CH719942B1 - Stationary device for clearing snow from inclined, preferably smooth, surfaces - Google Patents

Abstract

The invention relates to a stationary device for clearing snow from inclined, preferably smooth. Surfaces, in particular sloping roofs or solar panels, which comprise at least one rotatably mounted shaft on which conveying elements (1, 2, 3) are arranged for transporting a snow load, and at least one drive system, which is mechanically connected to the at least one or each rotatably mounted shaft. is operationally connected and through which the at least one or each shaft can be rotated in any direction of rotation, each shaft having at least two conveying elements in the form of screw modules (1, 2) and/or impellers (3) or at least a combination of three (6) consisting of one left-handed (1) and a right-handed screw conveyor (2) with an impeller (3) arranged between them; or is equipped with at least one impeller (3) without screw conveyors. The invention also relates to the use of the device for safe snow removal from inclined surfaces such as pitched roofs, solar roofs or solar panels.

Description

TECHNICAL FIELD

The present invention relates to a device based on screw conveyors and/or impellers, which are arranged in modular form on a rotatably mounted shaft and are intended for stationary use for clearing snow on inclined surfaces, in particular roof surfaces and solar panels .

STATE OF THE ART

[0002] In regions with usually snowy winters, snow loads on roofs represent a constant danger. On the one hand, the weight of the snow can cause static problems for roofs and, in extreme cases, lead to the collapse of roofs and, on the other hand, snow avalanches from roofs can cause damage to buildings , but in particular also lead to injuries to people underneath.

[0003] Another problem is that snow-covered roof windows can no longer perform their intended function, i.e. they can no longer allow sufficient light to penetrate into the room below and can no longer be opened for ventilation.

[0004] And last but not least, solar panels that are integrated into the roof of a building or mounted on it are also partially or completely impaired in their function by snow cover. In addition, solar panels, solar tiles or modern solar roofs can be massively damaged by the snow load, which is not uncommon, especially at higher alpine altitudes.

[0005] Numerous methods and devices are therefore known in the prior art that promise to remedy these problems. These include systems for defrosting, melting and/or washing away snow loads, but also mechanical clearing systems with conveyor screws, which are movably mounted in longitudinal rails mounted on the roof and move down the house roofs in a vertical or horizontal direction, thereby conveying the snow away in the desired direction.

[0006] A disadvantage of the known mechanical clearing systems with screw conveyors is the fact that, on the one hand, the snow is only ever conveyed in a predetermined direction and new snow can therefore only be picked up at the beginning of the screw conveyor and transported further. And on the other hand, in the case of linearly movable devices, the installation of edge and/or centrally arranged guide rails on the roofs is necessary. In addition, with larger conveyor routes, such as is the case with huge (solar) roof areas of modern agricultural stables, sports halls, industrial halls and similar hall-like buildings, substructures must be created to accommodate intermediate storage, which is essential for a stationary snow clearing device is easier to accomplish than with linearly movable systems, which are moved back and forth along the roof surfaces either up and down in the direction of the roof inclination or across the roof inclination.

The present invention attempts to overcome these disadvantages by providing a stationary snow clearing system based on rotating conveying elements, in particular screw conveyors and/or impellers or cellular wheels, which can be arranged in a modular manner on one or more drive shafts according to the respective requirements .

A snow clearing device similar to the present invention for removing snow loads on roofs is described in Japanese Patent Application No. JP201 501 7377A. The system disclosed there comprises a screw conveyor, which is mounted in a linearly movable manner in two guide rails arranged at the edge on a sloping house roof and is moved by a drive along these guide rails from top to bottom, i.e. from the roof gable towards the eaves or gutter, or vice versa conveys the snow horizontally in opposite directions, i.e. to the left and right. This is made possible by a two-part screw conveyor, the parts of which are arranged on a shaft in such a way that one part conveys to the left and the other part to the right.

BRIEF DESCRIPTION OF THE INVENTION

In contrast, it is an aim of the present invention to provide a stationary clearing system which is arranged at the deeper or lower end of a sloping or inclined roof or other sloping or inclined, preferably smooth, surface exposed to snowfall and which, if necessary, does not convey the snow away from the roof or not exclusively in a lateral direction to the left or right, but which can also convey the snow downwards in a metered form, i.e. in a specifically controllable amount and speed, away from the roof or other surface.

This is achieved according to the invention by a device according to claim 1, which comprises an elongated shaft with modules of left-handed and right-handed screw elements arranged thereon and connected in a stationary manner to the shaft, which are typically arranged in such a way that two adjacent screws either move towards each other or promote away from each other. Because each individual screw element picks up snow at one of its two ends, significantly more snow can be captured and conveyed than would be possible with a conventional device that only consists of a single screw conveyor and only conveys in one direction. Guide rails that run along the edges of the roof or other surface or centrally in the middle and would be required for a linear movement of the shaft along the roof surface are not necessary according to the present invention. However, the device according to the invention can have connecting means for stationary attachment to a sloping roof or other sloping surface and, when used as intended, is fixed in a stationary manner at the desired location, with the shaft being rotatably mounted at both ends in conventional bearings.

An electrically operated drive suitable for the respective purpose and known in the art, for example a belt, gear, toothed belt or chain drive, ensures a rotating rotational movement of the rotatably mounted shaft with the snow fixed thereon -Conveyor modules.

In one embodiment of the invention, the electric drive is equipped with a control unit which can be controlled by a user as desired, if necessary also using a smartphone via a mobile phone app specially developed for this purpose. In particular, the shaft - or in the case of several shafts, each shaft - can be rotated clockwise or counterclockwise as required. The direction of rotation can also be switched manually according to a preselected pattern at fixed time intervals or after user intervention. Likewise, the duration of the rotation and preferably also the speed of rotation of the shaft can be varied, both manually and automatically, for example sensor-controlled via a snow height sensor, a light barrier, a camera, or another suitable sensor element known to those skilled in the art. As a rule, the device according to the invention for snow removal is not operated continuously, even in heavy snowfall, but either in a preselectable automatic interval operation or manually as required in order to allow the buildup of at least a minimal snow cover of a few centimeters, typically at least 10 - 15cm.

According to the invention, at least a combination of two screw modules to be conveyed to one another can be separated from one another by an impeller or cellular wheel arranged between them, which can throw the snow conveyed from two sides simultaneously towards the impeller or cellular wheel downwards away from the roof or other surface. In the following, for the sake of simplicity, only the term “impeller wheel” will be used, although this always also includes a cellular wheel.

The shaft, which carries the worm and/or impeller modules, typically has a polygonal, i.e. triangular, quadrangular or polygonal, cross section, while the worm modules and impeller have corresponding, hollow ones that are adapted to the cross section of the shaft Have longitudinal axes, which enable the screw modules and impellers to be easily pushed onto the shaft. Due to the polygonal cross-section of the shaft, the worm and impeller elements attached to it are already fixed in a stable position without any additional aids and all rotate together at the speed of the rotation of the rotating shaft. Alternatively, the individual screw modules and impellers can each consist of longitudinal halves which are placed around the shaft and then connected to one another using connecting elements and thus at the same time to the shaft in a positionally stable manner. Although this variant is more expensive to manufacture, it does not require a polygonal cross-section of the shaft and also makes it easier to replace individual elements in the event of a defect.

It is a particular advantage of the invention that the screw modules can be selected and arranged as desired depending on the given local, spatial and/or precipitation-related requirements as well as the given roof situation. This includes the number and length of the individual screw modules, as well as their conveying directions (right-handed or left-handed), the pitch (steepness) of the screw blades, rotation diameter of the screw blades and/or the impeller wheels, the number of direction changes to be set up, as well as the number and placement of any intermediate or exclusively arranged impellers for targeted and metered throwing of snow downwards.

“Rotation diameter” is to be understood as meaning the diameter of that imaginary circle which is maximally described by the outer edges of the screw blades or the blades of an impeller during the rotation of a shaft equipped with conveying elements according to the invention.

The functioning of the snow clearing device according to the invention for sloping or inclined roofs and other inclined surfaces such as solar panels (thermal and photovoltaic) or skylights makes use of the independent sliding of the snow loads on such surfaces. As heat radiates through the roof, the underside of a snow load can begin to melt and create a sliding film that can cause the snow load to slide or slide due to gravity. However, the top layer of a snow load can also begin to melt due to solar radiation and the resulting melt water can reach through the underlying layers to the roof, which can also create a sliding film that causes the snow load to slide off. In addition, numerous possibilities are known in the prior art as to how such sliding films can be specifically created on the underside of snow loads or how the snow loads can be triggered to slide using other methods such as, for example, by generating vibrations or by using ultrasound.

Where it makes sense and is desired, the snow clearing device according to the invention can also be mounted stationary at any other location along the slope of an inclined roof surface or other inclined surface. This either in addition to or instead of being located at the lower roof edge or surface edge and typically in a horizontal orientation and substantially parallel to the lower roof edge or surface edge. If two or more snow clearing devices are placed on a single roof surface or other inclined surface, they are aligned so that the shafts equipped with the snow conveying elements run parallel to each other and parallel to the lower roof edge or surface edge.

In the case of bridging larger roof areas, two or more shafts can be rotatably connected to one another at the front in a linear alignment via intermediate bearings and can also be supported at the same time.

In a special embodiment of the snow clearing device, two or more shafts equipped with screws and/or impellers according to the invention can be arranged vertically one above the other and connected to a common drive system or to their own drive system in order to achieve snow depths of, for example, 30 cm and more, especially from 50 - 100cm and above, to be able to clear away successfully and in a well-dosed manner. The shafts can be spaced apart by more than one screw and/or impeller diameter (= rotation diameter), so that screw and/or impeller modules located one above the other can never touch each other and leave a continuous, horizontal gap or channel. However, they can also be arranged in such a way that the shafts are spaced apart by less than a rotational diameter and the screws and/or impellers mesh with one another.

[0021] In a snow clearing device according to the invention, the at least one shaft that is to be mounted in a stationary manner or is mounted in a stationary manner can be equipped exclusively with impellers instead of with screw modules. Depending on the snow clearing task, the axial length of the impellers, the number, length and geometric shape of the blades per impeller, as well as the number of impellers on the shaft can be adjusted and varied accordingly. In a typical embodiment, such an impeller has a rotation diameter of 10 - 25 cm, an axis length of 10 - 200 cm and a number of 2 - 6 blades per impeller.

This type of stationary snow clearer according to the invention for inclined roof surfaces and other inclined surfaces can also be designed in the form of two or more shafts arranged vertically one above the other and equipped with impellers. The shafts can also be arranged at a distance from one another by less or more than one rotational diameter and the impellers can therefore mesh with one another or not.

The shaft, the screw modules and/or the impellers of the snow clearing device according to the invention can be made of metal, in particular light metal, or plastic, or of a combination of these materials. Likewise, all screw modules and/or impellers can be arranged without gaps adjacent to one another on one or each shaft or all or some of them can be spaced apart from one another. An arrangement according to the latter case with at least partially spaced conveying elements can be particularly advantageous for a combination of two or more shafts distributed over the relevant (roof) surface and arranged at a distance parallel to one another. This is particularly the case when the conveying elements, i.e. the screw modules and/or impellers, of two adjacent shafts are arranged offset from one another in such a way that they fill or span the gaps of the other shaft. This allows material savings and thus weight and cost reduction while still maintaining high functionality and efficiency of the stationary snow clearing system according to the invention.

FIGURE DESCRIPTION

Fig. 1 shows schematically a screw module in side view 1A and in cross section 1B with right-handed screw blades and conveying direction to the right, when rotating counterclockwise. Fig. 2 shows schematically a screw module as in Fig. 1 in side view 2A and in cross section 2B, but with left-handed screw blades and the opposite conveying direction (left) when rotating counterclockwise. Fig. 3 shows schematically a double shaft with meshing screw blades in side view 3A and cross-sectional view 3B. Fig. 4 shows schematically a three-blade impeller module in side view 4A and cross-sectional view 4B. Fig. 5 shows schematically a double shaft with meshing impeller modules in side view 3A and cross-sectional view 3B. Fig. 6 shows schematically a part of a snow clearing device according to the invention in a side view, with a centrally arranged impeller and screw modules directly adjacent to it on both sides, which convey in opposite directions, e.g. when rotating counterclockwise towards the impeller. Fig. 7 shows a polygonal shaft in side view 7A and in cross-sectional view 7B, with a hexagonal cross-section, for receiving the screw and/or impeller modules.

DETAILED DESCRIPTION OF THE INVENTION

On a shaft 7 with a polygonal, in particular three-, four-, five-, hexagonal or octagonal cross-section, at least two conveying elements in the form of screw modules 1 and 2 and/or impellers 3 are arranged and fixed in a stationary manner.

In an embodiment 6 of the present invention, two screw modules 1, 2 and an impeller 3 are arranged on the shaft 7 as a combination of three in such a way that a left-handed screw module 2 with one end face directly adjoins the impeller 3 and a second, right-handed screw module 1 with one end adjacent to the other side of the impeller 3 (Fig. 6). When used as intended, the shaft is rotatably mounted on both sides by conventional bearings, e.g. ball bearings, and is connected at least at one end to a controllable drive unit, which can set the shaft in rotation. Depending on the direction of rotation of the shaft, the snow to be conveyed is either transported towards the centrally arranged impeller or away from the impeller.

In another embodiment of the invention, two or more such three combinations of worm-impeller wheel-worm are arranged on the shaft 7, possibly with different axial lengths.

In a further embodiment of the invention, only a single impeller module 3, which typically essentially completely spans the shaft, is arranged on the shaft 7 and no conveyor screw. As a rule, such a pure impeller system includes two or more impeller modules 3, which are arranged either directly adjacent to one another or at a distance from one another on the shaft 7.

In order to free snow-covered house roofs, solar panels, solar roofs or other inclined surfaces from winter snow loads in an energy-saving, safe and yet efficient manner, a combination of screw and impeller modules according to the invention is typically attached in a stable manner to the lower edge of a sloping roof or an inclined surface and through controllable rotation of the shaft, the snow is transported in a metered manner to the impeller and ejected from it or thrown downwards from the roof, the panel or other inclined surface.

Because the shaft 7 preferably has a polygonal cross section, worm and/or impeller elements of the desired axial length and desired geometric shape can and must simply be pushed onto the shaft via corresponding hollow axes 8 that are adapted to the cross section of the shaft only be fixed in the area of the two ends of the shaft in order to prevent lateral displacement on the shaft.

In an alternative embodiment, the shaft has an oval cross section, which also allows the simplicity of equipping the conveying elements as with a shaft with a polygonal cross section.

In a further embodiment, the shaft has a round cross-section, which requires additional connecting means such as clamping connecting means or screws to secure the conveying elements on the shaft in a stable manner. The disadvantage is that this increases the costs and may also make it more difficult to replace any defective conveying elements, unless the conveying elements are designed as half-shell products and can be placed around the shaft and connected to complete conveying elements using connecting means. Typically, they are also fixed in a stable position on the shaft at the same time.

In a further embodiment, the snow clearing system consists of a shaft with conveying elements permanently fixed thereon, for example glued or welded on.

In a special embodiment, two or more shafts equipped with screws and/or impellers according to the invention can also be arranged vertically one above the other in order to clear snow depths of, for example, 30 cm and more, in particular 30 - 100 cm, successfully and in a well-dosed manner can. The shafts can be spaced apart by more than one worm or impeller diameter (= rotation diameter), so that worm and/or impeller wheels located one above the other can never touch each other and leave a continuous, horizontal gap or channel, or in such a way that the shafts are spaced apart by less than a rotational diameter and the screws and/or impellers therefore mesh with each other. Fig. 3 shows such a double shaft system 4 with meshing screw modules 1, 2.

In another embodiment of the invention, the at least one shaft 7 to be mounted stationarily or mounted stationary can be equipped exclusively with impellers 3 instead of screw modules 1, 2. This variant of a stationary snow clearing device 5 (Fig. 4) can also be designed in the form of two or more shafts arranged vertically one above the other and equipped with impellers. Fig. 5 shows schematically such a double shaft system 5 with only impellers, in which case the shafts are arranged less than a rotation diameter apart from each other and the impellers therefore mesh with one another. This means that snow loads with snow depths of 30 cm and more, in particular from 30 to 100 cm, can be thrown off or removed from sloping roof surfaces, solar panels or other inclined surfaces in a targeted and well-dosed manner.

Where it is not absolutely necessary to convey the snow to the side to a suitable discharge point or collection point intended for this purpose, a pure impeller system, especially in the form of a double or multi-shaft system 5, is an excellent variant of stationary snow clearing -Device in accordance with the present invention.

In general, it should be noted that the various embodiments of the stationary snow clearing system according to the invention serve not only to remove the snow loads but in particular also to retain the snow loads on the inclined surfaces. This applies even more to the double and multi-shaft systems 4 and 5 in accordance with the invention. This retention function allows the snow to be held back until snow can be cleared safely or as efficiently as possible.

Since the snow clearing device according to the invention is primarily used on sloping roofs of residential buildings and halls of all kinds, as well as on solar panels and solar roofs, the shaft and the associated snow conveying elements are preferably made of light material, in particular of suitable plastic or light metal or a combination of these materials. Where there are no static concerns and/or larger distances are to be spanned with a single shaft, other materials such as stainless steel can of course also be used, especially for the shaft.

If roof surfaces of larger objects are to be equipped with the snow clearing system according to the invention, intermediate bearings may need to be provided for the shaft or shafts in order to ensure smooth operation under the given conditions. A combination of two or more shafts, which are rotatably connected and supported in axial alignment on the front side via intermediate bearings, can be implemented relatively easily with the technology of the stationary snow clearing device according to the invention and is of course significantly simpler and cheaper than with those known in the prior art. linearly moving snow clearing systems.

In one embodiment of the snow clearing device according to the invention, which is primarily intended for large, contiguous roof surfaces, a combination of two or more shafts connected to one another in axial alignment at the end comprises one or more additional drive units, which are typically in the axial direction are arranged between two shafts and at the same time act as a bearing and support for these shafts at their front ends. Each such intermediate drive unit is preferably equipped with means that allow the two shafts connected to a drive unit to be supported independently of one another and to be driven independently of one another. With such a snow clearing device system, it is also possible, for example, to clear individual sectors of a roof or other surface from snow independently of other sectors.

It is a particular advantage of the present invention that the stationary snow clearing system can be easily adapted to the respective requirements. Thanks to the preferred modular design based on a simple plug-in system, the number, length, screw or impeller geometry and dimensions of the screw and/or impeller modules can be tailored to the respective requirements for the length of the roof surfaces, solar panels or other inclined surfaces to be cleared of snow Adjust surfaces perfectly. This includes both the conveying direction of the amount of snow to where it can be thrown off safely, as well as the placement of the impellers to enable the snow to be thrown off or collected in a measured, safe manner. By reversing the direction of rotation of the shafts, self-cleaning effects of the conveying elements can also be achieved - especially in double and multi-shaft systems.

REFERENCE SYMBOL LIST

1 Conveying element in the form of a screw module, right-handed 2 Conveying element in the form of a screw module, left-handed 3 Conveying element in the form of an impeller or cellular wheel 4 Snow clearing device in the form of a double shaft system with meshing screw modules 5 Snow clearing device in the form of a double shaft system with meshing impeller or cellular wheel modules 6 snow clearing device in the form of a triple combination of screw module on the right - impeller - screw module on the left 7 polygonal shaft for receiving the conveying elements 8 hollow axis of a conveying element adapted to the shaft

Claims (13)

1. Device for clearing snow from inclined, preferably smooth, surfaces, in particular from sloping roofs, solar roofs, skylights, and solar panels, which comprises at least one rotatably mounted shaft (7) on which conveying elements (1, 2, 3) for removing a snow load are arranged, as well as at least one drive system, which is in mechanical-operational connection with the at least one or each rotatably mounted shaft (7) and through which the at least one or each shaft (7) can be rotated in any direction of rotation, characterized in that the device is designed as a stationary system and is free of means which, when the device is used as intended, would cause a linear movement of the at least one or each shaft in any direction, whereby on the at least one or each shaft (7) The following conveying elements are arranged in a stationary manner: a) at least two conveying elements in the form of screw modules (1, 2) and/or impellers (3); b) at least one combination of three (6) consisting of a left-hand screw conveyor (1), a right-hand screw conveyor (2) and an impeller (3) arranged between them; or c) at least one impeller (3), preferably two or more impellers, and no screw conveyors. 2. Device according to claim 1, with a shaft (7) which has an impeller (3) and no screw conveyors, characterized in that the impeller (3) has an axial length which essentially corresponds to the length of the shaft (7). . 3. Device according to claim 1, characterized in that all conveying elements on the shaft are arranged directly adjacent to one another or all or some conveying elements are arranged on the shaft at predetermined lateral distances from one another. 4. Device according to one of claims 1 to 3, characterized in that it has two or more shafts (7) equipped with conveying elements, which are rotatably connected and supported in the axial direction at the front via bearings arranged between them. 5. Device according to claim 4, characterized in that one or each bearing arranged between them is designed as a - preferably independently controllable - drive system, which supports each of the two shafts connected to the drive system independently of one another and can drive them independently of one another. 6. Device according to one of claims 1 to 3, characterized in that it has two or more shafts (7) equipped with conveying elements (1, 2, 3) which are arranged vertically one above the other, the vertical distance between the shafts being either is larger or smaller than the diameter of an imaginary circle described by the conveying elements on their outer edges when the shafts rotate. 7. Device according to claim 6, characterized in that the distance between the shafts is smaller than said circular diameter and the conveying elements (1, 2, 3) are arranged in a meshing manner. 8. Device according to one of claims 1 to 7, characterized in that the at least one or each shaft (7) has a round, oval or polygonal cross section and each conveying element (1, 2, 3) has a corresponding cross section adapted to the cross section of the shaft Has hollow axle (8). 9. Device according to one of claims 1 to 8, characterized in that it has means for stable, stationary attachment to the inclined, preferably smooth, surface, in particular to a roof, solar roof, skylight, or solar panel. 10. Device according to one of claims 1 to 9, characterized in that each drive system is equipped with means for manual, automatic and / or sensor-controlled operation. 11. Use of a device according to one of claims 1 to 10, for removing snow loads from inclined, preferably smooth, surfaces, in particular from sloping roofs, solar roofs, skylights, and solar panels. 12. Use according to claim 11, in combination with at least one second device according to one of claims 1 to 10. 13. Use according to claim 12, wherein a first device is mounted in a horizontal orientation in the region of a lower end of the inclined, preferably smooth, surface, in particular a pitched roof, solar roof, skylight or solar panel, and each further device is at a predetermined distance and parallel to the first device is placed.