NO783337L - DEVICE AT ROOF GUTTER. - Google Patents

Description

Device at gutters.

The present invention relates to a device for gutters in a roof with a slope towards the sides of the gutters, the gutters having outlets in the form of wells and openings.

The purpose of the present invention is to arrive at

to a gutter of the aforementioned type, whereby it is possible to construct a gutter that meets the special requirements of a roof with regard to the number of outlet wells, overflows, etc. Furthermore, it is an aim to arrive at a gutter that can be repaired without therefore the entire gutter must be dismantled. The roof gutter according to the invention also provides a simple possibility for accurate horizontal placement, regardless of any height differences in the roof's supporting structure. By height differences is meant here the small variations that can occur in height level from truss to truss, within the permitted construction tolerances. Furthermore, with the invention, by means of simple means, it can be ensured that no ice forms at the edges of the gutter.

To achieve these purposes, the invention comprises the features specified in the subsequent patent claims.

In the following, an embodiment of the invention will be described, with reference to the<1>attached drawings. Figs. 1, 2 and 3 show, seen from the side, three different types of chute sections which can be assembled in suitable combination and in suitable numbers to form a complete chute. Fig. 4 shows on an enlarged scale a cross-section of a chute section according to the invention. Fig. 5 shows means for connecting two gutter sections end to end. Fig. 6 shows in cross-section an anchoring profile intended for mounting the gutter sections, while fig. 7 shows the anchoring profile seen from the side. Fig. 5 - 7 are also on a larger scale than fig. 1 - 3. Fig. 8 shows in perspective a roof beam layer with gutters according to the invention.

The invention thus relates to roof gutters which are mounted on a roof that slopes in the direction of the gutter, and the gutter conducts the water via outlet wells and any other openings at the end of the gutter at the wall of the building. The drainage lines from the outlet wells can be led down through the building or in some other way. In the following description of the invention, with reference to the drawings, it is assumed that the gutter is mounted in the roof of the building in a conventional manner.

According to the idea of the invention, the roof gutters comprise several gutter sections. A gutter here means a gutter that runs from one side of the building to the other. Each gutter comprises several types of sections, and the different sections are shown in fig. 1-3. Thus, fig. 1 an outer section of the gutter, i.e. the section whose end is located at the end of the building. The left end of the section according to fig. 1 is assumed to be at the end of the building. The gutter section 1 thus has an extent in the longitudinal direction which enables it to be handled, and has in cross-section the shape of an upwardly open U, as shown on an enlarged scale in fig. 4. The section 1 thus has a bottom 2, sides 3 and upper edges folded into a flange 4. The sections are joined one after the other by means of rubber cuffs and pipe clamps that enclose the spigots 5, which protrude from the end wall of each gutter section. The connection between the connectors is shown in fig. 5, and shall be described in more detail below. The flow area of the pipe nozzles can e.g. be 20 liters per second when the water level in the section is 20 cm. There is thus free flow from section to section, and the sections are mounted in a horizontal position. The outlets from the section 1 are arranged in the form of an outlet well 6 with an outflow edge that is at the level of the bottom 2 of the section. A further outlet well 7 is arranged at the end of the section, and this outlet well has an elevated inlet in the form of an elevation ring 8. Thus, when the water level in the chute section rises above the elevation ring 8, the outlet well 7 comes into operation. As can be seen from fig. 1, the gutter section at the left end is equipped with an outlet 9, and this outlet is attached to a pipe connection 10 on the end wall of the gutter section. The outlet comes into operation as a final safeguard to prevent the gutter from overflowing. The dimensions are such that normally only the outlet wells 6 and 7 provide drainage of the rainwater. Under the edge flanges 4 and along the entire length of the gutter sections, pipes 12 are placed, which protrude from the ends of the gutter sections approximately as much as the pipe ends 5. The gutter section 1 does not, however, need to be provided with a protruding end of the pipe 12, as this section forms the end of the chute itself.

In fig. 2 shows an intermediate type of chute section 11. This chute section differs from chute section 1 in that it must be able to be connected at both ends with adjacent chute sections, and it thus has similarly designed pipe ends 5 at each end wall, and furthermore, the pipes 12 project equally far from both end walls. An outlet well 6 is arranged at the center of the chute section, and the outlet edge for this lies flush with the bottom 2 of the chute section 11. Number of chute sections

II that forms the gutter depends on the gutter's total length and the roof area from which water is to be diverted, as well as the amount of rain

which has been the basis for the dimensioning on the site where the building is located. Larger roof area and greater amount of rain thus require more outlet wells 6 and more gutter sections 11.

In fig. 3 shows a third type of chute section 13, and this differs from the other chute sections, and particularly from section 11, only in that it has no outlet well 6. With the help of chute sections 11 and 13, the required number of outlet wells 6 is adapted.

The gutter sections 1, 11 and 13 are thus assembled in suitable numbers one after the other, and they can be easily separated from each other, so that if a gutter section breaks, it can be replaced without the entire gutter having to be dismantled. The gutter section 1 forms the end section of the gutter, that is the gutter's left end as shown, and a gutter section which is reversed in relation to the gutter section 1 shown is placed at the gutter's right end. The gutter sections 11 and 13 are arranged in suitable numbers along the extent of the gutter between two gutter sections 1, i.e. between the gutter section 1 and a corresponding gutter section which has been reversed. Alternatively, a gutter section can be arranged at one end of the gutter which has a pipe connection 5.

In fig. 5 shows the connection between two adjacent chute sections. The two pipe ends 5 are thus arranged against each other, and a rubber sleeve 14 is pushed over the pipe ends. The rubber cuff is pressed against the pipe ends 5 using a conventional pipe clamp 15.

Each pipe section lies with its ends against an underlying one

part of the roof, i.e. a truss or roof beam, by means of an anchoring profile 16 which is common to two adjacent ends of two gutter sections. The anchoring profile is shown in fig. 6, and in principle have the same cross-sectional shape as the gutter sections. However, the anchoring profile has a somewhat larger width, like this

that the gutter sections can be laid down in the anchoring profile. The anchoring profile thus comprises a bottom part 17 and sides 18. The sides 18 are, as shown in fig. 7, designed with several rows of holes at different height levels, so that the installation of the anchoring profile can be adapted to each end of the respective gutter sections, so that a suitable height is obtained for one end of the gutter section in relation to its other end and in relation to the supporting part of the underlying roof. The gutter section must therefore lie horizontally, but with the current building tolerances this cannot be achieved if there is no compensation for the permitted difference in e.g. height level for the different

roof trusses or roof beams. Connection between the anchoring profile 16 and the gutter section is made by means of screws.

Each gutter section has an edge 19 which projects from the section's sides 3, and in these edges there is at least one hole 20. In order to

get the appropriate height for the gutter section, i.e. horizontal position, the hole 20 is connected to a suitable hole 21 in the side 18' of the anchoring profile 16. By having the holes 21 arranged in several rows and at different height levels, a very precise setting the height of the gutter sections in relation to the roof. The lower side 17 of the anchoring profile thus lies against a roof beam or truss or other fixed part of the roof.

In fig. 5, the pipes 12 are not shown, but these appear from fig. 4. As can be seen from fig. 1-3, and as mentioned above, the pipes 12 protrude from the end walls of the gutter sections approximately as far as the pipe ends 5. Adjacent pipes 12 can be connected in a suitable way, which does not form any part of the present invention. Heating cables are introduced into the pipes 12, in order to heat up the gutter sections in the area at the upper edges. It has been shown that at a certain snow depth the roof is insulated to such an extent that underlying heat penetrates so much that the snow on the roof melts in the vicinity of the gutter, but on the other hand the gutter itself is not sufficiently heated. When the water therefore flows down towards the gutter and it is below zero outside, ice forms at the upper edges of the gutter, and eventually such a large amount of ice can build up that the water does not flow down the gutter, but remains on the roof, and can be sucked down through capillary holes or the like, so that damage occurs due to moisture. A heating cable that is laid in the pipes 12 and heats the roof gutter prevents ice formation in the upper edges of the roof gutter. The heating cable can be controlled automatically, so that it e.g. is

switched on in temperatures between +2°C and -5°C, as well as when the snow layer is e.g. 20 cm. The control thus takes place with one or more temperature-sensing organs, and possibly in combination with one or more organs for sensing the snow depth.

The cross-section of the gutter sections can be chosen depending on the roof construction in question, and of course also based on consideration of the rain intensity at the site where the building is located. A suitable measure is that the cross-section is chosen as such (height and width)

that the storage capacity of the sections in a horizontal position and for a period of four minutes corresponds to two minutes of torrential rain. Thereby, sufficient drainage capacity is ensured for the gutter section to the outlets in the form of the outlet wells 6 and 7 as well as the outlet 9 which is required in a maximum case.

Within the framework of the subsequent patent claims, the invention can be thought of as changed in relation to the above-described embodiment. Thus, the cross-sectional shape of the gutter sections can be varied, and furthermore the shape and location of the spigots 5 can also be different. Any suitable outlet wells may be provided, and the number of outlet wells and gutter sections may vary within wide limits. It is stated above that the anchoring profile 16 has a shape that mainly corresponds to the cross-sectional shape of the gutter sections, but this is also not necessary, as the essential thing is that the anchoring profile has a shape that is adapted to the edge parts 19. It should be noted that a pipe section can easily be disconnected from the gutter, by that the connection to the pipe fittings 5 is loosened, after which the bolted connection between the edges 19 and the sides 18 of the anchoring profile is loosened. Furthermore, the heating cable must be disconnected between the gutter section to be removed and the other part of the gutter.

Claims (7)

1. Device for gutters in roofs with slopes towards the sides of the gutters, whereby the gutters have outlets in the form of wells and openings, each gutter comprising several sections which are closed at the ends and are connected one after the other with a free through-flow connection, characterized in that at least one section (1) (outer section) that ends at the outer edge of the roof is equipped with at least one outlet well. (6) with an outlet flush with the bottom of the section (2), a first overflow (8) connected to another outlet well (7) and another overflow (10) at a higher level, which is connected to an outlet (9). 2. Device as stated in claim 1, characterized in that the flow connections between the sections are made up of pipe spigots (5) which are interconnected by means of pipe clamps (15) and elastic cuffs (14), whereby adjacent ends of two sections are jointly supported by an anchoring profile ( 17, 18). 3. Device as stated in claim 2, characterized by the fact that the pipe connections have a flow area that gives 20 liters per second when the water level in the inlet section is 20 cm. 4. Device as stated in claim 2, characterized in that the anchoring profile (17, 18) has the cross-sectional shape of an upwardly open U, and that the profile and the ends of the adjacent sections can be fixed by means of e.g. a screw joint (20, 21) in several optional heights. 5. Device as stated in claim 1, characterized in that the cross-section of the sections (1) is chosen in such a way (height and width) that the storage capacity of the section in a horizontal position for a period of 4 minutes corresponds to 2 minutes with the dimensioning driving rain. 6. Device as stated in claim 1, characterized in that each section (1) in the vicinity of the longitudinal, upper edges has pipes (12) which can be joined with corresponding pipes in an adjacent section, .an electric heating cable can be inserted into the pipes to heat up the edge areas of the section. 7. Device as stated in claim 4, characterized in that the anchoring profile (17, 18) has two sides, with several holes at different heights and rows, and that the gutter sections have edges that project longitudinally from the sides and have one or more holes , whereby the edges can be united by means of the sides of the anchoring profile by means of screws or equivalent.