EA037062B1 - Lintel - Google Patents

Abstract

A lintel 100 is disclosed herein. In a described embodiment, the lintel 100 comprises an elongate lintel body 106 including an elongate base member 110 and side legs 112, 114 extending from the elongate base to define an elongate channel therebetween. The elongate body 106 further includes a load bearing element in the form of lip members 118, 120 projecting from respective side legs 112, 114 for supporting masonry elements 206, end portions 102, 104 at ends of the lintel body for engaging with the support structures 202, 204, and a plurality of protrusions 122 disposed at least at the end portions.

Description

(31) 10201607534S (56) GB-A-2226346 (32) 2016.09.09 US-B1-6560938 GB-A-2071725 (33) SG WO-A1-2007086811 (43) 2019.08.30 (86) PCT / SG2017 / 050425 (87) WO 2018/048347 2018.03.15 (71) (73) Applicant and patentee: 2ELMS PTE LTD (SG) (72) Inventor: Ng Wee Beng (SG), Wyatt Gary Donald (AU) (74) Representative: Medvedev V.N. (RU) US-A1-20020121068

037062 B1 (57) The invention discloses a jumper (100). In the described embodiment, the web (100) comprises an elongated web body (106) including an elongated base member (PO) and side supports (112, 114) extending from the elongated base to define an elongated channel therebetween. The elongated body (106) further includes a load bearing member in the form of edge members (118, 120) protruding from respective side supports (112, 114) to support the masonry members (206), end portions (102, 104) at the ends of the body webs for engaging with supporting structures (202, 204) and a plurality of protrusions (122) located at least at the end portions.

037062 Bl

Prior art

The technical field to which the invention relates

The invention relates to a jumper.

A typical bridged lintel contains a horizontal base with vertical lateral supports along both sides of the horizontal base. The supported masonry is placed in the channel, i.e. between side supports and on a horizontal base. However, this arrangement is structurally ineffective.

Thus, it is desirable to provide a bridge that solves at least one of the disadvantages of the prior art and / or provides users with a practical choice.

The essence of the invention

In a first aspect, a web is provided to bridge an opening defined by the supporting structures, the web comprises an elongated web body including an elongated base member; side supports extending from the elongated base to define an elongated channel between them; a load bearing member projecting from at least one of the side supports to support the masonry members; end portions at the ends of the bulkhead body for engaging with supporting structures; and a plurality of protrusions located at least at the end portions.

The described embodiment is capable of reinforcing the web in view of the projections. Moreover, the load bearing member is capable of supporting the masonry elements, and thus the masonry is not required to fill the channel, resulting in material savings.

Preferably, the projections can be spaced apart from each other and are located along the length of the body of the bridge. Some of the plurality of projections may be located on the base member and others on the side supports.

Preferably, each of the projections may be elongated and may have a longitudinal axis of the projection that intersects the longitudinal axis of the body of the web. Preferably, each of the projections may be located inwardly towards the channel.

Preferably, the load bearing member may include edge members projecting from respective edges of the side supports and along the longitudinal axis of the channel, the edge members being configured to support the masonry members.

The web may include a plurality of perforations, and the plurality of perforations may alternate with corresponding one of the plurality of projections. The perforations can be circular or other shapes.

Other aspects may relate to the method for making the lintel of the first aspect (eg, forming the lintel protrusions by stamping) or constructing a hand-made wall using the lintel of the first aspect.

It should be understood that features related to one aspect may also refer to other aspects.

Brief Description of Drawings

Exemplary embodiments will now be described with reference to the accompanying drawings, in which:

fig. 1 is a simplified view of a web bridging an opening in accordance with a first embodiment;

fig. 2 is an enlarged perspective view of part A of FIG. 1 to show the bulkhead section in more detail;

fig. 3 is a perspective view of the bulkhead section of FIG. 2, not showing masonry;

fig. 4 is a cross-sectional view of the bridge of FIG. 3 in the B-B direction and FIG. 5 is a partial longitudinal sectional view of the bulkhead of FIG. 3 towards C.

Detailed description of the preferred embodiment

FIG. 1 shows a lintel 100 in accordance with a preferred embodiment for covering an opening 200. The lintel 100 has end portions 102, 104 that are supported by supporting structures 202, 204 defining the opening 200. As can be understood, the lintel 100 is positioned to receive the load 206 on top of the opening 200, and, in this embodiment, the load 206 and the supporting structures 202, 204 are formed from masonry such as bricks, concrete blocks, building stones, etc.

FIG. 2 is an enlarged view of part A of FIG. 1 to show the bulkhead section 100 in more detail, and FIG. 3 is a perspective view of a section of FIG. 2, not showing supporting structures. FIG. 4 is a cross-sectional view of the bridge of FIG. 3 in the B-B direction, while FIG. 5 is a partial longitudinal sectional view of the web 100 in the direction C of FIG. 3.

Bridge 100 is usually pre-fabricated and preferably made of steel or other metal. The web 100 comprises an elongated web body 106 having a longitudinal

- 1 037062 axis 108 that overlaps the opening 200 and the bulkhead body 106 includes an elongated base member 110 that is generally flat. The bulkhead body 106 further includes side supports 112, 114 projecting vertically along respective sides of the base member 110 to define a generally U-shaped channel 116 (see FIG. 4).

The web 100 further includes a load bearing member for supporting masonry, and the load bearing member is positioned to protrude from at least one of the side supports 112, 114. In this embodiment, the load bearing member includes edge members 118, 120 projecting inwardly and towards each other approximately at right angles to the side supports 112, 114. Each of the opposing edge elements 118, 120 has a width W of about 10 mm.

The dam 100 further comprises a plurality of protrusions 122 for strengthening or strengthening the structural strength of the body 106 of the dam. The protrusions 122 are formed on the bulkhead body 106 and are equally spaced along the longitudinal axis 108 of the bulkhead body 106, and the center-to-center distance between adjacent protrusions is about 30 mm. Projections 122 are formed on base member 110 as well as side supports 112, 114 to form groups of projections, each group 122a having one projection 122 on each of base members 110 and side supports 112, 114 aligned along a common plane.

Each projection 122 is elongated, has an end length and a projection longitudinal axis 124, and, in this embodiment, the projections 122 are positioned such that the projection longitudinal axis 124 intersects the length or longitudinal axis 108 of the web body 106. The projection 122 has a projection width Pw of about 8 mm (see FIG. 5) with an end radius of about 4 mm to form semicircular ends. As shown in FIG. 4 and 5, the projections 122 define an inwardly facing channel 116, preferably by stamping, to create a concave depression about 1 or 2 mm deep. It goes without saying that other sizes are possible.

The body 106 of the bridge further includes a series of perforations, and, in this embodiment, the perforations are circular holes 126 arranged in rows and alternating between a plurality of elongated perforations. Each row has two circular holes 126 on each of the base members 110 and side supports 112, 114. These circular holes 126 are adapted to receive mortar to allow for greater adhesion between the lintel 100 and the cement / sand finish applied to the lintel 100 ...

In use, the web 100 is positioned to overlap the opening 200 as shown in FIG. 1. However, instead of masonry located in channel 116, masonry (or load) 206 rests on edge members 118, 120, and thus edge members 118, 120 are configured to support the weight of load 206 on top of bulkhead 100. Load 206, acting on the edge members 118, 120 is progressively transmitted to the support structures 202, 204 via the bulkhead body 106 (via the side supports 112, 114 and base member 110) and the ends 102, 104 of the bulkhead body.

The presence of protrusions 122 reinforces base member 110 and side supports 112, 114 to reduce the possibility of base member 110 bending and / or flexing or bending of side supports 112, 114 due to stress on base member 110 in contact with supporting structures 202, 204. and this results in more efficient load transfer. The use of protrusions 122 also eliminates the need to increase the thickness of the web 100 or the degree of stress of the structural material to address these types of faults, and thus more cost-effective use of materials can be achieved.

In fact, the protrusions 122 allow the web 100 to support a greater load, especially in situations with narrower openings 200 (and thus the web 100 would be correspondingly shorter).

Additional benefits are provided by the bridge 100 supporting the load 206 at the edge members 118, 120 (and not in the channel 116):

i) indirect reduction in weight and use (or less use) of masonry, since the use of masonry in channel 116 is not required; and ii) plaster with a thickness of 3 mm (eg overlay cases) can be used for masonry elements. This is not possible with traditional ducted lintels, as the lateral supports of such lintels would be located outside the masonry.

Edge elements 118, 120 can increase the loading capacity of lintel 100. For example, the stiffness of lintel 100 with dimensions 60 mm by 60 mm (i.e. width and height) with edge elements 118, 120 with dimensions 10 mm is about 30% greater than a lintel of the same dimensions without edge elements.

As explained above, the protrusions 122 on the side supports 112, 114 help increase the loading capacity for shorter slabs and also aid in adhesion or bonding of the plaster. The protrusions 122 may not be as good as the perforations 126 (since the protrusions 122

- 2 037062 are blind holes, not through holes) that allow more mortar to penetrate and better adhere, but the projections still aid the bonding process as the mortar can fill (outside) the projections 122.

The described embodiment should not be construed as limiting. For example, in the described embodiment, the projections 122 are in the shape of elongated end portions, but other shapes are contemplated. Moreover, the projections 122 are positioned with their projection longitudinal axis 124 extending across the width of the base member 110 and upward of the side supports 112, 114 for maximum benefit, but the projections 122 may be located in other orientations or directions, such as parallel to the length or longitudinal the axle 108 of the body 106 of the dam, although this is not preferred.

In the described embodiment, the projections 122 are spaced apart and positioned along the entire length of the body 106 for ease of manufacture. This is also preferred since the number of end portions 102, 104 of the web 100 that are supported or supported by the supporting structures 202, 204 is usually determined in situ, based on the length of the web and opening 200, etc. However, it is contemplated that the protrusions 122 need to be formed only at or adjacent to the end portions 102, 104 of the web body 106 that are supported by the support structures 202, 204 in order to take advantage of the load transfer efficiency, and thus the protrusions 122 may not be formed along the entire length. body 106 of the lintel. Likewise, while it is preferable to form protrusions 122 on both side supports 112, 114, this may not be necessary, and in certain applications, the protrusions 122 may be formed on only one of the side supports 122, 144, or not on the side supports 122, 144, but only on element 110 of the base.

In the described embodiment, the projections 122 are formed to face inwardly towards the channel 116, but it is contemplated that the projections 122 can face outward, i. away from channel 116.

The shape and size of the edge elements 118, 120 may vary. For example, while the described embodiment shows continuous edge members 118, 120 extending along the length of the body of the web to facilitate fabrication, it is contemplated that edge members 118, 120 may include a series of discrete members spaced apart from each other. The size of the edge elements 118, 120 may vary depending on the size of the web 100 and the application. There is no particular limitation on the size of the edge members, but if the edge members 118, 120 are too small, the effect and benefit may be limited, while if the edge members 118, 120 are too large, load transfer may be ineffective. In fact, it has been found that the width W of the edge members 118, 120 can vary as a function of the thickness of the steel and the size of the side supports 112, 114 to achieve a particular load transfer efficiency. For example, for edge members 118, 120 with a width of 10 mm, a bulkhead body 106 with a thickness of about 1 mm can be used to achieve optimum load transfer efficiency.

Edge elements 118, 120 protrude towards each other in the described embodiment, but it is contemplated that edge elements 118, 120 may face outward and away from each other.

The bridge 100 of the described embodiment includes a generally U-shaped channel 116, but the shape of the channel 116 may vary. In fact, it is contemplated that aspects of the described embodiment could also be used for a box bulkhead, where the load bearing member could exclude channel 116. For example, the load bearing member could protrude from one edge of one of the side supports 112, 114 and extend laterally relative to the other side support. 112, 114 to create a box-like bulkhead where the load still rests on the load bearing member.

Having now fully described the invention, those of ordinary skill in the art should understand that many modifications may be made to it without departing from the claimed scope of the invention.

Claims (9)

1. A lintel for overlapping an opening defined by supporting structures, while the lintel contains an elongated lintel body, including: (i) an elongated base member; (ii) side supports extending from the elongated base to form an elongated channel therebetween; (iii) load bearing edge members projecting inwardly from respective edges of the side supports towards each other and along the longitudinal axis of the channel, with the load bearing edge members spaced apart to form a bulkhead opening for the elongated channel and adapted to support the masonry members ; 3 037062 (iv) end portions at the ends of the bulkhead body for engaging with supporting structures, and (v) a plurality of protrusions located at least at the end portions; wherein the load-bearing edge members are positioned such that, in use, the load-bearing edge members support the masonry members without the structural filling material used in the elongated channel. 2. A web according to claim 1, wherein the projections are spaced apart from each other and located along the length of the web body. 3. A web according to claim 1, wherein some of the plurality of projections are located on the base member and others on the side supports. 4. A web according to claim 1, wherein each of the projections is elongated and has a longitudinal axis of the projection that intersects the longitudinal axis of the body of the web. 5. A dam according to claim 1, wherein each of the projections are located inwardly toward the channel. 6. A web according to claim 1, further comprising a plurality of perforations. 7. A web according to claim 6, wherein the plurality of perforations alternate with corresponding one of the plurality of projections. 8. A web according to claim 6, wherein the perforations are circular. 9. A method of constructing a hand-made wall using a lintel containing an elongated lintel body, wherein the elongated lintel body includes: (i) an elongated base member; (ii) side supports extending from the elongated base to form an elongated channel therebetween; (iii) load bearing edge members projecting inwardly from respective edges of the side supports towards each other and along the longitudinal axis of the channel, with the load bearing edge members spaced apart to form a bulkhead opening for the elongated channel and adapted to support the masonry members ; (iv) end portions at the ends of the body of the bridge and (v) a plurality of protrusions located at least on the end portions; the method comprises the steps of placing a lintel to cover the opening defined by the supporting structures with end portions engaging the supporting structures, and placing the masonry elements on the load bearing edge elements without structural filling material used in the elongated channel.