RU2131661C1 - Greenhouse - Google Patents

Abstract

FIELD: agriculture, in particular, garden hothouse for growing vegetables, flowers etc. SUBSTANCE: greenhouse has sectioned carcass with end walls, double-pitch roof with at least one triangular fixed frame, side double-pitch walls positioned at obtuse angle relative to pitches of double-pitch roof, door, light-transmitting covering, angular supporting side members whose lower strip is faced outside and positioned at obtuse angle to other strip. Roof pitches are pivotally connected one with another so as to define inner angle of 110-119 deg upon assembling. Fixed frame with center of gravity at its top is connected by lock joint with roof ridge. Angle between strips of each side member is 102-108 deg and inner angle at base of each side wall is 80-86 deg. Inner angle between pitches of each side wall is equal to inner angle between roof pitch and upper pitch of side wall and makes 153-157 deg. Length L of greenhouse is (815xN) + 50 mm, where 815 is length of one section, mm; N is number of sections; 50 is allowance for increased length of greenhouse as compared to predetermined value, mm. Door is mounted on one end wall for moving along it. EFFECT: simplified construction and assembly, improved operating characteristics. 4 cl, 3 dwg

Description

 The invention relates to the field of agriculture, in particular to garden greenhouses for growing agricultural plants, vegetables, flowers, etc.

 Known arched greenhouse containing a rigid body consisting of a gable roof, translucent coating, lateral gable walls with gates and side support elements (see Brandman S.E. and Fedorov V.I. Goods for personal subsidiary plots / Reference book. - M. : Saving. - S. 66-68, Fig. 21).

 The well-known greenhouse is of a single standard size and can only be used with a certain climatic zone. In addition, its installation causes inconvenience due to the fact that the hull of the greenhouse is first assembled entirely, and then it is installed on the foundation. With a sufficiently large structural weight (up to 200 kg), only a few people can do this. Therefore, the installation of a greenhouse requires a lot of labor.

 Closest to the claimed invention is a greenhouse containing a sectional frame consisting of end walls having a gable roof transom, to the slopes of which there are lateral gable walls, a door, a translucent coating, side corner support elements, the lower shelf of each of which is facing outward at an obtuse angle and placed to another shelf at an obtuse angle (see RU, patent 2067813, INC A 01 G 9/14, 1996).

 In the well-known greenhouse, the casing is made in two tiers, the upper removable tier of which is formed by a gable roof and side walls, and the lower tier has two support frames, each of which is formed by a gable wall and internal struts. As you can see, this greenhouse has a definitely complex structure and great complexity during its installation. In addition, transoms in the form of frames with automatic opening by means of thermal cylinders are mounted in pairs on the roof of the greenhouse. The installation of thermal cylinders during installation requires great accuracy. If you put one cylinder, then the skew of the frame is possible, and the installation of two cylinders increases the cost of the greenhouse.

 The objective of the invention is to remedy these disadvantages.

This problem is solved in that in a greenhouse containing a sectional frame consisting of end walls, a gable roof with at least one transom, to the slopes of which there are lateral gable walls, a door, a translucent coating, side corner support elements, a lower shelf each of which is facing outward and placed to the other shelf at an obtuse angle, according to the invention, the roof slopes are interconnected articulated to form an internal angle of 110 to 119 ^o when mounting, the transom is triangular in shape and is in castle engagement with the ridge of the roof. The transom center of gravity is located at the top. The angle between the shelves of each side element is equal to 102-108 ^o , and the internal angle at the base of each side wall is 80-86 ^o . The internal angle between the slopes of each side wall is equal to the internal angle between the roof slope and the upper slope of the side wall and is 153-157 ^o . The length of the greenhouse L = (815 • N) + 50 mm, where 815 is the length of one section in mm; N is the number of sections; 50 - technologically permissible excess length of the greenhouse in mm from the specified. A door mounted on one of the end walls is arranged to move along it.

 The connection of the roof slopes articulated to each other allows you to smoothly change the width of the greenhouse within 200 mm, which makes it possible to install it with any defects in the foundations (bases) and, in addition, adjust the angle of inclination of the roof slopes to achieve the necessary illumination for plants in any light Times of Day. Placing the slopes of the side walls at the indicated angles, as well as making the angle between the shelves of the side support elements, simplifies installation and improves the operational reliability of the greenhouse. Performing a triangular transom with a center of gravity in its upper part and installing it in the castle mesh with the roof ridge allows to improve the operational parameters of the greenhouse and reduce the wind load due to its streamlining. Sectional implementation of the greenhouse allows you to get any of its length, depending on the specified operational parameters.

 Thus, as a result of using the invention, the operational characteristics of the greenhouse can be improved and its installation simplified.

 From the prior art (see Berson G.Z. Polar vegetable growing. - M .: Kolos. - 1979. - S. 43-52), gable and polygonal greenhouses with different angles at the top of the roof are known, installation of lateral gable walls to the roof slopes, with different lengths, widths and heights.

 At the same time, the inventors calculated the claimed parameters of the greenhouse and substantiated design features that do not explicitly follow from the greenhouses known from the prior art and from the prototype, and the combination of which allows to obtain the specified technical result.

 Industrial use of the claimed design of the greenhouse does not cause difficulties, since the manufacture of its elements can be performed on any industrial equipment designed for stamping and bending of metal profiles.

 Analysis of the information known to the authors on this topic allows us to conclude that the claimed invention meets all the conditions of patentability: novelty, inventive step and industrial applicability.

 The design of the greenhouse is illustrated by drawings.

In FIG. 1 shows a greenhouse, an end view;
in FIG. 2 shows a greenhouse having an end sliding door and a side door, side view;
in FIG. 3 - the same, end view.

 The greenhouse contains a frame 1 made of sections 2, end walls 3 and side gable walls 4, gable roof 5, translucent coating 6 (for example glass). The door 7 can be located either on one of the end walls 3 and / or on the side wall 4. The door can be made single-leaf 8 (on the side wall of Fig. 2) or double-leaf 9 (on the end wall - Fig. 1). A sliding door 10 can be mounted on the end wall 3 (Fig. 3), i.e. the door is mounted to move along this wall. In addition, the side entrance can be made on either side and in any place for which two light openings of the first and second row of glasses are freed.

The slopes 11 and 12 of the roof 5 are interconnected pivotally, for example, using a bolt and nut (without strut). This allows for the installation of the greenhouse, depending on the climatic zone and its other parameters, to adjust the angle at the top of the roof 5 from 110 to 119 ^o .

The installation angle of the side walls 4 to the slopes 11 and 12 of the cover 5 is 153-157 ^o . It is preferable to choose the average value of this angle (Fig. 1), which makes it possible to provide better illumination inside the greenhouse. In this case, and with other values of this angle, a technical result is achieved.

 The greenhouse is assembled from a set of standardized parts using bolted connections. Parts are of the same type and are made of sheet steel (or its waste) by bending and stamping, which during assembly provides the necessary geometry and dimensions of the greenhouse. Mounting holes in the parts are located symmetrically, thereby achieving their interchangeability.

 The frame 1 of the greenhouse consists of arched racks 13 with a broken generatrix assembled from bearing rods 14 (bent elbow) by means of struts 15 on bolted joints.

 Arched racks 13 are sequentially installed on the foundation (base) and are interconnected by lower 16, middle 17 and upper 18 connections through bolted connections through compensating grooved mounting connections.

After installing the end door blocks, the frame of the greenhouse acquires the rigidity of the spatial truss. The frame is attached to the foundation (base) through the mounting holes of the lower 16 ties, which are lateral corner support elements, the lower shelf of each of which is facing outward. The angle between the shelves of the corner element is equal to 102-108 ^o . Such installation of the frame on the foundation allows it to work under loads as a spatial truss with sufficient structural strength. In this case, the internal angle at the base of each side wall is 80-86 ^o .

 After alignment with a plumb line and cords, the nuts of the bolted connections are finally tightened and glass sheets are successively laid on the light openings, which are held and fastened by the clamping strips 19 by means of bolted connections with the simultaneous installation of the skates 20, overflows 21 and triangular transoms 22. Each of the latter is on one side in castle engagement with the ridge, and its center of gravity is located in the upper part, so the transom easily opens. The transom frame is locked with a specially curved ridge, but if necessary, the transom is easily removable. The triangular shape of the transom reduces the wind load due to its streamlining. The transom units are interconnected with glass, so they can be put in any opening of the upper row and in the required quantity. The linear contact of the transom frame with glass creates a reliable waterproofing of this opening. The transom can be opened manually and have a stand 23 with hooks, due to which its degree of opening is fixed. The transom can also be opened using thermal cylinders as in the prototype. In view of the widespread use and rather simple device, the design of the thermal cylinder is not disclosed in the application.

 The length of the greenhouse L is determined by the formula L = (815 • N) + 50 mm, where 815 is the length of one section in mm; N is the number of sections; 50 - technologically permissible excess of the length of the greenhouse in mm from the specified, i.e. the length of the greenhouse is increased in sections of 815 mm. The width and height of the greenhouse is determined by the length of the supporting rods 14 and the angle at the top of the roof.

 The optimal length of the bearing rods 14 is determined by the standard dimensions of the glass, so it is advisable to use the following lengths of the bearing rods - 1010, 1210 and 1610 mm.

 Combining the lengths of the bearing rods 14, discretely change the width of the greenhouse from 3 to 5 m and the height, respectively, from 2.4 to 3.6 m. The geometry of the greenhouse provides spontaneous snow discharge. Greenhouses do not require a high foundation (150 mm above the ground), this reduces the cost of installation and increases the luminous flux. The angles of inclination of the walls of the greenhouse create optimal conditions for the perception of solar energy at any light time of the day.

 The method of water insulation and glass reinforcement used in this design of the greenhouse does not require puttying or any other sealing elements known in practice, and is based on the meniscus effect when the pressure bar is in linear contact with glass and provides reliable waterproofing, as well as a “floating” state glass, which protects it from cracking during any movement of the frame of the greenhouse.

 Calculation of loads, their axial distribution of compression or tension in the elements (parts) of the frame of the greenhouse allows you to ensure the operation of the structure as a spatial truss. Therefore, the elements (parts) of the greenhouse are made in a lightweight version.

Claims (4)

1. A greenhouse containing a sectional frame consisting of end walls having at least one gable roof transom, to which there are oblique lateral gable walls, a door, a translucent coating, lateral corner support elements, each lower shelf facing outward and posted to the other shelf at an obtuse angle, characterized in that the roof slopes pivotally interconnected to form when mounting the internal angle of 110 - 119 ^o, transom formed triangular located in one side of mkovom engagement with the ridge of the roof and is located above the center of gravity, the angle between the flanges of each side member is 102-108 ^o, and the inner angle at the base of each side wall 80-86 ^o. 2. The greenhouse according to claim 1, characterized in that the internal angle between the slopes of each side wall is equal to the internal angle between the roof slope and the upper slope of the side wall and is 153-157 ^o . 3. The greenhouse according to claim 1, characterized in that the length of the greenhouse L is
L = (815 • N) + 50 mm,
where 815 is the length of one section in mm;
N is the number of sections;
50 - technologically permissible excess length of the greenhouse in mm from the specified.  4. The greenhouse according to claim 1, characterized in that the door mounted on one of the end walls is arranged to move along it.

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