RU2754402C1 - Method for manufacturing metal post with rectangular cross-section having spacer anchor for a fence and use of such post - Google Patents

Abstract

FIELD: construction industry, agriculture.

SUBSTANCE: invention relates to the field of construction, municipal services or agriculture and can find application in the creation of metal posts for fences. The technical results achieved in the implementation of the claimed technical solution are: simplification of the manufacture of a fence post; simplification of the installation process and increasing the convenience of installing a fence post and, as a result, simplifying the installation process and increasing the convenience of installing the fence as a whole; and, as a result, reducing the labor requirements for installing a fence post hence the fence as a whole; reducing the amount of labor required to install one fence post; as a result, increasing the speed of installation of each fence post, as well as the entire fence as a whole; increasing the operational reliability of the fence post and significantly complicating its unauthorized extraction. The above mentioned technical results are achieved by the same set of essential features, namely: a method for mounting a rectangular cross-section metal column with a spacer anchor in the ground, consisting in the fact that the said column, which is a rectangular metal pipe with a part buried in the ground, containing longitudinal slots made in the ribs at the same level, providing the formation of a spacer anchor by deforming sections of the pipe faces, the perimeters of which are limited by the beginning and end of the corresponding slots, they are placed in a pre-prepared well for the column and a longitudinal force is applied to the walls of the pipe or a transverse force is applied to the inner surfaces of the sections directed towards the ground until the sections are deformed to form an anchor connection of the column with the ground.

EFFECT: technical results achieved in the implementation of the claimed technical solution are: simplification of the manufacture of a fence post; simplification of the installation process and increasing the convenience of installing a fence post and, as a result, simplifying the installation process and increasing the convenience of installing the fence as a whole; and, as a result, reducing the labor requirements for installing a fence post.

20 cl, 7 dwg

Description

[0001] TECHNICAL FIELD

[0002] The technical solution relates to the field of construction, utilities or agriculture and can be used in the creation of metal posts for fences.

[0003] BACKGROUND

[0004] As you know, the fence is a fence, consisting of supports and a canvas, fixed on the supports between them. As a rule, supports (pillars) of fences (fences) are made of rectangular, less often circular, metal pipes, which is due to the fact that rectangular pipes have greater bending strength; and also easier to install due to the fact that they have flat edges, regardless of the method of installation, including welding installation. Moreover, rectangular pipes are easier and more efficient to transport and store, since in this case more usable area and volume are used. In this case, the installation of the fence fabric on pillars (supports) of rectangular cross-section can be carried out in many ways, for example, using consoles fixed on the planes of the pillar, brackets for the crossbars on which the canvas is mounted; using U-shaped strips for attaching canvas lamellas between them; using lugs with a hole for attaching mesh cloths to them; and in similar ways. At the same time, the flat edges of the pillars with a rectangular section also make it possible to simplify the process of installing the fence curtain due to the simpler installation of the fasteners for the curtain themselves, which makes it possible to simplify and speed up the process of installing the fence (fence) as a whole.

[0005] Based on this, one should distinguish between supports (pillars) for fences (fences) of circular and rectangular cross-sections, that is, such products are products with different installation and operational characteristics, and in some cases also have different purposes.

[0006] Other characteristics of the post (support) for the fence (fence) may relate to its height, which, as a rule, does not exceed three to four meters, depending on the characteristics of the fence (fence). It should be borne in mind that when installing high pillars, that is, those exceeding about 2.5 m in height, it will not always be possible to install them using an anchor connection with a point or strip concrete foundation, since in this case, the deepening of the concrete foundation must be carried out to a too great depth, in connection with which it is preferable to mount high pillars by burying some of them in the ground or concrete, or by performing a flange connection with a pre-assembled pile.

[0007] As you know, there are several ways to install the fence posts in the ground. In accordance with GOST R 57278 - 2016 “Protective fences. Classification. General provisions ", depending on the type of soil, the point foundation for the support is performed: a) by pouring concrete or backfilling with a specially prepared sand-gravel mixture into pre-drilled holes with the simultaneous installation of the support; b) as a foundation block in the form of a "shoe", a screw support or a tubular driven support; at the same time, in general, the installation of supports should be carried out in one of the following ways: a) concreted into a strip reinforced concrete foundation; b) fasten the support to the foundation through a flange connection using a flange connection; c) fasten the support to the foundation with anchors. When using a point foundation, the support should be installed: a) in a specially prepared sand-gravel mixture or concreted in pre-drilled holes of wells; b) either by driving a metal pile into the ground with the subsequent fastening of the support to it with bolts through a flange connection; c) either by fastening the support with bolts through a flange connection to a pre-installed screw support. At the same time, screw and driven supports can be used on all types of soils, except for rocky ones. It is generally known that an alternative to a driven or screw pile can be a ground anchor (see, for example, GOST R 57355-2016 / EN 1537: 2014 "Ground anchors. Work rules") - a device consisting of a head, a tensile element (anchor traction) and root. Ground anchors, as a rule, are installed in a pre-drilled well, followed by concreting or compaction with a sand-gravel mixture and serve to strengthen the structure or to fasten a building element to the ground on slopes. At the same time, expansion anchors for fastening in concrete are known (see, for example, GOST R 56731-2015 "Mechanical anchors for fastening in concrete. Test methods"). Such expansion anchors, of course, cannot be used to fasten fence supports directly into the ground due to their small size, but this technique can be used to create expansion ground anchors.

[0008] For example, a driven pile is known as described in RU 139587 U1 (D1). The driven pile known from D1 consists of a metal perforated pipe with a tapered tip, having holes provided with opening and closing metal plates fixed to the pipe, with a removable tee with a metal cover located on the upper part, and the lower part of the perforated pipe has longitudinal slots that form cantilever blades, and the tip is made in the form of a cylinder, turning into a truncated cone, ending in a cone-shaped head. The immersion and operation of the driven pile known from D1, designed to strengthen the base with a widened heel and cementation of soils, is carried out as follows. The supply of cement slurry into the pipe and its immersion are carried out simultaneously, which causes the advance of the metal tip along the longitudinal slots at the end of the pipe and creates the conditions for the formation and symmetric rotation (bending) of the cantilever blades 6 from the reactive resistance of the base soil to the outside of the pipe, thus creating the necessary the gap between the pipe and the surrounding soil, into which, through the ellipsoidal holes, pressing the plates, the fixed solution is pumped under pressure. As it sinks into the ground, the cantilever blades move apart from the reactive resistance of the soil and are fixed in the cement stone, increasing the pile support area, creating a widened heel and increasing the bearing capacity of the pile.

[0009] At the same time, an anchor pile is known as described in BY 10542 C1 (D2). Known from D2, the driven anchor pile includes a rod-rod, around the barrel of which an anchor head of circular cross-section is mounted with a gap (see D2: Fig. 3-6), and the rod-rod and the anchor head are rigidly connected to a pointed tip, and the anchor head is made in the form of a pipe with longitudinal slots in its walls, while the longitudinal slots in the anchor head are made in several tiers along the height of the pipe and are deployed in each tier relative to each other at an angle α = (360 ° / 2n), where n is the number of slots in each tier, and between the longitudinal slots, as well as above and below them, there is a continuous continuous section of the pipe of the anchor head. The performance of the anchor pile during immersion is achieved by driving the rod-rod together with the pipe into the ground, opening the anchor head by driving it with the inventory pipe in the ground, during operation due to the possibility of applying a pulling load to the rod-rod. In the first case (see D2: Fig. 1) the anchor pile is driven into the ground by means of a rod to the design mark. Due to the presence of a gap between the outer diameter of the anchor head pipe and the outer diameter of the tip (2-5 cm), the pile is immersed in the ground without obstacles. Next, the blades of the anchor head are opened in the ground by hammering (see D2: Fig. 2) by means of an inventory pipe (not shown in Fig. 2 of document D2). In this case, the blades of the anchor head (Fig. 2), due to the presence of the slots, are bent in an unstable or previously weakened place (half the length of the slots) and turn into a "flashlight" in each tier. The anchor pile is capable of absorbing the pulling load, turning the rod into a rod (see D2: Fig. 2). In the second case (see D2: Fig. 7), the first tier of the anchor head is directly driven into the ground by means of a rod or immersed in a previously drilled hole in the ground. Then the blades of the first tier of the anchor head are opened in the ground (see D2: Fig. 8) by means of an inventory pipe (Fig. 8 of document D2 is not shown). Similarly (by driving or lowering into the well), the anchor head 2 is immersed in the ground of the second and subsequent tiers (see D2: Fig. 7), as well as the opening of their blades in the ground and turning them into a "flashlight" (see D2: Fig. . eight).

[0010] At the same time, it is obvious that the main disadvantage of the known from the prior art ground anchors, as well as those known from D1 and D2 spacer piles, is that they themselves cannot perform the function of pillars (supports) for fences (fences) ... Such devices, however, if they contain an external suitable head, can serve as supports to create a flange connection with a support (post) for the fence (fence). At the same time, the following drawback of using spacer anchors and spacer piles is obvious when installing pillars (supports) for fences (fences), namely, the need to perform an additional installation operation associated with the need to connect, in fact, the post (support) with the spacer anchor (pile). In particular, when installing a fence (fence) using a spacer anchor (pile) as a foundation, it is necessary, for example, to make the head of the spacer anchor (pile) containing a flange, while the mounted support (pillar) of the fence (fence) must also have a flange for coaxial connection with an expansion anchor (pile) using, for example, tightening bolts or studs, which significantly lengthens and complicates the installation process of each such support (pillar) in particular, and the fence (fence) as a whole.

[0011] Thus, one should distinguish between expansion anchors (piles) and, in fact, posts (supports) for fences (fences), since these products not only have different characteristics, but are means for different purposes and cannot be interchangeable; moreover, in the case of installation of a fence (fencing), these products can only be used as independent products together.

[0012] Thus, in order to simplify the installation process and accelerate it while maintaining other positive properties inherent in expansion anchors (piles), such as, for example, the reliability of anchoring in the ground, it is necessary that the post (support) itself for the fence (fence) the properties of a reliable connection with the ground are inherent. In this regard, there is a known method of mounting a screw post, mainly for a fence, described in patent RU 133181 U1 (D3). The metal post known from D3, mainly for a fence, contains a support post and a part loaded into the ground, which is made of a cylindrical pipe and is equipped with a cutting screw blade, characterized in that the support post is made of a profile pipe with flat edges, the upper end is recessed into its lower part the said cylindrical pipe with the formation of contact with the male surface, and the pipes are connected by welding along the contour. As indicated in D3 and does not fully correspond to reality, to facilitate screwing in the column known from D3, you can use a knob acting as a lever, which is a short pipe segment, the section of which is similar to the section of a profile pipe, for example, a square-square, with a transverse dimension, slightly exceeding the transverse dimension of the rack. Radial arms are attached to the pipe section. Such a pillar known from D3 does not have the disadvantages of conventional pillars (supports) for fences (fences), and is also able to eliminate the need to perform an additional installation operation associated with the need to connect the expansion anchor (pile) and, in fact, the pillar (support).

[0013] At the same time, the column known from D3 has a number of significant disadvantages. Firstly, the pillar known from D3 is difficult to manufacture - to create it, it is necessary not only to perform the buried part with cutting blades, but also to ensure its connection with the profile pipe of the support post (that is, with a metal square pipe, in fact, a post (support ) for the fence). Secondly, the column known from D3 is connected to the ground by means of a screw connection, which reveals the following disadvantages: 1) unreasonably large efforts are required to screw the column into the ground, and the possibility of using manual devices for screwing is excluded - such suitable manual devices simply do not exist, and the well-known manual devices for screwing piles cannot be used, since they can be used, in fact, only for screwing piles of short length - for long piles, the use of special heavy equipment is required; 2) the denser the soil, the more lever is required for manually screwing the screw column into the ground, which can be a critical disadvantage, since with a large length of the fence (fence), the spans between the posts (supports) should be performed less frequently to create greater operational reliability of the fence (fence) as a whole, and, thus, the required length of the lever may exceed the span length, which will lead to the impossibility of mounting such a screw post; 3) the longer the buried part of the screw post, the higher the height the knob should be placed, which leads to the fact that in some situations the installation will in principle be impossible due to the lack of labor force of suitable height; or this circumstance may require the manufacture of additional levers on the lever, which reduce its effectiveness due to the indirect effect of the load on the lever; 4) in most cases, several people are required to mount the column known from D3, since, as a rule, one person is not able to simultaneously support the weight of the screw column when screwing it in, position it in the necessary center and, in fact, screw the screw column; 5) when screwing in the screw pillar, a stone may be found in its path, which will require the pillar to be removed to excavate the stone or crush it. Thus, the screw post known from D3 has an increased complexity of installation; in addition, the installation of such a screw pillar is not convenient enough and may require the selection of a tall labor force, as well as a large number of labor force; in addition, the process of mounting the screw post is more time-consuming. Thirdly, the pillar known from D3 provides insufficiently reliable anchoring in the ground, since such a pillar can easily be unauthorizedly removed by simply unscrewing it in the opposite direction, which is critical for situations when the fence (fence) is not under constant supervision; in particular, the ease of removal of the screw post may attract unauthorized scrap collectors. Fourthly, the installation of a pillar known from D3 does not imply the possibility of strengthening the connection created with the ground with reinforcing solutions or reinforcing bulk materials, since such a connection and the structure of the column known from D3 do not imply their use at all and there is no possibility of filling or filling connection with reinforcing solutions or bulk materials, in particular, the pillar known from D3 in the buried part is solid, without holes, which does not allow spilling (spilling) the solution (material) through the pillar into the junction, and the installation of the pillar known from D3 does not imply the creation of any -or a well through which access to the earth connection is possible.

[0014] The method known from D3 for mounting a screw post is selected as the closest analogue of the claimed technical solution, since the analogue is a method that has a purpose that coincides with the purpose of the claimed technical solution, known from information that has become publicly available in the world before the priority date of the claimed technical solution. solutions.

[0015] DISCLOSURE OF THE INVENTION

[0016] The technical problem solved by the claimed technical solution is the creation of a non-flawed closest analogue of the method of mounting a fence post, provided by the creation of a fence post with the possibility of anchorage connection with the ground, providing: 1) ease of manufacture, including directly in the process installation; 2) the simplicity of its installation and, as a consequence, the ease of installation of the fence as a whole, as well as, as a consequence, the increased convenience of mounting each pole separately and, as a result, the fence as a whole, and also, as a consequence, reduced labor requirements and less manpower to install one fence post; 3) a more reliable connection of the fence post with the ground and a significant complication of its unauthorized extraction.

[0017] Based on the formulation of the technical problem, the technical results achieved when implementing the claimed technical solution are: 1) simplifying the manufacture of a fence post; 2) simplifying the installation process and increasing the convenience of installing the fence post and, as a result, simplifying the installation process and increasing the convenience of installing the fence as a whole; as well as, as a consequence, a decrease in labor requirements for the installation of a fence post and, as a result, for the fence as a whole; 3) reducing the amount of labor required to install one fence post; 4) as a consequence - an increase in the speed of installation of each fence post, and also, as a result, of the entire fence as a whole; 5) increasing the operational reliability of the fence post and a significant complication of its unauthorized extraction.

[0018] The above technical results are achieved by the same set of essential features, namely: a method of mounting a metal post of rectangular cross-section with a spacer anchor in the ground, which consists in the fact that the said post, which is a metal pipe of rectangular cross-section, having a part buried in the ground containing longitudinal slots made in the ribs at the same level, ensuring the formation of an expansion anchor by deforming sections of the pipe edges, the perimeters of which are limited by the beginning and end of the corresponding slots, is placed in a pre-prepared well for the column and a longitudinal force is applied to the pipe walls or applied to the inner surfaces of the sections lateral force directed towards the ground before deformation of the sections with the formation of an anchorage connection of the column with the ground.

[0019] More specifically, the technical result 1) is achieved due to the fact that it is not required to manufacture the buried part of the fence post with a cutting blade and, as a consequence, it is not required to make the fence post from two parts, but it is enough to use a metal pipe of rectangular cross-section of the required length and make longitudinal slots in the ribs of its buried part at the same level, due to which it will be possible to create an anchorage connection with the ground by deforming pipe sections, the perimeters of which are limited by the beginning and end of the corresponding slots, in the direction of the ground. In comparison with the general state of the art, in particular with the anchoring joints of circular spacer piles, the manufacturing process is simplified due to the fact that there is no need to make unnecessary calculations and markings to make the slots, since the slots are made in the elements inherent in the rectangular cross-section of the metal pipe - ribs - of which there are only four and which are able to detect even the lowest qualified personnel.

[0020] In turn, the technical results 2), 3) and 4) are achieved due to the fact that it is not required to perform the operation of screwing the post for the fence into the ground, but it is enough to prepare the well, place the declared post into it and create an anchor connection with the ground by deforming pipe sections, the perimeters of which are limited by the beginning and end of the corresponding slots, in the direction of the ground, which can be carried out by one of the tools described in more detail hereinafter; at the same time, it is not required to use any levers that are required when screwing the screw post; at the same time, obstacles to the installation of the column in the form of, for example, stones can be detected even during the drilling of the well and eliminated before the installation of the column begins, while removing the column to access the obstacle will not be required; in this connection: a) only one person is required for the installation of one declared pillar, moreover, for the installation of high pillars, a tall labor force is not required, since the installation is carried out using specialized tools; b) since only one person is required for the installation of one declared pole, other employees of the installation team can install other fence posts; c) since the installation is carried out in pre-prepared wells, which can be performed quickly using drilling devices, while the installation itself is carried out using a specialized tool, the installation speed of a unit of the declared column increases significantly; d) since several pillars can be installed at the same time, and the installation speed of one pillar is significantly increased, the speed of installation of the fence as a whole increases.

[0021] In turn, the technical result 5) is achieved due to the fact that created by deformation of pipe sections, the perimeters of which are limited by the beginning and end of the corresponding slots, in the direction of the ground, the anchor connection to the ground provides increased operational reliability due to the reliability of the connection of the column to the ground , since it provides at least four surfaces of engagement (according to the number of deformable sections), the area of which can vary by the length of the slots even after the post is made, in contrast to the screw connection, where the engagement surface is limited by the width of the cutting blade, which cannot significantly exceed the limits of the section of the helical post , since this, when screwed, will lead to the formation of a too wide hole; in addition, the proposed anchor connection does not imply the extraction of the declared fence post by simply pulling it out (this is prevented by the petals formed by the deformed sections), or unscrewing (this is prevented by the absence of any cutting blade in the buried part), and therefore unauthorized extraction of the declared post after its installation, it is significantly complicated and requires excavation to a depth exceeding the depth of the created anchor connection with the ground; in addition, after the installation of the proposed fence post, it remains possible to further strengthen the anchor connection with the ground by filling the anchor connection with a reinforcing mortar or by filling the anchor connection with a reinforcing bulk material, since the design of the proposed fence post provides the possibility of pouring (filling) the reinforcing mortar (bulk material) through the column pipe to the point of connection with the ground.

[0022] BRIEF DESCRIPTION OF DRAWINGS

[0023] Illustrative embodiments of the claimed technical solution are described below in detail with reference to the accompanying drawings, which are incorporated herein by reference, and in which:

[0024] FIG. 1 shows an exemplary embodiment of the claimed metal post of rectangular cross-section with an expansion anchor for the fence.

[0025] FIG. 2 shows an exemplary use of a rectangular metal post with a fence expansion anchor to create an anchorage in the ground using one version of the expansion tool.

[0026] FIG. 3 shows an example of an anchorage in the ground made with one version of a spacer tool and a rectangular metal post with a fence spacer.

[0027] FIG. 4 shows an exemplary use of a rectangular metal post with a fence expansion anchor to anchor in the ground using another expansion tool.

[0028] FIG. 5 shows an example of an anchorage in the ground made with another spacer tool and a rectangular metal post with a fence spacer.

[0029] FIG. 6 shows an exemplary use of a rectangular metal post with a fence expansion anchor to anchor in the ground using a pull tool.

[0030] FIG. 7 shows an example of an anchorage in the ground using a pull tool and a rectangular metal post with a fence anchor.

[0031] CARRYING OUT THE INVENTION

[0032] Described in this section, possible implementations of the claimed technical solution are presented on non-limiting examples of legal protection in relation to specific embodiments of the claimed technical solution, which in all their aspects are intended to be illustrative and not limiting. Alternative options for implementing the claimed technical solution, which do not go beyond the scope of legal protection, are obvious to those skilled in the art with ordinary qualifications for which this technical solution is designed.

[0033] FIG. 1 shows an exemplary embodiment of the claimed metal post of rectangular cross-section with an expansion anchor for a fence (anchor post 100 for a fence). Preferably, but not limited to, the claimed fence post 100 is a rectangular metal pipe, preferably, but not limited to, square, having edges 101 and fins 102. Preferably, but not limited to, the metal pipe is predominantly a standard metal profile pipe, in terms of dimensions and geometric parameters mainly corresponding to GOST 8645-68 or GOST 8639-82. Preferably, but not limited to, said metal pipe has an anti-corrosion coating, for example, but not limited to, zinc-based, which increases the operational reliability of the claimed post 100. Preferably, but not limited to, longitudinal slots 103 are provided at one end of said pipe in the ribs 102. Preferably, not limited, the slots 103 are formed so as to form face sections 104 which, with sufficient longitudinal action on the respective facets 101, can bend outwardly towards the ground when the fence post 100 is installed in the post borehole, while, as can be seen from FIG. 1, the perimeter of the sections is limited by the beginning and end of the respective slots 103, and the slots 103 themselves are preferably, but not limited to, at the same level. Preferably, but not limited to, the slots 103 are configured to form face sections 104 that are capable of flexing outwardly towards the ground when the fence post 100 is positioned in the post wellbore with sufficient predominantly lateral action from the inside out. Preferably, but not limited to, the predominantly lateral action is directed predominantly towards the center of the face sections 104. Preferably, but not limited to, the sections 104 are partially pre-bent outward, which, preferably, but not limited to, simplifies the process of mounting the post 100 in the ground. At the same time, it should be obvious to a person skilled in the art having ordinary qualifications for which the claimed technical solution is designed, it should be obvious that the above-mentioned partial deflection of sections 104 should not significantly exceed the estimated diameter of the well for the column 100. Preferably, without limitation, said slots 103 are made according to a length that provides an overall sufficient extension of the anchor (i.e. the sum of the lengths of the abutment surfaces formed by opposing deformed sections). It should be apparent to those of ordinary skill in the art for whom the claimed technical solution is designed that the sufficient extension length of the anchor can depend on many factors, such as, but not limited to, the density of the soil in which the fence post 100 will be used, and the geometric parameters of the column 100. In this case, it should be obvious to the aforementioned specialist that the length of the expansion of the anchor on each side of the column approximately corresponds to half of the corresponding length of the corresponding slots 103, which mainly follows from the fact that the section 104 bends towards the ground mainly in its middle part , since this part is the most weakened. At the same time, it should also be obvious to the above-mentioned specialist that, depending on the geometric parameters of the column 100, as well as on the characteristics of the soil, one or another length of the anchor extension on each side of the column 100 can be selected; moreover, preferably, but not limited to, the total length of the anchor extension, and therefore the length of the slots 103, is selected in such a way as to provide a sufficiently reliable anchorage in the ground. In this case, if the soil, for example, but not limited to, has a high density and a low degree of frost heaving, then a reliable anchorage connection of the column 100 can be formed by a shorter length of the anchor extension from the corresponding sides of the column 100 and, therefore, a shorter length of the corresponding slots 103 in the column 100 ; Moreover, if the soil, for example, but not limited to, has a low density and a high degree of frost heaving, then a reliable anchorage connection of the pillar 100 can be formed by a longer extension of the anchor from the corresponding sides of the pillar 100 and, consequently, by the greater length of the corresponding slots 103 in the pillar 100. Preferably, but not limited to, face sections 104 have additional openings and / or bulges and / or concavities where the sections 104 are preferably folded. However, it should be obvious to a person skilled in the art with ordinary skill in the art for which the claimed technical solution is designed that the presence of the aforementioned holes, and / or bulges, and / or concavities in the places where the sections 104 are preferably folded will provide, but are not limited to, the section 104 bending at the desired location and simplify the installation process as a whole, which will also affect the installation speed. Preferably, but not limited to, the fence post 100 is longitudinally through to allow a reinforcing solution (bulk material) to be poured through it to provide additional support for the post 100 and to strengthen the anchoring.

[0034] The claimed technical solution works as follows. It should be apparent to those of ordinary skill in the art, for which the claimed technical solution is designed, that the methods described below for performing an anchorage in the ground using the claimed pillar 100 follow one principle of deformation of the corresponding section 104 in the direction of the ground, and such deformation is achieved either due to the longitudinal force on the walls of the column 100, which in the region of the sections 104 due to the existing weakening in the ribs 102 in the form of slots 103 do not fully close longitudinally to form an anchorage in the ground due to the outward bending of each section 104, and such a longitudinal force, which is obvious to a specialist, can be directed both downward (deep into the well of the column) and upward (from the well of the column); or by a lateral force on the sections 104 from the inside, which similarly bends towards the ground and provides a similar longitudinal closing of the walls of the column 100. However, it should be obvious to the person skilled in the art with ordinary skill, for which the claimed technical solution is designed, that methods and tools other than those described below with reference to FIGS can be used to achieve a similar effect. 2-7, for example, without limitation, explosive methods and methods, or methods and methods associated with heating, or any other methods and methods, in connection with which described below with reference to FIG. 2-7 methods and methods cannot be used as limiting examples of the implementation of the claimed technical solution.

[0035] In all of the following with reference to FIG. 2-7 cases, for the installation of the column 100, a column well is preliminarily formed, into which the declared anchor column 100 is inserted for the fence. Preferably, but not limited to, the borehole of the pillar is made across a width not exceeding the width of the pillar 100, without limitation, taking into account the preliminary bending of sections 104. Methods of forming the borehole (for example, drilling with a tool for drilling wells) and inserting the pillar into the borehole (for example, manually the placement of the column in the borehole or placement by means of a manipulator) are known from the prior art and, accordingly, are not further described in detail.

[0036] FIG. 2 illustrates an exemplary use of a fence post 100 to anchor in the ground using one embodiment of a spacer tool 200. FIG. 3 shows an example of an anchorage in the ground obtained with one embodiment of a spacer tool 200. Such a spacer tool 200 is, for example, but not limited to, a spacer tool having, as a rule, a rod with a support, on which a common pusher is threaded, pivotally connected with cranked pushers 201, which at the other end are connected to the support of the rod of the tool 200, the pushers 201 by protruding elbows oriented in the direction mainly of the middle of the sections 104 when the tool 200 is used. corresponding to the location of the sections 104, for which the corresponding control marks can be made on the handle or cable. After the fence post 100 has been driven into the pre-formed borehole to the required depth, the spacer tool 200 is driven inward to the required level, after which the common pusher is actuated hydraulically or otherwise, for example, but not limited to mechanical (through the use of a lever or a system of levers , or rack and pinion) method, and forces the protruding legs of the pushers across the cross-section of the column to act on the sections 104, forcing them to bend outward in the direction of the ground, thus forming a reliable anchorage connection with the ground. Preferably, if a cavity forms in the well due to the convergence of the walls of the column 100, this cavity can be filled with a reinforcing mortar (for example, but not limited to a concrete mixture) or reinforcing bulk material (for example, but not limited to, soil, crushed stone, gravel, sand concrete) , or a combination of both. By way of example, but not limitation, if the borehole of the pillar is made with a width greater than the width of the pillar 100, the anchor of the pillar 100 can be brought into working condition in the aforementioned manner, after which it is additionally reinforced with the aforementioned reinforcing mortar or reinforcing bulk material. ...

[0037] FIG. 4 illustrates an exemplary use of a fence anchor post 100 to anchor in the ground with another spacer tool 300. FIG. 5 shows an example of an anchorage in the ground obtained using another spacer tool 300. Such another spacer tool 300 is a rod, at one end of which movable pins 301 are fixed, containing stops made with the possibility of engaging with sections pre-formed on the inner walls of the 104 protrusions and / or slots (holes of any section), or with the possibility of resting on said protrusions and / or slots (holes of any section). Such other spacer tool 300 has a handle or cable adapted to set the tool 300 to a level corresponding to the location of the projections of the sections 104, for which purpose the handle or cable may be provided with appropriate reference marks. After the fence post 100 has been driven into the pre-formed borehole to the desired depth, such other spacer tool 300 is driven inward to the desired level where the finger stops of the tool 300 abut the pre-formed projections and / or slots on the sections 104. Thereafter, when while holding the post 100 in the mounting position, the tool 300 is pressed in some way, for example, not limited to hydraulic or mechanical (via a system of levers or a rack and pinion), into the post 100, due to which the finger stops acting on the protrusions act on the sections 104, forcing them to bend outward towards the ground, thus forming a reliable anchorage to the ground. Alternatively, such a spacer tool 300 is inserted into the column 100 from the bottom side in advance (prior to placing the column in the wellbore) so that the stops of the fingers of the tool rest against the projections of the sections 104 in the "bottom-up" direction. After that, if necessary, keeping the post 100 in the mounting position, they begin to pull the tool 300 in some way, for example, not limited to hydraulic or mechanical (through a system of levers or a rack and pinion), from the post 100 outward, due to which the stops acting on the protrusions fingers exert pressure on sections 104, forcing them to bend outward in the direction of the ground, thus forming a reliable anchorage to the ground. Preferably, in the case of the formation of a cavity in the well due to the closure of the walls of the column 100, this cavity can be filled with a reinforcing mortar (for example, but not limited to a concrete mixture) or reinforcing bulk material (for example, but not limited to soil, crushed stone, gravel, sand concrete) , or a combination of both. By way of example, but not limitation, if the borehole of the pillar is made with a width greater than the width of the pillar 100, the anchor of the pillar 100 can be brought into working condition in the aforementioned manner, after which it is additionally reinforced with the aforementioned reinforcing mortar or reinforcing bulk material. ...

[0038] FIG. 6 illustrates an exemplary use of a post for anchoring in the ground using a pulling tool 400. FIG. 7 shows an example of an anchorage in the ground obtained with a pulling tool 400. Such a pulling tool 400 is a rod with protrusions 401 at one end, for example, but not limited to, by a solid metal plate, the width of which is greater than the width of the tool rod. , but slightly less than the width of the inner section of the post 100. Preferably, the width of such a plate or the length of the projections are designed to freely pass inside the post 100 in the first position, for example, without limitation when the sides of the plate are parallel to the inner walls of the post 100, and with the impossibility of free passing inside the post 100 in a second position, for example, without limitation, when the sides of the plate are at an angle to the inner walls of the post 100. After the fence post 100 is driven into a pre-formed borehole to the required depth, for example, without limitation, inside the post pulling tool 400 to the full depth, after which the fence post 100 is lifted in the borehole, and the pulling tool 400 is rotated so that after lowering the post 100 in the opposite position, the protrusions of the tool 400 act as a support for the ends of the walls of the post 100. Alternatively, the pulling tool 400 can be used as a support when driving the pillar 100 into the borehole for the pillar, for which the aforementioned actions for driving and turning it can be carried out in advance. Thereafter, holding the post 100 in the mounting position if necessary, preferably leaning against the edge of the post, begin to pull the drawing tool 400 in some way, for example, but not limited to, hydraulic or mechanical (via a leverage or rack and pinion), from the post 100 outward, which creates a longitudinal upward force on the walls of the column 100, and at the same time, due to the pressing of the column 100 against the bottom of the well, a downward force is also created on the walls of the column 100, which leads to the fact that the sections 104 bend outward towards the ground, thus forming a reliable anchor connection to the ground. Preferably, in the case of the formation of a cavity in the well due to the closure of the walls of the column 100, this cavity can be filled with a reinforcing mortar (for example, but not limited to a concrete mixture) or reinforcing bulk material (for example, but not limited to soil, crushed stone, gravel, sand concrete) , or a combination of both. By way of example, but not limitation, if the borehole of the pillar is made with a width greater than the width of the pillar 100, the anchor of the pillar 100 can be brought into working condition in the aforementioned manner, after which it is additionally reinforced with the aforementioned reinforcing mortar or reinforcing bulk material. ...

[0039] The present description of the claimed technical solution demonstrates only particular options for implementation and does not limit other options for its implementation, since possible other alternative options for implementation that do not go beyond the scope of information set forth in this application should be obvious to a person skilled in the art, having the usual qualifications for which the declared technical solution is designed.

Claims (20)

1. A method of manufacturing a metal post of rectangular cross-section with a spacer anchor for a fence, which consists in the fact that in a metal pipe of rectangular cross-section in its part buried in the ground, longitudinal slots are made in the ribs at the same level, ensuring the formation of a spacer anchor by deformation of the sections of the edges of the pipe, the perimeters which are limited by the beginning and end of the corresponding slots, in the direction of the soil due to the application of a longitudinal force to the pipe walls or due to the application of a transverse force directed towards the soil to the inner surfaces of the pipe face sections. 2. A method according to claim 1, characterized in that said pipe has an anti-corrosion coating. 3. The method according to claim 1, characterized in that said sections of the pipe edges are made in such a way that the lateral force of the assembly tool is directed predominantly to the preferred point of deformation of the section to ensure deformation of the sections in the direction of the ground by bending. 4. The method according to claim 1, characterized in that said sections of the pipe edges are made in such a way that when a longitudinal force is applied to the pipe walls, they are deformed by bending in the direction of the ground. 5. A method according to claim 1, characterized in that said longitudinal cuts of the pipe ribs are made along a length corresponding to approximately half the length of the anchor extension, selected depending on the characteristics of the soil in which the borehole for the column is made. 6. A method according to claim 1, characterized in that said pipe is continuous in the longitudinal direction. 7. A method according to any one of claims. 1-6, characterized in that holes are made in the said sections of the pipe edges at the places of the supposed bending of the sections. 8. The method according to any one of claims. 1-6, characterized in that in the above-mentioned sections of the edges of the pipe bulges are made at the places where the sections are supposed to be bent. 9. A method according to any one of claims. 1-6, characterized in that in the above-mentioned sections of the edges of the pipe, concavities are made at the places of the supposed bending of the sections. 10. The method according to any one of claims. 1-6, characterized in that said sections of the ends of the pipe are made partially curved outward. 11. The use of a metal pipe of rectangular cross-section, which has a part buried in the ground, containing longitudinal slots made in the ribs at the same level, ensuring the formation of an expansion anchor by deforming pipe sections, the perimeters of which are limited by the beginning and end of the corresponding slots, in the direction of the ground due to application to the walls pipes of longitudinal force or by applying to the inner surfaces of the sections of a transverse force directed towards the ground, as a post for the fence. 12. The use according to claim 11, characterized in that said pipe has an anti-corrosion coating. 13. The use according to claim 11, characterized in that said sections of the pipe edges are designed in such a way that the lateral force is directed predominantly towards the preferred point of deformation of the section to ensure deformation of the sections in the direction of the ground by bending. 14. The use according to claim 11, characterized in that said sections of the pipe edges are designed in such a way that, when a longitudinal force is applied to the pipe walls, they are deformed by bending in the direction of the ground. 15. Use according to claim 11, characterized in that said longitudinal slots of the pipe ribs are made along a length corresponding to approximately half the length of the anchor extension, selected depending on the characteristics of the soil in which the borehole for the column is made. 16. Use according to claim 11, characterized in that said pipe is continuous in the longitudinal direction. 17. The use according to any one of paragraphs. 11-16, characterized in that the said sections of the edges of the pipe have holes in the places of the supposed bending of the sections. 18. The use according to any one of paragraphs. 11-16, characterized in that said sections of the edges of the pipe have bulges at the places of the supposed bend of the sections. 19. The use according to any one of paragraphs. 11-16, characterized in that the above-mentioned sections of the edges of the pipe have concavities at the places where the sections are supposed to be bent. 20. The use according to any one of paragraphs. 11-16, characterized in that said sections of the edges of the pipe are made partially curved outward.

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