FR2655075A1 - Building with rotary structure - Google Patents

Abstract

The invention relates to a type of building with a rotary structure supported and oriented by particularly compact mechanical means. The rotary structure (51) is mounted on a rolling bearing of the live ring type (54) with a vertical axis of rotation (62). The ring (54) comprises an outer collar provided with a toothing which is driven by a pinion of an electric geared motor (55). The latter is preferably supplied with current of variable frequency in order to make it possible to modify the speed of rotation of the building. The live ring (54) can support the entire weight and stresses of the rotary structure. Application to buildings for dwelling purposes or for commercial use.

Description

The present invention relates to a rotating structure building comprising a fixed structure provided with a foundation, and a rotating structure mounted on the fixed structure by means of support and orientation so as to be able to rotate on command about an axis. vertical and to be maintained in different orientations relative to the fixed structure, said support and orientation means comprising at least one ball bearing or roller, arranged to support both radial forces and axial forces.

The achievements of rotating buildings are becoming more and more numerous, both for tourism or pleasure purposes as for functional reasons such as the controlled use of solar radiation. In general, the vertical load constituted by the rotating structure with all that it carries is transmitted to the fixed structure by one or more circular rings of rubberized rollers with horizontal axes, rolling on one or more corresponding circular tracks, of which at least l one is near the periphery of the structure. The construction of such roller or wheeled devices is difficult to achieve with precision, their diameter being of the same order as that of the building, so that they are often the cause of shocks, vibrations or deformations of the rotating structure, creating noise and can affect operating safety. In addition, these devices have a relatively high rolling resistance, requiring fairly powerful and energy-consuming drive means. A simple example of a building of this kind, guided by a central pivot and supported by a peripheral row of rollers, is described in document FR-A-2 346 508.

Furthermore, patent FR-B-2 276 433 describes a construction with a rotating structure of the type specified in the preamble, in which a bearing, called an orientation ring, is intended to center the rotating structure and incidentally to support a small central part. of it. However, the term "slewing ring" does not seem correct in this case, since the bearing in question is not designed to play a role in the orientation of the rotating structure.

More specifically, the rotating structure comprises a platform having radial beams supported by three separate devices, namely the slewing ring in the center, a train of wheels with horizontal axes at the periphery of the platform, and floats arranged between the two other devices and supporting the majority of the permanent vertical load of the rotating structure. The drive and the rotational positioning are carried out in the usual manner, by means of a motorized pinion driving a circular rack disposed along the track of the peripheral wheel train. All of these devices are obviously expensive and require an infrastructure which extends over a large area, roughly corresponding to that of the rotating structure.

The present invention aims to avoid the drawbacks mentioned above, by arranging the support and orientation means of the building in a compact manner, making it possible to do without a roller device or another large device. for the support and training of the rotating structure.

For this purpose, the invention relates to a building of the type indicated in the preamble, characterized in that said bearing is an orientation ring which supports substantially all of the weight and vertical loads of the rotating structure, and in that this ring orientation comprises a toothing on which motorized means for driving in rotation are engaged.

In a preferred embodiment of the invention, said toothing is a circular toothing carried by a ring of the slewing ring and cooperating with a pinion driven in rotation by a geared motor group.

Advantageously, the toothing and the rotating structure are integral with an outer ring of the slewing ring, and the gearmotor and an inner ring of the slewing ring are mounted on the fixed structure. Preferably the teeth are an integral part of said outer ring.

In a preferred embodiment, the motorized drive means are at variable speed.

In a particular embodiment, said slewing ring is arranged to support horizontal centering forces at this level, and the building comprises at least one second bearing disposed at another level and arranged to support horizontal centering forces on this other level. Said second bearing can be arranged to also support part of the weight and vertical loads of the rotating structure and can be of the slewing ring type.

In cases where the building is designed to be able to carry out more than one revolution, the slewing ring can be arranged around a central set of rotary connections of distribution networks, in particular of water and electricity. If, on the contrary, the building is provided with stops preventing it from going beyond a complete turn or a fraction of a turn, the slewing ring can be arranged around a central set of cables or flexible pipes for connection to distribution networks.

In both cases, these network connections can be made optimally in the relatively large free space that the slewing ring surrounds.

Other features and advantages of the present invention will appear in the following description of various embodiments, presented by way of nonlimiting examples and with reference to the accompanying drawings, in which - Figure I is a schematic perspective view, partially
section of a lower part of a rotating structure building
carried by an orientation ring, - Figure 2 is a perspective view of the orientation ring,
cut diametrically, - Figure 3 is a schematic view in partial vertical section
showing motorized drive means, coupled to the
slewing ring, - Figure 4 is a schematic view in vertical section illustrating a
another embodiment of the invention, - Figure 5 is a view similar to Figure I, showing another
embodiment, and - Figure 6 is a schematic view in vertical section showing
the connection of distribution networks to a rotating structure
by means of flexible cables or conduits.

In the example illustrated by FIGS. 1 to 3, a rotating structure of building 1 is pivotally mounted, around a vertical axis, on a fixed structure 2 by means of an orientation ring 3. The rotating structure 1 is driven in rotation and / or maintained in a desired orientation, by means of a geared motor group 4 mounted on the fixed structure 2 and provided with a pinion 5 attacking a toothing 6 extending all around the slewing ring 3. Preferably, the geared motor group 4 includes an electric motor supplied at a variable frequency on command, so that the speed of rotation of the building carried by the rotating structure 1 can be adjusted as desired.

This structure I is only shown in an incomplete and very schematic manner by a rotating metal frame 10 on which are mounted two parallel beams 11 fixed with bolted plates 12. It will be appreciated that these beams 11 can support, by example, the whole of a light building of the chalet type (not shown), which can thus be placed in any orientation, in particular using a programmed command from the geared motor group 4.

The fixed structure 2 comprises a stationary metal frame 14 mounted on a concrete assembly 15 forming the foundation of the building and containing a chamber 16 which is preferably in the basement and which is provided with external access.

Figure 2 shows in more detail a portion of the slewing ring 3, which is a type of bearing known in the field of construction machinery, in particular for supporting and orienting the super rotating structure of machines such as cranes, hydraulic or cable excavators, etc. This ring comprises a circular inner ring 18 provided with vertical bores 19 allowing it to be fixed to the lower frame 14, an outer ring 20 provided with vertical bores 21 allowing it to be fixed to the upper frame 10 and an external toothing 6, and a series of inclined rollers 22 disposed between the two rings 18 and 20. This provides a bearing designed to support high axial loads, but also high radial loads and tilting moments with respect to horizontal axes. relatively low loads, there are also such slewing rings comprising balls instead of rollers 22.

FIG. 3 shows in more detail the principle arrangement of the geared motor group 4, comprising an electric motor 24 with a horizontal axis and a reduction gear 25 carrying the pinion 5 with a vertical axis. Another position 4 ′ of group 4, located substantially lower and drawn in broken lines, shows another possibility of arrangement of the drive members if a transmission shaft 26 is used. In both cases, the mechanism illustrated in the figure 3 has a set of advantages compared to traditional constructions with wheel or roller train 1 generally used in the field of rotating buildings. The slewing ring 3 outperforms roller systems for safety, operational reliability and low levels of friction, noise and vibration. In addition, the drive on teeth 6 takes place in close proximity to the components of bearing, without creating parasitic forces and deformations in the structure. The drive by gearmotor and gear causes little loss and therefore requires relatively low power. The motor can advantageously be supplied with alternating voltage at variable frequency. With a suitable control device, a user can change the speed by simply adjusting a potentiometer, for example to slowly follow the orientation of the sun or to perform rapid rotations in order to present a panoramic view to the occupants of the buildings. In addition, the variable frequency control can easily be slaved to an electronic programming device.

In another variant, particularly useful for a dwelling house, the drive can be provided by a two-speed reciprocating motor: a first relatively slow speed corresponding to that of the sun used during the day, and a second faster speed for return at night to the starting position by a movement in the opposite direction.

In the example of FIGS. 1 to 3, the building carried by the rotating structure 1 is arranged so as to be able to rotate continuously in the same direction, so that the various distribution networks must be connected to the building by rotating connections represented schematically in the FIG. 1. This is a rotary joint 27 for the water supply, a rotary collector 28 for telephone lines, a rotary collector 29 for electrical supply, and a rotary collector 30 for Wastewater. All these connections are known elements and do not need to be described in detail. An interesting aspect of the construction presented here is that these connections can all be arranged near the orientation crown 3. In the present example of a construction for a light building, this crown can have a diameter of the order of '' one meter, providing enough interior space for cables and conduits from different networks and their swivel connections.

Figure 4 schematically shows an arrangement for a larger building. having a rotating structure 31 mounted on a fixed central structure 32 of cylindrical shape. by means of two slewing rings 33 and 34 located at different levels. The lower crown 33 is the main and larger of the two; it is arranged to support the vast majority of the weight of the rotating structure 31 and it is coupled to a drive pinion (not shown) actuated by a motor. In this example, it carries metal beams 35, 36 carrying a horizontal platform 37 of the rotating building. This platform is accessed by a stairwell and an elevator 38 forming the center of the fixed structure 32 and provided with lateral outlets 39 at the level of the platform 37.

The second slewing ring 34 supports the central area of a roof 40 of the rotating part. In this case, not only the axial loads, but also the radial loads can be large, depending on the overturning torques which can be created by asymmetric loads on the rotating structure 31. In this example, a rotating manifold 41 for the electrical supply is advantageously arranged in the zone of the secondary crown 34.

The example of FIG. 5 is that of a construction the size of which can be between that of the two examples described above. A building with a polygonal rotating structure 51, for example of glued laminated wood, has a platform 52 supported by a frame with less than twelve arms 53, resting on an orientation ring 54 driven in rotation by a geared motor group 55. The ring 54 is supported by a frame 56 on a circular concrete foundation 57 which therefore supports the entire building. A circular wall 58 is placed below the periphery of the platform 52 and supports the surrounding terrain, for example a terrace 60 bordering the building. A set 61 of rotary connections for the distribution networks can be provided in the basement, on the axis of rotation 62. Above the platform 52, the rotary structure comprises a tubular central mast 63 used for the structural element and sheath for the passage of cables and distribution pipes.

FIG. 6 schematically illustrates a simpler embodiment, making it possible to avoid the set 61 of rotary connectors shown in FIG. 5, if the rotation of the rotary structure 51 is alternative and limited to 3600 or less. With this operating mode, all of the rotating structure to the distribution networks can be done, in the region of the axis of rotation 62, by flexible pipes or cables 66 to 69. To limit rotation, it suffices to provide at least one pair of limit switches 70 on the slewing ring 54.

The present invention is not limited to the embodiments described above, but it extends to any modification or variant obvious to a person skilled in the art. In particular, it is possible to provide multiple forms of rotating structures, even on several floors, mounted on one or more slewing rings, the sizes of which can be very variable according to requirements, while remaining compact assemblies which can be easily maintain and protect against harmful external influences. On the other hand, other drive means can be used in cooperation with the teeth of an orientation ring, for example hydraulic motors, a chain transmission, a rack actuated back and forth by a cylinder, or other similar devices.

The present invention is applicable both to residential buildings and to buildings for commercial or leisure use.

Claims (9)

Claims 1. Building with a rotating structure, comprising a fixed structure provided with a foundation, and a rotating structure mounted on the fixed structure by means of support and orientation so as to be able to rotate on command about a vertical axis and to be held in different orientations relative to the fixed structure, said support and orientation means comprising at least one ball bearing or roller arranged to support both radial forces and axial forces, characterized in that said bearing is a slewing ring (3) which supports substantially all of the weight and vertical loads of the rotating structure (1), and in that this slewing ring has teeth (6) on which motorized means for rotational drives are engaged. 2. Building according to claim 1, characterized in that said toothing (6) is a circular toothing carried by a ring of the slewing ring and cooperating with a pinion (5) driven in rotation by a geared motor group (4). 3. Building according to claim 2, characterized in that the toothing (6) and the rotating structure (I) are integral with an outer ring (20) of the slewing ring (3), and in that the group gear motor (4) and an inner ring (18) of the slewing ring are mounted on the fixed structure (2). 4. Building according to claim 3, characterized in that the toothing (6) is an integral part of said ring. 5. Building according to claim 1 characterized in that the motorized drive means are at variable speed. 6. Building according to claim 1, characterized in that said orientation ring (33) is arranged to support horizontal centering forces at this ring, and in that the building comprises at least one second bearing (34) disposed at another level and arranged to support horizontal centering forces at this other level. 7. Building according to claim 6, characterized in that said second bearing (34) is arranged to also support part of the weight and vertical loads of the rotating structure (31). 8. Building according to claim 1, characterized in that the slewing ring (54) is arranged around a central assembly (61) of rotary connections of distribution networks, in particular of water and electricity. 9. Building according to claim 1, characterized in that the slewing ring (54) is arranged around a central assembly of cables or flexible conduits (67, 68, 69) for connection to the distribution networks.