RU185482U1 - SECTION OF ALUMINUM HEATING RADIATOR - Google Patents

Abstract

The utility model relates to sectional aluminum heating radiators containing devices that protect the radiators from damage caused by excessive pressure. Each section of the aluminum heating radiator contains an internal vertical channel for the coolant with a technological hole in the end part, closed with a plug using an integral lock connection, sealed with a gasket in the form of a membrane containing a mounting part located around the perimeter, and a central part of a convex shape with the formation of a compensation tank between membrane and plug. At the same time, a rounded cap with an emphasis of its lower edge on the bottom of the plug is installed in the compensation tank under the membrane. The cap is made of sheet metal material 0.4-0.8 mm thick. In the center of the bottom of the plug, an inspection hole can be made. The technical result is the ability to compensate for high excess pressure and increase the period of trouble-free operation of the radiator.

Description

The utility model relates to aluminum heating radiators with devices that protect radiators and their mounting elements from damage caused by exposure to excessive pressure that exceeds the working or test pressure.

Aluminum radiator consists of sections that are interconnected with nipples and gaskets. Before the layout of the radiator, the technological hole of the cast section is closed with a plug.

A mandatory step in the radiator manufacturing process is to control the tightness conditions and reliability criteria of the heater. To do this, he is tested on a special stand. On it, the heater is immersed in a liquid and air is supplied inside. Further, the absence of bubble exit is observed. Particular attention is paid to the area of intersectional joints and plugs.

Only after such factory crimping can a long trouble-free service of radiators be expected in conditions under which the pressure of the heating system does not exceed the declared operating one. The aluminum radiators on sale have an operating pressure of 2.0 MPa, with a test pressure of 3.0 MPa. However, during operation of the radiator, conditions may arise for excessive pressure increase inside it, which can lead to its depressurization and even destruction. Such an emergency is possible due to errors in the design and installation of the heating system, with improper start-up and commissioning. Specialists note a special danger in the event of a water hammer. This is a phenomenon in which there is a sharp increase in pressure in the heating system (pressure surge), including inside a radiator filled with coolant.

Depressurization of the radiator occurs with the filling of the room with hot water. If you do not quickly shut off the water supply, then material damage can be serious and significantly exceed the cost of a new heating device. Also, hot water is a danger to people in the room.

Known sectional radiator for water heating from an aluminum alloy, each section of which includes two transverse parallel sections and a longitudinal section connecting the transverse sections and mated with them in their middle zones, containing a pressure compensator made in the form of a blind sleeve, the inside of which is fixed oriented longitudinally in the cavity of the transverse section section of the gas-filled element, made with the possibility of elastic changes in its external volume under the influence of external liquid pressure eplonositelya, at least in the longitudinal direction along the cross section axis of the section, in which the socket pipe pressure compensator is fastened (in Russian Patent OF №2499203, publ. 20.11.2013). The gas-filled element is a sealed chamber in the form of a bellows or an open cylinder at one end with a piston freely located in it, forming a sealed cavity. In this case, the gas-filled element can be made of steel, copper, brass and filled under pressure from 0.1 to 16 MPa with gas or a mixture of gas and liquid with a boiling point of 50 to 95 ° C.

This invention allows to reduce the negative impact of pressure surges, dampen water hammer, which increases the reliability and service life of the radiator.

However, such a pressure compensator with a gas-filled element is quite difficult to manufacture and requires additional installation in the radiator, taking into account the specific scheme of connecting the heating network pipelines to the radiator and taking into account the distribution of the shock flow of the coolant. If you need to quickly remove the coolant and bleed air from the radiator, difficulties may arise. All this complicates the installation and maintenance of such radiators.

A known section of an aluminum heating radiator containing an internal vertical channel for a coolant, in which the hole of the end part of the vertical channel is closed with a plug using an integral lock connection, sealed with a gasket in the form of a membrane containing a mounting part located around the perimeter, and the central part is convex in shape compensation capacity between the membrane and the plug. An elastic element is located in the container between the plug and the central part of the membrane. In the event of causes leading to an increase in pressure, the deformation of the membrane increases, and the outer surface of its convex central part begins to move toward the plug. This compensates for excess pressure and thereby prevents the destruction of the walls of the radiator channels. When the heating system pressure returns to operating state, excess pressure inside the compensation tank leads to the restoration of the membrane shape to its original state. The elastic element allows to increase the elastic properties of the membrane and contributes to a better restoration of its shape after removing the load (RF patent for PM No. 175696, publ. 12/14/2017).

This technical solution, adopted as a prototype, allows to reduce the possibility of depressurization of the aluminum radiator section caused by exposure to high pressure in the heating system. However, the presence of an elastic membrane with an elastic element does not always make it possible to compensate for high overpressure, which may ultimately lead to an emergency. In addition, the membrane loses its elastic properties due to pressure drops over time.

The technical result of the claimed utility model is the ability to compensate for higher excess pressure and increase the period of trouble-free operation of the radiator.

The specified technical result is achieved in that in the section of the aluminum heating radiator containing an internal vertical channel for the coolant with a technological hole in the end part, closed with a plug using an integral lock connection, sealed with a gasket in the form of a membrane containing a mounting part located around the perimeter, and a central part of the convex shape with the formation of the compensation capacity between the membrane and the plug, ACCORDING TO THE USEFUL MODEL, in the compensation capacity under the membranes a rounded cap is installed with the emphasis of its lower edge on the bottom of the cap, while the cap is made of sheet metal material 0.4-0.8 mm thick.

In a particular case, the side surface of the cap is made with an inclination of 2 to 20 °.

In another particular case, the cap has a spherical shape with a radius of 15 to 40 mm.

The lower part of the side surface of the cap can be flanged with an angle of 40 to 60 °.

The cap may have a protective anti-corrosion coating.

The mounting portion of the membrane may comprise a shoulder.

The bottom of the plug may be protruding outward.

In the center of the bottom of the plug, an inspection hole can be made.

The possibility of implementing the claimed technical solution with the above set of features, as well as the possibility of realizing the purpose can be confirmed by drawings and a description of an example of the construction of an aluminum radiator section with a device for pressure compensation.

In FIG. 1 shows a longitudinal section through the end of the vertical channel of the radiator section, which is closed by a plug (without the bottom protruding outward) with a sealing gasket-membrane, between which a cap is placed (working pressure).

In FIG. 2 shows a longitudinal section of the end of the vertical channel of the radiator section, closed with a plug (with the bottom protruding outward) with a sealing gasket-membrane, between which a cap is placed (working pressure).

In FIG. Figure 3 shows a longitudinal section of the end part of the vertical channel of the radiator section, closed with a plug with a sealing gasket-membrane, between which the cap is placed (in case of overpressure: 3a is a slight deformation of the cap; 3b is the maximum deformation of the cap).

In FIG. 4 shows a longitudinal section of the cap with a slope of the side surface of 15 ° (longitudinal section).

In FIG. 5 shows a longitudinal section of a cap of a spherical shape, the lower part of the side surface of which is flanged at an angle of 60 ° (longitudinal section).

In FIG. 6 shows a longitudinal section of the membrane, the mounting part of which is made with a shoulder (longitudinal section).

The end part of the vertical channel 1 of the radiator section contains a technological hole closed by a plug 2 with the formation of an integral lock connection (Fig. 1, 2). The sealing gasket is a membrane containing along the perimeter of the mounting part 3 and the Central part 4 of a convex shape. Between the plug and the central part of the membrane there is a compensation tank 5. Under the membrane in the compensation tank 5 there is a metal cap 6, the lower edge of which abuts against the bottom part 7 of the plug 2. The bottom part 7 of the plug 2 can be made protruding outward to increase the volume of the compensation tank 5 ( Fig. 2, 3a, 3b) and may have a viewing hole 8.

The manufacture and assembly of the aluminum radiator section is as follows.

The aluminum section is made using high pressure casting technology. Material - aluminum alloy, for example, aluminum-silicon-copper AK12M2 system.

The plug 2 is made of rolled steel with cutting blanks and its subsequent stamping on the press. To give anti-corrosion properties, the plug may have a special protective coating. If an inspection hole 8 is provided, then the operation of drilling the hole to a predetermined diameter is performed.

The membrane is made of non-metallic materials that provide the necessary sealing properties, heat resistance and elasticity, for example, heat-resistant elastomers based on fluororubber, ethylene - propylene copolymer, polyurethanes. The mounting part of the membrane is performed with a shoulder 9 (Fig. 6). This collar prevents the installation of the membrane from penetrating under the influence of an overpressure jump (water hammer) into the space between the metal cap and the metal plug, which can serve to clamp and rupture the membrane.

The cap 6 is made of a metal material with a thickness of 0.4-0.8 mm, for example, of sheet steel rolled low-carbon steel grade 08ps with a corrosion-resistant coating. The sheet blank is shaped like a cap with a rounded upper surface by rotational drawing, while the side surface of the cap can be made with an inclination (Fig. 4) or the cap can be made spherical with a flange at the bottom (Fig. 5). Flanging allows you to most rationally distribute the load from the increased pressure on the cap 6, namely, to provide the main load and the deformation of the middle of the upper surface of the cap.

With a cap thickness of less than 0.4 mm, it breaks when a high pressure jump (water hammer) occurs, and with a thickness of more than 0.8 mm, the cap does not have sufficient ductility for deformation.

The cap 6 is installed with the emphasis of its lower edge on the inner bottom part 7 of the plug 2, centering along the axis; a membrane is placed above the cap. Then, by rolling, bending or crimping, an inseparable locking connection of the plug 2 around the technological hole of the end part of the vertical channel 1 of the radiator section is created. During operation of the heating radiator, such a connection ensures tightness and reliability of the structure.

The sections of the heating radiator are interconnected with the help of nipples - and intersectional gaskets in a single device. After checking the tightness of the assembled radiator, it is packaged. The device is ready for installation.

Radiators are connected to the heating system using pipelines. When the radiator is in operation, in case the operating pressure is exceeded, the cap 6 (together with the central part 4 of the membrane) bends in the compensation tank 5 towards the plug (Fig. 3a), which makes it possible to compensate for the pressure surge and prevent an emergency. The metal cap allows you to compensate for high pressure surges, gradually bending under their influence. Only when the curved surface of the cap 6 is near the bottom of the plug 7 (Fig. 3b), it can no longer deform and compensate for excess pressure in the system. The radiator will continue to work as a regular heating device that does not have additional protection against water hammer.

The control of the degree of deformation of the cap 6 is carried out through the inspection hole 8 in the bottom of the stub. Visually assess the distance from the bottom part 7 of the plug to the cap 6. If their surfaces are closed, the cap is maximally deformed, and the user decides to continue using this radiator or to purchase a new radiator with a similar device to compensate for overpressure and water hammer.

Thus, the proposed utility model in comparison with the prototype provides compensation for higher excess pressure and increases the period of trouble-free operation of the radiator. Moreover, the pressure compensation device (metal cap) is easy to manufacture and convenient to install.

Claims (11)

1. Section of an aluminum heating radiator, containing an internal vertical channel for the coolant with a technological hole in the end part, closed with a plug using an integral lock connection, sealed with a gasket in the form of a membrane containing a mounting part located around the perimeter, and the central part of the convex shape with the formation of compensation a container between the membrane and the plug, characterized in that a rounded cap with an emphasis on its bottom is installed in the compensation tank under the membrane edges on the bottom of the stub, while the cap is made of sheet metal material with a thickness of 0.4-0.8 mm 2. Section of an aluminum heating radiator according to claim 1, characterized in that the side surface of the cap is made with an inclination from 2 ° to 20 °. 3. Section of an aluminum heating radiator according to claim 1, characterized in that the cap is made spherical in shape with a radius of 15 mm to 40 mm. 4. Section of an aluminum heating radiator according to claim 3, characterized in that the lower part of the side surface of the cap is flanged with an angle from 40 ° to 60 °. 5. Section of an aluminum heating radiator according to paragraphs. 1-4, characterized in that the cap has a protective anti-corrosion coating. 6. Section of an aluminum heating radiator according to paragraphs. 1-4, characterized in that the mounting part of the membrane may contain a flange. 7. Section of an aluminum heating radiator according to paragraphs. 1-4, characterized in that the bottom of the stub can be made protruding outward. 8. Section of an aluminum heating radiator according to claim 6, characterized in that the bottom of the plug can be made protruding outward. 9. Section of an aluminum heating radiator according to paragraphs. 1-4 or 8, characterized in that in the bottom of the stub in the center there is a viewing hole. 10. Section of an aluminum heating radiator according to claim 6, characterized in that a viewing hole is made in the center of the bottom of the plug. 11. Section of an aluminum heating radiator according to claim 7, characterized in that a viewing hole is made in the center of the bottom part of the plug.

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