FR2770864A1 - Shutter roof structure - Google Patents

Abstract

The roof structure comprises a flat ceiling shutter (18) and a convex roof shutter (20) placed above the former to form the building roof. Each shutter is formed from a sheet impermeable to gas and fixed in the upper edge part of the main body. The roof shutter is supported by convex supports forming a closed space between them and the ceiling shutter. The pressure inside the closed space is maintained at a negative or positive value relative to the external atmospheric pressure. Frame bars (50) filled with air are arranged in the internal surface of the roof shutter.

Description

 The present invention relates to a curtain roof structure and, in particular, to a curtain roof structure comprising a ceiling curtain which forms the ceiling of a building and a roof curtain which forms the roof of the building.

 In a usual Japanese house, the roof is a "tiled roof" formed by tiles which are placed on a support structure which is inclined, and the ceiling is formed by panels which are placed on a number of support crosspieces .

 In a building such as a gymnasium which must have a large floor area without an intermediate pillar, the roof and the ceiling must have special support structures other than those of a normal dwelling.

 A house with a tiled roof, however, poses problems because it is not anti-seismic since the tiles are heavy, and the construction cost is very high because the formation of the roof with tiles and the formation of support sleepers constitute a job. long term. A building with a large floor area, such as a gymnasium, also poses problems in that it is not earthquake-proof and the construction cost is too high since it requires a very complicated support structure for the roof. or the ceiling.

 In view of the aforementioned problems, the invention has been carried out and its object is the formation of a curtain roof structure which is simple and easy to produce, which is anti-seismic, and which also allows cost reduction.

 The invention relates to a curtain roof structure in which the roof of a building can be formed by a simple and light structure and the structure is anti-seismic and can be easily produced so that the construction cost is reduced and, moreover, the framework bars support the roof curtain from the inside so that the configuration of the roof can keep its properties of aesthetics and stability.

 In one embodiment, the atmospheric pressure inside the curtain roof structure remains constantly negative and the framework bars remain constantly full of air so that the configuration of the roof can constantly keep its aesthetic properties and stability.

 In one embodiment, the atmospheric pressure in the curtain roof structure remains constantly positive and the framework bars remain constantly filled with air so that the configuration of the roof can constantly keep its aesthetic and stability properties.

 In one embodiment, the external appearance of the structure of the curtain roof is excellent since the support members cannot be observed from the outside.

 In one embodiment, there is no need to mount the frame bars to the inner surface of the roof curtain and the frame bars never separate from the roof curtain.

Other characteristics and advantages of the invention will be better understood on reading the description which will follow of exemplary embodiments, made with reference to the appended drawings in which
Figure 1 is a perspective view of a building having a curtain roof structure according to the present invention
Figure 2 is a front elevational view showing the body of the building
Figure 3 is a plan view of a building
Figure 4 is a side elevational view of a building body
Figure 5 is a developed view of a ceiling curtain
Figure 6 is an exploded developed view of a roof curtain
Figure 7 is a perspective view of an example of a frame bar
Figure 8 is a sectional view of an example of a frame bar
Figure 9 is a diagram showing an example for the description of the mounting of a frame bar
Figures 10 (A) and 10 (B) are perspective views showing a structure of a discharge or supply device
Figure 11 is a schematic perspective view illustrating the mounting of a ceiling curtain
Figure 12 is a schematic perspective view of the mounting of a roof curtain
Figure 13 is a section through a connection part of a ceiling curtain and a roof curtain
Figure 14 is a side elevational view of traction devices, essentially showing the right and left support members
Figure 15 is a perspective view showing the work of a curtain roof structure when the atmospheric pressure in an enclosed space is in depression
Figure 16 is a schematic perspective view showing the work of a curtain roof structure when the pressure in the closed space is maintained positive
Figure 17 is a schematic perspective view showing a discharge device connected to a frame bar
Figure 18 is a schematic view showing a supply device connected to a frame bar
FIG. 19 is a perspective view of another example of a building having a curtain roof structure according to the present invention
Figure 20 is a front elevational view of a building body of Figure 19; and
Figure 21 is a front elevational view of another example of a building body.

 Reference is made to the drawings for the description of examples of a structure with a curtain roof according to the present invention.

 FIG. 1 is a perspective view of an example of a building 2 having a curtain roof structure 1 according to the present invention.

 A main body 2A of building 2 is essentially formed of steel chassis. Figure 2 is a front elevational view of the main body 2A, Figure 3 a plan view and Figure 4 a side elevational view of the body 2A.

 The dimension of the body 2A is however not limited, and side walls 18 m wide and front and rear walls 54 m wide can be used.

 The body 2A which has doors 3 and windows 4 at desired locations is surrounded by a wall 5 reinforced by cross members 6 diagonally and which is formed on foundations 7.

 As shown in Figure 3, an armature member 8 is mounted at each of the corners of the body 2A but no beam is provided with the ceiling. Although a reinforcing beam 10 can be arranged as shown in phantom in FIG. 3, where appropriate from the point of view of mechanical strength, it is advantageous not to have a reinforcing beam, when the body 2A of the building has sufficient strength, so that a ceiling curtain 18, described below, has an excellent aesthetic appearance.

 A support gutter 12 which opens upwards is mounted on the external surface of a beam 11 at the upper circumference of the body 2A by welding or bolting as shown in FIG. 11.

 A number of rods 13 of bolts protrude from the support gutter 12, and these rods are separated by the distance necessary for the support of a ceiling curtain 18 and a roof curtain 20 as described below. The vertical surface 12A of the gutter 12, of which the rods 13 of bolts protrude, is smooth and coated beforehand with a fastening material. The gutter 12 is integral with the beam 11 and the rods 13 of bolts can protrude therefrom. Evacuation tubes (not shown) are arranged in a suitable position relative to the gutter 12.

 In the center of each of the side walls 14 of the body 2A, as indicated in FIGS. 1 to 4, a support tube 15 extends over a significant height beyond the body 2A and is fixed permanently to a member 16 of frame. The support tubes 15 are intended to fix a tension cord 26 in tensioned form so that, as shown in FIG. 14, the upper end of each support tube has a roller 15A mounted on a shaft, the lower end extending towards the middle of the height of the side wall 14 of the body 2A or near this middle for the formation of a device for pulling the tension cord 26.

 The ceiling of the body 2A is formed by a flat ceiling curtain 18 and a roof curtain 20 intended to form the roof of the building is placed above the ceiling curtain 18.

 Figure 5 is a plan view of the ceiling curtain 18 formed by a sheet member of dimension such that it covers the ceiling with a margin 18A of connection to its outer circumference.

 The connection margin 18A has a double structure formed by folding the circumference of the sheet member so that the mechanical resistance is increased, and a number of holes 19 are formed for the introduction of the rods 13 of gutter bolts. 12, in the connection margin 18A, the holes being separated by a distance equal to that which separates the rods 13 from bolts.

 FIG. 6 is a developed view of the roof curtain 20 intended to form an attic roof on gables, representing a sheet material cut in the form of a front member 21, a rear member 22, a straight member 23 and a left organ 24.

 The sheet-shaped members 21, 23 and 24 have margins 21A, 23A and 24A respectively intended to be sewn on the designated sides and a number of holes 25 for the introduction of the rods 13 of the gutter 12 are arranged with connection margins 21B, 22B, 23B and 24B of the members 21, 22, 23 and 24 and are separated by a distance equal to that which separates the rods 13. The connection margins 21B, 22B, 23B and 24B respectively have a double structure formed by folding the sheet organs so that their mechanical resistance is increased.

 After the corresponding sides of the sheet-like members have been placed on top of each other, the margins 21A, 23A and 24A are sewn together to form a roof curtain 20.

 The tension cord 26 is placed at the edge 20A of the front member 21 and of the rear member 22, intended to be sewn with the sheet-shaped members.

 The ceiling curtain 18 and the roof curtain 20 are formed from a gas-impermeable sheet material which does not allow the passage of air, and a sheet of a laminated resin can advantageously be used as sheet material. multilayer, a treated fabric sheet coated with rubber or resin, etc. The sewn parts of the roof curtain 20 are coated with rubber or a resin which does not allow the passage of air.

 FIG. 7 is a perspective view of a framework bar 50 fixed inside the roof curtain 20 at a desired location, and FIG. 8 is a section of the framework bar 50.

 The framework bar 50 comprises an elongated tubular member made of a gas-impermeable material, for example a sheet of rubber or of a multilayer laminate resin and a sheet of treated fabric coated with rubber or a resin, and it is filled with air.

 The air is charged and discharged by an inlet 51 having a tap 52 which regulates the air introduced inside the bar 50 and evacuated from it and which seals this bar 50 in a sealed manner.

 The frame bars 50 are mounted on the internal surface of the roof curtain 20 so that each of the frame bars 50 flexes in the center, forming an inverted "V" intended to be fixed to the lateral sides of each of the straight members 23 and left 24 by sewing, fixing by gluing, etc. FIG. 9 shows an example of attachment of one of the framework bars 50 to the straight member 23 by sewing the straight member 23 with a wire 53 which forms loops and by passing the bar 50 through the loops , but the fixing method cannot always be limited to the example shown.

 When mounting the framework bars 50 on the internal surface of the roof curtain 20, the bars 50 can be mounted on the lateral edges of the front 21 and rear members 22 or can be mounted inside the roof curtain 20 produced by sewing leaf-shaped organs.

 It is advantageous to form tubular parts at the edges of the sheet-shaped members of the roof curtain 20 by folding the edges of the sheet-shaped members, for the construction of the framework bars 50 which are filled with air.

 Thus, the frame bars 50 are integral with the roof curtain 20 and not separated from it, and it is therefore no longer necessary to mount these bars 50 to the internal face of the curtain 20 and the bars 50 can no longer separate from the roof curtain 20.

 The sheet-shaped members in which the tubular parts constituting the bars 50 of the edges are formed can be the front member 21, the rear member 22, the right member 24 and the left member 24.

 One of the lateral members, for example the left member 24 of FIG. 6, has an opening 27 in which is mounted a fan 30 shown in FIG. 10.

 The fan 30 is used as an air evacuation device from the closed space formed between the roof curtain and the ceiling curtain, towards the exterior of the building, or in the form of a supply device which charges the outside air in the closed space.

 As indicated in FIGS. 10 (A) and 10 (B), the fan 30 comprises a motor M fixed to support members 32 in an air hole 31A, formed in a support plate 31, and a movable blade 33 mounted on the axis of the motor M.

A cylinder 34 surrounding the moving blade 33 is fixed in the hole 31A for air circulation. The blade 33 is driven at high speed by the motor M for the introduction or extraction of air via the cylinder 34.

 The fan 30 in which the cylinder 34 is mounted on the plate 31 is sewn, by using holes 31B for sewing the plate 31 so that the plate 31 is located inside the left member 24 and the cylinder 34 protrudes outside the opening 27, and the sewn pad is coated with rubber or a resin preventing the passage of air.

 When the part intended to form the ceiling of the body 2A is covered with the ceiling curtain 18 as shown in FIG. 11, the connection margin 18A is drawn inwards towards the gutter 12 and the rods 13 of the gutter 12 penetrate deeply in the holes 19 of the margin 18A for fixing the ceiling curtain 18 to the body 2A.

 An elongated plate 36 impermeable to gas and forming a cushion is mounted on the rods 13 of the gutter 12.

As shown in FIG. 12, the plate 36 is an elongated member having holes 36A separated by a distance equal to that which separates the rods 13 so that a closed space is produced by mounting and tightening the margin 18A for connecting the curtain 18 and the margins 21B, 22B, 23B and 24B for connecting the roof curtain 20 to the rods 13.

 The roof curtain 20, produced in a roof configuration whose frame bars 50 are fixed to the internal surface, is placed above the ceiling curtain 18, the front member 21 being directed towards the front of the body main and the tension cord 26 placed to the right of the roof curtain joins the support tube 15 to the right of the body 2A by means of a roller 15A and is pulled outside the tube to be kept temporarily stretched.

 The connection margins 21B, 22B, 23B and 24B of the roof curtain 20 are pulled inwards towards the gutter 12 and the rods 13 of bolts are successively introduced into the holes 25 of the margins 21B, 22B, 23B and 24B. After the rods 13 have been introduced into all the holes 25 as shown in Figure 13, a nut 39 is placed on each bolt rod 13 for fixing the circumference of the roof curtain 20 tightly.

 The temporarily maintained tension cord is then firmly fixed so that, as shown in FIG. 14, a mass 41 is fixed to one end of the cord 26 or that a tension spring is placed between a fixing device 42 and the cord 26 so that the configuration of the roof curtain 20 is retained. The cord 26 can be fixed so that it is stationary, but it is preferable that the cord 26 is removably fixed as shown in Figure 14 so that it can be flexibly adjusted when the temperature or atmospheric pressure varies .

Thus, an attic space S between the curtains 18 and 20, when the cord 26 is tightly stretched, is closed apart from the presence of the hole 31A for air circulation of the fan 30.

In the state indicated above, the pressure in the attic space S becomes negative (low) relative to the external atmospheric pressure when the motor M of the fan 30 is supplied so that the blade 33 evacuates the air from the space S of the attic so that, as shown in Figure 15, the ceiling curtain 18 is pulled up relative to the body 2A and the roof curtain 20 remains taut. When the blade 33 moves to transmit the outside air to the attic space S, the pressure in the space
S becomes positive (high) relative to the external atmospheric pressure so that, as indicated in FIG. 16, the curtains 18 and 20 are pulled outwards and the roof curtain 20 is kept in the stretched state.

 Thus, the roof curtain 20 can have an excellent external appearance without creases and the configuration varies very little when the pressure in the space S varies since the framework bars 50 which are filled with air are fixed to the internal surface of the roof curtain 20 and, in addition, the curtain roof structure is earthquake-resistant since the entire roof is light.

 According to the invention, the air evacuated from the attic space S can be transmitted to the rebar 50. As shown in FIG. 17, the valve 52 of the inlet 51 of one of the bars frame 50 protrudes from the roof curtain 20 (from the left member 24 as shown for example) so that it is connected to an opening end of the cylinder 34 by a flexible connection tube 6. In this connection, the border existing between the valve 52 and the curtain 20 must be coated with a resin or the like so that the attic space S is properly closed. Another frame bar 50 placed on the right can be filled with air by mounting a fan on the right member 23 in the same manner as in FIG. 17, or by connecting the right and left frame bars 50 by a flexible tube in the attic space S. Part of the air evacuated from space S, but not all, can be transmitted to the framework bars 50.

 In the state in which each tap 52 of the framework bars 50 is connected to the cylinder 34 of the fan 30 or each cylinder 34 of the fan 30, the pressure in the space S is constantly maintained at a negative value, the bars 50 being constantly filled with air by driving the fan 30 as an exhaust fan which transmits the air evacuated from the space S to the bars 50. Consequently, the configuration of the roof curtain 20 can always remain excellent.

 According to the invention, the fan 30 can be used as a supply fan which transmits part of the air coming from the outside to the space S and also in the bars 50. As shown in FIG. 18, the cylinder 35 mounted as a bypass is placed inside with respect to the air circulation hole 31A and the flexible tube 6 connects a bypass 35A of the cylinder 35 to the valve 52 of the bar 50. In this case, the valve 52 of the bar 50 is placed inside the space S so that the bypass 35A and the valve 52 are connected inside the space S.

Another framework bar 50 can be filled with air by mounting a fan on the other side sheet member in the same manner as in FIG. 18 or by connecting the right and left bars 50 by a flexible tube. air circulation placed in the attic space S.

 In the state in which each tap 52 of the bars 50 is connected to the branch 35A of the fan 30 or to each branch 35A of the fan 30, the pressure in the space S remains constantly positive and the bars 50 are constantly filled with air by driving the fan 30 as an outside air supply fan transmitted to the attic space S as well as to the frame bars 50. Consequently, the configuration of the roof curtain 20 can always remain excellent.

 According to the present invention, the support tubes 15 can advantageously be placed inside the attic space S as indicated in FIG. 19. As indicated in FIG. 20, the support tubes 15 are then rigidly mounted on the beam 11 or the gutter 12 and not on the side walls 14, by welding or bolting.

When the roof curtain 20 is mounted so that it covers the support tubes 15, the fan 30 is driven so that the tension cord 26 is superfluous since the roof curtain 20 can be supported by the upper part of each tube support 15, but it is advantageous to place a bead 70 between the right and left support tubes 15 with a determined clearance as shown in Figure 21, so that the configuration of the upper part of the curtain roof is preserved.

 The fan 30 is preferably constantly driven, but it can be stopped after being driven for a while or it can be driven intermittently.

 Although the main body 2A has the shape of a parallelepiped in the embodiments shown, the invention can be adapted to any configuration of body 2A such as a rectangular parallelepiped, a cylinder, etc. without any restrictions, and it can take any form of curtain roof which is suitable for the flow of rain, for example a triangular shape, a hemispherical shape, a semi-cylindrical shape, etc.

 Any device can be used to delimit a closed space by mounting the margins for connection of the ceiling curtain 20 to the roof curtain 18 on the main body 2A, in addition to the device described in this specification, without any restriction.

 The mounting position of the fan 30 is not limited to that shown since it can be mounted in any position, for example in the form of the front member 21 or the rear member 22.

 In the curtain roof structure according to the invention, the roof and the ceiling are formed of a sheet material so that the structure is simple to produce easily with reduction in cost, and it is earthquake resistant, and the curtain roof can be adopted for many types of buildings with a large floor space, such as gymnasiums and exhibition halls.

 Of course, various modifications can be made by those skilled in the art to the structures which have just been described solely by way of non-limiting example without departing from the scope of the invention.

In particular, the evacuation and supply devices, instead of being mounted on the roof curtain (20), can be mounted on the ceiling curtain (18).

In addition, the roof curtain (20) placed above the ceiling curtain (18) can be in a convex form when it is supported by the support members for the formation of a closed space.

Claims (5)

 1. Curtain roof structure, comprising a flat ceiling curtain (18) intended to form a ceiling of a building (2) and a convex curtain (20) of roof placed above the ceiling curtain for the formation of the building roof, characterized in that  each ceiling and roof curtain is formed of a gas-impermeable sheet material and attached to the upper edge portion of the main body (2A) of the building at each circumference,  the roof curtain is supported by support members in a convex form for the formation of a closed space between the roof curtain and the ceiling curtain,  the pressure inside the closed space is maintained at a negative or positive value with respect to the external atmospheric pressure, and  framework bars (50) filled with air are arranged on the internal surface of the roof curtain in the necessary positions.  2. Structure according to claim 1, characterized in that an exhaust device is mounted on the ceiling curtain or the roof curtain for the evacuation of air from the closed space, and the evacuated air is transmitted to the frame bars.  3. Structure according to claim 1, characterized in that a supply device is mounted on the ceiling or roof curtain for the transmission of outside air to the closed space, and part of the transmitted air is loaded into the frame bars.  4. Structure according to any one of the preceding claims, characterized in that the support members are placed inside the closed space.  5. Structure according to any one of the preceding claims, characterized in that each of the framework bars has a tubular part formed by folding an edge of the sheet-like members of the roof curtain.