NO823857L - SOCKET FOOT CONSTRUCTION OF CONCRETE OR SOCKET SHEET OF CONCRETE, WITH INSTALLED BREAKING MECHANISM, AND PROCEDURE FOR THE PREPARATION OF SUCH FOOT CONSTRUCTION OR SOCKET - Google Patents

Description

The present invention relates to a post foot construction made of concrete or a post plinth made of concrete, with a built-in breaking mechanism. The foot structure or plinth is intended to reinforce a wooden post or column that has been set into the ground, and to eliminate the disadvantages that arise due to the post rotting at ground level. However, a foot structure or plinth according to the invention can also be used

es as a foundation element for concrete posts, or posts made of another material, as it is not necessary that the post has previously been in contact with the ground.

When such a foot construction is used, e.g. in connection with wooden posts or pillars that are set up along the sides of roads for vehicular traffic, the damage to a vehicle that collides with such a post or foot structure is often very extensive, due to the inability of the post or foot structure to provide after with some degree of softness in the event of an impact, among other things as a result of the relatively large mass of the post or foot structure and the thus relatively large inertia. Consequently, in such a collision there is a serious risk of serious injury to those in the vehicle.

PCT Publication WO 80/02167 and Swiss Patent No. 572,131 describe the manufacture of a metal foot structure for posts, provided with areas of weakness that facilitate shearing. However, none of these publications describe a concrete footing construction or plinth which has an embedded fracture mechanism.

Another type of fracture mechanism in footing structures is shown and described in US Patent No. 3,837,752. However, this publication does not describe the idea of a fracture mechanism included in a concrete footing structure for posts.

A main purpose of the present invention is to arrive at a concrete footing structure for posts or a concrete plinth, with which the risk of injury to those in a vehicle that collides with the footing structure or the post is much less than the previous has been.

Another purpose of the invention is to arrive at a foot construction or plinth of the aforementioned type, which can be produced easily and attached to an existing post or pillar in the ground, and/or which can form a separate or integrated foundation element .

A foot structure or plinth according to the invention is mainly characterized by the breaking mechanism comprising a plate which is embedded in the middle part of the foot structure or the plinth, and which is designed to facilitate cutting off the foot structure or the plinth when these are subjected to horizontally acting impact forces.

A foreign body of the aforementioned type, made e.g. of plastic material or metal, will not stick to the concrete when embedded in it, and will weaken the foot structure or plinth to the desired extent, so that the foot structure or plinth will be cut off when exposed to impact forces.

The break plate is preferably located in the area where the footing structure or plinth has the largest cross-sectional area, approximately at level with the ground surface or at a place slightly above the ground surface. When the post is exposed to impact forces, the concrete will crack around the slab, particularly in the area of reinforcing bars when such bars are part of the footing or plinth. As a result of the weakening of the post caused by the rupture plate, the concrete will crack and cause the footing structure to shear off. When the footing or plinth includes reinforcing bars, the bars will bend on impact, in the area above and below the fracture plate, and probably cause the concrete to crack in these areas.

A wooden post or column is usually weakened due to decay in the part of the post that is in the ground, and thus breaks easily in this part when exposed to shock.

Despite the fact that a foot construction according to

until the invention greatly stiffens the post or column with which it is used, the shear strength is significantly reduced due to the design of the foot structure according to the invention, so that it is possible to significantly reduce the degree of damage caused by a vehicle colliding with a wooden post or concrete post is exposed to.

In practice, the shape of the breaking mechanism is adapted to the cross-sectional shape of the foot structure and the mechanism is preferably equipped with holes. or openings, through which reinforcing bars can protrude in the longitudinal direction of the footing structure.

Plus; to simplify the manufacture of the foot structure, this adaptation of the shape of the breaking mechanism to the cross-sectional shape of the foot structure enables the breaking mechanism to be correctly positioned and reliably held in place inside the foot structure. According to another embodiment of the invention, the openings arranged in the fracture plate are designed to contain sleeve-like holding devices for reinforcing bars, which enables the bars to move in relation to the plate. This simplifies the mentioned, desired formation of cracks in the foot structure when the post is exposed to shock forces.

The formation of cracks is further promoted when, according to a preferred embodiment of the invention, the plate has slits or grooves in the area of the openings, in order to promote the formation of cracks when the post or the foot structure is exposed to shock forces.

As previously mentioned, the shape of the break plate is adapted to the cross-sectional shape of the foot structure. Thus, the break plate can have a mainly triangular shape, with a corresponding opening in the area of the side which is located next to the part of the substructure which is intended to lie against the circumference of a wooden s£6ipe.

Alternatively, the break plate can have mainly the shape of the letter Y, as the foot construction itself can also be given an aesthetic Y profile.

In practice, the foot structure can include three fracture mechanisms, namely one in its middle area and one in the area of each end of the structure.

The foot structure can have a length of approximately 1.5 m, and can be driven into the ground near a wooden post or column, using suitable tools, after which the foot structure can be connected to the post using e.g. steel bands, steel loops etc. fastening elements, using suitable tools for this. Alternatively, the foot structure can be placed in a hole and possibly arranged to support the post.

The invention also relates to a method for production

of a concrete footing structure, and the method is mainly characterized by the steps that reinforcing bars are arranged in a horizontal form, that the bars are guided through respective openings at least in a plate-like breaking mechanism which has a shape adapted to the cross-sectional shape of the form, so that the breaking mechanism supports the reinforcing bars in the form , and that concrete is poured into the form and allowed to solidify, after which the finished foot construction achieves a weakened part in the area of the plate-like fracture element which will yield when subjected to shear forces. The production is simplified by using one or more plate-like fracture elements such as jigs, which ensures that the reinforcing bars are correctly placed in the form. Simple means are used at the same time to ensure that the plate-like fracture mechanism or mechanisms used are also correctly positioned.

More examples of execution forms of. the invention must be described in more detail, with reference to the attached drawings. Fig. 1 shows in perspective a wooden post which is rotten at the bottom and is supported by a foot structure according to the invention. Fig. 2 shows in perspective a cut-off middle part of the foot construction shown in Fig. 1, equipped with a weakening or breaking mechanism arranged on reinforcing bars.

Fig. 3 shows a section along the line III-III in fig. 2.

Fig. 4 shows a cross-section through a foot construction that has been exposed to shock forces, the figure being intended to illustrate what happens when such shock forces occur. Fig. 5 shows in perspective a foot construction equipped with a modified breaking mechanism.

Fig. 6 shows a section along the line VI-VI in fig. 5.

A wooden post 1 with a toe-tight lower part la is shown placed in the ground 2 and connected to a foot structure 4 by means of clamps 3, comprising e.g. steel loops attached using a suitable tool (not shown). The foot construction 4 will first be described with reference to fig. 1-4.

The foot structure shown has a mainly Y-shaped design, with an insertion part 4a projecting in the longitudinal direction, intended to lie against the circumference of the wooden post 1.

The thickest part of the foot structure 4 lies approx

at the middle of the construction, or slightly above the middle, as the foot construction is slightly beveled towards the ends. The lower end of the foot structure is slightly pointed, which makes it possible to drive the foot structure into the ground using a suitable impact tool, after which it is connected to the wooden post 1.

The shape of the foot construction in the area of the largest cross-section is shown in fig. 2.

Three reinforcing bars 5 protrude through the foot structure 4,

and holds between them a Y-shaped breaking mechanism 6. For this purpose, the breaking element 6 is equipped with slots or recesses 6a and with slotted sleeves 6b, in which the reinforcing bars 5 are passed through. The cross-section shown in fig. 3 also helps to illustrate the design of the sleeves 6b.

The breaking element 6 is suitably made of polyethylene plastic, and can have a thickness of approximately 3 mm. In accordance with the above-mentioned, the breaking element weakens the foot construction so that the construction will be cut off when the wooden post 1 is subjected to strong impact forces, e.g. when a vehicle collides with the post.

Fig. 4 is intended to show what happens inside the foot structure when the post or the foot structure is exposed to shock forces. The reinforcing bars 5 are able to move freely through the plastic sleeves 6b to a certain extent, and the sleeves also have break-promoting means in the form of slots 6a. Thus, when the footing structure is subjected to impact forces of the type previously mentioned, the reinforcing bars are able to deform to a certain extent, causing a larger amount of concrete to crack. As a result, the amount of concrete that breaks is so great that the entire post can be compressed on one side. On it

on the opposite side of the post, instead, the reinforcing bars are bent outwards. This breaking up of the concrete means that the kinetic energy of the vehicle is progressively absorbed, as the vehicle slows down.

Figs 5 and 6 show a modified foot structure 4, equipped with a triangular breaking mechanism 6 which is provided with holes and recesses to contain four reinforcing bars 5. In this embodiment, two plastic breaking elements 6 are welded together to form a single unit. The breaking mechanism according to this embodiment is also equipped with slots 6a containing sleeves 6b, which surround the reinforcing rods 5.

Preferably, the foot construction 4 according to the invention comprises four breaking mechanisms 6 of the type shown in fig. 2 and 5. In addition to a breaking mechanism arranged in the area of the strongest cross-section of the foot structure,

a breaking mechanism can be arranged in the area at each end of the structure.

The breaking mechanisms 6 can also simplify the manufacture of a foot structure. When manufacturing a foot structure, reinforcing bars 5 with adapted lengths are passed through the sleeves 6b in a breaking mechanism 6, after which the breaking mechanism,

which may possibly include three break plates, are placed in a horizontal form. This ensures that both the reinforcing bars 5 and the breaking mechanisms 6 are placed correctly in the form. Concrete is poured into the form and allowed to solidify, after which the foot construction is ready for use. In this way, the foot structure gets a weakened part in the area of the middle breaking mechanism 6, which means that the foot structure is cut off when it is exposed to forces of the above-mentioned type.

Although not shown, the foot construction can be used as

a foundation element or plinth, e.g. for a concrete

or wooden post. The foot structure can then be placed, either completely or partially, e.g. in a hole dug in the ground to attach the post. The foot structure may comprise a part separate from the post, adapted to support the main part of the post in some suitable manner, or it may also be integral with the post itself. In all cases, the foot structure has a weakened part which. facilitates cutting off the post when the post is subjected to impact forces.

Claims (8)

1. Post foot construction made of concrete or post base made of concrete, with a built-in breaking mechanism, characterized in that the breaking mechanism (6) comprises a plate (6) embedded in the middle part of the foot structure (4) or the post base, and designed to facilitate cutting off the foot structure or the base when subjected to horizontal impact forces. 2. Foot construction or plinth as stated in claim 1, characterized in that the plane of the foot (6) approximately coincides with the horizontal plane. 3. Foot construction or plinth as stated in claim 1 or 2, characterized in that the breaking mechanism (6) has a design adapted to the cross-sectional shape of the foot structure or plinth, and exhibits a recess (6a) to contain a reinforcing bar (5) which projects in the longitudinal direction of the foot structure or plinth. 4. Foot construction or plinth as specified in claim 3, characterized in that the breaking mechanism comprises sleeve-shaped holding devices (6b) for reinforcing bars (5), which holding devices enable the reinforcing bars to move in relation to the breaking mechanism. 5. Foot structure or plinth as specified in claim 4, characterized in that the breaking mechanism is equipped with slots or recesses (6c) in the area of the openings containing the reinforcing bars, which slits or recesses serve as fracture indications that promote the formation of cracks in the foot structure or plinth when it are exposed to horizontal impact forces. 6. Foot construction or plinth as stated in claims 1-5, characterized in that the breaking mechanism (6) is mainly triangular in shape (fig. 5) . 7. Foot construction or plinth as specified in requirements 1-5, characterized in that the breaking mechanism (6) has mainly a Y-shaped design (fig. 2). 8. Foot construction or plinth as stated in claims 1-7, characterized in that, in addition to a central breaking mechanism (6) in the area of its largest cross-section, the foot structure or plinth is also equipped with a similar breaking mechanism at each end, each breaking mechanism being designed to serve as a holding device for reinforcing bars (5) which are connected to the foot structure or plinth during casting. 8. Procedure for manufacturing a foot structure made of concrete for posts or a plinth made of concrete for posts, characterized in that reinforcing bars (5) are arranged in a horizontal row and are inserted into recesses in at least one plate-like element (6) with a design adapted to the cross-sectional shape of the mold, so that the plate-like element supports the reinforcing bars in the mold, and that concrete is poured into the form and the concrete is allowed to solidify, after which the cast foot construction or plinth (4) is given a weakened part in the area of the plate-like element (6), to facilitate cutting off the post when it is subjected to shear forces.