RU195913U1 - WELL RING - Google Patents

Abstract

The utility model relates to the field of public utilities, in particular to manholes, and can be used to construct sewer, water, heating and other networks. The technical result of this utility model is to increase the strength of the well ring and reduce its weight. This is achieved by the well ring is a cylindrical frame with a diameter of 0.5 to 2.5 meters and a height of 0.5 to 2.5 meters, made of a composite fiberglass reinforcing mesh having thicknesses from 2 to 16 millimeters and a binder is uniformly impregnated over the entire surface. From 1 to 20 layers of fiberglass are wound on the frame, and all layers of fiberglass must have a height exactly matching the height of the frame. Each of the layers of fiberglass is uniformly impregnated with a binder. Polyester, epoxy resins with appropriate hardeners are used as a binder material. As a reinforcing mesh basalt can be used. On top of the well ring from one of its ends is made a connecting element in the form of a bell. 1 ill.

Description

The utility model relates to the field of public utilities, in particular to manholes, and can be used in the construction of sewage wells, water supply, heating and other networks.

Known wells of cable ducts designed to protect and facilitate the detection of accidents and cable repairs [Utility model No. 88713, IPC: E04H5 / 06, E02D29 / 12, H02G9 / 10; Utility Model No. 134955, IPC: E02D29 / 12; Utility Model No. 151543, IPC: E04H5 / 06]. Such wells are a monolithic or hollow body with a neck made of polymer materials and additionally containing stiffeners. Polymeric materials, such as polyethylene, are resistant to thermooxidative aging, which is the advantage of this type of wells. However, to protect and strengthen the structure, it is necessary to use additional frames, for example from steel strands.

The most common are sewer wells, which are a monolithic ring made of reinforced concrete or reinforced concrete rings rigidly connected to each other by special ties [Patent No. 2629780, IPC: E02B11 / 00, E03F5 / 02; Utility Model No. 179696, IPC: E03F5 / 02, B28B7 / 00; Utility Model No. 170607, IPC: E02B11 / 00; Utility Model No. 130614 IPC: E03B3 / 08; Utility Model No. 130615 IPC: E03B3 / 18; Utility Model No. 10192 IPC: E03F5 / 00; Utility Model No. 57305, IPC: E03F5 / 02]. For maximum protection of the structure from the damaging effects of water, soil and mechanical pressure, a sheet protective cover is additionally used [Utility model No. 189310, IPC: E03F5 / 00, E02D29 / 045, E04F13 / 21], and a protective reinforcing coating of fiberglass is applied [Patent No. 2460001, IPC: F16L55 / 1645; Utility Model No. 28141, IPC: E03F 5/04, E03F11 / 00]. Facing the inner surface of the reinforced concrete ring can be made of plastic sheets with anchor ribs [Utility model No. 187646, IPC: E03F 5/00; Utility Model No. 162268, IPC: E03F 5/00; Utility Model No. 152410, IPC: E03F5 / 00]. The advantage of using polymeric materials for facing is that the installation of the facing coating of the inner surface of the reinforced concrete ring can be carried out directly at the construction site without dismantling or replacing the entire existing structure. The use of reinforced concrete structures for the production of sewer wells currently reduces the cost of the finished product and, due to this, is widely used in large cities where a large number of such structures are needed. Reinforced concrete is resistant to moisture and freezing, it is durable, but for protection it still requires additional lining with polymers that protect concrete from damage, and the metal reinforcement base from corrosion. Also, the complexity of manufacturing reinforced concrete structures is that the structure is very heavy, equipment for mixing the mortar, as well as special equipment for loading and mounting the well, are needed.

Wells are also known, which are cylinders made of polymer-metal compositions [Utility Model No. 101055, IPC: E02D29 / 12]. Such structures are easy to manufacture and easy to install due to their low weight. The disadvantage of such structures is the low strength of the finished products, since instead of a solid metal base, a metal component is used.

Currently, they are striving to make sewer pipes and sewer wells from cheaper and lighter materials, which are at the same time durable and durable. Some types of plastics are resistant to acidic and other aggressive environments. Fiberglass materials are frost-resistant and are widely used for hydro- and thermal insulation of pipes.

A well-known engineering plastic well [Utility model No. 179010, IPC: E03F11 / 00] is a plastic pipe wound in a spiral, and the coils are welded with a polymer composition. The advantage of this utility model is the simplicity of manufacturing a well, low cost, light weight of the finished product, as well as the lack of need for waterproofing. The disadvantage of this design is the low strength.

Known multi-sectional passage well, made of rings of polymeric material and having additional stiffeners [Patent No. 2188910, IPC: E03F5 / 02, E02D29 / 12]. Such a well has light weight and tightness. The disadvantage of this well is its low strength due to the use of polymer material.

The technical result of this utility model is to increase the strength of the well ring and reduce its weight.

This is achieved by the fact that the well ring is a cylindrical frame with a diameter of 0.5 to 2.5 meters and a height of 0.5 to 2.5 meters, made of a composite fiberglass reinforcing mesh having a thickness of 2 to 16 millimeters and uniformly impregnated with a binder over the entire surface. From 1 to 20 layers of fiberglass are wound on the frame, and all layers of fiberglass must have a height exactly matching the height of the frame. Each of the layers of fiberglass is uniformly impregnated with a binder. Polyester, epoxy resins with appropriate hardeners are used as a binder material. As a reinforcing mesh basalt can be used. On top of the well ring from one of its ends is made a connecting element in the form of a bell.

This design has a low weight and high strength. The presence of fiberglass impregnated with a binder eliminates the need for additional waterproofing of the product. Fiberglass reinforcement makes the finished product strong enough in comparison with wells made of polymeric materials. The product is easy to transport and assemble. The presence of a docking ring makes it possible to connect well rings to each other, which in turn allows you to make wells of great depth.

The essence of the utility model is illustrated in the drawing.

In FIG. 1 shows a well ring corresponding to the present utility model

1 - layers of fiberglass impregnated with a binder;

2 - reinforcing frame;

3 - docking ring.

The well ring is a frame (1) made of a reinforcing stack (fiberglass or basalt), to which fiberglass layers (2) are uniformly glued using a binder, and all layers of fiberglass (2) have a height exactly matching the height of the frame ( 1). On one side of the well ring there is a docking ring (3) made of fiberglass layers and representing a bell.

The utility model is as follows.

A reinforcing stack made of fiberglass or basalt is wound on a technological cylinder (mold) with a diameter of 0.5 to 2.5 meters and a height of 0.5 meters to 2.5 meters, and the thickness of the reinforcing layer should be from 2 to 16 mm. The reinforcing stack is attached to the process cylinder (form) mechanically with a gap between it and the form using the process gasket. The frame of the reinforcing mesh is impregnated evenly over the entire surface with a binder. Fiberglass is wound over the reinforcing mesh (from 1 to 20 layers), each layer of which is covered by impregnation of a binder evenly over the entire surface during winding. On one side, over the well ring, with a protrusion 5 cm from the edge of the well ring, layers of fiberglass are wound, which are evenly impregnated with a binder during winding. These additional layers will play the role of the docking ring (bell), and the thickness of the docking ring should not exceed the thickness of the well ring itself. After the binder layers are completely dry, the finished well ring is removed from the technological form and transported to the installation site. If a well of great depth is needed, then several ready-made well rings are inserted one into another with simultaneous sizing with sealant.

Sources of information:

1. Utility model No. 88713, IPC: E04H5 / 06, E02D29 / 12, H02G9 / 10;

2. Utility model No. 134955, IPC: E02D29 / 12;

3. Utility model No. 151543, IPC: E04H5 / 06;

4. Patent No. 2629780, IPC: E02B11 / 00, E03F5 / 02;

5. Utility model No. 179696, IPC: E03F5 / 02, B28B7 / 00;

6. Utility model No. 170607, IPC: E02B11 / 00;

7. Utility model No. 130614 IPC: E03B3 / 08;

8. Utility model No. 130615 IPC: E03B3 / 18;

9. Utility model No. 10192 IPC: E03F5 / 00;

10. Utility model No. 57305 IPC: E03F5 / 02;

11. Utility model No. 189310, IPC: E03F5 / 00, E02D29 / 045, E04F13 / 21;

12. Patent No. 2460001, IPC: F16L55 / 1645;

13. Utility model No. 28141, IPC: E03F 5/04, E03F11 / 00;

14. Utility model No. 187646, IPC: E03F 5/00;

15. Utility model No. 162268, IPC: E03F 5/00;

16. Utility model No. 152410, IPC: E03F5 / 00;

17. Utility model No. 101055, IPC: E02D29 / 12;

18. Utility model No. 179010, IPC: E03F11 / 00;

19. Patent No. 2188910, IPC: E03F5 / 02, E02D29 / 12.

Claims (1)

A well ring, which is an element in the form of a hollow cylinder with a diameter of 0.5 to 2.5 meters and a height of 0.5 to 2.5 meters, made of an inner reinforcing layer of a composite fiberglass reinforcing mesh having a thickness of 2 to 16 millimeters evenly impregnated with a binder over the entire surface, and on which the outer layers of fiberglass are wound in an amount from 1 to 20, having a height exactly matching the height of the inner reinforcing layer, and a connecting hour is made on top of the well ring from one of its ends s in the form of a bell.

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