RU98137U1 - DEVICE FOR DESCENT - Google Patents

Abstract

 1. The device for the descent, containing the first and second power elements interconnected by connecting elements, characterized in that in it the first and second power elements are made in the form of synthetic inelastic warp threads, and the connecting elements are made in the form of elastic weft threads, interwoven woven synthetic non-elastic warp yarns of the first and second strength elements with the formation of many layers, each layer being formed by elastic weft yarns intertwined with the warp threads of the first power element for an even number of passes equal to or greater than four passes, and transferred to inelastic main threads of the second power element, with which elastic weft yarns are interlaced for an even number of passes equal to or greater than four passes. ! 2. The descent device according to claim 1, characterized in that a gap is made between the nearest main threads of the first and second power elements. ! 3. The descent device according to claim 2, characterized in that the gap is from 0.2 to 200 mm.

Description

The claimed utility model relates to devices for lowering people and goods from buildings, high-rise structures and other high-altitude objects, and can be used to save people during fires and natural disasters.

It is known that the descent device selected as the closest analogue contains two parallel power elements made, for example, in the form of a cable and connecting elements connecting the power elements, while the connecting elements are made in the form of strips of woven material braiding the cables (Japanese Application for patent for invention No. H 08-004031, class IPC А62В 1/10, publ. 02/07/1996).

The disadvantage of this device is that the implementation of the connecting elements in the form of strips of fabric, leads to their slipping along the power elements (cables).

The technical result that can be obtained in the claimed utility model is the creation of a descent device in which there is no slipping of the connecting elements along the power elements and the descent is carried out with the required constant speed.

The technical result is achieved by the fact that, in the descent device containing the first and second power elements interconnected by connecting elements, the first and second power elements are made in the form of synthetic inelastic warp threads, and the connecting elements are made in the form of elastic weft threads interwoven woven synthetic non-elastic warp yarns of the first and second strength elements with the formation of many layers, each layer being formed by elastic weft yarns, bound with the main threads of the first power element for an even number of passes equal to or more than four passes, and transferred to inelastic main threads of the second power element with which elastic weft threads are interlaced for an even number of passes equal to or greater than four passes.

And also by the fact that a gap is made between the nearest inelastic main threads of the first and second power elements, which allows descent at the required constant speed, while the gap is from 0.2 to 200 mm.

The claimed utility model is illustrated using the schemes shown in figures 1-3.

Figure 1 presents the device for descent;

figure 2 presents the device for descent during operation.

The claimed device for descent consists of a first power element 1 and a second power element 2, each of which is made of synthetic inelastic warp threads 4, interwoven in a woven fashion by connecting elements made in the form of elastic weft threads 3, with the formation of many layers. Each layer is formed by elastic weft threads 3, interwoven with the main threads 4 of the first power element 1 for an even number of passes equal to or greater than four passes, and transferred to inelastic main threads 4 of the second power element 2, with which the elastic weft threads 3 are bound for an even number passes equal to or greater than four passes. An even number of passes of the elastic weft threads 3 allows you to securely fix the elastic weft threads 3 on the inelastic main threads 4 of the first and second power elements 1 and 2, and thereby prevent slipping of the elastic weft threads 3 along the power elements 1 and 2.

The main threads 4 of the first and second power elements 1 and 2 closest to each other are located close to each other or a gap S is made between them, which can be from 0.2 to 200 mm.

The claimed device for the descent works as follows.

Before starting the descent, one free end of the first power element 1 is attached to the place where the descent begins. The adjacent fixed end of the first power element 1, the free end of the second power element 2 is attached to the load or person (hereinafter the object), which must be lowered. Then the object is suspended at the indicated end of the second power element 2, as shown in FIG.

After the object is suspended on the free end of the second power element 2, several elastic weft threads 3 closest to the indicated free end are stretched simultaneously, forming a group of loaded connecting elements, with a tensile force equal to the gravity created by the object, indicated in FIG. 2 as P, the direction of which is shown in the same figure 2 by an arrow.

It should be noted that elastic threads (for example, latex or polyurethane threads) are able to stretch, increasing their length by 50-500%, so in this design of the descent device even a minimum clearance of 0.2 mm allows elastic weft threads 3 to stretch well . However, a larger gap S between the first and second power elements 1 and 2, shown in Fig. 1, allows the flexible weft yarns 3 to be more freely released and quickly stretched from weaving with the main non-elastic yarns 4.

The main threads 4 forming the first and second power elements are selected inelastic to avoid stretching during the descent of the object, since when stretching, the vertical gap between the elastic weft threads 3 can significantly increase, which will lead to a significant increase in the speed of descent of the object and even damage to it contact with the surface onto which the object should be lowered. As inelastic warp yarns 4, it is possible to use, for example, kapron yarns or yarns made of aromatic polyamide, or other yarns similar to them, capable of stretching from 0 to 20%. This combination of warp and weft threads completely eliminates slipping of the weft threads during the descent of the object.

The distribution of tensile forces on the elastic weft yarn 3 from the group of loaded connecting elements is uneven. All stretched elastic weft yarns 3 are located in one plane, the main threads 4 of the first power element 1 and the second power element 2 are located in the same plane. The most loaded will be the elastic weft thread 3, which is closest to the free end of the first power element 1, which fixed in place of descent. The next, according to the magnitude of the loading (tension), will be the thread 3 following the elastic weft thread 3 in the direction of the descent of the object, which is closest to the free end of the first power element 1, which is fixed at the place of descent. Further, the degree of loading (tension) of each elastic weft thread 3 from the group of loaded connecting elements will decrease in the direction of descent of the object.

Thus, the elastic weft yarn 3 is subjected to tensile forces until they break. In this case, the elastic weft yarns 3, from the group of loaded connecting elements, are torn in a queue, starting with the elastic weft yarn 3, which is the closest (extreme upper elastic weft yarn 3) to the free end of the first power element 1, which is fixed in place of the descent, and further towards the descent of the object. The number of threads of the 3rd group of loaded connecting elements, all other things being equal, the descent is constant, especially when descending inanimate objects that do not create oscillations when changing their position in space. After tearing the elastic weft thread 3, which is closest to the free end of the first force element 1 fixed at the place of descent, the elastic weft thread 3, which was closest to the group of loaded power elements, is subjected to tensile forces. As noted above, elastic weft yarns 3 form a plurality of layers on the first and second strength elements. Each layer is formed by elastic weft threads 3, interwoven with the main threads 4 of the first power element 1 for an even number of passes equal to or greater than four passes, and transferred to inelastic main threads 4 of the second power element 2, with which the elastic weft threads 3 are bound for an even number passes equal to or greater than four passes. To fix the elastic weft threads 3 on inelastic warp threads 4, at least 4 passes of the specified thread 3 are required. A larger number of passes allows a more reliable fixation of the position of the elastic weft thread 3, as a result of which the descent will be carried out at the required constant speed, however, increasing the number of passes weakens the device for descent.

Thus, tearing each elastic weft thread 3 alternately, the free end of the second power element 2 on which the object is suspended is moved along the surfaces of the first and second power elements 1 and 2 and the object is lowered. Moreover, the descent of the cargo is carried out at a constant speed, which may have deviations in magnitude of no more than 25%.

It should be noted that the speed of descent of the object depends on the thickness of the elastic weft thread 3, the total width of the first and second strength elements 1 and 2 and the distance between them and the step between the passages of the weft. Therefore, it is recommended to choose a step between elastic weft threads 3, comprising from 0 to 5 mm, and the diameter of the threads from 0.2 to 1 mm. With such dimensions, the descent speed will be from 0.2 to 2 m / s.

Thus, due to the fact that the first and second power elements are made in the form of synthetic inelastic warp threads, and the connecting elements are made in the form of elastic weft yarns that weave the synthetic non-elastic warp threads of the first and second power elements with the formation of many layers, while each layer is formed by elastic weft threads interwoven with the main threads of the first power element in an even number of passes equal to or greater than four passes and thrown on inelastic main threads of the second power element, with which the elastic weft threads are intertwined for an even number of passes equal to or greater than four passes, and also due to the fact that a gap is made between the nearest main threads of the first and second power elements, there is no slippage in the descent device connecting elements along the power elements and the descent is carried out with the required constant speed.

Claims (3)

1. The device for the descent, containing the first and second power elements interconnected by connecting elements, characterized in that in it the first and second power elements are made in the form of synthetic inelastic warp threads, and the connecting elements are made in the form of elastic weft threads, interwoven woven synthetic non-elastic warp yarns of the first and second strength elements with the formation of many layers, each layer being formed by elastic weft yarns intertwined with the warp threads of the first power element for an even number of passes equal to or greater than four passes, and transferred to inelastic main threads of the second power element with which elastic weft yarns are interlaced for an even number of passes equal to or greater than four passes. 2. The descent device according to claim 1, characterized in that a gap is made between the nearest main threads of the first and second power elements. 3. The device for the descent according to claim 2, characterized in that the gap is from 0.2 to 200 mm