms of reference

The first step is creating and analyzing terms of reference... Competent technical specification is the first step towards translating the project idea into reality.

Stage 2. Draft design

At this step, the architects and designers of the ESK-Proekt company develop the concept of the building and form the external appearance. After agreeing on the sketch, the engineers proceed with the design of the residential building and the creation of documentation for obtaining a building permit.

Stage 3. Design documentation

Design documentation - the process of creating this package of documents is important not only design solutions, but also legal registration. They are submitted to government agencies for approval.

Stage 4. Working documentation of the project.

Creation working documentation a process that includes the requirements, norms and rules of legal acts, such as: GOST, SP, SNiP and SanPiN.

When designing public buildings, engineers create plans for the project and the surrounding area, as well as drawings with specifications.

It is also important to consider when design works: zoning, indoor navigation and communication of premises, as well as security. Compliance with these factors will make public buildings comfortable for staying not only for adults, but also for children. A striking example is Kindergarten, where the building is clearly divided into rooms and interconnected taking into account the functionality, as well as provided with security systems.

ESK-Project architects and engineers recommend to simultaneously design and develop a design project. Competently developed construction and design projects will help to avoid not only a lot of mistakes in the installation of engineering networks, but also to get a comfortable building ready for operation in the shortest possible time.

TP in accordance with Decree No. 87 of the Government of the Russian Federation "On the composition of sections of project documentation and requirements for their content" consists of 12 volumes (text and graphic parts):

1. "PZ"
2. "Site organization scheme"
3. "Architectural solutions"
4. "Constructive and space-planning solutions"
5. "Information about engineering equipment, networks of engineering and technical support"
6. "POS"
7. "Project for the organization of work on the demolition or dismantling of objects"
8. "Environmental protection"
9. "Ensuring fire safety"
10. "Providing access for people with disabilities"
11. "Estimate for the construction of facilities"
12. "Documentation of a different kind in the cases provided for by the Federal Law"

Benefits of TP:

1. Versatility.
2. Save money on a small budget.
3. A ready-made standard project significantly reduces the design time.

Its cost, in contrast to the price of an individual development, does not exceed that indicated in the estimate. Personal works, created taking into account all the "whims" of the client, are more expensive. Those who prefer non-standard ideas are better off abandoning the same type of development. It is not suitable for clients with soil conditions on the site. The choice of the TP is beneficial if there is a permit for the construction of a structure, in a hurry with its construction.

Regulatory framework, site adaptation

TP are created according to Federal law No. 368, Decree of the Government of the Russian Federation No. 1159 of 2016, which approved the rules, performance criteria (a positive assessment of experts, an estimate within the cost of a similar object, an identical construction area). If the conditions are met, the re-use of TP is allowed.

Reasonable changes in documents are allowed to adapt the site (expertise is required only for the sections on foundations, engineering surveys).

Important questions

1. What does examination of a finished project mean? ?

This means that the TP must receive a positive assessment of the licensed state or independent organizations for compliance with the requirements. Russian laws... Additional expertise is needed when localizing TP.

1. How are TPs used outside of Russia?

For customers from the CIS countries and some non-CIS countries, we are ready to localize ready-made re-use projects or develop project documentation to order according to your terms of reference.

Our guarantees, advantages

We work with physical and legal entities, we help you choose the option that suits your conditions and budget. We "tie" the finished documentation to the site (changing the location of the structure on the cardinal points, foundation, style, etc.). We offer development of various types of buildings.

We are going through an additional examination of the modified sections of the TP. You will get significant cost savings by purchasing it from the catalog. Here are houses from different material, style, number of storeys. We guarantee a long service life of buildings erected according to the documentation of our accredited specialists!

Still do not know where to download the AutoCAD project? In this article, we will look behind the scenes of finished projects in dwg format, and you will also find useful links to AutoCAD projects / drawings.

If you are planning to create your own project "from scratch" in AutoCAD, then we advise, first of all, to go through (author: Alexey Merkulov). Here you can download a ready-made project that is being carried out in the course (download an example of a cottage.dwg). This file will help you with practical tasks (there are all the necessary sizes, and you can also take the template itself as a basis!)

Download TOP-10 AutoCAD projects.

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Rice. 13 - Cottages in AutoCAD. Ready dwg projects.

9) Classic cottage with a beautiful facade. Download the finished AutoCAD project.

Rice. 14 - Projects of houses in AutoCAD. Download ready-made drawings.

Rice. 15 - House in AutoCAD. Classic cottage.

10) 3D project of a cottage in AutoCAD. Free download home AutoCAD.

Rice. 16 - Download projects of houses AutoCAD.

11) 5 storey house in AutoCAD (3D model). Download the finished AutoCAD project.

Rice. 17 - Download 3D model of the house in AutoCAD.

Useful links to ready-made AutoCAD projects.

A large number of ready-made AutoCAD projects can be found on the website