CONCRETE STRUCTURE MANUFACTURING APPARATUS AND METHOD

Abstract

The present relates to an apparatus for manufacturing 3-dimensional concrete structures comprising a projection head (1) for spraying concrete material, wherein the projection head (1) comprises a projection nozzle (11) for spraying the concrete material and at least two guiding surfaces (12) provided on both sides of the projection nozzle (11) and defining a volume in between, such that the projection nozzle (11) is adapted to spray the concrete material into said volume, and wherein the projection head (1) is repeatedly moved along a predefined path by a control means and is configured to adjust the position of the two guiding surfaces (12) during the movement of the projection nozzle (11) so as to create a 3-dimensional concrete structure made of a plurality of projected concrete layers.

Claims

1. An apparatus for manufacturing 3-dimensional concrete structures comprising a projection head (1) for spraying concrete material, wherein the projection head (1) comprises a projection nozzle (11) for spraying the concrete material and at least one guiding surface (12) provided on one side of the projection nozzle (11) and defining a volume with a second wall element, such that the projection nozzle (11) is adapted to spray the concrete material into said volume, and wherein the projection head (1) is repeatedly moved along a predefined path by a control means and is configured to adjust the position of the at least two guiding surfaces (12) during the movement of the projection nozzle (11) so as to create a 3-dimensional concrete structure made of a plurality of projected concrete layers.

2. Concrete elements manufacturing apparatus to claim 1, characterized in that the second wall element is also a guiding surface such that it comprises at least two guiding surfaces (12) provided on both sides of the projection nozzle (11) and defining a volume in between.

3. Concrete elements manufacturing apparatus to claim 1 or 2, characterized in that it further comprises a scarping which is positioned at the rear of the projection head (1) and perpendicular to its advancement direction.

4. Concrete elements manufacturing apparatus according to any one of claims 1 to 3, characterized in that the at least one guiding surface (12) is made out of a water repellent and non-adhesive material taken form the group comprising polytotrafluoroethylene (PTFE), polyoxymethylene (POM), polydimethylsiloxane, ceramic and POM silicone surface.

5. Concrete elements manufacturing apparatus according to any one of claims 1 to 4, characterized in that the at least one of guiding surface (12) is coated with a slippery liquid-infused porous surface (SLIPS).

6. Concrete elements manufacturing apparatus according to any one of claims 1 to 5, characterized in that the at least one of guiding surface (12) is pivotably mounted to as be able to pivot along a vertical axis and/or an horizontal axis.

7. Concrete elements manufacturing apparatus according to any one of claims 1 to 6, characterized in that the at least one of guiding surface (12) is movable with respect to each other and/or the projection head so as to be able to vary the distance and/or the position between them.

8. Concrete elements manufacturing apparatus according to any one of claims 1 to 7, characterized in that it further comprises rollers (15) disposed in front of the at least one of guiding surface (12)

9. Concrete elements manufacturing apparatus according to any one of claims 1 to 8, characterized in that the at least one guiding surfaces (12) is made of a soft material such as a membrane.

10. Concrete elements manufacturing apparatus according to any one of claims 1 to 9, characterized in that it further comprises a quality control system which comprises at least one specific sensor verifying the consistency of the concrete and/or the height of the layer at different levels of said apparatus.

11. Concrete elements manufacturing apparatus according to any one of claims 1 to 10, characterized in that it further comprises a rotating device that maintains the projection nozzle (11).

12. Concrete elements manufacturing apparatus according to any one of claims 1 to 11, characterized in that it further comprises a scarping element adapted to scrap the concrete that has spilt on the side of the guiding surface (12).

13. A method of fabricating a 3-dimensional structure, using the apparatus of any one of claims 1 to 12, comprising the steps of: projecting a concrete material between a guiding surface (12) and the second wall element while moving the projection head (1) through a control means, along a predefined path so as to generate a first layer with a first height and a first thickness, lifting the projection head (1) according to a height adapted from layer to layer according to concrete rheology and operating conditions, and repeating the concrete material projection step so as to generate a second layer on top of at least a portion of the first layer, repeating the preceding steps until termination.

14. Manufacturing method according to claim 13, wherein when sprayed on a preceding concrete layer, the sprayed concrete layer reactivates the concrete on the upper side of said preceding concrete layer so as to prevent formation of cold joints.

15. Manufacturing method according to claim 13 or 14, wherein the concrete layer is projected according to a dense-flow spraying process.

16. Manufacturing method according to any one of claims 13 to 15, further comprising integrating a passive reinforcement (17) into said manufactured wall by providing it along the projection head (1) path and between the guiding surface and the second wall element (12) such that the projection head (1) projects and surrounds the concrete material on it.

17. Computer implemented method adapted control the manufacturing apparatus of any one of claims 1-12 to carry out the manufacturing method of claims 12 to 15.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0033] Further particular advantages and features of the invention will become more apparent from the following non-limitative description of at least one embodiment of the invention which will refer to the accompanying drawings, wherein

[0034] FIG. 1 schematically represents a projection head according to a first embodiment of the present invention,

[0035] FIG. 2 represents a detailed projection head according to a second embodiment of the present invention,

[0036] FIGS. 3A and 3B are schematically representations of the operation of the projection head of the present invention according to a first embodiment of the method,

[0037] FIGS. 4A and 4B are schematically representations of the operation of the projection head of the present invention according to a second embodiment of the method,

[0038] FIG. 5A to 5C shows a guiding surface according to a preferred embodiment of the invention,

[0039] FIG. 6A to 6C shows a guiding surface according to another preferred embodiment of the invention, and

[0040] FIG. 7 is a schematically representation of a complete spraying system comprising the projection head of the present invention, a concrete pump, and an air and accelerator supply.

DETAILED DESCRIPTION OF THE INVENTION

[0041] The present detailed description is intended to illustrate the invention in a non-limitative manner since any feature of an embodiment may be combined with any other feature of a different embodiment in an advantageous manner.

[0042] The present invention relates to a method and an apparatus for fabrication of 3-dimensional objects with any type of concrete material including conventional concrete, high performance concrete, ultra-high fiber reinforced concrete, polymer concrete, lightweight concrete, glass concrete and any other cement based material or hydraulic binder based material. Although the present invention relates to concrete material objects, it is sure and obvious that the present invention can be used with any other material adapted for 3D printing such as plastic and the same. The concrete material is sprayed through a projection nozzle 11 between the guiding surfaces 12 and the projection head 1 is guided by a control means, preferably a robotic arm. In order to provide a great liberty to the head 1, it is preferable that the projection nozzle 11 and the guiding surfaces 12 are held and directed by a robot arm having 3, 4 or 6 axes.

[0043] Although the present application will describe a preferred embodiment with two guiding surfaces, it has to be noted that an embodiment with a single guiding surface is also comprised in the present invention when, for example, the device is used to create a concrete wall against another wall where in this case, the other wall acts as the second guiding surface.

[0044] FIG. 1 shows the first aspect of the invention which is a projection head 1 according to a first embodiment of the concrete elements manufacturing apparatus for spraying the concrete to generate the 3-dimensional objects.

[0045] The projection head 1 comprises a projection nozzle 11 for spraying concrete and guiding surfaces 12, which in this embodiment comprise two guiding plates 12 provided on both sides of the projection nozzle 11 and preferably in front of the projection nozzle 11 (in the moving direction) and defining a volume in between such that the projection nozzle 11 is adapted to spray the concrete into the volume. With this apparatus, one can realize 3D concrete structures in way similar to regular 3D printing because the projection head 1 is controlled by a robotic arm and is repeatedly moved along a predefined path so as to create a concrete element made of a plurality of concrete layers 20, 21.

[0046] FIGS. 5A to 5C and 6A to 6C show two different examples of guiding surfaces. The guiding surfaces 12 can be curved and soft allowing complex shapes. On the other hand, the guiding surfaces can consist in flat guiding plates, either rigid or soft, in flat guiding surfaces, in curved guiding surfaces, in round guiding surfaces (in such a case a continuous circular guiding surface) or even guiding surfaces having the shape of rollers and so on. This being said, the term “guiding plate” will be used below in order to correspond to the drawings but it shall be understood that any type of guiding surface could be used.

[0047] In order to generate a concrete layer 20, 21 having an even height, the projection head 1 of the apparatus can further comprise a scarping element, preferably having the shape of an inverted comb, which is positioned at the rear of the projection head 1 and perpendicular to its advancement direction. This element, not represented in the figures, can provide a mean for scraping the surplus of concrete in order to have a controlled concrete wall height, facilitating positioning the head 1 and the robot arm for the successive layer.

[0048] Although this does not appear explicitly from the figures, the guiding plates 12 are preferably made out, or at least partially made out, of a water repellent and non-adhesive material such as PTFE, PDMS, PVC, ceramic or silicone, or possibly coated with a slippery liquid-infused porous surface (SLIPS). The term partially here refers to the portion of the guiding plates 12 which is intended to be in direct contact with the concrete material.

[0049] Therefore, the guiding plates 12 are not only guiding the sprayed concrete, but provide a smooth and dense surface to the sprayed concrete.

[0050] While the guiding plates 12 can be fixed and oriented in parallel with the moving direction to provide a straight layer 20, 21, one can advantageously, mount the guiding plates 12 with a system 3, 13 that allows them to rotate. This means that one can provide the guiding plates 12 such that they are pivotably mounted on an apparatus frame or on the projection nozzle 11, through a rotating head for example, so as to be able to pivot along a vertical axis and/or a horizontal axis, to prevent the winding of the concrete hose and the realization of angles or curved walls. FIG. 1 shows such a mechanism 3, 13 but it is only an example and any other suitable mechanism can be used, even a plurality of independent mechanisms for each plate.

[0051] Also, the guiding plates 12 are preferably mounted in a mobile way for opening and closing the guiding plates 12 so as to modify the gap d between them to vary the thickness of the wall/layer or their relative position to provide a shape modification to the wall/layer which is generated. They also can be mounted so as to be movable with respect to the projection head so as to modify their symmetry with respect to the head or even to be able to vibrate to improve compacting the concrete. This can be done with any conventional system 14 such as a worm screw for example or the like. FIGS. 1 and 2 also show such a mechanism 14 but it is only an example and any other suitable mechanism can be used, even a plurality of independent mechanisms for each plate.

[0052] Further, in order to adapt to possible obstacle, it is possible that at least one of the guiding plates 12 is made of a soft material such as a membrane. It is also possible that they can be made of a material having a variable stiffness to modify it according to the situation is real time.

[0053] Finally, in order to be even more modular, it is possible that at least one of the guiding plates 12 is made so as to be able to modify its length or even its width, for example by being telescopic or stretched.

[0054] FIG. 2 shows an isometric and schematic view of two assembled guiding plates 12. In this figure is represented a gap modifying mechanism 14 consisting in a worm screw. Also, height modifying mechanisms 16 are represented. Also, the apparatus can comprise rollers 15 disposed in front of the guiding plates 12 which are positioned so as to roll over the lateral sides of the wall under construction. This permit to stabilize the head 1 and also to improve the smoothening of the lateral sides.

[0055] Furthermore, while this is not represented in the drawings, the apparatus can comprise a quality control system which can comprise a specific sensor, or a plurality of them, allowing to verify online the consistency of the concrete at different level of the apparatus such as in the pump or in the projection nozzle 11 or anywhere. Also, it can comprise a system for verifying the height of the layer or even of the entire piece.

[0056] According to an alternative embodiment the apparatus may comprise two projection nozzles which project concrete into the same single space. The two concrete flows of are preferably projected crosswise and this provides reinforcement of the projected concrete.

[0057] The present invention relates to an apparatus but also to a method where concrete is projected/sprayed through the projection nozzle 11 between at least the two guiding plates 12 acting as a guide and moving together with the projection nozzle 11, the whole being moved by a robot at a controlled speed. The guiding plates 12 direct the projected concrete flow and provide a smooth and compacted surface or textured surface if the guiding plates 12 contain a texture too.

[0058] More particularly, in a method of fabricating a 3-dimensional structure according to the present invention, one controls the above apparatus of the present invention so as to carry out the following steps. First, one inputs all relevant information in a control means, such as the type of object we wish to create and the associated parameters if needed. Then we start and the projection nozzle 11 is controlled to project a concrete material between the two guiding plates 12 while the projection head 1 is moved by the control means along a predefined path so as to generate a first layer 20 with a first height and a first thickness d, once done, the projection head 1 is lifted to a height adapted from layer to layer according to concrete rheology and operating conditions, and the concrete material projection step is repeated so as to generate a second layer 21 on top of at least a portion of the first layer 20 and the preceding steps are repeated until termination. The method is such that the parameters are chosen such that when sprayed on a preceding concrete layer, the sprayed concrete layer reactivates the concrete on the upper side of said preceding concrete layer by eliminating and preventing any possible cold joints between the layers so as to provide a very strong connection between the layers. This can for example consist in a dense-flow spraying process.

[0059] Thanks to the method of the present invention, on can integrate a passive reinforcement 17 made out of any kind of proper material such as steel rebars and/or glass fibers of carbon mesh into said manufactured wall by providing it along the projection head path and between the two guiding plates 12 and adapting the projection head height above it and the related parameters as well such that the projection head 1 simple moves over the reinforcement 17 and projects the concrete material on the passive reinforcement and surrounds it with the same. This is represented in FIG. 4A showing the step when the first layer is created and FIG. 4B which shows the step when the second layer is created.

[0060] As shown in FIGS. 3A and 3B, the concrete is projected at a distance h typically ranging from 20 cm to 40 cm from the ground or bottom layer for a distance between the plates 12 of 8 to 12 cm, for an air debit of 4 m.sup.3/min, and a projection nozzle 11 having an opening of approx. 30 mm.

[0061] Alternatively, the concrete can be projected at a distance h typically of 1 m from the ground or bottom layer for a distance between the plates 12 of 20-25 cm.

[0062] These ranges are indicative only since the distance h may range from 20 cm to 1.5 m from the last projected layer or the soil, if the concrete flow, the thickness between the plates 12 (d) and any other parameters described below are suitable. The height here refers to the distance between the exit/opening of the projection nozzle 11 and the ground or lastly projected layer. From this, we can see that there is no particular preferred ranges since it depends on the need and then according to this need, all apparatus parameters are set so as to provide the best combination and the best results. For example, in order to achieve a proper projection with the above data, the air pressure can be increased to 5.5 m.sup.3/min at a pressure of 7 bars for a projection nozzle opening of 40 mm. The distance H can then also be increased and consequently the distance between the guiding plates 12 can be increased as well, for example.

[0063] The concrete flow is preferably adapted to the method, currently it oscillates between .sub.90-130 kg/min (.sub.35-60 L/min).

[0064] The height of the layers is typically between 15 and 30 mm in height. Alternatively, according to the needs, it is very likely that one can at least double the layer heights provided that the different parameters are adjusted

[0065] The preferred width (d) of the concreted walls which corresponds to the chosen distance between the guiding plates 12, typically varies from 5 cm to 25 cm. The apparatus and the method of the present invention provide concrete walls with the entire thickness of the wall being stuffed and not just the contours.

[0066] The method permits an ultra-rapid realization of walls such as angle elements, cable chambers, electrical cabinets, urban designs and architectural elements. Arches of circles are also possible to realize provided that the guiding plates 12 are pivotable along a vertical axis, so as to follow a circle having a typical radius of curvature of 50-60 cm and that the robotic arm is controlled to realize the same.

[0067] As represented in FIG. 7, the concrete is preferably sprayed using a dense flow method. In such method, a pump pushes an already prepared mixture comprising cement and binders, sand, aggregate and water, and not a dry mortar. Air and an activator allowing setting of the concrete is added in the projection nozzle 11 or a few cm before entering the projection nozzle 11. This is shown is FIG. 7. The apparatus is however not limited to it and can spray a thin flow wet sprayed concrete or a dry sprayed concrete. The method and the apparatus permit the use of concrete having a particle size up to 16 mm, preferably up to 8 mm.

[0068] The apparatus of the present invention, as well as the associated method has many applications, among which, Bespoke civil engineering products such as cable chambers, wastewater treatment chambers, retaining walls, or architectural and design objects such as façades and urban design objects.

Example 1

[0069] We use a concrete flow rate of 90 Kg/min, an air flow of 4 m.sup.3/min, an air pressure of 7 bar. The rheology of the concrete has been measured with a small steal cone of 5×10×15 cm and the resulting flow was of 13 cm. The height of the guiding plates 12 between the projection nozzle 11 and the bottom layer of concrete is comprised between 24 and 36 cm and the distance between the two guiding plates 12 is 8.5 cm. We varied the robot speed between 10 and 20 cm/sec with an optimum at around 18 cm/sec

[0070] The resulting object showed very satisfying lateral side smoothness and layer to layer adhesiveness.

Example 2

[0071] We use a concrete flow rate of 95-110 Kg/min, an air flow of 6 m.sup.3/min, and an air pressure of 7.5 bar. The height of the guiding plates 12 between the projection nozzle 11 and the bottom layer of concrete is comprised between 36 and 100 cm and the distance between the two guiding plates 12 varies between 14 to 20 cm. We varied the robot speed between 5 and 15 cm/sec [0072] The resulting object showed very satisfying lateral side smoothness and layer to layer adhesiveness.

[0073] While the embodiments have been described in conjunction with a number of embodiments, it is evident that many alternatives, modifications and variations would be or are apparent to those of ordinary skill in the applicable arts. Accordingly, this disclosure is intended to embrace all such alternatives, modifications, equivalents and variations that are within the scope of this disclosure. This is for example particularly the case regarding the different concretes or additives which can be used, or the different parameters chosen to optimize the projection of the concrete material such as the concrete flow rate, the air flow, the air pressure or the rheology of the concrete.