RU152314U1 - FASTENING ELEMENT FOR FIXING HEAT-INSULATING MATERIALS - Google Patents

Abstract

1. A fastener for fixing heat-insulating materials, comprising a pin with a cylindrical body and a plastic heat-shielding head, an integral plastic holding element, which consists of a pressure plate, a sleeve, a guide pin, and a seat in the form of a hole located between the sleeve and the pressure plate for placement the head of the pin after its introduction, characterized in that the head of the pin is provided with an outer expansion ring from the side of the pressure plate, and the inlet of the hole of the holding element that is provided with mating stepped extension in the head of the pin formed as a polyhedral socket blind hole, as well as inside the holding member at the bottom of the seat of the pin protrusion is formed as an annular ploschadki.2. A fastener according to claim 1, characterized in that the body of the pin is made of plastic. 3. The fastener according to claim 1, characterized in that the body of the pin is made of metal.

Description

The claimed technical solution relates to the field of construction of buildings and structures, in particular to devices for attaching heat-insulating materials to load-bearing structures, both by the shock method and the shock-free method of mounting fasteners.

A device for fixing heat-insulating plates, made in the form of a dowel, containing a polymer fastener in the form of a rod with a longitudinal hole, consisting of a head zone with a pressure plate at the end and the main zone, as well as a fixing element in the form of a nail with a hat, mounted in a longitudinal hole the rod with the possibility of placing its cap in the head zone, and the body in the main zone of the rod, characterized in that the cap at the ends is made in the form of two disks in contact with their lateral cylindrical surfaces with a cylindrical surface of the longitudinal hole of the head zone of the rod, and stiffening ribs located between them, mating with the respective ends with disks, on the lateral cylindrical surfaces of which are made at least one flat or one longitudinal groove, while paired with a hat part of the nail is installed in the longitudinal hole of the rod for a length exceeding the length of the cap and has a diameter equal to the diameter of the longitudinal hole (RF patent No. 2291988, publication date 01/20/2007, IPC F16B 13/00, E04B 1/76, “Anchor plug for heat insulating boards”).

The implementation in the known device of the nail head in the form of two disks of the same diameter and the stiffeners located between them does not provide the necessary sealing of the dowel, which impairs its thermal insulation and the reliability of the dowel.

The absence of a safety element that acts as a shock absorber, when exceeding the impact norm, leads to the transfer of all impact energy from the nail to the fastener, which reduces its reliability.

Installation of the fixing element - nail, in the fastening element with the help of impacts, the force of which exceeds the impact rate, is accompanied by direct impact contact of the supporting surface of the lower nail disk with the bottom of the cavity of the fastening element, which contributes to the appearance of cracks in the sections of the fastening element having low safety margins, which reduces reliability of fixing heat-insulating plates during shock mounting.

The design of the nail head does not provide the possibility of placing a blind hole on it for introducing the working body of a screwdriver in the center of the upper disk, which limits the use of mounting tools that create torque, thereby excluding the use of wall plugs for porous walls, such as foam concrete or porous brick.

The prototype of the claimed device is a fastener for fixing heat-insulating plates on a supporting structure, containing a pin with a metal main body and a head formed by a plastic shell, a holding element made of plastic, which has a pressure plate, a sleeve, a guide pin, and an opening between the sleeve and the pressure plate for placing the head after its insertion, characterized in that the head is configured to, after insertion of the pin, into the retaining element of radial contact with the inside the wedge wall of the hole after inserting the pin into the retaining element, and at an axial distance from the end of the metal main body of the pin facing the head equal to at least 5 mm, an upper radial seal is formed between the head and the inner wall of the hole (RF patent No. 2161229, publication date 12/27/2000, IPC E04B 1/76, F16B 13/02, “Fastener for fixing heat-insulating materials, pin for installation in a holding element”).

In this device, the execution of the head of the pin of a cylindrical shape, without a stepwise change in diameter, does not provide the necessary level of tightness, and, therefore, waterproofing and thermal insulation of the fastener, which reduces the reliability of the fastener. However, the accuracy of centering the pin head relative to the hole of the retaining element is not sufficiently ensured.

The implementation in the prototype of the hole in the head of the pin with a cross section of complex shape in the form of a six-pointed star complicates the design of the pin and increases the cost of the mounting tool used, and also narrows the scope of application of the fastener.

In addition, during the installation process for installing the pin, the impact force of the tool is transmitted from the pin directly to the holding element and, when the standard impact force is exceeded, it causes cracks in the sections of the holding element having the least safety margins, which leads to a decrease in the reliability and durability of the fastening element.

The objective of the proposed technical solution is to increase the reliability of the fastener for fixing heat-insulating materials on supporting structures.

The task is achieved due to the fact that in the fastener for fixing heat-insulating materials containing a pin with a cylindrical body and a plastic heat-shielding head, an integral plastic retaining element, which consists of a pressure plate, a sleeve, a guide pin, and a seat in the form of a hole located between a sleeve and a pressure plate for accommodating the pin head after it has been inserted, the pin head is provided with an outer expansion ring on the side of the pressure plate and the input part the holes of the retaining element are made in reciprocal stepwise expansion, a socket in the form of a polyhedral blind hole is made in the head of the pin, and also a protrusion in the form of an annular area is made on the bottom of the seat of the pin, while the body of the pin can be made of plastic or metal.

The implementation in the device of the pin head with an outer expansion ring from the side of the pressure plate and the inlet part of the hole of the retaining element with a reciprocal stepwise expansion allows to improve the tightness and thermal insulation of the connection of the pin head with the retaining element, which increases the reliability of the fastener. This increases the reliability and accuracy of fixing the head of the pin in the seat of the holding element.

The execution in the head of the pin head of the socket in the form of a multi-faceted blind hole designed to accommodate the tool during mounting and dismounting of the pin increases the reliability of fastening the heat-insulating material to the bearing surface, especially on surfaces with low bearing capacity.

The use of a multi-faceted hole in the head of the pin ensures reliable transmission of torque due to the uniform distribution of torque across all faces of the hole of the pin, in addition, it allows the use of commonly available screwing devices and their working bodies with a cross section in the form of a polyhedron.

The use of a protrusion in the form of an annular platform, made at the bottom of the seat inside the retaining element, provides increased reliability of the fastening element with a dynamic, impact method of its installation, as in the case of elastic deformation of the annular protrusion that receives the energy of the normative impact, determined by the design and applied materials of the fastener, and in the case of elastic-plastic deformation of the protrusion, perceiving the impact energy exceeding the energy of the normative impact. In any case, the installation of the protrusion in the form of an annular platform is an elastic-damping element of shock protection during the installation of the fastener.

If the deformation of the annular platform is only elastic, then the protrusion can be considered as an elastic element that softens the impact, and if it is elastic-plastic, then as an elastic-plastic element in which most of the energy is spent on plastic deformation of the annular protrusion, and less - on elastic deformation.

The safety margin of the fastening element increases due to a decrease in the magnitude of the shock load transmitted to the holding element.

Thus, the reliability of the fastener is improved by increasing the strength of the retaining element during the shock method of mounting the pin.

The presence of a protrusion in the form of an annular platform at the bottom of the seat of the retaining element assembly with a pin head installed in the seat provides a guaranteed air gap of 0.5 mm between the lower annular surface of the pin head and the ring plane of the bottom of the seat of the retaining element, which improves the thermal insulation of the fastener and increases reliability in low temperature and / or high humidity conditions.

The presence of distinctive features in the claimed technical solution allows us to conclude that it meets the condition of patentability “novelty”.

The patentability condition "industrial applicability" is confirmed by the example of a specific implementation.

The essence of the technical solution is illustrated by technical drawings, where

in FIG. 1 shows a fastener;

in FIG. 2 - general view of the pin;

in FIG. 3 is a longitudinal section of a holding member;

in FIG. 4 is a longitudinal section of a holding element (the sleeve is cut off);

in FIG. 5 is a longitudinal local section of the bottom of the seat of the retaining element;

in FIG. 6 is a longitudinal section through a pin head;

in FIG. 7 is a top view of a pin head.

The fastener for fixing the heat-insulating materials 1 (Fig. 1) on the supporting structure of buildings and structures, for example on the wall 2, consists of an integral plastic retaining element 3, which is placed in the wall 2, and a pin 4, consisting of a cylindrical body 5 (Fig. 2) and a plastic thermo-protective head 6, which is fixed in the holding element 3. A plastic thermo-protective head 6 seals the pin 4, fixed in the holding element 3.

The cylindrical body 5 of the pin 4 can be both plastic and metal. The choice of material of the cylindrical body 5 of the pin 4 is determined by tasks that take into account factors such as the material of the supporting structure or the magnitude of the shear load acting on the fastener. For rigid load-bearing structures, such as concrete, it is necessary to install a pin 4 with a metal body 5 (Fig. 6), and for non-rigid substrates, for example, from porous materials, the plastic body 5 of pin 4 should be used, that is, it is possible to use pin 4, head 6 and the body 5 of which is made of one type of plastic.

The body 5 of the pin 4 (Fig. 2) is driven hammered with annular notches 7 in the case of shock mounting of the fastener, or screwed in in the case of shockless mounting.

The head 6 of the pin 4 is provided with an outer expansion ring 8 (Fig. 6) from the side of the pressure plate 9 of the holding element 3 and, accordingly, the inlet part of the hole 10 of the pin 4 in the holding element 3 is made with a reciprocal step extension 11 (Fig. 3, four).

In addition, in the head 6 of the pin 4, a socket 12 is made in the form of a hexagonal blind hole (Fig. 7) for introducing into it the hexagonal working body of the screw device, which provides convenience and simplicity of both mounting and dismounting of the fastener.

The one-piece plastic retaining element 3 (Fig. 3) consists of a pressure plate 9, a sleeve 13 with longitudinal centering ribs 14 on its inner surface, guiding pin 4, a seat 10, located between the sleeve 13 and the pressure plate 9, designed to accommodate the head 6 pin 4 after its insertion.

Also, inside the retaining element 3 at the bottom 15 of the seat 10, a protrusion 16 is made in the form of an annular platform (Fig. 4, 5) with a height b of 0.5 mm, which serves as both an elastic-damping element during the shock mounting of the fastener and the elastic the stop of the thermal head 6 of the pin 4 in the retaining element 3 with an unshocked mounting option. The height of the protrusion of the annular platform, equal to 0.5 mm, is determined by the designs of the retaining element and the pin, the choice of their materials and is checked by tests.

A fastener for fixing heat-insulating materials 1 (Fig. 1) is mounted on a supporting structure, wall 2, as follows.

A one-piece plastic retaining element 3 is inserted into the hole of the wall 2, on which the heat-insulating material 1 is applied, for example a heat-insulating plate, with a corresponding coaxial hole, until the pressure plate 9 presses the heat-insulating material 1 against the wall 2.

Then the pin 4, which performs the functions of the locking element, is inserted into the longitudinal hole of the seat 10 of the holding element 3.

In this case, the annular notches 7 of the body 5 of the pin 4 come into contact with the inner longitudinal ribs 14 (Fig. 3) of the sleeve 13 of the holding element 3 in the case of shock mounting, which ensures centering of the pin 4 relative to the longitudinal opening of the holding element 3.

The movement of the pin 4 inside the holding element 3 continues to the position where the heat-protective head 6 of the pin 4 enters the longitudinal hole of the seat 10 of the holding element 3 and then the movement of the pin 4 continues to the position when the lower annular plane of the heat-protecting head 6 of the pin 4 abuts against the annular protrusion 16 (Fig. 5) the bottom 15 of the seat 10 of the retaining element 3.

Upon completion of the movement of the pin 4 inside the retaining element 3, the expansion ring 8 (Fig. 6) of the heat-shielding head 6 enters the stepped expansion 11 of the hole of the retaining element 3, ensuring the elimination of leaks in the seat 10 of the retaining element 3.

Shockless mounting of the fastener by screwing the pin 4 into the holding element 3 is carried out using a screw device. Removing the pin 4 by unscrewing, if necessary, can be done with the same screwdriver with reverse.

The hexagonal working body of the screw-tightening torque generating device transmits rotation to a geometrically similar hex-hole of the socket 12 of the heat-shielding head 6 of the pin 4, thereby providing translational movement of the pin 4 inside the holding element 3 with a metered low speed. At the same time, the moment of the end of screwing is reliably and easily determined by the installer of the fastener visually.

With shockless movement of the pin 4 by screwing it in contact with the lower annular plane of the thermal head 6 of the pin 4 and the bottom 15 of the seat 10 of the retaining element 3, a slight elastic deformation of the protrusion 16 in the form of an annular platform occurs.

The shock-free installation of the fastener in question by screwing the pin 4 into the retaining element 3 provides increased reliability in walls with low bearing capacity, for example in walls of porous brick or foam concrete.

Shock mounting is carried out by striking the heat-protective head 6 of the pin 4, that is, by driving it, with the corresponding pulse longitudinal displacements of the pin 4.

It is very difficult to limit the energy of impact produced, as a rule, manually to the head 6 of the pin 4, to the norm, including due to the uncertainty of the installation moment when it is necessary to complete the process of driving the pin 4.

When the pin 4 is mounted by impact force, elastic deformation of the annular protrusion 16 occurs at the bottom 15 of the seat 10 of the holding element 3, that is, the impact energy is elastically perceived and partially extinguished by the protrusion 16 in the form of an annular platform.

When the pin is mounted by impact force above normal, elastoplastic deformation of the protrusion 16 in the form of an annular platform occurs, which significantly reduces the load on the sections of the retaining element 3, which have minimal safety margins.

When the fastener is used, after the installation is completed, the sealing of the fastener is improved due to the introduction of an expansion ring 8 on the thermal head 6 of the pin 4 and a corresponding stepwise expansion 11 of the inlet portion of the retaining element 3, on the path of moist air from the atmosphere inside the retaining element 3, which improves thermal insulation and increases the reliability of the fastener.

Thus, the implementation of the fastener for fixing heat-insulating materials with a pin, the head of which is equipped with an expansion ring and has an hexagonal blind hole from the end, as well as a retaining element provided with a protrusion in the form of an annular platform at the bottom of the seat, provides increased mounting reliability and reliability of operation of the fastener item.

Claims (3)

1. A fastener for fixing heat-insulating materials, comprising a pin with a cylindrical body and a plastic heat-shielding head, an integral plastic holding element, which consists of a pressure plate, a sleeve, a guide pin, and a seat in the form of a hole located between the sleeve and the pressure plate for placement the head of the pin after its introduction, characterized in that the head of the pin is provided with an outer expansion ring from the side of the pressure plate, and the inlet of the hole of the holding element that is provided with mating stepped extension in the pin head is in the form of polyhedral socket blind hole, and the inside retaining member on the bottom of planting pin place a projection in the form of an annular pad. 2. The fastener according to claim 1, characterized in that the body of the pin is made of plastic. 3. The fastener according to claim 1, characterized in that the body of the pin is made of metal.

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