WO2018211159A1

WO2018211159A1 - Belt holder

Info

Publication number: WO2018211159A1
Application number: PCT/ES2018/070331
Authority: WO
Inventors: Jose Luis Ubiñana Felix
Original assignee: Sistemas Tecnicos De Encofrados, S.A.
Priority date: 2017-05-15
Filing date: 2018-04-27
Publication date: 2018-11-22
Also published as: US20210156157A1; CA3063521A1; ES1184286Y; EP3604708A1; EP3604708B1; CO2019012904A2; PE20200069A1; CN110621831A; ES1184286U; MX2019013556A; EP3604708A4; EP3604708B9

Abstract

The invention relates to a belt holder divided into a first part and a second part, the first part comprising a first end of the belt holder and the second part comprising a second end of the belt holder, opposite the first end, the first part having a projection inserted into an inlet of the second part, which projection can slide into the entrance such that the length of the belt holder can be adjusted. The belt holder further comprises at least one pressure means situated at the first end and/or the second end.

Description

PORTACORREA DESCRIPTION The present invention refers to formwork supports. More particularly, the present invention refers to horizontal formwork beams that are supported by vertical struts, which are usually referred to as belt beams, or simply, belt carriers or belt carriers.

At present, different types of beams for formwork formation are known. However, a problem with standard formwork support beams is that they have a fixed and determined length. On numerous occasions, the length of the mentioned beams does not coincide exactly with the length between formwork that is required. Given this eventuality, operators usually cut other beams to join them to the aforementioned standard beams and ensure that there are support beams wall to wall without the existence of gaps or spacing between the formwork beams and the formwork itself. Another possibility is to place the beams not consecutively, but adjacent to each other, so that their path overlaps. This, however, multiplies the number of struts necessary to support the belt holders and, consequently, decreases the space between struts, making it difficult and even preventing the passage of operators. It is an objective of the present invention to disclose a new belt carrier that offers a solution to the aforementioned problems.

For this, the present invention discloses a belt carrier according to claim 1. Preferred embodiments of the invention are set out in the dependent claims.

The present invention discloses a belt carrier that is split into a first part and a second part, the first part having a first end of the belt carrier and the second part a second end of the belt carrier, opposite the first end, in which The first part has a projection inserted in a recess of the second part, the projection having sliding capacity within the recess. This slide allows the length of the belt carrier to be adjustable. In addition, it comprises a pressure means located at the first and / or the second end.

The variable length beam of the present invention has the advantage that the operator does not have to cut other beams to join them to the standard beams to thus meet the particular length required. According to another aspect of the present invention, the telescopic beam or adjustable belt carrier has pressure means at least one end, and preferably both. In this way, the belt carrier is able to fit tightly between two vertical structures, such as walls. A pressure medium can be an elastic and deformable element capable of storing energy and detaching from it without suffering permanent deformations when the forces (compression) or tension (pressure) to which it is subjected cease. The pressure medium is designed to significantly reduce its length when subjected to an axial (compression) force by placing the adjustable belt holder in the operating position, that is, when it is located between wall and wall or between ceiling and ceiling. A pressure means may consist of a bevel cut at the ends of the belt carrier, which collaborates with a wedge to establish pressure on the horizontal structure or wall.

The adjustable belt carrier of the present invention having pressure means is particularly advantageous in monolithic constructions. Monolithic construction is a type of construction in which a building or structure is constructed in a single block. The monolithic system allows a very high construction execution and assembly speed, reducing the labor force since the higher construction costs are minimized due to the low execution times. Monolithic constructions are characterized by usually having small lights, generally up to 3 meters. In architecture, engineering and construction the word light is usually used to designate the distance, in horizontal projection, existing between the supports of a beam.

The present invention also has the advantage over standard beams that can be reused in different monolithic designs, that is, it can be used in different projects that have a different design with variations in sizing. Having a range of length values and not a single fixed and determined length allows it to be used in numerous monolithic projects and designs.

A strut can be defined as a structural element of very small cross-section with respect to its height, adjustable, which provisionally supports a horizontal formwork structure, usually through the belt beams.

In addition, the adjustable belt carrier of the present invention is especially advantageous in monolithic constructions because it allows two struts in length per beam to be used, instead of three struts used by the standard system, the third corresponding to the overlapping section between fixed length belt carriers. Thus, the present invention has the ability to decrease the number of struts used in monolithic constructions. The fact of using only two struts is especially advantageous because the monolithic constructions are usually small, although it is true that the range of sizes can vary considerably. Typically the length between walls (light) is less than 3 meters. This means that the space inside is small, and consequently the space available to operators to build and assemble the building or structure is very limited. In addition, operators have to carry out their work by overcoming obstacles such as the different construction elements used, such as props, boards, belts, tripods, etc. They hinder your work. The fact of using the adjustable belt carrier of the present invention allows operators to carry out their work activity inside a monolithic construction in better conditions.

In a preferred embodiment, the pressure means comprises an oblique cut made at the first and / or the second end of the belt carrier to insert a wedge between said oblique cut at the end of the belt carrier and a vertical structure or wall. The wedge allows the adjustable belt carrier to be easily staked and similarly removed when the formwork phase is over and the belt carrier is not required. Preferably, the oblique cut of the second end of the adjustable belt carrier has the same cutting angle as the pressure means such that it is suitable for inserting a wedge-shaped pressure means located between the telescopic beam and a wall or a ceiling . More preferably, said oblique cut forms an angle between 85 ^a and 45 ^a with the longitudinal axis of the belt carrier. More preferably, the oblique cut forms an angle of 80 ^a with the longitudinal axis of the belt carrier.

The pressure means could also comprise an elastic piece in the form of an elastic plug that is placed on the first, on the second end or both fixedly or with a thread system. It could also be a threaded foot. The thread allows the foot to be threaded so that it presses against the vertical structure or wall.

According to another aspect, the projection of the first part has an alignment of holes and the second part has at least one conjugate hole, such that it is possible to introduce a pin through a hole of the alignment of holes of the first part and through the conjugate hole, in order to fix the position of the projection in the recess.

Preferably, the section of the first part and the second part are the same. More preferably, the first part and the second part have a profile with a T-shaped cross section.

Thus, the present invention allows controlling the length of the beam within a range of values. The fixing of the pins by the plurality of holes is of discontinuous control, while the pressure means allows to regulate the length of the present invention in a continuous way. The discontinuous advance is controlled according to the location of the pin located through a hole of the alignment of holes of the first part a hole of the second part. The continuous advance is controlled by means of the pressure means which is preferably wedge-shaped. More specifically, the continuous advance is controlled by its material and its geometry, that is, its elastic modulus and the inclination of the wedge (the angle of the oblique cut of the second end). The first part and the second part are telescopically coupled to each other. Said coupling allows the first part to move in the recess of the second part. Said displacement allows at least one hole of the second part to be aligned with at least one hole of the plurality of holes of the first part. Due to said alignment, the pin is able to pass through the aligned holes allowing a fixation between the first part and the second part also called telescopic coupling.

For better understanding, some drawings of an embodiment of the adjustable belt holder object of the present invention are attached by way of explanatory but not limiting example. Figure 1 is a perspective view of a first embodiment of adjustable belt carrier according to the present invention placed between two walls.

Figure 2 corresponds to another perspective view different from the embodiment of Figure 1. Figure 3 shows another perspective view of the embodiment of Figure 1.

Figure 4 is a front view of the adjustable belt carrier embodiment shown in the previous figures.

Figure 5 is a longitudinal section of the embodiment of Figure 3, in which interior elements can be seen. Figure 6 is a cross section of the embodiment of Figure 3.

Figures 1 to 5 show a first preferred embodiment of the present invention. Figures 1 to 3 schematically represent an application of the present invention. In figures 1 to 3, for reasons of clarity, the struts that would support the belt holder -1 - have not been shown. Figures 4 and 5 show in more detail the adjustable belt holder -1 - of figures 1 to 3.

The adjustable belt carrier -1 - has an outer profile that is split, so that a first part -60- and a second part -20- are defined. Preferably, the length of both the first and the second part must be sufficient to be able to receive a strut head intended to support said part.

The first part -60- has a projection -10- that is inserted into an inlet of the second part -20-. The projection -10- has a plurality of holes -40- arranged in an aligned manner. The second part -20- comprises at least one hole -50- whose location and dimensions are combined with the plurality of holes -40- of the projection -10-, so that it is possible to align a hole -50- of the second part - 20- and a hole of the projection of the first part -10-, when the projection -10- is introduced in the second part -20-.

The holes -40- and -50- are designed in such a way that they allow the passage of a pin (not shown), in order to fix the relative position of the first part -10- and the second part -20-. The pin is inserted simultaneously in a hole -50- of the second part -20- and in a hole of the alignment of holes -40- of the projection -10- thus determining the total length of the adjustable belt holder -1 -. To vary the total length of the adjustable belt holder -1 -, the user or operator first removes the pin by sliding it through a set of holes of the plurality of holes -40- and -50-, and once the pin has been removed , the first part -60- is not fastened (fixed), so that it can slide inside the second part -20- to achieve an extension of the adjustable belt holder -1 - positive or negative, that is, increasing or decreasing the total length of the adjustable belt holder -1 -. Finally, the user or operator reintroduces the pin through a new set of holes of the plurality of holes -40- and -50- achieving a new configuration of fixing between the first part -10- and the second part -20-.

In addition, the second part -20- has a second end -30- of the adjustable belt holder -1 - with a pressure means -70- which in this case materializes as an oblique cut that allows interleaving a wedge shaped element.

In figures 1 to 3 the wedge -2- is sandwiched between the adjustable belt holder -1- and a wall -4-. Said wall -4- could be any other vertical structure, or with a vertical section. In particular, wedge -2- is interleaved thanks to the oblique cut -30- of the second end of the adjustable belt holder -1 -. The pressure element offers a double advantage: first, it provides the adjustable belt carrier -1 - the ability to have a continuous increase or decrease in length, that is, the ability to have a continuous and non-discontinuous advance such as that provided by the fixing of the pin with the plurality of holes -40- and -50-. Second, the pressure means -2- facilitates the disassembly of the adjustable belt holder -1 - when its use is no longer required.

Figure 6 shows another embodiment of belt carrier in which elements equal or similar to those indicated above have been identified with identical numerals, so they will not be described in depth. A difference of the embodiment of Figure 6 with respect to that of Figures 1 to 5 is that in this case the pressure means consists of an elastic piece -70- located at the free end of the second part -70-. The elastic piece -70- is made, for example, in an elastomeric material such as, for example, a rubber, and is capable of exerting pressure against a compression wall undergoing an elastic deformation thus regulating the length of the belt carrier. Also, the combination of the discontinuous control by fixing the first part -10- and the second part -20- and the continuous control by the elastic part -70- allows to regulate the length of the belt carrier.

While the invention has been described with respect to examples of preferred embodiments, these should not be construed as limiting the invention, which will be defined by the broader interpretation of the following claims.

Claims

one . Belt carrier characterized in that it is split into a first part and a second part, the first part presenting a first end of the belt carrier and the second part a second end of the belt carrier, opposite the first end, in which the first part has a projection inserted in a recess of the second part, the projection having sliding capacity within the recess, such that the length of the belt carrier is adjustable and also comprises at least one pressure means located in the first and / or in the second end

2. Belt carrier, according to the preceding claim, characterized in that the pressure means comprises an oblique cut made at the first and / or the second end of the belt holder for inserting a wedge between said oblique cut at the end of the belt carrier and a vertical structure or wall.

3. Belt carrier, according to any of the preceding claims, characterized in that the oblique cut forms an angle between 85 ^a and 45 ^a with the longitudinal axis of the belt carrier.

4. Belt carrier, according to any of the preceding claims, characterized in that the oblique cut forms an angle of 80 ^a with the longitudinal axis of the belt carrier.

5. Belt carrier according to claim 1, characterized in that the pressure means comprises a piece in the form of an elastic plug which is placed at the end by pressure or with a thread system.

6. Belt carrier, according to any of the preceding claims, characterized in that the projection of the first part has an alignment of holes and the second part has at least one conjugate hole, so that it is possible to introduce a pin through a hole of the alignment of holes of the first part and by the conjugate hole, in order to fix the position of the projection in the recess.

7. Belt carrier, according to any of the preceding claims, characterized in that the first part and the second part have the same type of outer profile.

8. Belt carrier according to any of the preceding claims, characterized in that the first part and the second part have a profile with a T-shaped cross-section.

9. Belt carrier according to any of claims 7 or 8, characterized in that the outer profile is made of a metallic material.

10. Belt carrier, according to any of the preceding claims, characterized in that both the first end and the second end comprise a pressure means.