RU2073778C1 - Water drain trough for greenhouses - Google Patents

Abstract

FIELD: construction of greenhouses. SUBSTANCE: trough is intended for draining weather precipitation and condensate and at same time it constitutes a component of greenhouse load-bearing structure. Tubular-type trough has a base, supporting, horizontal and upper flanges, vertical, outer and side walls, internal, external and additional spouts. Made in side walls of trough are open shaped recesses and seated in them are lugs of intermediate fastening members which are fastened to each other and to supporting columns. EFFECT: high efficiency and versatility of usage. 8 cl, 10 dwg

Description

 The proposed technical solution relates to the field of agricultural construction, namely, to the device and construction of greenhouses and hotbeds intended for growing various vegetable, fruit and flower crops and plants.

 A known tray for greenhouses made of steel bent profile, and the profile of the tray along the longitudinal edge sections is made with a step with the formation of a stop and shelves for glazing greenhouses (A.S. USSR N 118614 A, class A 01 G 9/14; E 06 B 3/54; 10.23.85). The disadvantage of this technical solution is the low rigidity of the tray (low compressive strength), due to the fact that when applying glass and spros (figure 2 image description) on the stops 4 and shelf 5, the entire length of the tray, the tray will be compressed relative to the axis of symmetry, passing in the center of the tray. In the case of compression, this will lead to the fact that the other edges of the glasses and spurs adjacent to the ridge profile (not shown in the drawings) can form gaps at the junctions, i.e. uncontrolled connections with the external atmosphere will occur, which will lead to a decrease in the accuracy of regulation of a given temperature and humidity regime in the greenhouse. In the case of inadmissibility of the formation of a gap in the junctions of the roof glasses and spurs with the ridge profile of the greenhouse, a significant increase in the compressive strength of the tray is required, which can only be achieved by increasing the thickness of the tray, and, therefore, increasing the metal consumption of the greenhouse design. In addition, the design of the tray and the junction of the glass cover and sprocket with the tray (Fig. 2, 4, 6 of the description of the invention) leads to the fact that the condensate formed on the bottom wall of the glass roof (and spros) will drain along the bottom surface of the tray, those. will return to the internal atmosphere of the greenhouse, i.e. also worsen the accuracy of maintaining a given temperature and humidity conditions.

 A greenhouse is also known, comprising side rails, roof glazing mounted on spurs, trays, gutters, roof rails, side rails for glass, side heating pipes and a sealing element, wherein the rafter heating pipes are located under the roof glazing supports, in which the profile the tray at the edges is made with a reverse bend, turning into a corner, forming stops for roofing, and the inner part of one of the sides of the reverse bend rests on the sides e fencing, and the pipes are located under the bend of the corner (A.S. N 1009332, A1, class A 01 G 9/14, 01/07/90). The disadvantage of this technical solution, as in the first analogue, is also the lack of compressive strength of the trays, due to the fact that the load from the roof tends to compress the tray in the direction of the axis of symmetry, passing through the center of the tray, at the junctions of the adjoining roof glasses and spros.

 Compared with the previous technical solution, the present invention eliminates the ingress of condensate formed on the underside of the roof glasses on the lower part of the tray and further into the greenhouse (on cultivated plants) due to the condensate falling on the pipe 5 of the tray heating (Fig. 1 description of the invention ) and evaporates. However, this leads to the fact that the evaporated condensate returns to the internal atmosphere of the greenhouse, which, as in the previous case, impairs the accuracy of maintaining the specified temperature and humidity conditions in the greenhouse.

 A known design of the tray (gutter) included in the greenhouse (Europatent N 0369508, B1, class A 01 G 9/14, 03/04/92, invented by Boom, Petrus Leonardus Joseph, patent holder PLJ BOM BEHEER, RV patent is valid in Belgium, Germany, France, Great Britain, the Netherlands). Compared with the technical solutions described above, the design of the gutter used in this technical solution is in the section a tubular (hollow) shape, i.e. It has significantly greater strength (compression, bending, torsion, etc.) and, therefore, a large bearing capacity. Due to the considerable strength of the gutters used in this technical solution, part of the load from the glazing of the roof, ridge profile and spurs is transferred to the bottom, which makes it possible to reduce the dimensions and weight of the ridge profile and spurs, and, accordingly, the material consumption of the entire structure of the greenhouse. However, the shape of the gutter itself and the junction of the glazing of the roof and the sprinkler to the gutter are made in such a way (Fig. 1 of the patent description) that the condensate formed on the underside of the spout enters the outer part of the gutter and then onto the soil and plants in the greenhouse .

 The closest in technical essence to the proposed technical solution is a gutter for a greenhouse, which is made of an extruded profile and includes a gutter with vertical walls, a bottom and an upper surface that forms the bottom of the external gutter with the joints for spros and roof glazing, made in this way that condensate from the roof elements on the outside of the profile of the gutter flows through openings made in the horizontal shelves of the gutter, and collects in the gutter for condensate, except On the other hand, the gutter includes a heating device that melts the snow falling on the external gutter (Dutch patent N 182361, CL A 01 G 9/14, patent owner PLJ BOM BEHEER, RT te Naaldwijk en Boal BV te De Lier, 03/01/88 ) The gutter is installed between two inclined planes of the roof glazing elements. The gutter itself is made of extruded aluminum with a tubular shape, the upper part of which (with a slight slope) serves to divert external atmospheric precipitation into the inner cavity of the gutter (with greater steepness) and further into the external atmosphere. To drain the condensate draining along the lower side of the roof glazing, holes were made on the horizontal shelves of the gutter, through which the condensate enters the internal cavity of the gutter and then, like atmospheric precipitation, is discharged into the external atmosphere. The lower part (base) of the gutter is fixed to the columns of the greenhouse using clamps, with which the gutter is fastened with bolts connecting the upper and lower parts of the gutter to the upper part of these clamps. A sealing putty is placed between the clamps and the lower part of the gutter. The lower part of the clamps (also made tubular (box-shaped)) is fixed with columns (bases, poles, supports) with screws. The connection of the lower part of the gutter and the upper part of the flange with a bolted connection is fixed with a nut, washer and sealing putty. An insulating strip, mainly made of foam, is attached to the outer surface of the lower part of the gutter, which is attached to the gutter using a metal strip, the edges of which are bent on the side shelves of the gutter. The connection of the glazing of the roof, spros and gutter is as follows. The dowels are fixed to the gutter, while the upper shelf of the gutter and the side shelf are captured in the recesses of the sprocket. In the longitudinal direction, the sprocket deepens due to a recess in the upper lateral shelf of the gutter. This technical solution operates as follows. Condensate flowing down the lower part of the roof glazing, through an opening in the side shelves of the gutter, enters the internal cavity of the gutter and then into the external atmosphere. Rain water along the upper part of the gutter through the grooves made along the gutter along its axis also falls into the internal cavity of the gutter and further into the external atmosphere.

 The gutter, by means of a fixing part, is fixed on the fence post of the greenhouse. Each fixing part consists of a clamp passing through the bottom of the gutter and a flange connected with it, which is screwed onto the column. The clamp is mounted on the profile with a vertical bolt that passes through the hole in the bottom of the gutter and the clamp, a waterproof sealing putty is applied between the clamp and the bottom of the gutter, while the nut and seal complete the fastening and sealing. On the inner wall of the greenhouse, the supporting surface of the sheet is provided with an insulating strip, predominantly made of foams, on both sides of which a plate of aluminum or copper is provided. The edges of the strip are fixed in the cavity of the profile by a metal strip, the ends of which are bent around the edges of the support.

 When assembling roof elements around and near the spros and glass, you can only move in the direction of the arrow. Installation of elements of the roof of the greenhouse using this gutter is as follows. Demand is mounted on the gutter due to the fact that the upper plate and the edge are captured by the groove. In the longitudinal direction of the groove, the sprocket is fastened as a result of deformation of the edge.

 Condensate flowing down along the spurs along the glazing flows exactly into the gutter and then is discharged through the outlet in the side cavity and then goes to the bottom of the gutter. Rainwater from the upper part of the gutter along the groove also enters the bottom of the gutter and is further discharged outside the greenhouse.

 When performing a version of this gutter in accordance with Fig. 3, the glass goes deeper into the recess formed in the groove for this purpose.

 When performing a version of this gutter in accordance with Fig. 4, the upper part of the gutter has an additional reinforcing part (step) for attaching an additional curved plate.

 The aim of the proposed technical solution is to create such a design of the gutter (and connecting units), which has wider operational capabilities due to the use of various sizes of support columns, reducing material consumption, simultaneous removal of external liquid precipitation and internal condensate, which reduces the amount of uncontrolled moisture inside the greenhouse, reduction of uncontrolled air exchange with the environment and the expansion of functionality through the use of in the side sections of the module.

 To achieve the goals in the gutter, mainly for greenhouses, supported by columns and made in the form of a tubular structure with a base supported through intermediate fastening elements on columns, supporting, horizontal, upper shelves with outer, vertical and side walls, forming together with the base an inner a tray in the form of a closed cavity for condensate drainage, while the upper shelf is connected to vertical walls with the formation of an external tray for collecting and removing external atmospheres black precipitation, and the outer, vertical walls and horizontal shelves are located with the formation of two open cavities, at least one of which is designed to fix the glazing and spurs, serving simultaneously as the main side trays to drain condensate flowing down the lower surfaces of the glazing and spros through grooves or holes in the side tray, made in it at certain distances, in the inner tray, on the side walls are formed open profile cavities in the form of castle soy pressure to fasten the gutter with an intermediate fastening element, which is made in the form of a clamp fixed by fasteners on the columns, and inclined shelves are made on the outer sides of the outer walls, forming additional side trays together with the outer walls for collecting and draining condensate draining along the lower surfaces spros through grooves made in the outer walls in the main side trays, and the upper end of at least one of the outer walls is placed in the slot of the spros.

 In FIG. 1 depicts the proposed technical solution, where: 1 - a gutter designed for rainfall in the form of water and condensate drain formed inside the greenhouse on the roof elements and is simultaneously part of the supporting structure; 2 spros; 3 roof covering; 4 column (rack) of the greenhouse; 5, 6 clamps securing the tray to the columns; 7 cornice element of the side railing; 8 and 10 bolts; 9 - a nut; in FIG. 2 shows a variant of the connection node of the gutters 1 with spros 2 and mainly a glass coating 3 of the roof; in FIG. 3 connection node of the gutter 1 with the fly 2, view along the axis of the fly (see Fig. 2); in FIG. 4 junction of gutters 1 with a cornice element 7 of the side fence of the greenhouse; in FIG. 5 junction of gutters 1 with columns 4 of the greenhouse; in FIG. 6 junction of gutters 1 with columns 32 of the greenhouse; in FIG. 7 option node connection gutters 1 with columns 32 of the greenhouse; in FIG. 8 node connecting the gutters 1 to each other at the junction of the trays; in FIG. 9 same node, side view; in FIG. 10 is a variant of the connection node of the gutters 1 with a roof covering 3.

 The gutter 1 is a box-shaped tray (pipe), the upper part of which forms an external tray 11 (Fig. 2) for rainfall, and on both sides in the upper part of the gutter 1 there are main side trays 12 for collecting condensate. The inner cavity of the gutter 1 serves to drain condensate. On both sides of the gutter 1 there are T-shaped grooves 13, which serve to connect the gutter 1 to the clamps 5, 6. In the upper part of the gutter there are support flanges 14, which serve as a support for covering 3 of the roof and spros 2. Outer walls 15 the main side trays 12 also serve to connect the gutter 1 to the sprockets 2 and for their support. To do this, grooves 16 and 17 are made in the supports 2. On the sides of the gutter 1 there are inclined shelves 18, which together with the outer walls 15 form additional side trays for collecting condensate flowing down the bottom of the spurs 2. To drain condensate from the inclined shelves 18 to the main side trays 12 in the outer walls 15 have grooves 19 (see Fig. 3). The vertical walls 20 of the outer tray 11 also serve as a support for covering 3 of the roof. In the lower part of the main side trays 12 there are openings 21 for condensate drainage into the inner tray 1.

 In FIG. 4 shows the connection node of the gutter 1, located near the side wall, with the cornice element 7 of the side fence. U-shaped groove 22 of the cornice element 7 is connected to the outer wall 15 of the main side tray 12, the shelf 23 of the cornice element abuts against the support shelf 14 of the gutter 1, the shelf 24 rests on the vertical wall 20 and the deformation of the shelf 24 allows you to fix the cornice element 7 on the gutter 1. The wall 25 of the cornice element 7 is necessary to ensure the flow of water, and the T-shaped groove 26 allows you to fix two adjacent cornice elements 7. The shelf 27 of the cornice element 7 is designed to connect the gutter eloba 1 with lateral railing greenhouse.

 In FIG. 5 shows the junction of the gutter 1 with the column 4 of the greenhouse using clamps 5, 6. The clamps 5, 6 have shoulders 28 that fit into the T-grooves 13 of the gutter 1. The posts 29 at the lower ends have openings 30 that include the bolts 8 when connecting the clamps 5, 6 to the column 4. To reduce the load on the bolts 8, the clamps 5, 6 have shelves 31. The bolt 10 and nut 9 fix the clamps 5, 6 on the gutter 1 (due to friction forces) when tightening the clamps .

 In FIG. 6 shows the connection node of the gutter 1 with the column 32 of the greenhouse using clamps 33, 34. The columns 32 are usually located on the end walls of the greenhouse and have a different cross section compared to the columns 4. The clamps 33, 34 can be made of the same profile from which the clamps 5, 6 shown in FIG. 5, but with the struts removed 29. The clamps 33, 34 are connected to the column 32 using bolts 35, nuts 36 and spacer sleeves 37. The clamps 33, 34 are fixed to the tray 1 with a bolt 10 and a nut 9.

 In FIG. 7 shows a variant of the connection node of the gutter 1 with the column 32 without spacer sleeves 37. The movement of the gutter 1 with the clamps 38, 39 relative to the column 32 is prevented by the special shape of the clamps 38, 39 having additional collars 40, while the clamps 38, 39 also made of the same profile as the clamps 5, 6, with the removal of racks 29.

 In FIG. Figures 8 and 9 show the junction of two gutters 1 between each other using clamps 41, 42 (since greenhouses often have a considerable length (several tens of meters) and long trays are very difficult to manufacture, and even more difficult to transport and assemble). The clamps 41, 42 can be made of the same profile as the clamps 5, 6, while the posts 29 are removed. The fixing of the clamps 41, 42 on the gutters 1 is provided with bolts 10 and nuts 9. The tightness of the connection is achieved using a special mastic (or glue) with elastic properties, which is introduced into the joint between the gutters 1, or by installing an elastic gasket.

 In FIG. 10 shows a variant of the junction of the roof covering 3 of the roof with the gutter 1. If it is necessary to provide additional fastening of the roof covering on the gutter 1, special grooves 43 are made, in which figured strips 44 are installed, which ensure that the roof covering 3 is clamped to the gutter shelf 1 and made mainly of metal.

 When installing the greenhouse, columns 4 and 32 are first installed, then clamps 5, 6 and 33, 34 are attached to the gutter 1 using bolts 10 and nuts 9 with a step equal to the distance between the columns. After that, gutters 1 with clamps 5, 6 (33, 34) are installed on columns 4 (32) and fastened with bolts 8 and 35 and nuts 36. If necessary, spacers 37 are installed. When installing gutters 1 on columns 4 and 32, sealing material with elastic properties is introduced into the joints between the gutters 1, and the connection is fixed with clamps 41, 42 using bolts 10 and nuts 9 (Fig. 8, 9).

 Dowels 2 are installed in pairs between two adjacent gutters 1 with a certain step and in an inclined position relative to the horizon. In this case, the support shelf 14 of the gutter 1 enters the groove 17 of the sprocket, and the outer wall 15 into the groove 16. This connection provides additional rigidity to the gutter 1 and prevents buckling of the walls if it is possible to deform the gutter 1. When connecting the sprocket 2 only to the support shelf 14 would require an additional jumper inside the gutter, which would result in additional material consumption.

 The sproses 2 thus installed are fixed to each other, as well as to the ridge run between them. Simultaneously with the installation of the sprockets 2 (or after their installation, depending on the design of the sprockets), a roof covering 3 is placed, which is made mainly of translucent materials (glass, plastic, etc.). Loads from the weight of the roof covering, as well as from atmospheric precipitation, are transferred to the gutter 1 through the support flanges 14, the outer walls 15 and the vertical walls 20. In this case, forces arise that deform the gutter 1, which are compensated by the rigidity of the gutter 1, which has box-shaped. A cornice element 7 is installed on the extreme gutter 1 (Fig. 4). In this case, the outer wall 15 of the gutter 1 enters the groove 22, and the vertical wall 20 and the support shelf 14 of the gutter 1 are between the shelves 23 and 24 of the cornice element 7. For reliable fixation on the gutter 1 of the cornice element 7 of the shelf 24 is deformed. At the junction of the cornice elements in the groove 26, a fixing bar is installed, which provides rigidity of the joint.

 If necessary, a special mastic is used to seal the joint.

 The installation of the strips 44 in the grooves 43 of the gutters 1 is carried out, as a rule, before installing the gutters on the column, while the strips 44 can be moved along the grooves 43 and set in the desired position, which provides reliable clamping of the roof covering 3 to the supporting shelf 14 of the gutter 1.

 During operation of the greenhouse, various precipitation falls on it in the form of rain, snow, etc. As a result of the fact that the greenhouse has a sub-roof, roof, etc. heating, all precipitation turns into water and flows down the roof covering into the outer tray 11 of the gutter 1, through which it is discharged outside the greenhouse or into the circulating water supply system. At the same time, the water level can be quite high, but there is no breakthrough of water inside the greenhouse along the external trays 11, because water leaking through leaks is discharged into the main side trays 12, and on the extreme gutters, the cornice elements 7 have a wall 25 that prevents water from draining along the side of the greenhouse. When the temperature outside the greenhouse is much lower than inside, then condensate forms on the spurs and the roof covering inside the greenhouse, which flows down and, as a result, enters the main side trays 12 of the gutter 1, and through the openings 21 into the internal cavity of the gutter 1, through which is diverted from the greenhouse or into the recycling water system. Condensate, which is formed on the spurs, as well as part of the condensate draining onto the sprockets from the roof covering, flows down along the lower and inner surfaces of the sprockets, enters the inclined shelf 18 of the gutter 1, and then through the grooves 19 located in the outer walls 15, the condensate enters in the main side tray 12 and is also discharged from the greenhouse or into the circulating water supply system.

 This solution eliminates the significant drawback of the prototype, in which the condensate flowing down the lower and inner surfaces of the spurs does not fall into the tray, but flows to the plants, which adversely affects their life and contributes to the emergence of various diseases.

 Condensation does not form on the lower outer surface of the gutter 1, since the inner cavity of the tray does not communicate with the atmosphere, and the surface itself is additionally heated using a base-plate heating system.

 The presence of cavities 13 in the gutter 1 and the use of clamps 5, 6 (33, 34) to connect the gutter 1 to the columns 4 (32) allows for the tightness of the gutter 1 at the installation sites of the columns 4 (32) and thereby eliminates another significant drawback a prototype in which the design of the gutter is such that it cannot be reliably connected to the columns without violating the tightness.

 The design of the gutter 1 also provides a reliable connection between them, and in the prototype such a possibility is not provided.

 Clamps 5, 6, 33, 34 can be made of the same extruded aluminum alloy profile, which ensures modular design and reduces the range of profiles and significantly reduces the complexity of manufacturing parts compared to the prototype.

 A variant of the junction of the roof covering 3 of the roof with the gutter 1 (Fig. 10) is made in such a way that the groove 43 is turned downward by the groove and this prevents the accumulation of water in it. In the prototype, the groove, on the contrary, is turned upward by the gutter, water can accumulate in it, freezing of which leads to deformation of the groove and, accordingly, of the gutter.

 Cleaning, washing and replacing roof covering elements is not difficult. For this, already known technical solutions are used, washing machines and special devices to ensure the installation and dismantling of roof elements during repair of the greenhouse.

 Due to the fact that in most cases greenhouses under construction use recycled water supply, in some countries the use of zinc-coated gutters is prohibited, and this invention allows the export of greenhouses with gutters made of aluminum extruded profile.

 A comparative analysis of the proposed technical solution with others allows us to conclude that the proposed 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 unknown to achieve the stated goals of the gutter without the need to seal the joints (junctions) of the gutter itself with the support columns. Thus, the proposed technical solution meets the criteria of the invention of "inventive step".

 The claimed technical solution can be used in agriculture during the construction and operation of greenhouses for growing vegetable, fruit and flower crops, can improve the operational reliability of greenhouses, use them with various sizes of support columns, reduce material consumption. Thus, the proposed solution meets the criteria of the invention of "industrial applicability".

Claims (9)

 1. The gutter mainly for greenhouses, supported by columns made in the form of a tubular structure, with a base supported through intermediate fastening elements on columns, supporting, horizontal, upper shelves, outer, vertical and side walls, which together with the base form an internal tray in in the form of a closed cavity for condensate drainage, while the upper shelf is connected to vertical walls with the formation of an external tray for collecting and removing external atmospheric precipitation, and the outer, vertical The walls and horizontal shelves are arranged with the formation of two open webs, at least one of which is designed to fix the glazing and spros, serving simultaneously as the main side trays for draining condensate draining on the lower surfaces of the glazing and spros through grooves or holes in the side tray made in it at certain distances into the inner tray, characterized in that open side shaped cavities are formed on the side walls in the form of castle joints for heating the gutter with an intermediate fastening element, which is made in the form of a clamp fixed by fasteners on the columns, and inclined shelves are made on the outer sides of the outer walls, forming, together with the outer walls, additional side trays for collecting and draining condensate draining along the lower surfaces of the spurs through grooves made in the outer walls into the main side trays, the upper end of at least one of the outer walls being placed in the slot of the spros.  2. The trough under item 1, characterized in that it is equipped with a cornice element mounted on one of the outer, vertical walls and supporting shelves and fixed by deformation of the edge on the upper edge of the vertical wall.  3. The gutter according to claim 1, characterized in that the clamp is made detachable with side shoulders included in the open, profiled cavities of the side walls, and the detachable parts of the clamp are fastened together under the base of the gutter.  4. The trough according to claim 3, characterized in that the detachable parts of the clamp are fastened together and simultaneously with the column.  5. The trough under item 1, characterized in that the vertical wall in the upper part is made with a L-shaped cavity for placement in it of the fastening element of the glazing in the form of strips.  6. The trough under item 1, characterized in that it is made integral along the length of the individual parts, the junction of which is covered by clamps.  7. The gutter according to claim 6, characterized in that a sealing element is placed between the connected parts of at least the gutter.  8. The trough under item 1, characterized in that the tubular structure is made of aluminum alloy.  9. The trough in paragraphs. 1 to 8, characterized in that the locking connection is made in the form of T-shaped grooves.

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