NL1020353C2 - Bricklaying aid, comprises support structure releasably securable to alignment device - Google Patents

Abstract

At least one support structure (3) is provided with a coupling which can be releasably secured to a counter-coupling forming part of an alignment device (8). The relative positions of the support structure and alignment device are adjustable. An Independent claim is also included for a method for use of the bricklaying aid (1), by locating the support structure in the desired position, connecting the alignment device to the support structure so that it is positioned close to the object (2) to be faced with bricks, using the alignment device to face the lower part of the object with bricks and removing the alignment device from the support structure.

Description

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Device for guiding the bricklaying of objects and method for applying such a method

The invention relates to a device for guiding the bricklaying of objects. The invention also relates to a method for applying such a method.

The bricklaying of some objects, such as columnar objects or a (decorative) oblique finish of objects, is usually time-consuming. If a columnar object, such as, for example, a penant, has to be bricked, a framework (frame) must first be constructed with great accuracy. This setting must be set in a secure manner, such that the desired exact position of the pin to be built in the setting is fixed. For an average person skilled in the art, building and adjusting the setting work usually takes approximately 90 minutes. The adjusting system must be built up separately for each pen from the ground, which is usually accompanied by contamination of at least a part of the adjusting system. It is generally also difficult to adjust the setting on an damaged surface. Moreover, the frame is generally relatively vulnerable, so that damage can occur relatively quickly. If the columnar object forms a chimney, then the chimney is generally prefabricated at an (ex-situ) location, after which the chimney is transported to the construction site. Producing chimneys elsewhere and also transporting them is cumbersome and also expensive. The above-mentioned oblique finishing of objects is also very time-consuming since building blocks used during bricklaying are often used at less stable positions during bricklaying, as a result of which pressing of the building blocks and partly curing used spoil is generally required. Masonizing such an oblique finish generally also requires a complex and maintenance-requiring framework as already described above.

The invention has for its object to provide a device for guiding the bricking of objects, with which objects that are relatively difficult to brick can be bricked in little time-consuming manner.

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To this end, the invention provides a device of the type mentioned in the preamble, comprising at least one support structure provided with coupling means, which coupling means are adapted for releasable coupling with counter-coupling means forming part of an alignment element, wherein the mutual position between the support structure and the alignment element is adjustable. An advantage of the device according to the invention is that it functions as a preformed frame that can be designed and placed relatively firmly, regardless of the substrate. The alignment element is thereby used as a guide or reference for a layered part of the object to be laid. Because the mutual position of the support structure and the alignment element is adjustable, the alignment element can be positioned at a desired position depending on the object to be bricked in. In this case, the alignment element can easily be repositioned after every brick layer. When brick-like objects are bricked in, the alignment element can (during normal operating condition) be positioned above a layer or object to be bricked. The alignment element, on the other hand, can also serve as a supporting element for an oblique finish of an object to be bricked in. The device has the additional advantage that the objects to be bricked can be bricked on site, as a result of which relatively expensive and laborious transport is no longer necessary. The coupling means can be designed, for example, if receiving spaces (openings) can engage hook-shaped counter-coupling means.

The alignment element preferably spans a two-dimensional plane. The surface can form a reference surface for a layer of a columnar object to be laid. In a particularly preferred embodiment, the surface extends at least substantially horizontally after coupling to the support structure. In that case, if the stretched surface is considered to be the reference surface, a vertical column can be laid.

In a preferred embodiment, the mutual position of the support structure and the alignment element is discreetly adjustable. Thus, a sequential movement of the alignment element with respect to the support structure can take place over a constant distance. In an embodiment variant, the mutual position between the support structure and the alignment element is continuously adjustable. The support structure is preferably formed by a main structure and coupling means detachably connected to the main structure. The supporting structure and thus the device obtain, by means of the aforementioned measure, an additional adaptive capacity to adapt to the conditions of the objects to be bricked in. The coupling means can for instance be adjusted on the basis of the dimensions of the building blocks to be used for the object to be bricked.

5

In another preferred embodiment, the support structure is provided with adjusting means. In case a base supporting the support structure is not completely flat or is chamfered, the support structure can be positioned in any desired position by adjusting the adjusting means. The setting of the support structure is relevant, since this determines the mutual orientation between the alignment element connected to the support structure and the object to be bricked. At least a part of the adjusting means is preferably formed by a stabilizing member. The stabilizing member can be in the form of a stabilizing rod which is connected at one end to the fixed world and at another end to the support structure. By making the dimensioning of the stabilizing member adjustable, the support structure - in particular the enclosed angle between the support structure and the fixed world - can be adjusted. In addition, the stabilizing member generally has a stabilizing effect in case an external load is imposed on the device, whereby the mutual orientation between the support structure and the fixed world can be maintained up to a certain maximum. In a particularly preferred embodiment, at least a part of the adjusting means is formed by at least one adjusting screw. The set screw is positioned such that it is adapted to place at least a substantial part of the support structure in a desired position relative to the fixed world. In a particularly preferred embodiment, the support structure comprises a plurality of set screws 25 in order to be able to perform adjustment of the support structure in an optimum manner. The check whether the support structure has been placed in a desired position can be done with the aid of conventional means, such as a spirit level.

In yet another preferred embodiment, an outer circumference of the alignment element 30 at least substantially corresponds to at least a part of an outer circumference of the object to be bricked. Thus, by taking the outer circumference of the alignment element as a reference, an object, or at least a part thereof, can be bricked into a shape already defined in advance - defined by the alignment element. The 4 O r'4 1 U: '-1

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Making separate provisions, such as a conventional setting in which the shape of the object is determined, is therefore no longer necessary.

The alignment element is preferably adapted for coupling with at least one separate shape-determining element. In that case, the alignment element also has a supporting function for supporting the shape-determining element. The shape-determining element is shape-determining for the shape of the object to be bricked in and serves, in accordance with the alignment element, as a linkable (modular) second alignment element. Due to the presence of a plurality of shape-determining elements, which can all be detachably coupled to the alignment element, the device obtains a relatively high adaptive power. The coupling between the alignment element and the shape-determining element usually takes place in a known manner.

The support structure is preferably at least substantially composed of a frame.

The advantage of a frame is that it is possible to construct relatively spatially with relatively little material. Manufacturing a support structure with relatively little material generally benefits the manufacturing and transport costs of the support structure. In addition, the brickwork is easily accessible when applying an (open) frame. In a particularly preferred embodiment the frame is of modular construction. The advantage of a modularly constructed support structure is that it is variable in size and can be placed or removed in parts.

In yet another preferred embodiment, the angle enclosed by the support structure and the alignment element is adjustable. Therefore, a fine adjustment of the alignment element can take place if the support structure is (partially) deformed or damaged, or if the support structure is set in an ideal manner. In addition to the fine-tuning advantage, the angle to be set that is enclosed by the alignment element and the support structure can also be advantageous during work on unusual or uncomfortable surfaces, such as pitched roofs, etc.

30

The invention also relates to a method for applying such a device, comprising the steps of: A) placing the support structure in a desired position, B) coupling the alignment element with the support structure, such that the alignment element is near the object to be bricked in is positioned, C)! I, 5 bricklaying a layered part of the object with the aid of the positioned alignment element, and D) disconnecting the alignment element from the support structure. Positioning the alignment element close to the object to be bricked can be done in several ways.

5

In a first preferred embodiment the coupling of the alignment element with the supporting structure according to processing step B) takes place such that the layered part to be bricked according to processing step C) will at least substantially be situated between the alignment element and the fixed world. The layered part of the object to be bricked is then positioned between the solid world bearing the layered part and the alignment element. Therefore, before processing step C) can be carried out, there must be a sufficient distance between the alignment element and the solid world in order to be able to bricklay the layered part to be bricked. After completion of the bricklaying part of the layered part, the alignment element can be positioned at a distance from the layered part, but can also engage on the layered part.

In a second preferred embodiment the coupling of the alignment element with the supporting structure according to processing step B) takes place such that the layered part to be bricked according to processing step C) will at least substantially be supported by the alignment element. The alignment element thus obtains a supporting function for the layered part of the object to be bricked in. After the layered part has been positioned sufficiently stably, for example after partially hardening used mortar, the alignment element can be removed and applied elsewhere. 1 2 3 4 5 6

In a preferred embodiment, the processing steps B) -D) are repeated at least once 2 for bricking at least one additional layered part of the object to be bricked. An object, or at least a part thereof, can thus be built up in a desired form in a simple and relatively fast manner. In a particular preferred embodiment, the mutual orientation of the support structure and the alignment element for repeating the processing steps B) -D) is changed. An object can thus be built up relatively quickly, in each case by adjusting the alignment element relative to the support structure, in a desired geometry.

6

The invention will be elucidated with reference to the non-limitative exemplary embodiment shown in the following figures. Herein: figure 1 shows a perspective view of a first embodiment of the device according to the invention and a part of a penant, figure 2 shows a fragmentary view of the first preferred embodiment according to figure 1, figure 3 shows a fragmentary view of a second embodiment variant of the device according to the invention, figure 4 shows a perspective view of an application possibility of the device 10 according to figures 1 and 2 or figure 3 and a part of a chimney, figure 5 shows a perspective view of a third embodiment of the device according to the invention invention and a part of a semicircular column, figure 6 shows another possibility of application of the device according to the invention, and figure 7 shows a perspective view of a fourth embodiment of the device according to the invention and a wall.

Figure 1 shows a perspective view of a first embodiment of the device 1 according to the invention and a part of a masonry pin 2. The device 1 comprises a support frame 3 which is connected at one end 4 to set screws 5, and at an opposite end 6 is connected to a stabilizing rod 7 connected to the fixed world. The supporting frame 3 is also detachably connected to an alignment element 8. The alignment element 8 serves - as already described above - as a reference for a brickwork part of the pin 2 Low. After completion of the bricklaying of this layer, the alignment element 8 is generally disconnected from the support frame 3 and again coupled to the support frame 3, closer to the end 6 connected to the stabilizing rod 7, the shortest distance between the two positions at least substantially corresponds to the thickness of a layer to be bricked. It is thus possible in a simple manner to brick-layer a penant 2 without first of all building up a complex, maintenance-sensitive framework. The supporting frame 3 can be set in part by means of set screws 5. The remaining setting of the supporting frame 3 is initially effected by displacing a coupling element 9 connected to the stabilizing rod 7 (and the fixed world). The fine adjustment is furthermore carried out by ΐ <. Modification of the length of the stabilizing rod 7, for example by an existing screw connection 10. In this embodiment, the support frame 3 is pivotally connected to a support element 11 for support on the fixed world. the supporting frame are fixed by the stabilizing rod 7, the orientation of the supporting frame 3 relative to the fixed world.

Figure 2 shows an exploded view of the first preferred embodiment according to Figure 1. The support frame 3 is made up of two at least substantially parallel uprights 12, which uprights 12 are mutually connected by a plurality of cross bars 13. The uprights 12 are provided with a plurality of receiving spaces 14 for receiving coupling means 15 forming part of the alignment element 8. The distance between two receiving spaces 14, whether or not adjacent to each other, at least substantially corresponds to the thickness of a layer to be bricked of the now not shown penant 6. The alignment element 8 is also provided with two handles 16 to facilitate mutual displacement of the alignment element 8 and the supporting frame 3.

Figure 3 shows an exploded view of a second embodiment of the device 17 according to the invention. The device 17 shown in Figure 3 closely resembles the device 1 shown in Figure 1 and Figure 2 with the difference that a supporting frame 18 forming part of the device 17 is uninterrupted and is thus not provided with receiving spaces for an alignment element 19 part first coupling means 20. The supporting frame 18 is now provided with second coupling means 21 for coupling the supporting frame 18 with two strips 22 provided with receiving spaces 23 for receiving the first coupling means 20. Depending on the object to be bricked, and in particular on the thickness of a layer of the object to be bricked in, the strips 22 can be replaced by other strips provided with receiving spaces of which the distance between two adjacent receiving spaces differs.

30

Figure 4 shows a perspective view of a possible application of the device 1.17 according to figures 1 and 2 or figure 3 and a part of a chimney 24. In the figure 4 shown, the stabilizing rod 7 is connected to a ridge beam 25 of a roof 26 of a house 27. The ridge beam 25 should generally run at least substantially 8 horizontally, so that the ridge beam 24 can be used as a reference when setting the device 1.17. A chimney 24 can thus also be bricked on site in a relatively inexpensive and simple manner. The supporting frame 3,18 rests on the roof 26 at an end remote from the stabilizing rod 7.

5

Figure 5 shows a perspective view of a third embodiment of the device 28 according to the invention and a part of a semicircular column 29. The device 28 is provided with a support frame 30 which is connected at one end to adjusting means and is connected to an opposite end connected to a stabilizing rod 31 connected to the fixed world. The supporting frame 30 is furthermore detachably connected to an alignment element 32, wherein the alignment element is provided with a coupling element for releasable coupling with a circle segment-shaped element 33. Thus, in addition to a penant and a pin chimney also other columnar objects are bricked using the device 28. The alignment element 32 can thereby be coupled to an element of any desired desired shape, such that any geometry of an object to be bricked can be made by means of the device 28 according to the invention manufactured.

Figure 6 shows the device 1,17 as already shown in Figures 1 and 2 or in Figure 3, wherein the alignment element 8,19 supports at least a part of a decorative layer 35 to be bricked onto a wall 34. The alignment element 8, 19 can thus also function as an (aligned) supporting element and generally considerably facilitates finishing of relatively difficult brickwork. Further advantages of the device have already been described above.

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Figure 7 shows a perspective view of a fourth embodiment of the device 36 according to the invention and a wall 37. The device 36 is placed over a part of the wall 37 and is provided with two pairs of uprights 38, 39 connected to each other. Both pairs uprights 38, 39 form a support structure for alignment elements, of which only one alignment element 40 connected to the first pair of uprights 38 is shown. The directional element 40 is hereby releasably connected to the uprights 38, wherein the mutual orientation between the uprights 38 and the alignment element 40 is adjustable. A columnar object, such as, for example, a pivot, can thus be bricked around a part of the wall 37 that has already been bricked. Since two alignment elements positioned on either side of the wall 37 (of which only one alignment element 40 is visible in Figure 4) can be used simultaneously, the pin can be built up on two sides of the wall 37 at the same time. Such a device 36 can result in a saving of time 5 since on several sides of an object that has already been bricked, such as wall 37, can be bricked at the same time. 1 f:; O

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Claims (18)

1. Device for guiding the bricklaying of objects, comprising at least one support structure provided with coupling means, which coupling means are adapted for releasable coupling with counter-coupling means forming part of an alignment element, wherein the mutual position between the support structure and the alignment element is adjustable is. Device as claimed in claim 1, characterized in that the alignment element tensiones a surface 10. Device as claimed in claim 2, characterized in that the surface extends at least substantially horizontally after coupling to the support structure. Device as claimed in any of the foregoing claims, characterized in that the mutual position of the support structure and the alignment element can be adjusted discretely. 5. Device as claimed in any of the foregoing claims, characterized in that the support structure is formed by a main structure and coupling means detachably connected to the main structure. Device as claimed in any of the foregoing claims, characterized in that the support structure is provided with adjusting means. 25 Device according to claim 6, characterized in that at least a part of the adjusting means is formed by a stabilizing member. Device as claimed in claim 6 or 7, characterized in that at least a part of the adjusting means is formed by at least one adjusting screw. Device as claimed in any of the foregoing claims, characterized in that an outer circumference of the alignment element at least substantially corresponds to at least a part of an outer circumference of the object to be bricked in. Device as claimed in any of the foregoing claims, characterized in that the alignment element is adapted for coupling with at least one separate shape-determining element. 5 Device as claimed in any of the foregoing claims, characterized in that the support structure is at least substantially composed of a frame. 12. Device as claimed in claim 11, characterized in that the frame is of modular construction. Device as claimed in any of the foregoing claims, characterized in that the angle enclosed by the support structure and the alignment element is adjustable. A method for applying a device according to any one of claims 1-13, comprising the steps of: A) placing the support structure in a desired position, B) coupling the alignment element with the support structure in such a way that the alignment element is near the object to be bricked in is positioned, C) bricking a layered part of the object with the aid of the positioned alignment element, and D) disconnecting the alignment element from the support structure. 15. Method as claimed in claim 14, characterized in that the alignment of the alignment element with the support structure according to processing step B) takes place such that the layered part to be bricked according to processing step C) will be at least substantially between the alignment element and the fixed world. 16. Method according to claim 15, characterized in that the alignment of the alignment element with the support structure according to processing step B) takes place such that the layered part to be bricked according to processing step C) will at least substantially be supported by the alignment element. «, * A method according to any one of claims 14-16, characterized in that the processing steps B) -D) are repeated at least once for bricking at least one additional layered part of the object to be bricked. Method according to claim 17, characterized in that the mutual orientation of the support structure and the alignment element is changed for repeating the processing steps B) -D).