RU112231U1 - ROOFING ELEMENT AND DEVICE FOR HEATING THE HEAT - Google Patents

Abstract

1. A roofing element, characterized by production by extrusion from a polymer material and the presence of internal cavities intended for circulation through the roofing element of the coolant, while the roofing element is configured to connect the internal cavities to the external, in relation to the element, coolant circulation system. ! 2. Roofing element according to claim 1, characterized in that a UV stabilizer is introduced into the polymer material. ! 3. Roofing element according to claim 1, characterized in that it is made of two or more layers. ! 4. Roofing element according to claim 1, characterized in that it is made in the form of a flat or wavy plate. ! 5. Roofing element according to claim 1, characterized in that it is in the form of a tile. ! 6. Roofing element according to claim 1, characterized in that it is provided with a cladding, for example decorative, on at least one side thereof. ! 7. The roofing element according to claim 1, characterized in that it contains a dye that allows the element to be given the desired color range. ! 8. A device for heating the heat carrier, comprising a heat exchanger connected to the heat carrier circulation system, characterized in that the roof of the building is used as the heat exchanger, including the roofing elements connected to each other made according to any one of claims 1-7. ! 9. The device according to claim 8, characterized in that the roofing elements on the roof of the building are placed obliquely. ! 10. The device according to claim 8, characterized in that the roof of the building roof consists of overlapping roofing elements. ! 11. The device according to claim 8, characterized in that the coolant circulation system contains collectors made in the form of elements

Description

A group of utility models relates to construction, namely, to the construction of the roof of a building, which allows the placement and use of devices that accumulate solar energy and are capable of exchanging heat with the environment.

Various devices are known for using the roof of a building to heat water using solar energy (for example, US patent No. 4201193, French patent No. 2566032, German patent No. 4006116, Chinese patent No. 1749671).

A sun-receiving device is known, combined with the roof of the building, containing a flat portion of the building's insulated roof with a waterproofing bitumen layer deposited on its surface, in which heat exchanger pipes are placed, on whose surface a metal mesh is laid (ed. St. USSR No. 1746155, IPC F24J 2/24 1992 publication).

A known solar collector comprising a housing made of a heat-insulating material based on polyurethane foam, a heat-absorbing plate mounted on the bottom of the housing, and transparent insulation, while the heat-insulating material is made anisotropic in the form of three layers with waterproof membranes made of polyurethane between the layers, while the outer layer has a porosity lower than the porosity of the other two layers (ed. St. USSR 1815525, F24J 2/02, 1991 publication).

Known solar collector containing a profiled metal surface made of sheet material and serving as a roof, while under the roof there is a flexible corrugated pipe filled with a working medium in the form of gas or liquid and made of polymeric material, and the corrugated pipe is placed on the inside of the profiled a metal surface in its gutters and is configured to absorb thermal energy from a roof heated from the outside by the working medium (RF patent No. 10 4680, IPC F24J 2/00, 2011 publication).

A known solar collector containing a heat-receiving element and devices for entering and exiting the heat carrier and which is an element of the roof of the roof, the solar collector comprising a housing hermetically connected to the heat-receiving element, the last of which has a developed surface either in the form of corrugations, or in the form of ribs, or in the form of needle protrusions on one side, which is facing the coolant, or on both sides, while on the case there are mounts for connecting the collectors to each other and for attaching them to the roof frame, and the joints of the collectors are hermetically sealed with sealant (RF patent No. 2183801, IPC F24J 2/04, publication 2002).

Known devices are economically inefficient when used as the roof of a building for heating water using solar energy.

The roof of a building is known with a device that accumulates solar energy, and consists of several elements connected to each other with communicating cavities, each element comprising a hollow body of heat-insulating material and a heat carrier and a light-absorbing receiver with a working surface located inside the body and in thermal contact, onto which solar radiation is incident (RF patent No. 27195, IPC F24J 2/05, 2003 publication).

The technical task of the proposed group of utility models is to expand the arsenal of technical equipment related to the roof structure of a building, which allows the placement and efficient use of solar energy storage devices.

The proposed technical solutions are technological in manufacturing and use, have a minimum cost, and ensure the efficient use of solar energy for heating the coolant.

The essence of the proposed group of utility models is as follows.

The roofing element is made by extrusion from a polymeric material and contains cavities inside it intended for circulation through the roofing coolant element, while the roofing element is configured to connect internal cavities to an external coolant circulation system relative to the element.

The roofing element can be made of two or more layers.

The roofing element contains a UV stabilizer.

The roofing element can be made in the form of a plate of a flat or wavy shape.

The roofing element can be made in the form of tiles.

The roofing element can be made with a lining, for example, decorative, at least on one side of it.

The roofing element may contain a dye, allowing you to give the element the desired color scheme.

A device for heating a heat carrier comprises a heat exchanger in communication with a heat carrier circulation system, wherein the roof of a building roof including said roof elements connected to each other is used as a heat exchanger.

Roofing elements on the roof of the building are placed obliquely.

The roof of the building roof consists of overlapping roofing elements.

The coolant circulation system contains collectors made in the form of tubular type elements.

The coolant circulation system contains a thermos storage device located under the ridge of the building roof above the location of the cavities of the roofing elements.

The cavities of each roofing element are connected via collectors in parallel or in series.

The cavities in each two nearby roofing elements are connected in series via a collector.

Thermos-storage system of the coolant circulation system can be made with a triangular cross-section.

In the drawings, the proposed technical solution is depicted, in which Fig. 1 shows a roofing element; figure 2 schematically shows the roof of the building with a roof; figure 3 is a cross section of the roof of the building with a roof; figure 4 - roofing element with lower and upper collectors (longitudinal section); figure 5 is an embodiment of a building roof with a roof; figure 6 is a cross section of the roof of the building with a roof in figure 5.

The roofing element 1 is made in the form of a wavy plate formed by extrusion of a polymer material. On the roof of the building, the roofing elements 1 are fastened to each other using a standard fastener, forming the roof of the building.

Each roofing element contains inside itself cavities 2, intended for circulation through the roofing element of the coolant.

Cavity 2 is in communication with an external (with respect to the element) circulation system of the coolant, including the lower 3 and upper 4 collectors of a tubular type.

Cavities 2 can be made of various shapes, with many cavities being formed in each roofing element. Cavities 2 can be connected to each other in parallel or in series.

Under the ridge of the roof of the building above the location of the cavities 2 of the roof elements, there is a thermos storage 5 of the coolant circulation system having a triangular cross section.

When using the proposed technical solution as a device for heating the coolant and heat storage (figure 2, 3), the cavity 2 are connected to each other in parallel. The entire system is filled with coolant (e.g. water) and is under pressure. The coolant inflow is carried out through the lower collector 3. Under the influence of sunlight, the coolant is heated in the cavities 2.

Next, the effect of natural convection arises - the lower layers of the substance heat up, become lighter and float, and the upper layers, on the contrary, cool, become heavier and fall down, after which the process repeats again and again. Thus, the heated coolant through the upper collector 4 enters the thermos storage 5, installed under the ridge of the roof of the building above the location of the cavities 2 of the roof elements. From the top of the thermos, the coolant flows to the consumer of thermal energy.

The proposed technical solution can be used as an evaporator in a heat pump (FIGS. 5, 6), designed to transfer heat energy from a source with low potential heat energy (low temperature) to a consumer (heat carrier) with a higher temperature.

The roof of the building roof is used as an evaporator, including the indicated roofing elements connected to each other.

The cavities 2 in the roofing elements 1 together with collectors 3 and 4 form a single system. The entire system is filled with coolant and is under pressure. The coolant inflow is carried out through the lower collector 3. The inlet to the collector is preceded by a throttle (not shown), which reduces the pressure and thereby reduces the temperature of the coolant. Next, the coolant enters the cavity 2. The cavity 2 is connected to each other sequentially by means of a collector made in the form of tubular elements 3, 4.

The coolant using a circulation pump (not shown) passes sequentially through all the cavities of all elements. During the passage of the coolant through the cavity 2, its temperature rises due to the fact that the temperature of the coolant is much lower than the ambient temperature. After the passage of the cavities, the coolant enters the compressor, which increases the pressure (not shown). As a result of increased pressure, the temperature rises. Next, the heat carrier enters the heat consumers and the temperature drops. After the passage of all heat consumers, the coolant returns to the choke, and the cycle repeats again.

The proposed design of the roofing element is simple and technologically advanced to manufacture. When using the proposed roofing elements on the roof of the building as a device for heating the coolant, it is possible to effectively use the energy of sunlight falling on the roof surface.

When using the proposed roofing elements on the roof of the building as an evaporator of a heat pump, the main problem of the heat pump is solved - the high cost of the evaporator and in many cases the inability to install the evaporator.

The proposed technical solution can be applied for the production of roofs in industrial and civil engineering.

Claims (16)

1. The roofing element, characterized by manufacturing by extrusion from a polymeric material and the presence of internal cavities intended for circulation through the roofing element of the coolant, while the roofing element is made with the possibility of connecting the internal cavities to the external, relative to the element, the circulation system of the coolant. 2. The roofing element according to claim 1, characterized in that a UV stabilizer is introduced into the polymer material. 3. The roofing element according to claim 1, characterized in that it is made of two or more layers. 4. The roofing element according to claim 1, characterized in that it is made in the form of a plate of a flat or wavy shape. 5. The roofing element according to claim 1, characterized in that it is made in the form of tiles. 6. The roofing element according to claim 1, characterized in that it is made with a cladding, for example, decorative, at least on one side of it. 7. The roofing element according to claim 1, characterized in that it contains a dye that allows you to give the element the desired color scheme. 8. A device for heating a coolant, comprising a heat exchanger in communication with a coolant circulation system, characterized in that the roof of the building is used as a heat exchanger, including roofing elements connected to each other made according to any one of claims 1 to 7. 9. The device according to claim 8, characterized in that the roofing elements on the roof of the building are placed obliquely. 10. The device according to claim 8, characterized in that the roof of the building roof consists of roofing elements overlapped. 11. The device according to claim 8, characterized in that the coolant circulation system contains collectors made in the form of elements of a tubular type. 12. The device according to claim 8, characterized in that the cavities of each roofing element are connected via collectors in parallel. 13. The device according to claim 8, characterized in that the cavities of each roofing element are connected in series via collectors. 14. The device according to claim 8, characterized in that the cavity in every two nearby roofing elements are connected in series via collectors. 15. The device according to claim 8, characterized in that the coolant circulation system contains a thermos storage device located under the ridge of the building roof above the location of the cavities of the roof elements. 16. The device according to claim 8, characterized in that the thermos-storage system of the coolant circulation system is made with a triangular cross section.