See Application Data Sheet.
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The present invention relates to a door and method of forming a door.
Door construction has remained the same for many years, being a timber or Medium Density Fibreboard (MDF) frame, with a honey comb insert material that is covered with a timber veneer or MDF panel suitable for staining or painting. In recent years, pre-finished material has been used for door surfaces. However, by way of construction, the door ends are exposed in the raw state that require painting.
By way of installation, all doors have only three visible surfaces, being an internal main face of the door (facing an inside of the room), an external main face (facing an outside of the room) and the latched side face. The top face, bottom face and hinged face of the door are not readily visible on an installed door.
The present invention seeks to overcome or substantially ameliorate at least some of the deficiencies of the prior art, or to at least provide an alternative.
It is to be understood that, if any prior art information is referred to herein, such reference does not constitute an admission that the information forms part of the common general knowledge in the art, in Australia or any other country.
According to a first aspect, the present invention provides a door comprising a single panel folded to form a latch face and first and second main faces of the door.
In a preferred embodiment, the panel further comprises edge tabs folded to form upper, lower and hinge faces of the door.
In another preferred embodiment, the panel is substantially rigid and comprises two parallel grooves formed into an inner surface thereof, the grooves being spaced by a distance equal to the width of the latch face and wherein sections of the panel at opposing sides of the latch face form the main faces of the door.
In another preferred embodiment, the panel comprises additional grooves formed in the inner surface along lines parallel to and inwardly spaced from edges of the panel to form side, upper and lower edge tabs which are folded towards each other to form the hinge, upper and lower faces of the door respectively.
In another preferred embodiment, the latch face comprises upper and lower triangular tabs, and the upper and lower tabs of the main sections are cut at an angle such that adjacent edge tabs are substantially contiguous when folded.
In another preferred embodiment, the panel is a composite panel comprising an inner metal sheet, an outer metal sheet, and a plastics core material between the metal sheets.
In another preferred embodiment, the core material is a thermosetting plastics which substantially does not melt when heated.
In another preferred embodiment, the door further comprises infill material disposed within the folded panel.
In another preferred embodiment, the door further comprises a frame disposed within the folded panel.
In another preferred embodiment, the infill material is fireproof material.
In another preferred embodiment, the infill material is inserted into the door in liquid form that expands and solidifies as foam.
In another preferred embodiment, the infill material is liquid polyurethane or polyethylene that sets solid.
In another preferred embodiment, the door further comprises at least one hinge, the hinge comprising a door mount section attached to the side tabs forming the hinge face.
In another preferred embodiment, the panel is a flexible wrap.
In another preferred embodiment, the panel is a metal or plastics sheet or a combination thereof.
In another aspect, the present invention provides a method of forming a door using a single panel, the method comprising folding the panel to form a latch face and first and second main faces of the door.
In another aspect, the present invention provides a method of forming a door, the method comprising
In a preferred embodiment, the panel is a composite panel comprising an inner metal sheet, an outer metal sheet with a plastics core material therebetween, the forming step comprising cutting the groove into the inner metal sheet and partly into the core material.
In another preferred embodiment, the method further comprises:
In another preferred embodiment, the method further comprises:
In another preferred embodiment, the method further comprises inserting a frame into the folded panel.
In another preferred embodiment, the method further comprises inserting an infill material into the folded panel, the infill material being inserted into the door in liquid form and expanding and solidifying as foam within the door.
In another preferred embodiment, the method further comprises mounting at least one hinge to the door, the hinge comprising a door mount section which is attached to the side tabs.
In another aspect, the present invention provides a method of forming a composite panel, the method comprising
In a preferred embodiment, the method further comprises further curing of the thermosetting plastics core material to harden the thermosetting plastics core material.
In another preferred embodiment, the method further comprises the intermediate step of folding the partially cured thermosetting plastic core material and the inner and outer sheets into a required shape prior to the further curing step.
In another preferred embodiment, the further curing step is performed by at least one of heat, radiation or a combination thereof.
In another preferred embodiment, the metal sheets are aluminium.
In another aspect, the present invention provides a door comprising a single panel folded to form a hinge face and first and second main faces of the door.
In a preferred embodiment, the panel further comprises edge tabs folded to form upper, lower and latch faces of the door.
In another preferred embodiment, the latch face comprises a double rebate.
In another preferred embodiment, the panel is substantially rigid and comprises two parallel grooves formed into an inner surface thereof, the grooves being spaced by a distance equal to the width of the hinge face and wherein sections of the panel at opposing sides of the hinge face form the main faces of the door.
In another preferred embodiment, the panel comprises additional grooves formed in the inner surface along lines parallel to and inwardly spaced from edges of the panel to form side, upper and lower edge tabs which are folded towards each other to form the hinge, upper and lower faces of the door respectively.
In another preferred embodiment, one of the main faces is wider than the other, the wider main face comprising two adjacent edge tabs.
Other aspects of the invention are also disclosed.
Notwithstanding any other forms which may fall within the scope of the present invention, preferred embodiments of the present invention will now be described, by way of examples only, with reference to the accompanying drawings.
It should be noted in the following description that like or the same reference numerals in different embodiments denote the same or similar features.
The panel 20 comprises an upper edge 61, a lower edge 62, a first side edge 63 and a second side edge 64. As shown in
As shown in
Additional V-shaped grooves 24c are cut into the inner sheet 65 and partly into the core 67 along lines parallel to and inwardly spaced from the edges 61 to 64, forming edge tabs 36. As shown in
As shown in
The grooves 24a and 24b divide the panel 20 into a first main section 52, a second main section 54 and a latch section 53. The latch section 53 is formed between the grooves 24a and 24b and the latch section 53 is dimensioned to have a width corresponding to the thickness of the door 100 in use (i.e. the distance between the grooves 24a and 24b corresponds to the door thickness). The first and second main sections 52 and 54 are disposed on opposing sides of the latch section 53. Both the first and second main sections 52 and 54 are generally rectangular and dimensioned to substantially cover the intended doorway. The first and second main sections 52 and 54 extend from a respective one of the grooves 24a and 24b to the perimeter grooves 24c. The external surfaces of the main sections 52 and 54 in use will define the internal and external main faces of the door 100.
The cutout portions 22a form upper tabs 36a, side tabs 36b, and lower tabs 36c. The cutout portions 22b form triangular upper tabs 36d at the upper and lower ends of the latch section 53.
The panel 20 comprises spaced pairs of hinge mount apertures 28 formed adjacent the side edges 63 and 64, the apertures 28 being disposed in the side tabs 36b. The panel 20 further comprises closely spaced latch mount apertures 26 formed at a mid-section of the panel 20, with two rounded apertures 26 formed in the main sections 52 and 54 and a rectangular aperture 26 formed in the latch section 53. A latch plate 27 is mounted to the outer sheet 66 aligned with the aperture 26 in the latch section 53. The latch plate can be recessed in the panel 20 as shown in
As shown in
As shown in
As shown in
Once the frame 40 and the infill material 39 are disposed within the folded panel 20, the panel 20 can be fully folded, as shown in
The hinge 90 provides the advantage in that it is not recess mounted and is symmetrical. This allows the orientation of the hinge 90 to be reversed on the door 100 for providing a left or right side opening door as desired.
The door 100 maintains simplicity in construction, using a single panel of composite aluminium, cut to the required size. Grooves 24 are carved at the required positions and dimensions, and folded at the top, bottom and hinged face of the door. The door 100 can be considered as completely pre-finished which requires no painting, and can be completely pre-assembled (hinged and latched) offsite and delivered on site as a working unit, ready for simple installation.
The folded sections meet at the centre of the top, bottom and hinged sides of the door are screwed and glued to the door frame 40. The depth of the hinges 90 covers the side tabs 36b hinged face, and locks the sections together.
The door frame 40 can be made from Aluminium, Medium Density Fibreboard (MDF) or High Density Plastic (HDP) to suit specific applications. Using varying insulation materials 39 between the door frame 40, the door 100 would be suitable as fire doors (fire rated), acoustic doors (sound proof) or thermal doors (for use as external doors).
The use of composite aluminium panels provides pre-finished doors of the highest quality that are suitable for many applications. The doors 100 is also suitable to have glass insert panels, and as such can be used for feature doors and front entry doors. The glass panels in such an embodiment will be mounted to the main panels and the material 39 can be omitted to have a hollow cavity within the frame 40 or the material 39 can be a transparent plastics block.
The present invention provides an improvement on the conventional door construction, and uses composite aluminium panels that are cut and folded to form a substantially seamless door. The present invention allows for door units to be completely pre-finished and pre-assembled in the factory with greater accuracy, whilst providing for easy onsite installation.
There are many possible alternative embodiments to the present invention.
The present invention provides a means for completely pre-finished door units to be manufactured, without any visible construction joints, resulting in a seamless door, having the appearance of a solid mass, and the hinge face of the door being partially hidden by the door jamb.
The present embodiment provides a door that is formed entirely out of a single panel of composite aluminium, having no visible joins in the external faces. The composite aluminium panel is cut and grooved in such a way that the joins are located only at the top, bottom and hinged sides of the door, providing the latched side with a seamless face. The composite aluminium panel provides a skin over a standard type door frame construction, with the door frame material varying from Aluminium, Medium Density Fibreboard (MDF) or High Density Plastic (HDP) to suit specific applications. Using varying insulation materials between the door frame, the high performance doors would be suitable as fire doors (fire rated), acoustic doors (sound proof) and thermal doors (external doors). The use composite aluminium panels in this innovative way, provides pre-finished doors of the highest quality that are suitable for many applications.
Whilst preferred embodiments of the present invention have been described, it will be apparent to skilled persons that modifications can be made to the embodiments described.
The tabs 36 can also be configured differently. For example, only one of the main sections 52 and 54 can have a tab 36 which extends across the width of the door. In this embodiment, the other main section does not require a tab 36.
The panel can alternatively be made from an aluminium or other metal sheet, and does not have to be a composite panel. In such an embodiment, folding grooves can be formed in the panel surface. As a further alternative, the panel can be made from plastics material, either bent or folded into shape, while cold or partly heated.
In another possible embodiment, the panel can be a flexible film such as an adhesive vinyl wrap which is folded over a door to provide finished latch and main faces to the door.
The preferred embodiment provides the following advantages:
In another aspect, the present invention provides a method for forming an aluminium composite panel. The method involves multi stage curing of thermosetting plastic for manufacture of fire proof aluminium composite panels.
In order to be used as a core material for manufacture of aluminium composite panels, the thermosetting plastic needs to be partially cured so that it is pliable and can be extruded into a continuous sheet.
The partially cured thermosetting core allows the panel to be folded and bent into required shapes.
Upon completion of the folding and bending, the partially cured thermosetting plastic core composite aluminium panel can be further cured to set the thermoplastic core hard.
The further curing of the thermosetting plastic aluminium composite panels can be achieved by means of heat, radiation or combination of both thereof to the desired hardness.
The use of a multi stage curing of thermosetting plastic as a core in manufacture of aluminium composite panel now gives opportunity for panels to be used as fire rated doors, which retain the structural integrity when exposed to fire.
Aluminium composite panels manufactured with a thermosetting plastic core provides a perfect solution as it becomes harder when heat is applied.
The behaviour of the thermosetting plastic is similar to clay in that the clay is pliable and able to be shaped, and sets hard when heat is applied.
The thermosetting plastic in a raw state is essentially is a resin which is too sticky and runny to be used as a core material for manufacture of aluminium composite panels.
Since the aluminium composite panel produced is more rigid, it is possible to make the composite panel without an inner skin of aluminium i.e. two layers only being the outer aluminium panel and the thermosetting plastic. This is currently not possible in other aluminium composite panels as the plastic core used in such previous panels is too soft.
The thermoset aluminium composite panel can be used for all current fabrications with the option of tertiary curing, giving the ability to mould panels to shape. This can eliminate the need for fireproof inserts in wall “tray” panel.
Stage 2 curing after extrusion is used to mimic the viscosity of the current PE (polyethelene) core. The multi-stage curing is to allow the aluminium composite panel material to be produced in the existing machinery with little or no modifications. Curing after fabrication produces a more durable material with high modulus and resistant to damage especially on the folded edges.
It is also possible to add particles of recycled thermoplastic to increase the viscosity at stage 1 as a “green” solution. Utilizing the thermoset plastic provides a much stronger aluminium composite panel which gets harder when subjected to heat, which is ideal for a fire door skin. The hinge has been designed to be reversible so that the door can be made a right or left handed door by simply unscrewing the hinge and reversing it. No cutting or drilling is needed. The door and hinge have matching symmetry.
The hinge is also used as a method of locating, retaining and fixing our door frame section within the door skin (panel) and locking the skin (folded panel) together.
Referring to
As shown in
Step 501 shows placement of the composite panel face up onto a CNC Punch Press machine.
Step 502 shows punching of all cutout shapes (hinge holes, latch holes, tab cut-outs), engraving of sheet for the latch plate, and cutting the V-shaped folding grooves in the panel. The corners and Top/Bottom centre sheet notched (punched)
Step 503 shows the panel is moved to an inverter where the panel is flipped and moves face down to a folding table and the folding sequence is commenced.
Step 504 shows insertion of the frame into the partly folded panel and pouring of the foam core. The final fold 6 is then made to close the door.
Step 505 shows the attachment of the hinges to lock the folded panel and attachment of the latch plate into the latch plate recess.
Step 506 shows the completed door is removed and packaged. The only manual work presently needed is the screwing of the hinges and removing the folded door from the folding table.
Number | Date | Country | Kind |
---|---|---|---|
2013100831 | Jun 2013 | AU | national |
Filing Document | Filing Date | Country | Kind |
---|---|---|---|
PCT/AU2014/000623 | 6/14/2014 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2014/197945 | 12/18/2014 | WO | A |
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