ES2383971B1 - SYSTEM OF CONSTRUCTION OF DUCTS AND OTHER HOLLOW STRUCTURES. - Google Patents

Abstract

Duct construction system and other hollow structures comprising a device (11) formed by a first outer membrane (7) and a second inner membrane (8), joined at least by a connector (5), between which a filling chamber (19), counting the outer membrane (7) with at least one access or nozzle (20) through which at least one self-hardening mass (2) and another access or nozzle (20) are introduced into the hollow chamber (3) for the gaseous flow that generates an internal pressure, maintaining the entire system the precise geometry of the device (11). # It is also characterized in that the system includes fixing means and seat of the device (11) with respect to a support ( 1) on which it is installed.

Description

Duct construction system and other hollow structures.

Object of the invention

The object of the present invention is a duct construction system and other hollow structures. Said system comprises a membrane-based device that serves as a flexible, enveloping and inflatable formwork and in which a self-hardening filling material or mass is injected. The device also fulfills other functions required both for the construction process, and for the element to be built. By means of diverse variants of the device elements with different forms, sizes, functions or uses can be constructed. The present invention is useful in various sectors of industry, among them civil works and construction in general, as well as the use of concrete as filler material.

State of the art

The current construction system of ducts and other hollow structures is currently made generally with prefabricated, rigid and small-sized elements, or they are carried out on site by rigid formwork. Usually the concrete is applied by pouring or spraying.

Rigid prefabricated elements imply a laborious process of site preparation, the commissioning of the element and its finishing according to each situation. Rigid formwork, generally recoverable, used to make elements in situ, is very expensive and especially when non-linear shapes or complex geometries are required. In many cases the amount of mass used to make structural elements is much greater than the structurally necessary amount. The use of lightweight rigid prefabricated materials for use in lightening structural elements, such as pieces made of rigid plastics, or hollow ceramic pieces is known. The elements to be manufactured in situations that are partially or totally below the water table, are usually done by freezing the ground, pumping the area, or depositing prefabricated water. In these, and in many other works not affected by a phreatic level, the waterproofing of the constructed element must then proceed. Likewise, with the traditional systems of rigid prefabricated use they use a lot of resources in transport and require a lot of labor and the execution of the work is slow.

At present, in modern architecture it is known to use inflatable, flexible and generally recoverable formwork with complex configurations, generally of double curvature, in order to make buildings and also certain independent elements. Concrete is usually used as filler material and applied by pouring or spraying.

The use of membranes to make elements is known, among its characteristics highlights that: They are easy to transport because of their weight, and their possibility of being folded and / or rolled. They extend at the place of realization of a structural element, and while controlling the air pressures, and where appropriate other means with which the formwork swells, masses are applied, such as for example concrete or polyurethane, shaping the element. They are inflatable with air, mass or other means, and do not have the problem of purging due to the possibility of injecting the mass in vacuo and its non-linear geometric shapes, with the possibility of performing valves at the appropriate points. The pressures applied depend on the circumstances of the element to be made, the amount of mass to be applied and the resistance of the membranes used. A membrane suffers due to pressure differences during its use. Controlling the pressure inside the formwork in reference to the concrete layers applied avoids having to use flexible formwork of high strength. Using independent chambers, they can be subjected to different pressures, or different masses can be applied to them. If its predetermined geometry defines curved shapes, they will in any case be concave from the point of view of greater pressure. They can be used in the final place of the element to be built, or in any other desired place, the element being transported later. They are even applicable in hard to reach places or in confined spaces. The support where they can be applied includes a land or excavation, traditional formwork, or the natural state of the site where the element is to be made. Its impermeability makes its surface or underground use feasible, partially or totally below the water table, even within the aquatic environment. Using them, the execution deadlines are shortened in relation to the usual methods. Due to the number of inventions related to flexible formwork and the uses of membranes in other fields of industry, such as inflatable castles and pneumatic rafts, many types of membranes are known to create flexible formwork and ways to develop devices based on of membranes.

The use of flexible formwork in the realization of elements has many advantages compared to the usual methods for the rigid elements mentioned above. Using flexible formwork, the dough is usually projected. Projected masses lose their liquid behavior once applied, and the formwork under pressure can support the weight of the dough. This process is especially applicable for sections with little inclination, so it is not suitable for making a wide variety of structural elements.

By injecting or pouring the masses, a flotation effect is caused that affects a flexible formwork, resulting in the loss of its geometric control, positioning problems and a nuisance in the realization of the base of the element. The invention WO03069073 deals with a way of making ducts, by thin-walled hoses. Insulator is injected between two concentrically arranged hoses, and concrete is applied externally to the hoses until an excavation is filled. This invention does not give a solution to the flotation problem, and is susceptible to several improvements, both in terms of the ease and control of positioning of the manqueras in the work, as well as the performance of the applied concrete. The invention US3899153 tries to create several different forms of ducts with flexible formwork. The proposed solution to the flotation is the subdivision of the formwork into sub-chambers, positioning it above the base of the previously prepared element, and fixing it by means of stops made on site. Possible improvements to this invention would be; to be able to avoid the previous preparation of the base, to be able to reduce the amount of sub-chambers, and to give a solution to the external formwork.

In conclusion, then, in relation to known flexible formwork, they have the following drawbacks:

-

 Geometry control

-

 Solve the base of the element.

-

 Control flotation.

-

 Pour or project and control the amount of dough to be applied, making it difficult to build when used on walls

or areas of certain inclination.

The present invention tries to give a solution to all these problems, incorporating additional functions to the flexible formwork, useful for an agile construction process or for an element to be made, incorporating new applications for flexible formwork.

Explanation of the invention.

The present invention proposes a duct construction system and other hollow structures that will contain at least one inner usable hole once a filler material applied by injection has hardened. It is characterized in that it comprises a device formed by a first outer membrane and a second inner membrane, between which a filling chamber closed at its ends is defined, the outer membrane having at least one access or nozzle through which at least one is introduced The mass that hardens.

The system also incorporates fixing means to a support on which said device is installed.

It also has at least one connector located in the filling chamber that connects the outer membrane with the inner membrane while maintaining the precise geometry of the device.

Another feature of the invention is that the outer membrane of the device has at least one access or nozzle for the inlet and / or outlet of a gaseous fluid that generates an internal pressure in the filling chamber to maintain the required volume of the device, of according to the required geometry of it.

The system also incorporates in the device an access or nozzle in its outer membrane with a connection hose that crosses a filling chamber and connects with the inner membrane for the entry and / or exit of a gaseous fluid that generates an internal pressure in the hollow chamber that maintains the required volume of the device, according to the required geometry of the device.

The connectors included in the device are flexible and formed by a membrane that is perforated, porous, or formed by wires and allows the self-hardening mass to pass through it. Said connectors may be fixed tangent to the outer or inner membrane.

Another feature of the proposed system is that the device has additional hollow chambers, and that they are located inside the filling chamber and that reduces the amount of mass that self-hardens to inject.

In one embodiment of the invention, the device has at least one additional membrane that creates a seat chamber with an access or nozzle through which the self-hardening mass is introduced and said seat chamber is supported and adapted to the existing support. It is also characterized in that the device includes anchors that reduce the free movement of its membranes, including connectors, seat chambers, additional ballasts and additional flat membranes that do not form chambers, which by means of anchors provided on site are fixed to the support.

The device includes in its hollow chambers, wired guides or pipes that are compatible with the folding and winding of said device being able to have in its hollow chamber some pendants arranged at a certain distance from each other that support said wiring or pipes.

If the calculations require it, the device has reinforcements or reinforcements attached to them on the outer membrane and / or on the inner membrane, and / or these adhere to the connectors through pin tubes,

or through holes provided in said connectors. Said reinforcements or reinforcements are foldable in themselves by ball joints. In addition, using an outer membrane and / or an inner membrane with the characteristic of being elastic, they compress the self-hardening mass injected into the filling chamber, improving its mechanical characteristics. The device also contains at least one outer membrane and / or one inner membrane with the characteristic of being resistant to traction and remaining in the element made and structurally collaborating with the self-hardening mass already hardened.

With the invention, the following advantages are achieved, among other things:

-

Resolution of the creation of the base of the element to be built, which is integrated into the device. And it adapts to both firm and regular and irregular supports.

-

Stabilization of the element to be constructed, by balancing hydraulic and pneumatic forces, forcing the device to position itself according to the calculations made previously, taking advantage of the floating of hollow chambers immersed in the filling material consisting of self-hardening masses that in their state of application have liquid or semi-liquid consistency.

-

Calculate and predict, depending on the balance of hydraulic and pneumatic nuts, the shape of the elements, not limited exclusively to circular sections.

-

By creating a filling chamber, and using the corresponding connectors and nozzles, the exact amount of self-hardening mass is used.

-

Lightening of elements.

-

Inclusion in the device of the necessary reinforcements or reinforcements, guides, or cables.

-

Use of the device as a collaborative tensile material in the calculations of the element to be built.

-

Complete tightness of the element made by having two membranes as barriers that prevent the passage of external water to the element.

-

Folding and rolling the entire device with all the built-in elements, including reinforcements or reinforcements.

-

Transport optimization.

-

Semi-automatic system compared to the state of the art, because in the place of realization only the self-hardening masses are usually used. High speed of execution of the elements.

Brief description of the figures

The attached figures represent schematic cross sections of devices in their swollen state. And they are presented by way of illustration and not limitation.

Figure 1 shows a front and schematic view of a swollen device with a single connector that is built on a regularized support that is part of the duct construction system and other hollow structures, object of the invention.

Figure 2.- Shows a front and schematic view of a swollen device with two connectors that are tangent to the inner hollow chamber that is constructed on a regularized support.

Figure 3.- Shows a front and schematic view of a swollen device with hollow chamber of circular section that has a seat chamber that adapts to an irregular support where it is built.

Figure 4.- Shows a front and schematic view of the filling chamber and the hollow chamber of a swollen device where guides, reinforcements or reinforcements, pipes or wiring, and pendants are included.

Figure 5.- It shows a front and schematic view of a swollen device more complex than the previous ones, which includes ballast chambers and a seat chamber to an irregular terrain. Said device for the use of for example, a tunnel, has an additional filling chamber forming a flat base.

Figure 6.- Shows a front and schematic view of a swollen device identical to that of the previous figure, without ballast chambers and without a seat chamber, on a regularized ground or support and fixed to it by means of anchorage provided on site through flat membranes

To facilitate the reading of the figures, a list of reference numbers used in them and in the text of the detailed description of the invention as well as in the claims is written, being: support (1), self-hardening mass (2), chamber hollow (3), flat membrane (4), connector (5), seat chamber (6), outer membrane (7), inner membrane (8), reinforcement or reinforcement (9), anchorage provided on site (10), device (11), guide (12), additional ballast (13), connection hose (14), wiring or pipe (15), pendant (16), pin tubes (17), ball joints (18), filling chamber ( 19), access or nozzle (20).

Detailed description of the invention

The present invention is a system for constructing ducts and other hollow structures, which uses a device (11), with additional functions, both for the corresponding construction process - by traditional means and which are not part of this invention -, As for the item to be made.

The device (11) is disposed in the place where the conduit or element is preferably folded and rolled. It extends in the firm or support (1) of the place of performance, since said device (11) has a fixing and seating system in both regular and irregular supports (1). For the latter case it is necessary that the device (11) has a seat chamber (6).

The device (11), has an outer membrane (7), and an inner membrane (8), which are joined by connectors (5), creating a filling chamber (19), which has at least one access or nozzle (20), by which the self-hardening mass (2) is injected, such as concrete or bicomponent silicone.

Since the device (11) is folded and rolled, in this situation the chambers they contain are empty, it would be sufficient to inject into the filling chamber (19) the self-hardening mass (2) or concrete through the accesses or nozzles ( 20) arranged for this purpose in the outer membrane (7) of the device (11). And if you have chosen to introduce air pressure in the aforementioned chamber, the same accesses or nozzles (20) are sufficient - with their corresponding regulators and traditional valves on the market - so that the flow of incoming air and exit.

Regardless of the above, the hollow chamber (3), which is closed at its ends, has accesses or nozzles (20) both at its ends, and through other nozzles that are located in the outer membrane (7) of the device (11), and reach the hollow chamber (3) inside through the corresponding connection hoses (14).

Depending on the previous calculations for the element to be carried out, as well as the desired shape to be acquired by the duct or element, the flexible enclosure formwork (11) will be swollen with air and / or other means, both the hollow chamber (3) such as the filling chamber (19), adopting the conduit or element to be constructed in various and natural ways, due to the balance of pneumatic and hydrostatic and punctual pressures to which the device (11) is subjected, and depending on such parameters, to achieve, between other shapes, circles, parabolas, ovoids, and "mushroom form".

Once the self-hardening mass (2) is injected into the filling chamber (19), and the hollow chamber (3) is swollen with air or other means at the desired pressure, a floating effect of said hollow chamber (3) occurs. for being immersed in the mass that just injected is a liquid or semi-liquid state. This flotation is controlled geometrically by the connector (5) that are in the filling chamber (19) and join the outer membrane (7) with the inner membrane (8).

In short, depending on the regularity of the ground or support (1), the devices (11) have a seat chamber (6) or not, or an additional flat membrane (4) that does not form a chamber is necessary. Likewise, if the ground is affected by a water table, the device (11) has additional ballasts (13).

If the calculations require it, the device (11) has reinforcements or reinforcements (9), outer membrane (7) and / or inner membrane (8) that collaborate with the self-hardening mass (2) already hardened. And any of the mentioned membranes can have the characteristic of being elastic.

In the duct construction system and other hollow structures we use a membrane-based device (11) that needs a positioning control on its support (1), because, after being swollen with air or other means, the mass injection that self-hardening (2) in a liquid or semi-liquid state, at desired heights or tonings, causes the device (11) to have a tendency to float. The anchors included in the device (11) determine the desired movement of the device (11) and the hollow chambers (3) and filling chamber (19) that are included therein, and which will form the gaps in the constructed element. Figures 1 to 4 represent the different ways of anchoring a device (11). In figure 3 a seat chamber (6) places the device (11) in its support (1) after being injected with self-hardening mass (2) and in a second phase the rest of the element is constructed. Connectors (5) position the hollow chamber (3) after the mass injection (2) into the filling chamber (19) that form the outer membrane (1) and the inner membrane (8) that limits the volume of mass (2) ) to be applied independently of the support (1) or the place where the element was made. By means of accesses or nozzles (20) provided in the chambers, the necessary flows can be regulated during the construction process. The accesses or nozzles

(20) can be carried out using connection hoses (14) as shown in figure 3, which in their case pass through intermediate filling chambers (19).

The anchors and connectors (5), ensure that the various chambers will be properly positioned after the application of the self-hardening masses (2), reserving the desired space to form the seat or support of the element to be constructed, providing free access to the masses that self-harden (2) to these areas, where appropriate through the use of connectors (5) and formed by a membrane that is perforated, porous., or formed by threads and that allows the self-hardening mass to pass through it ( 2). Depending on the pressures applied to the filling chamber (19) and the hollow chamber (3) and the control of these pressures during the application of self-hardening masses (2) in the desired layers or tonings, and using water or other means in other cameras where appropriate, the device will take a specific form. Cameras tend to adapt round shapes when inflated with air. Filling them with masses that self-harden (2) or liquids of a certain density tend to "flatten out", immersing them in a liquid or semi-liquid medium they tend to "ovoid." Differences in mass density that hardens (2) or other means on both sides of the membranes, and internal pressures inside the chambers, give rise to the flotation effect, whereby the membranes will be subjected to a balance of forces. The resulting geometry, of a device (11) during its use in the duct construction system and other hollow structures, can be predicted after a mathematical calculation of balance of these forces.

Figures 1 and 2 represent some specific forms of devices (11), resulting from a specific use situation, obtained by these calculations, and schematically reflected. Figures 1 and 2 represent devices

(eleven)

 With identical inner membranes (8) and outer membranes (7), the fixing of the hollow chambers (3) by connectors (5) is different in both cases. Injecting into the filling chambers (19) with a self-hardening mass (2), it will result in very different forms in both cases due to the floating of the hollow chambers

(3)

and how to counteract the consequent forces. To prevent the outer membrane (7), presented in Figure 1 from being lifted in the center, where the connector (5) is fixed, the self-hardening mass can be applied

(2)

 in two phases In the second phase the weight of the first layer, already fully or partially hardened, prevents possible deformations of the lower part of the device. As can be seen in figures 1 and 2, if the connectors (5) are fixed tangentially to the membranes, they will represent soft shapes, otherwise there is an angle jump at their fixing point. Placing connectors (5) at appropriate points can influence the shapes to be obtained, in relation to the filling chambers (19), as well as the shape of the hollow chambers (3). By controlling and regulating the internal pressures in the various chambers, the shapes obtained will be different, increasing the pressure in a chamber, this will increasingly adapt a circular section. If the device (11) contains an outer membrane (7) and / or an inner membrane (8) with the characteristic of being elastic, applying high pneumatic pressures during the process can cause deformation of the membranes themselves, due to their elastic behavior . This elasticity can exert a compression to the self-hardening mass (2), improving its quality and / or effect a compression to the hardened mass, compensating at least in part the forces of load in the element, if the calculations require it.

To facilitate and streamline the construction system, the device (11) may have the desired intended objects included for a given structural element. These objects include: Reinforcements or reinforcements (9) guides (12), wiring or pipe (15), pendants (16). Figure 4 represents a way of including the objects described above in the device (11). Wiring or pipes (15) can be hung inside a hollow chamber (3), using pendants (16), with or without the use of pin tubes (17) and guides (12) In filling chambers (19) the pipes or wiring (15), or the guides (12) or reinforcements or reinforcements (9) may be attached: to the membranes,

or connected to the connectors (5) directly or through holes provided, if desired, in this case the pin tubes (17) can also be applied. The reinforcements or reinforcements (9), can be foldable in themselves by means of ball joints (18) and pin tubes (17)

By means of the construction system and using a device (11), according to the present invention, a great variety of ducts and other hollow structures can be constructed between them: Tunnels and water, electricity, and sewer ducts. The device (11) remains in the finished element and provides functions to the finished element, such as offering watertightness, reserving a utility hole, or a tensile working membrane that

5 can contribute and collaborate structurally with the self-hardening dough (2) already hardened.

Finally, in an illustrative and non-limiting way, an example of a geometric configuration of a device is presented schematically, where for reasons of clarity the different accesses or nozzles (20) have been omitted. The configuration reflected in Figure 5 can be used for the construction of a tunnel. This device (11) comprises 10 of: Several hollow chambers (3), a central that will be of use, and others of lightening that in their case can be useful for wiring or others, a filling chamber (19), between a outer membrane (7) and an inner membrane

(8) fixed together by connectors (5); a seat chamber (6); two additional ballast chambers (13); and another additional filling chamber (19) that will form the inner hearth of the duct.

Alternatively, if the floor or support (1) is regularized, the device (11) is fixed to said support (1) by anchors provided on site (10) on the flat membranes (4).

Claims (15)

1. Duct construction system that will contain at least one inner useable hole once an injection applied filling material has hardened, characterized in that it comprises:

-

 a device (11) formed by a first outer membrane (7) and a second inner membrane (8), between which a filling chamber (19) closed at its ends is defined, the outer membrane (7) counting with at least an access or nozzle (20) by which at least the self-hardening mass (2) is introduced.

-

 fixing means and seat of the device (11) with respect to a support (1) on which said device (11) is installed.

-

 at least one connector (5) located in the filling chamber (19) that connects the outer membrane (7) with the inner membrane (8) maintaining the precise geometry of the device (11). Said connector (5) is flexible and is formed by a perforated membrane, porous, or formed by wires and that allows the self-hardening mass (2) to pass through it.

2.

 Duct construction system according to claim 1, characterized in that the outer membrane (7) has at least one access or nozzle (20) for the inlet and / or outlet of a gaseous fluid that generates an internal pressure in the chamber of padding (19) that maintains the required volume of the device (11), according to the required geometry of the device.

3.

 Duct construction system according to any of the preceding claims, characterized in that the device (11) has at least one access or nozzle in its outer membrane (7) with a connection hose (14) that crosses a filling chamber (19) and connects with the inner membrane (8) for the inlet and / or outlet of a gaseous fluid that generates an internal pressure in the hollow chamber (3) to maintain the required volume of the device (11), in accordance with the required geometry of it.

Four.

 Duct construction system according to any of the preceding claims, characterized in that the device (11) has at least one additional hollow chamber (3), and that is located inside the filling chamber (19) and that reduces the amount of dough that hardens (2) to be injected.

5.

 Duct construction system according to any of the preceding claims, characterized in that the device (11) has at least one additional membrane that creates a seat chamber (6) with an access or nozzle (20) through which it is introduced the self-hardening mass (2) and the mentioned seat chamber (6) is supported and adapted to the existing support (1).

6.

 Duct construction system according to any of the preceding claims, characterized in that the device (11) includes anchors that reduce the free movement of its membranes, including connectors (5), seat chambers (6), additional flat membranes (4) that do not form chambers, additional ballasts (13), and anchors provided on site (10) that are fixed to the support (1).

7.

 Duct construction system according to claim 1, characterized in that the device (11) contains at least one connector (5) which is tangentially fixed to the outer membrane (7) or to the inner membrane (8).

8.

 Duct construction system according to any one of the preceding claims, characterized in that the device (11) includes at least one hollow chamber (3) a guide (12), or wiring or pipe (15).

9.

 Duct construction system according to any one of the preceding claims, characterized in that the device (11) includes in at least one hollow chamber (3) pendants (16) arranged at a certain distance from each other that support a wiring or pipe (15) ).

10.

 Duct construction system according to any one of the preceding claims, characterized in that the device (11) is arranged in the outer membrane (7) and / or in the inner membrane (8) reinforcements or reinforcements (9) adhered thereto .

eleven.

 Duct construction system, according to any one of the preceding claims, characterized in that the device (11) has armatures or reinforcements (9) adhered thereto, or through pin tubes (17), or through holes provided in said connectors (5).

12.

 Duct construction system according to any of claims 11 and 12, characterized in that the device (11) has reinforcements or reinforcements (9) foldable in themselves by means of ball joints (18).

13.

 Duct construction system according to any of the preceding claims, characterized in that the device (11) contains an outer membrane (7) and / or an inner membrane (8) with the characteristic of being elastic, which compresses the self-hardening mass ( 2) injected into the filling chamber (19).

14.

 Duct construction system according to any of the preceding claims, characterized in that the device (11) contains at least one outer membrane (7) and / or an inner membrane (8) with the characteristic of being resistant to traction and that they remain in the element made and structurally collaborating with the self-hardening dough (2) already hardened.

SPANISH OFFICE OF THE PATENTS AND BRAND Application no .: 201100093 SPAIN Date of submission of the application: 24.01.2011 Priority Date: REPORT ON THE STATE OF THE TECHNIQUE 51 Int. Cl.: E04G11 / 04 (2006.01) RELEVANT DOCUMENTS

Category

56 Documents cited Claims Affected

X

DE 3442904 A1 (SCHELFHORST HENDRIK W) 05.06.1986, 1-4,6,7,9,10,14.15

& Summary of the WPI database. Recovered from EPOQUE; AN 1985-029452; page 8,

line 1 - page 10, line 29; figures.

X

US 3257481 A (MING-YANG CHANG) 21.06.1966, 1,3,4,6,7,9,10,14.15

column 2, line 40 - column 3, line 31; figures 5.6.

X

BE 1010458 A6 (DESSEL STEVEN VAN) 01.09.1998, 1,4,5,7-11,14,15

& Summary of the WPI database. Recovered from EPOQUE; AN 1998-468148; Figures 1.4-6.

X

GB 975975 A (JOHN KAY STIRLING et al.) 25.11.1964, 1,9,10,12,15

page 1, line 80 - page 2, line 97; Figure 1.

TO

DE 1938478 A1 (JUNG EUGEN) 08.04.1971, 1-3,11,14,15

& Summary of the WPI database. Recovered from EPOQUE; AN 1971-25256S; figures 1,2.

TO

WO 9633324 A1 (H G TECH AB et al.) 24.10.1996, 1,2,7,14,15

page 3, line 18 - page 4, line 16; Figures 1a-1c.

TO

US 4155967 A (SOUTH BARRY et al.) 22.05.1979, 1,9,10

column 6, lines 23-27.

TO

DE 10235044 A1 (BRANDENBURGISCHE TECH UNI COTT) 19.02.2004, 5

& Summary of the WPI database. Recovered from EPOQUE; AN 2004-192594; Figure 1.

Category of the documents cited X: of particular relevance Y: of particular relevance combined with other / s of the same category A: reflects the state of the art O: refers to unwritten disclosure P: published between the priority date and the date of priority submission of the application E: previous document, but published after the date of submission of the application

This report has been prepared • for all claims • for claims no:

Date of realization of the report 11.06.2012

Examiner S. Fernández de Miguel Page 1/5

REPORT OF THE STATE OF THE TECHNIQUE Application number: 201100093 Minimum documentation sought (classification system followed by classification symbols) E04G, E04B, B28B, B29C Electronic databases consulted during the search (name of the database and, if possible, terms of search used) INVENES, EPODOC State of the Art Report Page 2/5  WRITTEN OPINION Application number: 201100093 Date of Written Opinion: 11.06.2012 Statement

Novelty (Art. 6.1 LP 11/1986)

Claims Claims 9, 10, 13 1-8, 11, 12, 14, 15 IF NOT

Inventive activity (Art. 8.1 LP11 / 1986)

Claims Claims 13 1-12, 14, 15 IF NOT

The application is considered to comply with the industrial application requirement. This requirement was evaluated during the formal and technical examination phase of the application (Article 31.2 Law 11/1986).  Opinion Base.- This opinion has been made on the basis of the patent application as published. State of the Art Report Page 3/5  WRITTEN OPINION Application number: 201100093  1. Documents considered.- The documents belonging to the state of the art taken into consideration for the realization of this opinion are listed below.

Document

Publication or Identification Number publication date

D01

DE 3442904 A1 (SCHELFHORST HENDRIK W) 05.06.1986

D02

US 3257481 A (MING-YANG CHANG) 06/21/1966

D03

BE 1010458 A6 (DESSEL STEVEN VAN) 01.09.1998

D04

GB 975975 A (JOHN KAY STIRLING et al.) 11/25/1964

D05

FROM 1938478 A1 (JUNG EUGEN) 08.04.1971

D06

WO 9633324 A1 (H G TECH AB et al.) 24.10.1996

D07

US 4155967 A (SOUTH BARRY et al.) 05/22/1979

D08

DE 10235044 A1 (BRANDENBURGISCHE TECH UNI COTT) 19.02.2004

 2. Statement motivated according to articles 29.6 and 29.7 of the Regulations for the execution of Law 11/1986, of March 20, on Patents on novelty and inventive activity; quotes and explanations in support of this statement The present invention relates to a duct construction system and other hollow structures. Documents D01-D04 are considered the most representative of the prior art, anticipating the features described in claim 1 of the application. Document D01 discloses a system for the construction of a hollow structure of application in the realization of housing. The system comprises a device formed by a first membrane or outer wall (9) and a second membrane or inner wall (7) between which a filling chamber closed at its ends is defined. The outer membrane has an access through which a self-hardening mass (4) is introduced (see figure 2). The device also has fixing and seating means (3) with respect to the support on which it is installed and connectors (11) that maintain the precise geometry of the device (see summary). Document D02 shows a system for the construction of structures containing a usable hole in its interior once the filler material applied by injection has hardened. The system comprises an outer membrane (5) and an inner membrane (3) between which a filling chamber (2) is defined, the outer membrane counting with nozzles (7) through which a self-hardening mass is introduced. Likewise, said device has fixing and seating means (8) and connectors (6) located in the filling chamber. Documents D03 (see figures 1 and 5) and D04 (see figure 1) have similar characteristics. Likewise, the object of the invention described in claims 2-4 derives directly from document D01. The device described by this document shows in its outer membrane an access for the entrance of a gaseous fluid that generates an internal pressure in the filling chamber and another access that connects with the inner membrane for the entrance of a gaseous fluid that generates a pressure internal in the hollow chamber to maintain the required volume of said device (see figure 2). Said device also has flexible connectors formed by plastic wires. In relation to claim 5, document D03 shows the existence within the filling chamber of additional chambers as separators that reduce the amount of mass to be injected (see Figure 6). Referring to claims 6 and 7, the device disclosed by document D01 has seat chambers with nozzles through which the self-hardening mass is introduced (see figure 1). In relation to claim 8, document D03 shows connectors attached tangentially to the membranes (see Figure 5). In relation to claims 11 and 12, documents D03 and D04 respectively show the existence of reinforcements or reinforcements adhered to the membranes or separators. Claims 14 and 15, referring to membrane properties, are considered anticipated by document D01. In view of the cited documents, claims 1-8, 11, 12, 14 and 15 are included in the prior art and are therefore not new or imply inventive activity (Art. 6.1 and Art. 8.1 of LP 11/1986). State of the Art Report Page 4/5  WRITTEN OPINION Application number: 201100093 Claims 9 and 10 add the inclusion in hollow chambers of the device of guides, wiring or pipes and pendants for the support of said wiring or pipes. However, the introduction into hollow chambers of wiring or pipes supported by pendants is widely known in the state of the art (see, eg, document D07). On the other hand, the indication that they are compatible with the folding and rolling of the device is considered a mere expression of desire as the specific technical characteristics are not provided. Therefore, it is considered that the invention defined in these claims derives from the state of the art in an obvious way for a person skilled in the art and does not imply inventive activity (Art. 6.1 LP / 1986). State of the Art Report Page 5/5