NL1001184C1 - Expandable constructional component with chambers enclosed by folding material - Google Patents

Abstract

The expandable chambers are separated by transverse rigid partitions (2). The shield formed extends in a line in the folded state. The partitions can be joined together by guides extending in the expansion direction, and the folding material can be flexible, or formed by plates hinging together. Each partition can consist of an open frame joined to the folding material. Expansion can be by gas or air, or the generation of electro-magnetic forces thrusting the partitions apart.

Description

EXPANDABLE BUILDING ELEMENT

The invention relates to an expandable building element, comprising a number of expandable chambers which are mutually separated by substantially parallel, rigid transverse partitions, each of which is otherwise enclosed (at least partly foldable material) (the skin), and means for expanding in this case quo contracting the chambers.

In the expanded state, the building element extends along a plane of a certain thickness (the distance of the skin layers of the building element in the expanded state), the shape of which is determined by the transverse partitions. When folded, it forms a line-shaped package of the abutting transverse partitions, with or without parts of the folded skin between them. The boundary 15 of the plane consists of lines, one of which is the line along which the bulkheads join when folded. The other boundary lines are freely selectable from straight or curved lines.

The building element can also consist of an assembly of such surfaces.

The construction element is rigid and stable in both closed and fully or partially open condition.

Such a building element offers great design freedom for movable (parts of) walls, doors, ceilings, roofs, for roofs, bottom covers and interior or exterior sun protection, as part of a building or as an independent structure.

Such a building element as an expandable screen is known from US-A-4255 908.

This known screen, even in the fully inflated state, has little rigidity, so that it is only suitable for use in vertical planes. In addition, this prior art screen requires a retractor for rolling up the deflated screen.

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Such a winding-up device takes up a relatively large amount of space, so that the window covered with the prior art screen is not completely free in the unrolled state, while such a winding-up mechanism can also easily become defective and become dirty.

The object of the present invention is to provide such a screen, wherein the drawbacks of a winding device are avoided, and which can also be used with non-vertical surfaces, such as horizontal and oblique surfaces. Therefore, in addition to being a screen, it can also be used in the other applications indicated above.

These objectives are achieved in that the transverse partitions are rigid, and they extend substantially perpendicular to the direction of expansion. As a result of this measure, the screen in the expanded state has a high transverse stiffness, so that it can easily be used in non-vertical planes. Furthermore, due to the rigidity of the transverse bulkheads, such a screen can be easily collapsed, so that a rolling-up device is unnecessary.

According to a preferred embodiment, the transverse partitions are connected to guide means extending in the direction of expansion. These guide means extending in the direction of expansion provide rigidity to the building element in the direction of expansion of the building element. As a result, the building element becomes self-supporting, so that no intermediate supports are required and a large space can be covered and spanned.

The invention will be elucidated hereinbelow with reference to the annexed drawings, in which: figure 1 shows a schematic perspective sketch of a rectangular building element according to the invention; Figure 2: as figure 1, but now as an assembly of two control surfaces, each of which has the shape of a hyperbolic paraboloid (hyppar shell) according to the invention, 10 01 1 3 figure 3: a schematic perspective sketch of a rectangular building element according to the invention in the form of a control surface deployed along curved guide devices to form a unidirectional curved building element; figure 4: as figure 3 with use of curved transverse partitions and straight guiding devices, whereby also a unidirectional curved building element is formed; Figure 5: as figure 3 with both curved transverse bulkheads and curved guide devices, whereby a two-way curved building element (dome) is formed; figure 6 is a cross-sectional view of such a building element, wherein the skin conforms to the outside when collapsed; figure 7: as figure 6, but now with the skin joining inward when folded; figure 8 is a sketch top plan view of a flat, quadrilateral expandable building element showing two possible opening and closing sequences; figure 9 is a schematic perspective view of an expandable building element for the movable covering of a large space, for instance a sports stadium; figure 10: a partly broken away schematic perspective view of an expandable building element for the movable covering of grounds, for instance sports fields; figure 11: a partly broken away perspective view of an expandable building element for non-vertical, for instance horizontal application; figure 12 is a partly broken away perspective view of an expandable building element for vertical application; figure 13: a partly broken away view of an expandable building element according to an embodiment deviating from the two previous figures, figure 14: a view of a mainly circular 1001184.

4 -shaped embodiment of a building element according to the invention; figure 15: a partly broken away perspective view of a greenhouse provided with expandable screens according to the present invention; figure 16: a partly broken away perspective view of a screen according to the invention arranged between both plates of a double-glazed window ; figure 17 is a perspective broken away detail view of a valve system to be arranged in a building element according to the invention; figure 18: a partly broken away perspective detail view of another embodiment of a building element according to the invention; Figure 19: a cross-sectional view of a building element according to the invention, wherein means are provided for compressing the building element; figure 20 is a perspective detail view of the means shown in figure 19; Figure 21: a cross-sectional view of a building element according to the invention, wherein other means are provided for compressing the building element; figure 22: a perspective bottom view of a building element according to the invention in the application as a sunshade; figure 23: a building element according to the present invention, wherein the guiding means are not longitudinal; and figure 24: a schematic view of a space, the ceiling of which is covered with arbitrarily shaped screens according to the invention.

The examples shown in figure 1 to figure 5 show that building elements made according to the invention offer an almost unlimited design freedom with regard to the shape of the surface covered by the building element.

Figures 6 and 7 show the two possibilities with which the skin (3 and 4) can fold up when the construction element is joined (closing), namely outside the transverse bulkheads 2 or in between. Situation A is completely open, B is partly open and C is completely closed.

Figure 8 shows two deployment regimes according to the invention: by choosing the deployment sequence in a partially opened (closed) state, the covered area is either determined by the right, or in this case the left circumference lines.

Figure 9 shows the application of the expandable building element as a movable roof 1 of a sports stadium in a partially opened condition. In this example 46 is the permanent roof of the stands.

Figure 10 shows the movable cover of a sports field. Here, wheels 47 are mounted on the underside of the transverse bulkheads, which cause the building element to roll over the ground upon expansion. When folded, the building element is stored in a storage space 48.

20 Following these general application examples, explanations of the operation and parts of the display will now follow.

The inflated expandable building element 1 shown in Figure 11 is formed by a series of mostly parallel transverse bulkheads 2 made of rigid material, which are interconnected at their bottom and top sides, respectively, by pleated material made of foldable material top and bottom walls 3.4.

The sides of the respective transverse bulkheads 2 are mutually connected by pleated folded side walls 5 also made of foldable material. Both side walls 5 are gastightly connected to the top wall 3 and the bottom wall 4, respectively, so that the building element 35 is formed by a number of chambers 6 which are mutually separated by the transverse partitions 2, and which are incidentally enclosed by the top wall 3, the bottom wall 4 10 01 1 84.

6 and the two side walls 5 (the skin). A number of chambers 6 are thus obtained. The first chamber 6 is bounded at its front side by a base wall 7, which can for instance be fixedly connected to a frame or other constructive part of a building, in which the building element according to the invention is applied.

Provided in the base wall 7 is a supply channel 8 which is used for supplying gas, for example compressed air to the first chamber 6. When gas 10 is supplied under pressure, for example compressed air to the first chamber 6, it will expand, whereby the foldable material is will fold. This process will continue until the first chamber 6 is fully expanded.

In order to also expand the other 15 chambers, separating transverse partitions 8 are provided in the respective chambers 6, with which the chambers 6 are connected to each other. Thus, when sufficient compressed air is supplied to the first chamber 6, this compressed air will pass through the relevant openings in the transverse partitions 2 and cause the other chambers to expand, until the maximum expansion is obtained.

In the reverse situation, when the relevant chambers are emptied, these will only be compressed, so that the building element is transferred to its minimum, compressed state. In this case, the air line 8 functions as a discharge line.

Although the rigidity of the transverse bulkheads 2 gives a certain rigidity in the respective direction, both of the building element in the inflated state, in the collapsed state, and in intermediate states, the stiffness of the building element is in the other direction low, and even in the inflated state, is not sufficient for a wide variety of applications.

According to a preferred embodiment, the present invention provides for this by arranging guide means for guiding the building element in the construction.

7 expansion direction.

In the embodiment shown in figure 11, these guide means are formed by two rods 9 extending in the relevant direction and brackets 10 attached to each of the transverse bulkheads 2 and wrapped around the rods 9. A sufficient stiffness is thus also obtained in the expansion direction, these guide means also allowing the movement of the transverse partitions in the expansion direction.

Compressed air is used as the expansion medium in the relevant exemplary embodiment. It is of course possible to use other principles for driving the expandable building element. For example, it is possible to make use of static electricity, whereby a voltage of the same name can be connected to each of the transverse bulkheads 2 when the building elements expand. Of course, the transverse partitions 2 must then be made of conductive material or be provided with a layer of conductive material.

When each of the transverse bulkheads is charged with a positive voltage, the respective walls will repel each other, resulting in expansion. In order to recompress a relevant device, the transverse partitions must be supplied alternately with a positive * and a negative voltage, so that the relevant transverse partitions will attract each other and a compression is obtained.

Instead of this electrostatic drive, it is of course possible to use other forms of drive, for instance a magnetic one. The transverse partitions will have to be provided with coils.

The embodiment shown in Figure 12 differs from the embodiment 35 shown in Figure 11 only in that the embodiment shown in Figure 12 is suitable for vertical application. This is reflected in the other form of the guide means.

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In the embodiment shown in Figure 12, the guiding means are formed by rods 11 attached to the transverse partitions 2 and provided with a head 12 at their end.

Profiles 13 extending in the direction of expansion are further arranged which have such a shape that the heads 12 can move slidably into the interior of the profile 13, thereby taking the rods 11 with them. Otherwise, this embodiment corresponds to the embodiment shown in figure.

In the embodiment of the building element according to the invention shown in figure 13, use is made of rigid plates 14, with which the walls 3 and 4 are coated.

This gives a different appearance and different functional properties of the building element; the respective rigid plates can be made of plastic or, for example, aluminum, and they can be decorated. For example, it is possible, for example when used as sun protection, to make the plates of the building element located on the sunny side reflective, for example as plates of aluminum foil. When the plates have sufficient rigidity, a greater stiffness of the building element is obtained, both in collapsed, partially expanded, and in fully expanded situation.

Furthermore, in this embodiment, the walls 3 and 4 delimiting a single chamber also extend along both transverse partitions 2 delimiting the respective chamber. Thus, a closed coating is obtained which can easily be made gas-tight when using compressed air as an expansion agent.

The embodiment shown in figure 14 illustrates the possibilities of designing the building element according to the invention. By using one of the building elements according to the embodiments of the preceding figures and by connecting the respective transverse walls 2 on one side to each other, the configuration shown in figure 14 is obtained. The shape of the guide means must of course be adapted; for instance, instead of a straight rod 9, use is made of a curved rod 15. In this embodiment it is of course also possible to use a circular sector shape or, by connecting only a part of the transverse partitions 2 on one side. , to obtain a shape that is partly rectangular and partly formed by a circle sector.

Figure 15 shows a building 15, for example a house, which is provided with a conservatory 16. The ceiling 17 of the conservatory 16 is formed by a glass plate 18, on the underside of which rods 9 are arranged which extend between the frame 19, which secures the conservatory to the building, and the actual frame 20 of the conservatory. A screen is arranged on these rods 9 in the manner of the embodiment of the invention shown in Figure 11. It will be clear that the base 20 wall 7 of this screen is attached to the side of the frame 19. The shape of the screen is adapted to the shape of the conservatory, which is only possible with a construction according to the invention. However, it is also possible to arrange the screen on the outside, that is to say above the ceiling 17 of the greenhouse.

The side walls 21 of the greenhouse which, as appears from the drawing, are partly circular, are provided with a screen construction corresponding to the embodiment shown in figure 12.

Thus, it appears from this exemplary embodiment that it is possible to make the screen according to the invention curved and to adapt its shape to the circumstances.

Figure 16 shows an application of the embodiment shown in Figure 13 in a double-glazed window. The screen 1 according to the invention is herein arranged between an outer glass plate 22 and a 10 01 1 84.

Inner glass sheet 23. For the rest, this embodiment corresponds to the embodiment shown in figure 13 with the proviso that this embodiment is provided with a light-sensitive operating mechanism. This mechanism is provided with a motor 24, a photosensitive cell 25 and a check valve 26. From the check valve 26, an air pipe 8 leads to the interior of the screen, while the space between the two glass plates 22, 23 with a pipe 27 with the pump 26 is connected. The operation of this device is as follows.

When the screen is in the closed state and sunlight falls on the cell 25, energy will be supplied to the motor 24, whereby the pump 26 will operate and air will be supplied to the interior of the screen via the conduit 8. This will cause the screen to expand. In the reverse situation, when the amount of light falling on the cell 25 exceeds the limit value, the pump will start operating in the reverse direction and will draw air from the interior of the screen 1 20 and supply it to the room through line 27 between both glass plates.

Figure 17 shows a detail of a building element according to the invention. In this construction element, the transverse partitions 2 are each provided with additional openings 28 which can be closed by means of a resilient flap 29. The resilience of these flaps 29 is such that they close the openings 28 in a normal situation. When the building element is expanded, the air from the first chamber to the second chamber 6 and from there to the following chambers 6 is passed through openings not shown in the drawing, which are located elsewhere in the transverse partitions 2. Generally, in such an operation, the openings 28 will be closed.

In order to prevent, when the building elements are being contracted, for example, one of the intermediate chambers 6 closes before the chambers on the opposite side of the supply side are completely emptied, and the further 10.

11 when the system becomes impossible to contract, the openings 28 are provided which ensure that, even when the building elements 2 touch, gas discharge is possible by means of the resilient flaps 29.

In a preferred embodiment shown in Figure 18, adhesives such as Velcro strips, mechanical joints, or, for example, permanent magnets, adhere rigidly to the transverse bulkheads when the screen is collapsed, so that the folded package is rigid and of minimum thickness .

In combination with blown-in air as an expansion medium, the two opening and closing regimes shown earlier in Figure 8 can be realized.

In the first regime, the chambers open in the order from the blow-in opening. When compressed air is introduced, the chamber adjacent to the air inlet 8 first opens. As long as this chamber does not expand, the supply of air to the following chambers is not possible because the staggered holes are blocked by the adjacent transverse partitions. If the air pressure in the first chamber exceeds the adhesive force, the chamber will burst open and inflate completely. This releases the staggered openings in the bulkhead separating the first two chambers, allowing air to flow into the second chamber. In this way all chambers open successively in the order from the blow-in opening. This continues until the desired part of the screen is opened.

When the screen is closed, air is sucked away, which creates negative pressure in the screen. All 30 internal transverse bulkheads remain in balance. The first and last shots, however, get extra pressure, in the closing direction. Since the last chamber closes more easily than the first due to the friction of the transverse partitions over the guide structure, the last chamber will close the first, then the next to last and so on.

In the second regime, the room 1001184 opens first.

12 is furthest from the blow-in opening, and so on. In this regime, there are also central openings in the transverse bulkheads in addition to the staggered holes. These have collars that prevent air from escaping laterally when the 5 cross dividers are on top of each other. Only in the last room is this collar missing. Now, when inflated, the air is passed through the central openings without resistance to the last chamber, which will therefore open first. When it has been blown up, air 10 will flow back through the staggered holes into the next to last chamber, which will then unfold, etc.

Closing can be done in the same order under the second regime as in the first.

However, it is also possible to opt for closure in the reverse order, namely by connecting the last bulkhead to the guide construction in a slightly inhibiting manner. Therefore, the chamber closest to the gas supply will close first, then the adjacent and so on.

Figures 19 and 20 show another construction 20 with which, when contracting, it is only possible for air to be sucked away from the chamber furthest from the supply side.

For this purpose, the transverse partitions 2 are provided with openings 33, while no other openings are otherwise provided in the transverse partitions 2. Hinges 35 are pivotably mounted in the openings 33 by means of a shaft 34, which levers are kept in their unfolded position as much as possible by means of a spring 36.

This construction ensures that only 30 air is pumped out of the chamber 6 furthest from the supply side. To this end, the levers are provided with a piece 37 which, when the chamber 6 in which the lever 37 is located, causes the entire lever 35 to fold inwards to the closed position, after which it is possible to empty the next chamber. . The relevant part 37 of the lever is only actuated when the relevant chamber 6 is almost completely closed.

The construction shown in figure 21 also has such an effect; the spouts 41 with a substantially conical shape ensure that it is always possible to extract gas from chambers that are not completely compressed. Furthermore, in this embodiment, separate gas supply openings 42 are provided, which are each in line with a supply channel 43. The spouts 41 are incidentally all in line with a discharge channel 44.

It will be clear, however, that other constructions are also conceivable for achieving the relevant opening and closing regime.

Figure 22 shows how a building element 1 according to the present invention can be used as a flat sunshade. The guiding means are formed in the form of substantially horizontally extending supports 38 which are provided with a construction, as shown in figure 11 or in figure 12.

Figure 23 shows how the guide means can also be bent in a manner somewhat similar to the construction shown in Figure 15.

Figure 24 finally shows how a ceiling 38 of a building 39 is covered with randomly shaped surfaces 40, each of which can be covered by a screen according to the present invention.

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Claims (20)

Expandable building element, comprising: - a number of expandable chambers which are mutually separated by substantially parallel transverse partitions, and which are otherwise enclosed by at least partly foldable material; and - means for expanding the chambers, characterized in that the transverse partitions are rigid, that they extend substantially perpendicular to the direction of expansion, and that the screen extends along a line when folded. Expandable building element according to claim 1, characterized in that the transverse partitions are connected to guide means extending in the direction of expansion. Expandable building element according to claim 1 or 2, characterized in that the foldable material is flexible. Expandable building element according to claim 1 or 2, characterized in that the foldable material is at least partly formed by mutually hingedly connected plates. Expandable building element according to any one of claims 1-4, characterized in that the transverse partitions are each formed by a substantially open frame connected to the folding material. Expandable building element according to any one of claims 1 to 5, characterized in that the means for expanding the chambers are formed by means for generating the transverse bulkheads repelling electromagnetic forces. Expandable building element according to any one of claims 1 to 5, characterized in that the means for expanding the chambers are formed by a gas supply member connected to the chambers, for example an air pump, and in that the chambers are substantially gastight. 10 01 1 84. Expandable building element according to claim 7, characterized in that the gas supply member is connected to each of the chambers separately. Expandable building element according to claim 7, characterized in that the gas supply member is connected to one of the chambers, and that the chambers are each connected to their two neighboring chambers. Expandable building element according to claim 9, characterized by means for expanding the chambers successively from the gas supply member. Expandable building element according to claim 10, characterized in that the means for interconnecting the chambers are arranged to open only when the pressure in the chamber located on the supply side exceeds a certain value. Expandable building element according to claim 9, 10 or 11, characterized in that at least one opening is arranged in each of the walls, the openings being arranged in a zigzag staggered manner in adjacent walls. Expandable building element according to claims 10 and 11, characterized by means, for example permanent magnets, Velcro or mechanically clamping connections, for pressing the partitions against each other with a limited force. Expandable building element according to claim 9, characterized by means for successively expanding the chambers to the gas supply member. Expandable building element according to any one of claims 9-14, characterized by means for closing the openings arranged in the walls when the chamber facing away from the supply side is closed. Expandable building element according to any one of claims 9-15, characterized by means for maintaining a minimum distance between two adjacent walls, until the chamber opposite the supply side, adjoining the respective wall, is closed. Expandable building element according to any one of the 10 01 1 84. Claims 14-16, characterized in that openings are arranged in the transverse partitions which lie one on the other when the transverse partitions are folded together. Expandable building element according to claim 17, characterized in that at least a part of the transverse partitions are provided with collars surrounding the openings and which extend substantially transversely of the partitions. Expandable building element according to any one of claims 7-18, characterized in that the extreme chamber opposite the supply side is provided with controllable valves connecting the chamber to the environment. Expandable building element according to claim 19, characterized in that at least one opening is made in each of the walls, the openings each coinciding with the projection of the controllable valve on the walls. 10 01 1 84.