The present invention will be understood more fully from the detailed description given hereinafter and from the accompanying drawings of the preferred embodiment of the present invention, which, however, should not be taken to be limitative to the invention, but are for explanation and understanding only.
The present invention will be discussed hereinafter in detail in terms of the preferred embodiment of a mechanical load bearing device according to the present invention with reference to the accompanying drawings. In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present invention. It will be obvious, however, to those skilled in the art that the present invention may be practiced without these specific details.
Each support 27 ideally has a wheel 21 attached to the bottom of each leg 27 to allow the mechanical load bearing device 10 to be moved. The wheels 21 also include a lock 28 to prevent the wheels 21 and subsequently the device 10 from moving when the locks 28 are engaged.
A lifting means 30 is mounted on the top end of the shaft 22 to a flat metal plate 23. The lifting means 30 may include a bottle jack 25 and an elongate extension means 31. The lifting means 30 provides the higher pressure required to repair a sagged ceiling. The high pressure required is significantly more than what known panel lifters and other similar devices used in the industry are capable of producing and therefore does not allow for the substitution of known panel lifters or other similar known devices to repair sagged ceilings. A further requirement for the lifting means 30 is that it must only have a short lift in order to lift a ceiling 50 which requires repositioning and repairing. The short lift is required as a ceiling will generally only sag a distance of 8 cm, once the plasterboard has set in this position it requires a short lift and a high pressure lift in order to repair the sagged ceiling. There is also the added advantage that by having only a short lift the load bearing device 10 and the lifting means 30 can be quickly retracted to enable the user to move on to further repairs and also provides the time saving factor for the overall job. Alternatively the bottle jack 25 may include a screw jack or a combination hydraulic/air jack to lift and repair the ceiling 50.
The bottle jack 25 is secured to the plate 23 by bolts (not shown) or similar securing devices. The bottle jack 25 has been modified so as to extend the operating mechanism 26, for example a handle to allow for one-handed operation. The bottle jack 25 also includes a pressure release valve (not shown) which is operated by mechanism 24. The mechanism 24 is in the shape of a t-bar, however, alternatively it could form any shape which allows the user to easily release the pressure in the bottle jack 25.
To mount the elongate extension means 31 to the bottle jack 25 a short housing spigot 60 is welded to the hydraulic shaft 29 of the bottle jack 25. It should also be noted that other methods of attaching the short housing spigot 60 to the bottle jack 25 and the hydraulic shaft 29 may be used such as a simple screw thread on the bottle jack 25 and a mating screw thread on the short housing spigot 60. The housing spigot 60 has an aperture 61, when the lower end of the elongate extension means 31 is placed over the spigot 60 the aperture 61 lines up with aperture 33 in the elongate extension means 31 and a bolt 34 is passed through both apertures 61, 33 to secure the elongate extension means 31 to the spigot 60. This allows the elongate extension means 31 to be easily disassembled from the bottle jack 25 for transport and storage.
At the upper end of the elongate extension means 31 a bolt hole 35 and fixing pin 32 enable the pressure plate assembly 40 to be inserted into the upper end of the elongate extension means 31 and secured by use of the fixing pin 32. The T-bar 41 has several height adjustment holes 42 which enable the user to vary the overall height of the mechanical load bearing device 10 for the repair of different ceiling 50 heights. It is also possible to incorporate different length T-bar assemblies 41 to vary the overall height of the mechanical load bearing device 10.
On the T-bar cross-member 43 a flat rectangular aluminium plate 44 is mounted to the T-bar cross member 43 by screws (not shown) which are countersunk into the aluminium plate 44 so that they do not appear above the surface of the aluminium plate 44. Alternatively the rectangular aluminium plate 44 can be attached to the T-bar cross-member 43 by any other suitable means, for example it may be welded. To reinforce the aluminium plate 44 the T-bar cross member 43 is preferably constructed from a open box channel which is fixed to the underside of the aluminium plate 44. The open box channel is used to strengthen the plate and provide for the distribution of weight over a greater cross-sectional area when the mechanical load bearing device 10 is used to push up a sagging ceiling 50.
The four corners of the aluminium plate 44 are rounded. The aluminium plate 44 is the flat member which comes into contact with the ceiling 50. The contacting portion of the plate 44 which comes into contact with the ceiling 50 is substantially planar so as it easily distributes the pressure across the portion of the ceiling 50 to be lifted and repaired. The aluminium plate 44 is sized so as to span three rafters which are 450 cm apart from the centre of each rafter to the centre of the next rafter.
To repair a sagging ceiling 50 the operator of the mechanical load bearing device 10 must first make an estimation of the height of the ceiling 50 to be repaired. The estimation is carried out by lifting the pressure plate assembly 40 manually until it is located just below the centre of the concave part 51 of the ceiling 50 to be repaired (see
A mechanical load bearing device 10 according to the present invention may also be used to repair or replace damaged cornices or install a new cornice to a ceiling 50 in a similar manner as described above. The device 10 allows the operator to repair and install long and heavy lengths of cornice without the need for another operator who would normally be required to install a standard ceiling cornice. It can be seen that the use of a mechanical load bearing device 10 according to the present invention will simplify the ease in which the task of repositioning a ceiling cornice is accomplished.
A mechanical load bearing device 10 according to the present invention may also be used to repair steel rafter ceilings were the distance between steel trusses is usually between 1.5 to 1.8 metres. To repair this type of ceiling more than one mechanical load bearing device 10 can be used with the two pressure plate assemblies 40 placed side by side to cover the span of the steel trusses.
Although the present invention has been illustrated and described with respect to exemplary embodiment thereof, it should be understood by those skilled in the art that the foregoing and various other changes, omission and additions may be made therein and thereto, without departing from the spirit and scope of the present invention. Therefore, the present invention should not be understood as limited to the specific embodiment set out above but to include all possible embodiments which can be embodied within a scope encompassed and equivalent thereof with respect to the feature set out in the appended claims.
Number | Date | Country | Kind |
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2006904835 | Sep 2006 | AU | national |