The present invention relates to a tectonic origami device.
There are two relevant design tracks in the state of the art for origami inspired structures. There are a number of designs that focus on regular repeating plates. These are typically connected with hinge joints. These designs include volumes that are open at one or both sides. A very simple example of this is expanding solar panels on satellites or the retracting roof of a stadium. These designs typically feature expansion in one dimension and cannot be used to form closed volumes. Another design is an origami inspired handbag, which can be opened at one side, and consists of regular repeating soft triangles. The current designs however leave at least one face open.
One object of the present invention is therefore to address at least one of the problems of the prior art and/or to provide a choice that is useful in the art.
According to a 1st aspect, there is provided a tectonic origami device comprising: a flexible supporting substrate; and a plurality of substantially rigid planar members arranged on the supporting substrate, the planar members configured in a non-overlapping cooperative arrangement to permit assembly of the device to form an enclosure. The device is configured to be transformable between a collapsed form where the supporting substrate and planar members are collectively in a planar arrangement and an assembled form where the supporting substrate and planar members are collectively assembled as the enclosure.
Advantageously, the device has a flexible configuration in which it may reversibly and rapidly transform between the collapsed and assembled forms. Particularly, the collapsed form makes it easy to stow the device when needed, while the assembled form can easily be deployed to provide substantial structural rigidity for the device in functioning as an enclosure (e.g. a bag) to store loose items.
Preferably, each planar member may include a plate.
Preferably, the plate may include being formed of cardboard, plastic, wood or a composite material.
Preferably, the supporting substrate may include felt or canvas.
Preferably, the device further comprises a locking cap having a plurality of female members, and the device includes a plurality of male members, wherein in the assembled form, the male members are received into the respective female members to enable the locking cap to hold the enclosure in the assembled form using interference friction locking.
Preferably, the female member may include a slot and the male member may include a pin.
Preferably, each planar member may include being formed in a polygonal shape.
Preferably, the polygonal shape may include a triangle, a pentagon, or a toroid. It is also to be appreciated that asymmetric variants of these fundamental shapes are possible as well, which include pyramid and prism.
Preferably, the planar members may alternatively include first and second plurality of planar members, each of the first plurality having a first polygonal shape and each of the second plurality having a second polygonal shape which is different to the first polygonal shape.
Preferably, at least some of the planar members may include decorative images formed on respective surfaces thereof.
Preferably, the device may further include a plurality of elastic cords attached respectively to at least some of the planar members to enable the device to transform from the collapsed form to the assembled form by pulling the elastic cords collectively in a direction in opposition to a platform on which the device is positioned.
According to a 2nd aspect, there is provided a method of operating a tectonic origami device, which includes a flexible supporting substrate and a plurality of planar members arranged on the supporting substrate, the planar members configured in a non-overlapping cooperative arrangement to permit assembly of the device to form an enclosure. The method comprises: configuring the device to transform between a collapsed form where the supporting substrate and planar members are collectively in a planar arrangement, and an assembled form where the supporting substrate and planar members are collectively assembled as the enclosure.
According to a 3rd aspect, there is provided a method for manufacturing the tectonic origami device, the method comprising: determining a shape of the enclosure of the device; forming the shape of the enclosure from a planar element, the formation causing markings to be formed on the planar element; and determining characteristics of the planar members based on the markings formed on the planar element.
Preferably, determining characteristics of the planar members comprises: based on the markings, identifying areas on the planar element corresponding to surfaces providing the shape of the enclosure when the planar element is formed into the enclosure; providing the supporting substrate as the planar element; and determining shapes and locations of the planar members to be arranged on the supporting substrate based respectively on shapes and locations of the identified areas.
It should be apparent that features relating to one aspect of the invention may also be applicable to the other aspects of the invention.
These and other aspects of the invention will be apparent from and elucidated with reference to the embodiments described hereinafter.
Embodiments of the invention are disclosed hereinafter with reference to the accompanying drawings, in which:
A tectonic origami device 100 (hereafter abbreviated as “device”), according to an embodiment, is shown in
The device 100 is configured to be transformable between a collapsed form (e.g. see
In this case, each planar member 104 takes the form of a plate, although it is not to be construed as limiting. Each plate may be made of cardboard, plastic, wood, a composite material, or any other suitable low costs material as will be appreciated. For this embodiment, each planar member 104 is formed using acrylic. Moreover, each planar member 104 has a polygonal shape, e.g. a triangle, a pentagon, or a toroid. In this case, the planar members 100 include first and second plurality of planar members 104a, 104b, wherein each of the first plurality of planar members 104a has a first polygonal shape (e.g. a triangle shape) and each of the second plurality of planar members 14b has a second polygonal shape (e.g. a square shape) which is different to the first polygonal shape. This should not be construed as limiting because in variant embodiments, it is possible for all the planar members 104 to have only a single type of polygonal shape, or more than two types of polygonal shapes.
Briefly, tectonic origami is an origami-inspired manufacturing technique for devising a functional design, where there is a plurality of hard plates (e.g. the planar members 104) arranged on a soft substrate (e.g. the supporting substrate 102) to form the design. Beneficially, this arrangement permits configuration of a design that is transformable between a collapsed form to change to a planar arrangement, and an assembled form to change into a rigid structure (i.e. an enclosure). The planar members 104 are arranged to be coincident in terms of layout on the supporting substrate 102, where the planar members 104 are purposefully segmented along predetermined planar subdivisions or “tectonic” divisions. Specifically, the arrangement of the tectonics divisions is what enables the design to be able to be foldable to become the rigid structure. Needless to say, this arrangement can flexibly be adapted to design any type and shape of specific “folded” structural volumes.
In this embodiment, the male members 204 are respectively formed only on the first plurality of planar members 104a which form the “roof” of the enclosure (i.e. top of the enclosure), when the device 100 is in the assembled form (e.g. see
Further, a way to actuate all the planar members 104 in one movement to enable transformation of the device 100 from the collapsed form to the assembled form is to provide four elastic cords 106 of equal length at each of the first plurality of planar members 104a. Without loss of generality, non-elastic cords, or rope-like cords may also be used in place of the elastic cords 106. Specifically, each cord 106 is (detachably or fixedly) coupled to each corresponding male member 104a. Hence, by pulling all four cords 106 in a single direction (e.g. pulling upwardly relative to a platform, on which the device 100 sits), the supporting substrate 102 and planar members 104 are collectively and concurrently drawn upwards, and consequently caused to close-up to form the enclosure due to the converging movement of the first plurality of planar members 104a towards one another as depicted in
Therefore, a method of operating the device 100 (of
Next,
Specifically, forming of the tectonic divisions on the planar element 300 is performed as illustrated in
To elaborate on determining characteristics of the planar members 104, it largely comprises: (1). based on the markings, identifying areas on the planar element 300 corresponding to surfaces providing the shape of the enclosure when the planar element 300 is formed into the enclosure; (2). providing the supporting substrate 102 as the planar element 300; and (3). determining shapes and locations/positions of the planar members 104 to be arranged on the supporting substrate 102 based respectively on shapes and locations of the identified areas.
An example of placing the planar members 104 over the tectonic divisions is illustrated in
In summary, the proposed device 100 is advantageous in able to attain substantial structural rigidity when assembled into the enclosure versus conventional solutions. Also, the device 100 may allow forming a variety of easy storage solutions with rapid deployment. The device 100 may find commercial markets in countries such as Singapore, United States, and Australia, and some envisaged useful applications of the device 100 include:
1. For usage as a commercial disposable gift bag that may easily be opened for accessing the interior. Using low costs material for the supporting substrate 102 and planar members 104, the disposable gift bag can be mass-produced at relatively low costs and can be of substantial use as a packing solution, due to the beneficial compact storage requirements offered by the device 100 and ease of assembly (in which only a single motion is required).
2. For usage as a backpack, a purse, or a laptop bag with high structural integrity, that offer very easy access to items stored inside (as compared to other existing hard-shell bags on the market). In this instance, the planar members 104 may be made of plastic, wood, or a durable composite material, while the supporting substrate 102 may (for example) be made of cloth from a heavy bag type canvas material. The planar members 104 may then either be attached to the supporting substrate 102 with rivets, stitching, or with an industrial adhesive (or some suitable combination of all techniques).
3. For usage in rescue operations (e.g. configuring the device 100 with appropriate dimensions to be used as deployable structures, such as tents), in aerospace applications (e.g. using the device 100 for development of a toroid for producing artificial gravity in space), or in toy designs or corporate gift designs (e.g. a variety of toys for children could be based on the disclosed concept of the proposed device 100).
4. For usage as deployable furniture such as forming from the collapsed form (i.e. deployed for convenient packing) into structures like a stool, which may be formed in one embodiment as a polygonal solid. Such an object may have the dual capacity to act as a storage device as well as a piece of furniture and could be easily collapsed from the assembled form into the collapsed form for easy transportation and relocation, when required.
Generally, the proposed device 100 provides a fundamentally new structural rigidity to origami-inspired structures and a ‘stand-alone’ capacity, which has not yet been demonstrated in conventional solutions.
While the invention has been illustrated and described in detail in the drawings and foregoing description, such illustration and description are to be considered illustrative or exemplary, and not restrictive; the invention is not limited to the disclosed embodiments. Other variations to the disclosed embodiments can be understood and effected by those skilled in the art in practising the claimed invention. For example, the supporting substrate 102 and planar members 104 may be appropriately configured with suitable shapes and sizes such that the enclosure formed may be of a variety of different shapes, e.g. as a dodecahedron 700 shown in
In other variant embodiments, some portions of the flexible supporting substrate 102 are not necessarily covered by the planar members 104, i.e. those portions are not covered up. There may also be some regions that are open in the assembled enclosure, and so include regions with only a single layer, between the planar members 104, consisting solely of the flexible supporting substrate 102, which advantageously allows the proposed device 100 to have a smoother transformation between the collapsed form and the assembled form.
Number | Date | Country | Kind |
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10201503609W | May 2015 | SG | national |
Filing Document | Filing Date | Country | Kind |
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PCT/SG2016/050209 | 5/6/2016 | WO | 00 |