RU2239986C2 - Hothouse - Google Patents

Abstract

FIELD: agricultural construction, in particular, building of protected ground cultivation constructions, such as hothouses for growing of vegetable and fruit crops, as well as medicinal and flower crops under artificial microclimate conditions.

SUBSTANCE: hothouse has vertical sprues and roof sprues, roof and side wall purlins, ridge profile, air vents, and light transmitting panels. Ridge profile is equipped with slot, where air vent hinges are rotated and fixed in operating positions by means of tie-rods of opening-closing mechanism. Upper and lower braces of air vents bind light transmitting panels with air vent sprues. Lower brace rests upon profile under air vent, i.e. immediately upon rib and through flexible shock-absorbing layer. Light transmitting panels extending along ridge profile are connected by roof sprues and extending along roof slope are connected through connecting profiles. Lower and upper roof brace profiles support light transmitting panels and roof sprues, with lower profile resting upon side rib of water gutter. Upper braces of roof and air vents are equipped with hinges shaped so as to provide for preliminary mounting of braces for mounting of hothouse, and final mounting thereof in operating position.

EFFECT: increased efficiency in removal of condensate from hothouse roof and air vent inner surfaces, enhanced reliability in operation of joints between air vent and lower parts of hothouse roof, strong and reliable connections of light transmitting panels, simplified mounting-dismantling of air vents on ridge profile and rigid attachment of roof upper brace to ridge profile, and reduced material usage for hothouse ridge profile.

8 cl, 6 dwg

Description

The proposed solution relates to the field of agricultural cultivation facilities of the protected soil and can be used, in particular, in the construction of greenhouses intended for growing various vegetable, fruit, medicinal and flower crops in an artificial microclimate under a translucent coating.

It is known to cover a greenhouse comprising a load-bearing structure consisting of upper and lower belts and a grill, and a fence with a ridge and tray elements, spros and translucent filling, in which the load-bearing coating structure is installed above the fence, and the ridge element of the fence is combined with the lower belt of the load-bearing structure ( ed. St. USSR No. 1083962 A, IPC A 01 G 9/14, publ. 07.04.84).

This technical solution provides for the removal of atmospheric moisture in the tray element (8), and condensate in the tray element (12). The disadvantage of this technical solution is the lack of ventilation vents, i.e. the impossibility of changing the temperature and humidity conditions inside the greenhouse depending on the state of the external atmosphere to ensure agronomic requirements when growing various crops.

This disadvantage is eliminated in a greenhouse containing internal racks, inclined beams installed with a gap between them, a horizontal bolt in which the horizontal axes of the upper ventilation transoms are mounted on the upper ends of the inclined bolts, and the horizontal axes of the side ventilation transoms are mounted on suspensions that are mounted on the lower ends consoles of inclined crossbars (ed. St. USSR No. 1416081, IPC A 01 G 9/14, publ. 15.08.88). This technical solution solves the problem of ventilating the atmosphere inside the greenhouse, depending on agronomic requirements when growing various crops with changes in temperature and humidity outside the greenhouse, because continuous ventilation transoms (vents) during rotation of the horizontal axes (opening mechanisms - manual or automatic - not shown) open along the entire length of the greenhouse and form ventilation ducts. Compared with others in this technical solution, operational reliability is increased due to the stability of the roof of the venting transom, however, specific solutions for the joints (connections) of the venting transom (vents) with a roof and / or side walls are not given with the exception of the general phrases “Horizontal axes 7 are mounted on the pendants made in the form of an earring 8. The pendants 8 are fixed on the lower ends of the consoles of the inclined crossbars 2 ". In fact, only the technical task has been set - providing a reliable, tight joint (connection) of the ventilation transom (window) with the roof or side wall of the greenhouse, and no concrete example of this joint has been given. Another disadvantage of this technical solution is that condensate, which can form on the inner side walls and the inner side of the greenhouse roof, will drain into the greenhouse on cultivated plants and greenhouse construction elements, adversely affecting them, and no special measures for condensate drainage not provided (at least in such a general form as in the description of the invention according to ed. St. USSR No. 1083962 A).

A greenhouse is also known, including a translucent coating and a frame made of longitudinal strength elements made of sheet metal interconnected, in which the translucent coating is made of rigid elements, the transverse force elements are U-shaped, the longitudinal force elements are installed on the outside transverse power elements and made L-shaped, while the limb of the longitudinal power elements made outward, the width of the horizontal shelf of the L-shaped element is equal to two the translucent element, and the L-shaped elements are installed in pairs with the bends towards each other, while the rigid translucent elements are installed between pairs of L-shaped elements with the possibility of their longitudinal free movement (claim 1 of the invention according to RF patent No. 2054865 C1, IPC6 A 01 G 9/14, publ. 02.27.96). In this technical solution, rigid translucent elements (38-43) slide into the L-shaped grooves of the longitudinal elements (10-30), closely adjoining each other with their ends, forming a continuous dome. To ventilate the greenhouse, it is enough to displace one translucent element relative to the adjacent translucent element and push them one on top of the other (to some extent similar to the design of bookshelves and cabinets with movable glasses). Obviously, the translucent elements will not "... tightly adjoin each other with their ends, forming a continuous dome." Between the ends of the translucent elements there will be an uncontrolled exchange of air in the premises of the greenhouse and outside air at any time of the day or night, because no special measures to ensure the tightness of the joints of translucent elements are provided. In addition, no special measures are provided to remove condensate from the inside of the roof and greenhouse.

Closest to the proposed technical solution is a greenhouse containing frame elements made of profiled metal beams, in particular vertical spros, roof sprockets, roof girders, side wall girders, for example, from aluminum alloys, in which structural elements are mounted using translucent panels, for example glass or similar, and the joints (joints) are, on the one hand, components of roof spurs and, on the other hand, an integral part profiles fixed to the roof runs, where the ridge profile has recesses (grooves) in which the ventilation window hinges are attached, and the lower ends of the roof ducts are connected to the drainage gutters, where the profiled beams for both roof roofing profiles and supporting profiles have holes for screws used to fix the insulating gaskets and / or the insulating element, in which the ridge profile has a flexible cap mounted on it with insulating chambers, and the window profile is made in the form of a profile, supporting vayuschego glass and lead-out area covering translucent panel (as per claim 1. EP 0744121 B1 Patent invention MPK6 A 01 G 9/14, publ. 01/21/98, the patent holder is EKONAL Bausystem GmbН Co. KG). In paragraphs 2 ... 9 of the claims of patent EP 0744121 B1, a specific embodiment of the individual nodes of the greenhouse structure is disclosed, namely:

- in paragraphs 2, 3 (figure 3) - the junction (connection) of the translucent panels and roof spros;

- in paragraphs 4, 5 (figure 4) - the junction of the ridge profile with roof spurs;

- in claim 6 (FIGS. 5, 7, 7a) - a unit for fixing translucent panels both in the ventilation window and in other parts of the greenhouse;

- in paragraph 7 (figure 5) - the junction of the lower piping of the ventilation window with the underlying parts of the roof of the greenhouse;

- in paragraph 8 (Fig.6) - the junction of the translucent panels;

- in PP.9, 10 (Fig.7, 7a) - the node of the junction of the roof of the greenhouse with a gutter.

This technical solution has the following disadvantages. During the operation of the greenhouse, namely, in the case of artificially maintaining the temperature and humidity conditions inside it, necessary for growing various crops - vegetables, fruits, flowers, medicines, etc. plants - on the lower (inner) side of the translucent roof, vapors from the atmosphere inside the greenhouse settle. No matter how high the degree of thermal insulation is used in the construction of the greenhouse, condensate from the water vapor of the internal atmosphere forms on the lower (inner) surface of the translucent roof due to the difference in atmospheres inside and outside the greenhouse. This condensate reduces the level of natural light inside the greenhouse. In addition, and this is much more serious, small droplets of condensate increase, merge into larger ones, and, finally, overcoming the forces of surface tension and adhesion (adhesion) to the surface, flow down into the greenhouse. Firstly, this adversely affects cultivated plants, which is undesirable from an agronomic point of view, and secondly, drops of condensate flowing down the inner surface of the roof and the side walls of the greenhouse adversely affect the structural elements of the greenhouse (ventilation windows, roof spros and vertical spros, roof runs and side walls, racks, supports, etc.). The metal elements of the greenhouse are corroded. Plastic (rubber, plastic, etc.) elements of the greenhouse under the influence of condensate (and substances dissolved in it) undergo a premature aging process and lose their ductility, which may lead to a loss of insulating properties of joints of various elements of the greenhouse, the appearance of gaps in vestibules of air vents, etc. As a result, this leads to a deterioration in the operational characteristics of greenhouses, an increased consumption of energy and heat carriers to maintain the necessary temperature and humidity conditions inside the greenhouse to ensure agronomic requirements for growing crops. According to this technical solution, the design of the greenhouse does not provide for special measures for the efficient removal of condensate formed on the inner surfaces of the roof and walls of the greenhouse structure, which negatively affects both cultivated plants and greenhouse construction elements. The next disadvantage of this technical solution is the insufficiently reliable operation of the joint (connection) of the lower piping of the ventilation window with the underlying section of the roof of the greenhouse. This is because the longitudinal insulating gasket (key 60 in figure 5) performs several functions simultaneously. Its main function is the formation of a plastic insulating gasket between the lower piping of the ventilation window with the underlying section of the roof of the greenhouse, i.e. to ensure this function, the joint should be as deformable (ductile) as possible. Another function is the transfer of load from the bottom piping to the underlying sections of the roof of the greenhouse with the necessary rigidity of the connection, i.e. To perform this function, the connection must be as rigid as possible. Naturally, the simultaneous presentation of diametrically opposite requirements for the same structural element of the greenhouse, namely, the junction of the ventilation window with the underlying roof sections, leads to a compromise solution, i.e. some intermediate characteristics of the joint are provided, which perform the required functions not in the best case. As a result, this leads to the fact that if the requirements of the maximum deformability (ductility) of the joint are met to ensure the required insulation between the lower piping of the ventilation window and the underlying section of the roof of the greenhouse, this leads to the need to use a very soft gasket. This can lead to the fact that the ventilation window will be able to move relative to other parts of the roof of the greenhouse under the influence of wind loads, solid and liquid precipitation, and other reasons. As a result, the gasket will wear out intensively, become unusable, which in turn will lead to a loss of tightness. If the requirements of maximum rigidity are met to the greatest extent, i.e. ensuring the immobility of the position of the ventilation window relative to the underlying sections of the roof of the greenhouse, this can lead to the formation of places of loose fit, which lead to loss of tightness of the joints and, as a result, to the leakage of warm air from the greenhouse, i.e. to increased energy consumption to ensure the required atmospheric characteristics inside the greenhouse for growing agricultural plants. As a result, we have to apply a compromise solution, i.e. use a gasket, on the one hand soft enough to provide a sufficiently flexible insulating gasket at the junction of the ventilation window and the underlying part of the roof, and on the other hand, this gasket must be rigid enough to provide reliable support for the ventilation window.

Another design option for the junction of the lower piping of the ventilation window with the underlying parts of the greenhouse roof is disclosed in the application of the Netherlands No. 9201651, IPC5 A 01 G 9/14, publ. 04/18/94, in which the profile of the lower trim of the ventilation window is made with a protrusion at the lower end, resting on the shelf of the under-run run and an open cavity in which a flexible shock-absorbing element is placed, which also rests on the shelf of the under-run run (see figure 2). This design allows you to obtain, on the one hand, a reasonably acceptable stiffness of the narthex joint, provided by the presence of a hard contact of the protrusion at the lower end of the lower piping of the ventilation window with a shelf of the undercut run and, on the other hand, a sufficient degree of tightness of the narthex joint provided by the use of a flexible cushioning pad (element ) between the lower trim of the ventilation window and the under-window run. However, this technical solution has some disadvantages. As follows from figure 2, the flexible cushioning pad rests on the stiffener of the undercut run, i.e. the entire load from the ventilation window is transferred to the flexible cushioning pad, but compresses it until the protrusion at the lower end of the profile of the lower trim of the ventilation window is touched (rests) on the shelf of the under-window run and only then the load from the ventilation window will be distributed between the support points - the protrusion at the lower end of the profile of the lower trim of the ventilation window, flexible cushioning pad and the junction of the upper trim of the ventilation window with the ridge profile of the greenhouse, Flexible damper gasket it rests on the shelf podfortochnogo run in the hard its location - directly above the rib podfortochnogo run, leading to excessive load on the flexible cushioning pad, its premature wear, aging, loss of insulating properties. In addition, the relatively small cross section of the inner cavity, which, in combination with the compressibility of the actually flexible cushioning pad and provides insulating properties of the joint, with significant load, can lead to the fact that the cross section of the inner cavity can be reduced to almost zero and the flexibility of the cushioning pad will be provided almost exclusively due to the elastic deformation of this gasket, which has physical limits.

Another disadvantage of the technical solution according to patent EP 0744121 B1 is the impossibility of quick, easy and convenient installation (during initial installation of the greenhouse) and replacement (during repair, maintenance work) of the ventilation window of the greenhouse. Figure 4 shows a section of the upper part of the greenhouse - ridge profile and adjacent parts of the window. As follows from figure 4, in the assembled state, the hinges (38) of the ventilation window (34) enter the grooves of the recess (37) of the ridge (35) in such a way as to allow the ventilation window to be raised (rotated) by a certain angle (as follows from the drawing , the rotation angle is less than 90 °), while ensuring the reliability of fixing the loops (38) of the ventilation window (39) in the grooves (37) of the ridge (35). As follows from figure 4, in view of the foregoing, it is possible to mount the ventilation window (39) uniquely, namely by inserting the ventilation window (39) into the ridge profile (35) along the generatrix of the ridge profile (35). This is inconvenient with the significant size of the ventilation window (39) both in length and in width (see the application of the Netherlands No. 9201524, IPC5 A 01 G 9/14, publ. 01.04.93 and Belgian patent No. 1005363 A3, A 01 G, publ. 07/06/93), and in the case of using the so-called "tape" ventilation windows, i.e. window leaves along a significant part of the ridge profile or even along the entire ridge profile (see application of the Netherlands No. 9101442, IPC (5) A 01 G 09/14, publ. 16.03.93, Belgian patent No. 1006370 A3, IPC A 01 G, publ. 08/02/94), it is almost impossible, because the weight of the ventilation window can be quite significant.

The roof of a (any) greenhouse consists of many translucent panels, the dimensions of which (both in length, in and in width) depend on many factors, the most significant of which are the stiffness (bending strength) of the translucent material used, for example glass (which, in its the turn depends on the thickness of the material, etc.), and the ease of installation (maintenance, repair, replacement) of these panels. Therefore, the developers of greenhouses are always faced with the problem of ensuring a reliable joint of translucent panels, which can be solved in a variety of ways. In the technical solution according to patent EP 0744121 B1, the joints of translucent panels (along the ridge profile) are reflected in paragraphs. 2, 3, 8 of the claims (see figure 3, 6). The disadvantage of these design options for the junction of translucent panels is their (fairly) complex design. For example, the joint of two translucent panels depicted in FIG. 3 (claims 2, 3 of the claims) contains a flange (18) with a hole (20) drilled for screws (27) in it, which presses the sealant (24) and the metal cap (26) through the insulating insert (23) to the flange (18), thereby securing on top of the translucent panels (15). From the bottom side of the joint, the roof sprocket (16) is attached to the roof run (12) by means of a bolt (17), and through flexible gaskets (not indicated in Fig. 3), pressing down on the translucent panels (15). The junction of the translucent panels (15) shown in FIG. 6 (claim 8) is also complicated. Looking at the cross section of the greenhouse (across the ridge profile), it can be seen that in all versions of the greenhouse (regardless of the presence or absence of central and / or intermediate columns (supports)) the weight of the greenhouse roof (including the weight of ventilation windows, spros and roof runs, translucent coatings etc.) is distributed between two support points - the top of the ridge profile and the side wall, i.e. from the point of view of the course of resistance of materials in this case, we are dealing with an inclined beam resting on supports of various heights (see Fig. 2, 4, 7, 7a). The upper part of the ridge profile is subjected to difficult load. From figure 4 it follows that the upper part of the ridge profile (35) is subjected to stretching, and the middle part of it (at the level of connection with the loop (38) of the ventilation window (39)) is compressed. During the operation of the greenhouse, this connection is subjected to a variable load (opening and closing the ventilation window, wind load, exposure to liquid and solid precipitation, etc.), which forces the ridge profile to be made with a strength that guarantees reliable trouble-free operation under the most adverse conditions, i.e. . when summing up all the adverse factors, and as a result, the ridge profile turns out to be excessively material-intensive. Further, when using the profile (38) in the variant of the constant (fixed) position of the roof of the greenhouse, it may be necessary to rigidly fix the profile (38) and the ridge (35). This can be done by drilling a hole in the vertical bridge of the profile (38) for screws (screws) and then in the thickened part of the ridge (35) (which is obvious from figure 4). This is inconvenient to do because of the need to ensure the perpendicular position of the drill relative to the drilled profile jumper (38), which is almost very difficult to ensure in the field during installation of the greenhouse when the profile (38) is already inserted into the ridge (35). Figure 4 shows that it is very difficult to drill a hole in addition because when drilling holes in an upright post (jumper) of the profile (38), the open cavity posts (46) interfere with which to fix the fixing element (45) in them, as an integral part flexible cap (42).

A knot of the junction of the upper piping of the ventilation window (roof) of the greenhouse and the ridge profile of the greenhouse, in which the above disadvantages are eliminated to some extent (see patent EPV 0529725 A1, IPC5 A 01 G 9/14, publ. 03.03.93). In this embodiment, it is possible to drill a hole in the profile of the upper roof of the greenhouse perpendicular to the flat part of the profile of the upper roof of the greenhouse and then in the ridge of the greenhouse. However, in this embodiment, it is very difficult (almost impossible) to drill a hole at an angle different from normal to the flat jumper profile of the upper trim of the greenhouse roof without special tools. Another serious drawback of this technical solution is the excessive complexity of the articulation nodes of individual structural elements of the greenhouse, in particular translucent panels (7), using bolt (screw) connections (Figs. 3, 6). The use of assemblies with bolted (screw) connections in itself implies the implementation of two rather labor-intensive operations - actually drilling holes in the manufacture of the greenhouse in the factory and installing bolted (screw) joints in the factory or field conditions during the installation (assembly) of the greenhouse. In addition, the complexity of the design of the connecting nodes using bolted (screw) connections leads to the formation of a significant number of closed cavities, articulation surfaces of various elements in complex spatial forms (see Fig. 3, 6), which can lead to accumulation of moisture (condensate) in these cavities and joints, premature aging, wear of these structural elements and, as a result, to the deterioration of the operational characteristics of the greenhouse as a whole.

The construction of the mount of translucent panels (15) is rather complicated both in the longitudinal (along the ridge profile of the greenhouse) and transverse (along the slopes of the greenhouse roof) directions. As can be seen, for example, from FIG. 3, for this a significant number of structural elements are used, in addition to the roof spurs (16), namely, a sealing plate (24, 25), a metal cap (26), an insulating element (23), screws (17 , 27). Roof splices (16) are connected to the roof girders (17) by means of screws, and cushioning pads (shown but not indicated in FIG. 3) are inserted into its symmetrically located open cavities, through which the lower surface of the translucent roofs is laid panels (15). From the upper side of the roof of the greenhouse, the screws (27) press the heat insulator (25) through the metal cap (26) to the upper surface of the translucent panels (15). Such a technical solution is material-intensive, structurally difficult, time-consuming during installation (maintenance) of the greenhouse, unreliable during operation when condensate and dissolved substances enter the internal cavities of the junction of the translucent panels (15) and roof spurs (16).

The objectives of the proposed technical solution are to increase the efficiency of removal of condensate from the inner surfaces of the roof of the greenhouse and ventilation windows; increasing the reliability of the junction of the narthex of the ventilation window with the underlying parts of the roof of the greenhouse; ensuring a strong and reliable connection of translucent panels of the roof of the greenhouse; simplification of the installation and dismantling of ventilation vents on the ridge profile of the greenhouse; ensuring rigidity of fastening of the profile of the upper trim of the greenhouse roof to the ridge profile; decrease in material consumption of the ridge profile of the greenhouse.

To achieve these goals in a greenhouse containing a frame consisting of profiled metal beams, in particular vertical spurs (2) and roof spurs (4), roof girders (3) and side wall girders (1), ridge profile (6), ventilation window leaves (5) made, for example, of aluminum and / or other alloys, in which the frame elements of the greenhouse are mounted using translucent panels (7) made, for example, of glass, plastic or similar translucent materials, in which the ridge profile The ball (6) is made with a groove in which the loops of the ventilation windows (5) rotate, which are fixed in the upper (open) and lower (closed) states using the rods of the mechanism (17) for opening and closing the ventilation windows (5), the upper strapping of which is made in the form of a profile (14) with an open cavity, covering translucent panels (7), and a shelf for accommodating ventilation ducts (13) vents on it (5), and the lower piping of ventilation vents (5) is made in the form of a profile (16) with the top a shelf for placing a translucent panel on it d (7), the first open cavity for placing vents (5) on it (13) and through the lower shelf of the ventilation window (5) resting in the lower (closed) state through a flexible cushioning pad (12) on the under-profile (18) the lower part of the roof of the greenhouse, and the translucent panels (7) of the greenhouse roof are interconnected along the ridge profile of the greenhouse with spurs (4) of the greenhouse roof, which on the upper side rest on the under-profile (18) or profile (23) of the upper greenhouse roof trim, and bottom side decree These spros are supported through the lower profile (20) on the gutter (8), and along the roof slope of the greenhouse - by connecting profiles (10) with shelves for placing translucent panels (7) on them, in it the upper trim (14) of the ventilation window (5) ) is made with a loop in the form of a cylindrical surface with a generatrix in the form of an open circle with a concavity on the outer surface that provides the initial installation of the loop of the upper trim (14) of the ventilation window (5) in a vertical position in the groove of the ridge profile (6) of the greenhouse, followed by setting said harness (14) in the working (upper-open and lower-closed) position by turning it around the longitudinal axis of the ridge profile (6), the lower harness (16) of the ventilation window (5) is made with a second open cavity with a L-shaped protrusion facing down and the lower shelf for placing a profile (9) in it for fastening translucent panels (7) and a shank for fastening the rods of the mechanism (17) for opening and closing the ventilation window (5), the under-profile (18) from the side facing ridge profile (6) of the greenhouse, in it is full with a cantilever located upwardly directed first open cavity for placement in it of an arrow-pointed part of a flexible cushioning pad (12), under which there is a first shelf for collecting and draining condensate from the inside of the ventilation window (5), and from the side facing the side wall of the greenhouse, the specified profile (18) is made with a second open cavity for placing translucent panels (7) in it, under which there is a second shelf and a L-shaped protrusion for the roof bolt (4), and on the lower edge of the second shelf there is a third open cavity for accommodating the shelves of the mounting bracket (19), the connecting profile (10) for connecting the translucent panels (7) is made with an internal closed cavity for accommodating the connecting part (11) for mounting the specified connecting profile (10) ) to the crosshairs (4) of the greenhouse roof, and the lower profile (20) of the greenhouse roof trim is made with an upper shelf for placing translucent panels (7) on it and the first open cavity with a L-shaped protrusion facing down for placement in a profile (9) for attaching translucent panels (7), a second open cavity with a shelf for accommodating the lower end of the spurs (4) of the greenhouse roof, and a third open cavity for accommodating a side edge of the gutter therein (8).

The greenhouse can be made in such a way that the upper harness (21) of the roof of the greenhouse is made with a loop in the form of a cylindrical surface with a generatrix in the form of an open surface with a concavity on the outer surface, which ensures the initial installation of the specified harness in a vertical position in the groove of the ridge profile (6 ) when installing a greenhouse with the subsequent installation of the specified strapping in a working fixed position by turning it around the longitudinal axis of the ridge profile (6), and the ability to install a self-tapping screw and in the hole drilled through the indicated concavity to the body of the ridge profile (6) to ensure rigid fixation of the specified strapping with the ridge profile (6) of the greenhouse; the profile (9) for fastening the translucent panels (7) is made with a L-shaped protrusion facing up, which is placed in the second open cavity of the profile (16) of the lower trim of the ventilation window (5), and an open cavity with a shelf for placing translucent panels in it (7), and these panels (7) are supported in the same plane on the shelf of an open cavity of the specified profile (9) and the upper shelves of the profile (16) of the lower piping of the ventilation window (5) or profile (20) for joining the roof spurs (4) with gutter (8); the under-profile (18) from the side facing the ventilation window (5) is made with a rib for stopping the profile (16) of the lower trim of the ventilation window (5), the height of which is less than the outer diameter of the flexible cushioning pad (12) in the undeformed state, placed in cantilevered open cavity of the specified profile (18), and providing, when the ventilation window (5) is in the lower (closed) position, the deformation of the specified gasket (12) to a state that guarantees reliable isolation of the internal volume of plates from the external atmosphere, and a console located open cavity of the specified profile is made with boards bent inward to accommodate and secure the specified gasket (12); shelves of the connecting profile (10) for connecting translucent panels (7) are made with L-shaped protrusions for placing said panels (7) on them, the inner closed cavity for placing the connecting part (10) in it has a box-shaped, for example, rectangular section, and the lower a face of said profile (10) is made with a first open cavity for collecting and draining condensate from the inner surface of the greenhouse roof, and the upper face of said profile (10) is made with an open cavity with boards bent inward for placement the appearance of a protective element in it; the flexible cushioning pad (12) is made in the form of a closed cylindrical surface with an inner generatrix in an undeformed state in the form of a full circle and an arrow-pointed protrusion on the outer surface To install the specified pad (12) in a cantilever-positioned open cavity of the undercut profile (18), and the thickness the walls of the specified strip (12) is selected equal to 0.02-0.4 of its diameter; the greenhouse roof bolt (4) is made with two symmetrically arranged shelves for accommodating translucent panels (7) of the greenhouse roof and an upper open cavity for placement of an arrow-pointed end of the protective element and with an internal closed cavity of a box-shaped trapezoidal section, the base of the said green rail ( 4), made with two symmetrically arranged bent tabs and a T-slot for accommodating, for example, the heads of the mounting bolts, is included on the upper side of the sprocket (4) open the hollow cavity of the under-profile (18) and abuts against the L-shaped protrusion of this profile, and from the lower side enters the open cavity of the lower profile (20) and lies on the lower shelf of this profile, the upper open cavity being made with the sides curved inward, and the shelves for placement of translucent panels on them (7) are made with protrusions; the air duct (13) of the ventilation window (5) is made with two symmetrically located side open cavities with shelves for placement of translucent panels (7) of the ventilation window (5), the upper open cavity to accommodate the arrow-pointed end of the protective element and the inner a closed box-shaped cavity of rectangular cross section, the base of said spros (13) being made with two symmetrically spaced bent tabs, abutting from the upper side of said spros (13) on a shelf profile (14) of the upper bracing of the ventilation window (5), and from the lower side of the said air duct (13) to the shelf of the first open cavity of the profile (10) of the lower bracing of the ventilation window (5), the upper open cavity being made with the sides curved inward, and the shelves for placement on them of translucent panels (7) are made with protrusions.

Figure 1 presents a General view of the greenhouse; figure 2 presents a transverse section (aa) of the roof of the greenhouse (roof spros); figure 3 is a joint of the lower piping of the ventilation window with the underlying part of the roof of the greenhouse; figure 4 - the joint of the translucent panels of the roof of the greenhouse; figure 5 - the junction of the ridge profile with the upper trim of the ventilation window; in Fig.6 - the joint of the ridge profile with the upper trim of the greenhouse roof (option).

The greenhouse (Fig. 1) consists of runs of the side walls 1, vertical struts 2, runs of the roof 3, struts of the roof 4, ventilation windows 5, (Fig. 1 shows only one ventilation window, but there may be more), ridge profile 6, translucent panels 7. In Fig. 1, which shows the most general, schematic view of a greenhouse, the foundation, end walls of the greenhouse, support columns, a device for opening and closing a ventilation window, a system for providing the necessary temperature and humidity conditions, etc. are not shown. The roof of a modern greenhouse is a rather complicated structure, the requirements for which were discussed above and its composition (Fig. 2) includes roof spros 4, a ridge profile 6, translucent panels 7, a gutter 8 (which is also used to drain condensate from the inside roof of the greenhouse), profiles 9 for attaching translucent panels 7, profile 10 for connecting translucent panels 7, connecting part 11, flexible cushioning element 12, air ducts 13 ventilation vents, profile 14 of the upper ventilation air vents, connecting plates 15, profile 16 of the lower vents ventilation vents, mechanism 17 for opening and closing the ventilation vents (shown schematically), undercut run 18, mounting brackets 19, profile 20 for joining roof spokes 4 with the gutter 8. Into open cavity profiles 10 for the connection of translucent panels 7, roof spurs 4 and vents 13 of the ventilation window, protective caps (not shown in FIGS. 2, 4) are inserted to prevent liquid atmospheric precipitation from entering the greenhouse. Figure 3, 4, 5, 6 on an enlarged scale shows the individual parts of the greenhouse - the joints of the lower piping 16 of the ventilation window with the underlying part of the roof of the greenhouse (Fig. 3), the joint of two translucent panels 7 of the greenhouse (Fig. 4), options for the ridge joint profile 6 of the greenhouse with the upper trim 14 of the ventilation window (Fig. 5) and the upper trim 20 of the roof of the greenhouse (Fig. 6). All of these figures show the structural elements of the greenhouse, their geometric shape, relative position and connections between the elements. For joining roof splices 4 with a gutter 8, a profile 20 is used (the length of the parts from this profile is selected, for example, equal to 6 m). To drain the condensate into the gutter 8, holes 20 are made in the profile 20, through which condensate is removed from the inside of the greenhouse roof, draining both along the roof spurs 4 and on the inner surface of the translucent panels 7, the holes being made at the level of the shelf adjacent to the tray. Roof splices 4 are attached to profile 20 using clamps, bolts, nuts, washers - this is a common mounting option. In Fig.2, the fastening is shown by the axial line. To the steel girders 3 located on the roof of the greenhouse, the sprockets 4 of the roof of the greenhouse are fastened with brackets 19 (for example, 30 mm wide). The upper part of the roof sprockets 4 is attached to the undercut run 18 similarly to the fastening to the profile 20 (using clamps, bolts, nuts, washers). The length of the individual components of the undercut run 18 is selected, for example, also equal to 6 m. To drain the condensate into the central inner cavities of the roof spurs 4, under the run run 18 holes are made at the level of the tray of the run run 18. The run runs 18 are attached to supporting runs using brackets 19 fasteners, for example, with a width of 30 mm (see figure 2). To seal the junction of the translucent panels 7 (made, for example, from glass), to improve the condensate collection and the conditions for joining the translucent panels 7 (opposite the brackets 19 for attaching to the steel roof girders 3), profiles 10 are installed between the roof rods 4 for connecting the translucent panels 7, and the profiles 10 are attached to roof sprockets 4 by means of connecting parts 11, for example, 100 mm long. Condensate collected in the tray profiles 10, merges into the trays available in the lower part of the roof sprockets 4, through the gaps between the walls of the sprockets 4 and the ends of the profiles 10. The lower piping 16 of the ventilation window with its considerable length, for example along the entire greenhouse, is made of separate parts , for example, 6 m long and connected to each other by means of linings 15, bolts, nuts, washers similarly to the connection of other parts of the greenhouse (in Fig. 2, the connection is shown by an axial line). The ventilation duct vents 13 are connected to the upper 14 and lower ventilation duct vents 16 by screws, for example 4 pieces for each ventilation duct vent 13. In the lower harness 16 of the ventilation window next to each vent 13 of the ventilation window, holes are made, for example, two for draining the condensate into the tray of the under-window run 18, at the level of the lower shelf of the air duct 13 of the ventilation window. The lower glasses are fixed in translucent panels 7 and ventilation windows with the help of profiles 9, for example, 40 mm long, two pieces per glass. The shape of the profile 9 is made in such a way that its short protrusion engages with the protrusions of the lower trim 16 of the ventilation window and profile 20 for joining the roof spurs 4 with the gutter 8, and the glasses lie on the upper shelves of these profiles 16 and 20 and abut against open cavities profiles 9. It should be especially noted that profile 9 is installed by turning the specified profile 9 counterclockwise until the glasses are installed (see arrows in figure 2), and for this the height of the small shelf of profile 9 is less than the height of the open x cavities in the profiles 16, 20, and immediately before the glass is installed, the profile 9 is shifted to the side along the under-profile and then, after the glass is installed, it is set to the working position. The upper harness 14 of the ventilation window is connected to the ridge profile 6 using a swivel (see Fig. 5, 6), the working angle of rotation of which is, for example, 50 °, and the loop shape of the upper harness 14 of the ventilation window (Fig. 5) and the upper strapping 21 of the greenhouse roof (Fig. 6) is made in such a way that it allows easy installation of both the ventilation window and the roof of the greenhouse by making the upper surface of the loop of the upper strapping 14 (21) with a protrusion that makes it easy to dock them (insert the loop of the upper strapping 14 , 21 per cylinder open cavities of the ridge profile 6) by turning along the ridge profile 6 (in Fig. 6 clockwise, figure I indicates the initial installation of the upper harness 14 (21), figure II indicates the working position of the upper harness 14 (21)). If necessary, additional rigid fixation of the upper lining 21 of the greenhouse roof to the ridge profile 6 after mounting the greenhouse roof in the groove of the loop of the upper lining 21 of the greenhouse roof and the ridge profile 6, a hole is drilled to allow a self-tapping screw to be screwed into it securely connecting the above greenhouse construction elements . The working angle of the hinge of the upper piping 14 of the ventilation window is usually chosen to be equal to twice the angle of rotation (from horizontal) of the ventilation window in the closed position (for example, 25 ° below the horizon, which, as a rule, coincides with the general inclination of the greenhouse roof), and the open position ( e.g. 25 ° above the horizon). The mechanism 17 for opening and closing the ventilation window in figure 2 is shown schematically, as an example of a possible implementation, you can specify patents GDR No. 213117, IPC3 A 01 G 9/14, publ. 05.09.84, German patent No. 3126788 C2, IPC4 A 01 G 9/20, publ. 04.21.88, RF patents №2001553 C1, IPC5 A 01 G 9/14, publ. 10/30/93. No. 2028758 C1, IPC6 A 01 G 9/14, publ. 02/20/95 and others. The ridge profile 6, made of separate sections (for example, 6 m long), is interconnected using brackets, bolts, nuts, washers similar to the above. In those places where there are no ventilation vents, roof spros 4 reach the ridge profile and can be rigidly fixed to it with bolts, nuts, washers (in Fig. 6, the attachment points are shown conventionally by axial lines) similarly to the above. The joints of the lower piping 16 of the ventilation window with the underlying part of the roof of the greenhouse (the lower vestibules of the ventilation window) are sealed using flexible cushioning pads 12 (made, for example, from rubber), the arrow-pointed ends of which are inserted into open cavities of the under-window runs 18, and closed cavities play the role of a damping element, the operation of which is described in detail above. Parts of the lower harness 16 of the ventilation window (length, for example, 6 m) are interconnected by two plates 15 using bolts, nuts, washers. Parts of the upper harness 14 of the ventilation window (for example, also 6 m long) are interconnected in the same way.

A comparative analysis of the claimed technical solution allows us to conclude that, according to the totality of the claimed features, the technical solution is unknown from the prior art and, therefore, meets the criteria of the invention of "novelty."

From the patent and scientific and technical literature available to specialists, it is not known to achieve the stated objectives that, in particular, the junction of the vestibule of the ventilation window with the under-profile directly onto the rib and through the flexible cushioning strip to the cantilever located open cavity, the upper ropes of the roof and the ventilation window with a loop in the form, providing both the initial installation of the harnesses during the installation of the greenhouse, and the subsequent installation in the working position, the execution of the profile for crepe eniya translucent panels with T-shaped projection and a cavity with an open shelf for placing said panels etc. in accordance with paragraph 1. claims and, thus, the proposed technical solution meets the requirements of the criteria of the invention "inventive step".

The claimed technical solution can be used in the construction of greenhouses intended for growing various vegetable, fruit, medicinal and flower crops in an artificial microclimate under a translucent coating and, thus, the proposed solution meets the requirements of the criteria of the invention "industrial applicability".

The test results confirm the high efficiency of the proposed technical solution, in particular, it was possible to increase the efficiency of condensate removal from the inner surfaces of the roof of the greenhouse and ventilation windows, increase the reliability of the joint of the porch of the ventilation windows with the lower parts of the greenhouse, provide a simple and reliable connection of translucent panels of the roof of the greenhouse, simplify the process mounting and dismounting ventilation vents on the ridge profile of the greenhouse, to ensure the rigidity of the profile mounting in rhney binding greenhouse roof to the ridge profile, reduce material consumption profile ridge greenhouses.

Claims (8)

1. A greenhouse containing a frame consisting of profiled metal beams, in particular vertical spurs (2) and roof spurs (4), roof girders (3) and sidewall girders (1), ridge profile (6), ventilation windows (5 ) made, for example, of aluminum and / or other alloys, in which the frame elements of the greenhouse are mounted using translucent panels 7, made, for example, of glass, plastic or similar translucent materials, in which the ridge profile (6) is made with a groove, in which loops of ventilation vents (5) are fixed in the upper (open) and lower (closed) states using the rods of the mechanism (17) for opening and closing the ventilation vents (5), the upper piping of which is made in the form of a profile (14) with an open cavity, covering translucent panels (7), and a shelf for accommodating air ducts (13) of ventilation vents (5), and the lower trim of ventilation vents (5) is made in the form of a profile (16) with an upper shelf for placing translucent panels on it (7) , the first open cavity for placement of air vents (13) on it (5), and through the lower shelf of the ventilation window (5) resting in the lower (closed) state through a flexible cushioning pad (12) on the under-profile (18) of the lower part of the greenhouse roof, and translucent panels (7) the roofs of the greenhouse are interconnected along the ridge profile of the greenhouse with spurs (4) the roofs of the greenhouse, which on the upper side are supported by the undercut profile (18) or the profile (23) of the upper trim of the greenhouse roof, and on the lower side, these spros are supported through the lower profile (20) to the gutter (8), and along the slope of the greenhouse roof with connecting profiles (10) - with shelves for placement of translucent panels (7) on them, characterized in that it has the upper trim (14) of the ventilation window (5) made with a loop in the form of a cylindrical surface with a generatrix in the form of an open circle with a concavity on the outer surface, providing the initial installation of the loop of the upper trim (14) of the ventilation window (5) in a vertical position in the groove of the ridge profile (6) of the greenhouse with subsequent installation at the indicated strapping (14) to the working (upper - open and lower - closed) position by turning it around the longitudinal axis of the ridge profile (6), the lower strapping (16) of the ventilation window (5) is made with a second open cavity with a L-shaped protrusion, facing down, and a lower shelf for placing a profile (9) in it for fastening translucent panels (7) and a shank for fastening the rods of the mechanism (17) for opening and closing the ventilation window (5), the under-profile (18) from the side facing the ridge profile (6) of the greenhouse, made with a slightly located, directed upward first open cavity for placement in it of an arrow-pointed part of a flexible cushioning pad (12), under which there is a first shelf for collecting and draining condensate from the inside of the ventilation window (5), and from the side facing the side wall the greenhouse, the specified profile (18) is made with a second open cavity for placement of translucent panels (7), under which there is a second shelf and a L-shaped protrusion for the roof bolt (4), and on the lower edge of the second shelf there is a third open cavity for accommodating the shelves of the mounting bracket (19), the connecting profile (10) for connecting the translucent panels (7) is made with an internal closed cavity for accommodating the connecting part (11) for attaching the specified connecting profile (10) to to the crosshairs (4) of the greenhouse roof, and the lower profile (20) of the greenhouse roof trim is made with the upper shelf for placing translucent panels (7) on it and the first open cavity with a L-shaped protrusion facing down to accommodate the profile in it (9) for fastening translucent panels (7), a second unclosed cavity with a shelf for placing the lower end of the spurs (4) of the greenhouse roof in it and a third unclosed cavity for placing a lateral edge of the gutter therein (8). 2. A greenhouse according to claim 1, characterized in that the upper harness (21) of the greenhouse roof is made with a loop in the form of a cylindrical surface with a generatrix in the form of an open surface with a concavity on the outer surface, which ensures the initial installation of the specified harness in a vertical position in the groove of the ridge profile (6) when installing the greenhouse with the subsequent installation of the specified strapping in a working fixed position by turning it around the longitudinal axis of the ridge profile (6), and it is possible to install a self-screw cut into the hole drilled through the indicated concavity to the body of the ridge profile (6) to ensure rigid fixation of the specified strapping with the ridge profile (6) of the greenhouse. 3. A greenhouse according to claim 1, characterized in that the profile (9) for attaching translucent panels (7) is made with a L-shaped protrusion facing up, which is located in the second open cavity of the profile (16) of the lower trim of the ventilation window (5) , and an open cavity with a shelf for accommodating translucent panels (7), said panels (7) resting in the same plane on a shelf of an open cavity of the specified profile (9) and upper profile shelves (16) of the lower trim of the ventilation window (5) or profiles (20) for joining roof splices (4) gutter (8). 4. A greenhouse according to claim 1, characterized in that the under-profile (18) from the side facing the ventilation window (5) is made with a rib to support the profile (16) of the lower trim of the ventilation window (5), the height of which is less than the outer diameter flexible cushioning gasket (12) in an undeformed state, placed in a cantileverly located open cavity of the specified profile (18), which, when the ventilation window (5) is in the lower (closed) position, deforms said gasket (12) to a state that guarantees reliable the proper isolation of the internal volume of the greenhouse from the external atmosphere, and the cantilever located open cavity of the specified profile (18) is made with the sides curved inward to accommodate and secure the specified gasket (12). 5. A greenhouse according to claim 1, characterized in that the shelves of the connecting profile (10) for connecting translucent panels (7) are made with L-shaped protrusions for placing said panels (7) on them, an internal closed cavity for placing a connecting part in it (10) has a box-shaped, for example, rectangular section, and the lower face of the specified profile (10) is made with the first open cavity for collecting and draining condensate from the inner surface of the roof of the greenhouse, and the upper face of the specified profile (10) is made with an open cavity inturned flanges for receiving the security element. 6. A greenhouse according to claim 1, characterized in that the flexible cushioning gasket (12) is made in the form of a closed cylindrical surface with an inner generatrix in an undeformed state in the form of a full circle and a swept-pointed protrusion on the outer surface for installing said gasket (12) in a cantilever located open cavity of the under-profile (18), and the wall thickness of said gasket (12) is chosen equal to 0.02-0.4 of its diameter. 7. A greenhouse according to claim 1, characterized in that the spreader (4) of the greenhouse roof is made with two symmetrically arranged shelves for placement of translucent panels (7) of the greenhouse roof and an upper open cavity for placement of an arrow-pointed end of the protective element and with an internal closed cavity of a box-shaped trapezoidal cross-section, the base of said spros (4), made with two symmetrically arranged bent tabs and a T-slot for accommodating, for example, heads of fastening bolts, enters from the top the torons of this sprocket (4) into the open cavity of the under-winding profile (18) and abuts against the L-shaped protrusion of this profile, and from the lower side enters the open cavity of the lower profile (20) and rests on the lower shelf of this profile, the upper open cavity being made with the sides bent inward, and the shelves for placing translucent panels (7) on them are made with protrusions. 8. A greenhouse according to claim 1, characterized in that the sprocket (13) of the ventilation window (5) is made with two symmetrically located side open cavities with shelves for placement of translucent panels (7) of the ventilation window (5), the upper open cavity to accommodate the arrow-pointed end of the protective element and with an internal closed cavity of a box-shaped rectangular section, and the base of said spros (13) is made with two symmetrically arranged bent tabs abutting against the top the henna of the side of the bolt (13) into the flange of the profile (14) of the upper binding of the ventilation window (5), and from the lower side of the said flail (13) into the shelf of the first open cavity of the profile (10) of the lower binding of the ventilation window (5), the upper open cavity made with boards bent inward, and shelves for placing translucent panels (7) on them are made with protrusions.

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