RU2229076C2 - Convector heating element - Google Patents

Abstract

FIELD: computer-based energy-efficient heating systems for various buildings. SUBSTANCE: heating element has delivery and return pipes with junction ends, thermostatic valve disposed on U-bend, and duct connected in parallel with valve; return pipe is made in the form of horizontal section smoothly bent through 90 deg. in plane where both delivery and return pipes are located. EFFECT: enhanced energy saving capabilities of system; facilitated assembly of heating element. 2 cl, 1 dwg

Description

The invention relates to building heating systems, as well as energy-saving automatic heating systems of various buildings.

Known heating elements of convectors such as Comfort-20, Progress, KB, Rhythm, Accord, etc., consisting of 2 horizontal pipes - supplying heat and return, removing heat from the heating element, and having a pipe element in the form of kalach for communication between pipes (V.I.Manyuk, Ya.I. Kaplinsky, E.B. Hizh et al. M., Stroyizdat, 1988, p. 106).

A disadvantage of the known devices is the lack of a radiator valve with the possibility of installing a thermostatic head to control the temperature in the room and the lack of structural accessory of the regulator valve to the heating element in order to simplify the installation of the heating device on the heating object.

Known heating elements incorporating a thermostatic valve, see, for example, heating elements with radiator thermostats, presented at the 3rd Aqua-Therm exhibition (Moscow, 1999), as well as exhibits from F.W. Oventrop GMBH & CO.KG (Germany, stand 2.1.20) and Herz Armaturen GESMBH (Austria, stand 2.1.08), see the catalog of the exhibition SHK Moskau 2000, 4 International Specialized Exhibition for Heating, Ventilation, etc., Moscow, 13 March 16, 2000

A disadvantage of the known devices is the lack of kalach closing the supply and return pipes of the heating element made of the same material as the pipes. This design is focused on closing with the help of an additional valve-kalach type device, which is more expensive and complex in design and made of another material. At the same time, “valve-kalach” reduces energy saving.

In single-pipe heating systems with energy-saving equipment, which includes radiator thermostats, there is a phenomenon of "residual" heat transfer (V.I. Livchak. On the issue of strengthening the role of ITP in implementing the energy-saving strategy. Inf. Bull. Energy-saving, No. 7, 1996, pg. 1-2). The effect of "residual" heat transfer occurs when the thermostat valve is closed. There is no coolant flow through the heater. However, in this case, heat transfer from the heating system through the heating device (convector) to the room is still possible, which leads to significant (up to 40%) and unaccounted for heat losses. To reduce this phenomenon, known devices are used, for example (Oventrop, Handbuch 1/98, Technische Daten, p. 1.43). The heat carrier, giving its heat to the room through the heating element of the heating device, is cooled and the layer with a lower temperature moves to the lower part of the horizontal pipeline, and with a higher temperature to the upper part. The bottom layer flows into the heating system and a new one moves in its place. Such substitution of the layers leads to heat leakage.

Known devices, using different values of the specific gravity of the temperature layers of the liquid at low speeds, form obstacles to the movement of the layers when exchanging their location: special bends, double bends of the pipeline, inclined sections of the pipeline, oblique channels in special inserts in the pipeline, etc. (R. Petitjean. Balancing of Radiator Systems. Tour & Andersson Hydronics AB, Ljung, Sweden, 1994, p. 47).

To reduce heat loss, circuit solutions are used in which the location of the radiator thermostat is changed: before entering the heating device (convector), after it and between the supply (for example, upper) and return (lower) pipes of the heating element.

The disadvantage of circuit solutions is the insufficient reduction of the effect of residual heat transfer and without using additional coolant energy.

Further, the upper and lower pipelines of the heating element are in unequal conditions of heat transfer, because the upper part of the pipeline experiences additional heat influx from the lower part, thereby decreasing the temperature difference in the upper part and heat transfer to the room, which also worsens layer-by-layer liquid division and the operation of barrier devices such as a thermal shutter.

The closest device is the heating element of the Universal-convector convector adopted for the prototype (see assembly drawing Kn 407B.06.000.sb of the heating element for the convector Vitaterm LLP; article “Cold or hot”, the newspaper Construction Expert No. 18 (61), 1999, p. 14).

The known device contains a supply and return pipes with connecting nodes for heating equipment, a valve and a channel connected in parallel with the valve. For the connection between the pipes and the coolant flow through the heating element, a “valve-kalach” is used, replacing the structural pipe element in the form of kalach.

The disadvantage of this known device is the small values of the coefficient of inflow.

In fact, the function of kalach is performed by a rotary channel with an angle of 90 ° and flow sections in the body of the kalach valve less than the passages of the supply pipes. The hydraulic resistance of the kalach valve is always higher than the pipe kalach. Hence the reduced leakage coefficient at different temperature conditions of the radiator thermostat, the transition time for restoring the specified thermal equilibrium in the room is overestimated, the heat consumption is increased in the valve shutter shift mode when the valve is not yet closed. In practice, a valve valve with a modified housing from a standard valve according to EN-215-2 (European standard for radiator thermostat valves) has lower K _v coefficients.

In addition, when the valve is closed, the known device has a significant residual heat transfer due to the fact that the material of the valve body is not the same with the supply and return pipes and has a large thermal conductivity, leading to accelerated division of the heat carrier into the temperature layers inside the heating element and an increase in the residual heat transfer.

The listed design parameters increase the hydraulic resistance and pressure loss of the entire assembly, despite two parallel flow lines with the valve open. In general, for the heating system, energy losses increase for pushing the coolant through the system and, as a result, to increase the required pump power of the heating system of the building.

In addition, complicated manufacturing technology of the valve body, which acquired in the known device part of the function of kalach. This property leads to an increase in the cost of the heating unit, additional consumption of non-ferrous metal, complication of manufacturing technology, additional costs for installation and assembly of the heating element with the valve body, excessive requirements for alignment (tightening tolerances) between the connecting nodes of the housing and the heating element in different planes. Otherwise, for example, during installation, overcoming misalignment, lateral forces arise, skew joints with the deformation of the gaskets and the appearance of leaks in the connecting unit.

Similar phenomena are possible at high coolant temperature, causing thermal deformations of the joints due to substitution of other material with respect to the pipe material and the curvilinear part of the feces disappearing with a rigid valve body, which previously contributed to temperature compensation.

To eliminate the aforementioned drawbacks, a convector heating element is proposed, comprising a supply and return pipe with connecting ends, a valve located on the stream, and a channel with a passage of fewer pipe passages connected in parallel with the valve, in which the return pipe is made in the form of a horizontal section with a smooth turn 90 ° in the same plane in which the direct and return pipes are located, to the connecting end located under the supply pipe with a distance between the ends of the supply and return pipes, p an apparent distance between the connection ends of the angular type valve, the passages of pipes are equal and equal to the supply and drain pipes of the heating system.

In addition, in the heating element of the convector, the valve is made thermostatic.

The introduced new features make it possible to increase the energy-saving capabilities of a single-pipe heating system with the layout of radiator thermostats in it, and to facilitate the assembly of the heating element.

The principal novelty of the proposed device consists in the following areas: 1) increasing energy conservation; 2) transfer of some functions of kalach to the smooth rotation of the return pipe; 3) increasing the characteristics of the heating device from the constructive combination of an angular valve and smooth rotation of the return pipe of the convector heating element, departing from the valve connecting unit.

An essential feature in the proposed device - a smooth rotation after the valve on the return pipe - increases energy saving by reducing the transition process during operation of the radiator thermostat, i.e. in position when the valve shutter is open. The transition time, in turn, is reduced due to the fact that the leakage coefficient is increased, after the valve the hydraulic resistance of the return pipe path is reduced, the coefficient K _{v is} increased.

In addition, the residual heat transfer due to a smooth rotation is reduced. In the position close to the closed, as well as when the valve is closed during the temperature separation into layers, the flow of the coolant in the bend knee is inherently a double vortex, which disrupts the separation process, the flow is turbulent, the layers are mixed and the temperature is aligned along the return pipe. At the same time, leakage of the lower layer with a lower temperature to the heating system is reduced, the substitution of the temperature layers occurs less intensively, which generally reduces the residual heat transfer.

The same phenomenon is facilitated by the transfer of a part of the function of kalach from the kalach valve in the known device to a smooth rotation in the proposed heating element, which has a different type of material with lower thermal conductivity. In the proposed device, a part of kalach and a return pipe are made of the same material, heat transfer from this part of the heating element is reduced, which helps to reduce layer-by-layer division of the heat carrier and to reduce the residual heat transfer.

Improving the characteristics of the heater from the constructive combination of an angular valve and smooth rotation of the return pipe of the convector heating element, departing from the valve connecting unit, consists in the following:

- reduced hydraulic resistance of the entire path of the heating element due to the fact that the pipe passages are equal to each other and equal to the supply pipes from the heating system;

- improves temperature compensation of changes in the volume and length of the structural components of the heating element as a whole;

- standard angle-type valves have increased K _v coefficients compared to the kalach valve. The proposed device uses a standard valve of the angular type;

- increases the coefficient of inflow;

- reduced assembly requirements during installation, because smooth rotation curve is a mounting compensator in planes (pulling due to bending and rotation);

- cheaper design due to the use of less scarce non-color material and the use of a standard type valve;

- when installing in a heating system, such as a residential building, a large number of proposed heating elements require less pump power, due to a decrease in the hydraulic resistance of each element;

- installation of the valve for the thermostat allows you to effectively control the temperature in the room.

The drawing shows the heating element of the convector, where it is indicated: 1 - feed pipe, 2 - return pipe, 3 - angle-type valve, 4 - smooth rotation of the return pipe 90 °, 5 - connecting ends of the supply and return pipes, 6 - channel with reduced the passage relative to other pipes of the heating element, 7 - the input of the coolant in the heating element, 8 - the exit of the coolant from the element.

The heating element operates as follows. With the valve 3 open, the coolant from the inlet 7 simultaneously flows into two branches of the heating element: the first branch - through the supply pipe 1, valve 3, smooth rotation 4 and the return pipe 2 to the output 8; the second branch - through the supply pipe 1, channel 6 passes into the return pipe 2 and is removed into the heating system 8.

With the valve 3 closed, the coolant from the inlet 7 passes through only one branch - through channel 6 to the outlet 8 to the heating system.

When the shutter of the valve 3 is open, energy saving is increased by reducing the transient time during operation of the radiator thermostat. In this position, the flow rate of the coolant is increased due to an increase in the leakage coefficient and a decrease after the valve 3 of the hydraulic resistance of the return pipe path 2.

When the shutter of the valve 3 is closed, the residual heat transfer is reduced due to the smooth rotation of 4. In the position close to the closed and also when the valve 3 is closed during the temperature separation into layers, the flow of the heat carrier in the smooth rotation elbow 4 has a double vortex in nature, which violates the separation process, the flow is turbulized, the layers are mixed and the temperature is equalized along the return pipe 2. This reduces the leakage of the lower layer with a lower temperature into the system 8, the replacement of the temperature layers oiskhodit less intensively, which generally reduces the residual heat the entire heating element.

Orientation in the space of the connecting ends of the supply and return pipes is performed with less requirements for tolerances and assembly requirements during installation are reduced, as the curve of smooth rotation is a mounting compensator (pulling due to bending and rotation around the axis of the return pipe).

Claims (2)

1. The heating element of the convector, containing the supply and return pipes with connecting ends, the return pipe made in the form of a horizontal section with rotation, a valve located on the roll, and a channel connected in parallel with the valve, characterized in that the return pipe is made with a smooth turn on 90 ° in the same plane in which the direct and return pipes are located. 2. The heating element according to claim 1, characterized in that the valve is made thermostatic.