HU190115B - Method for controlling one by one the radiators of single-pipe heating eqipments according to room temperature - Google Patents

Abstract

The present invention relates to a method of individually controlling the radiators of a single-tube heater according to the room temperature, whereby a portion of the liquid heat carrier is passed through the radiators, and a duct section for performing the process consisting of two horizontal and one vertical tube members connecting one side thereof with one side of the horizontal tube members. a liquid heat carrier is conveyed into the conduit, the other side is connected to the particular radiator, and a valve is mounted between the vertical tube member and the radiator stub in the upper horizontal tube member. The object of the invention is to develop a solution that can compensate for the spontaneous effects of snow formation in different rooms of a given building during the operation of the heating system. According to the present invention, this task is solved by passing up to 35% of the heat carrier mass flow rate on each radiator, preferably up to 26%, and the mass flow of the heat carrier passed through the radiators as a function of the room temperature, while the maximum flow rate is given by the respective radiators. temperature. The point of the invention is that the valve is preferably a thermostatic valve (5), the nominal diameter of the vertical tube member (4) optionally being smaller than the nominal diameter of the horizontal tube members (2, 3) at a nominal diameter. (Figure 1) 10 25 190115 -1-

Description

According to the invention, the valve is preferably a thermostatic valve (5), the nominal diameter of the vertical valve member (4) being optionally smaller in nominal size than the nominal diameter of the horizontal tube members (2, 3). (Figure 1)

The present invention relates to a method for individually controlling radiators of a single-pipe heater as a function of room temperature, wherein a portion of the liquid heat carrier is passed through the radiators, and a bridging section for carrying out a method consisting of two horizontal and the other side is connected to the respective radiator, and a valve is installed in the upper horizontal trough between the vertical tube member and the radiator nozzle.

The heating equipment of medium-high and high-rise buildings, especially residential buildings, is connected to the district heating system. In its construction it follows and fits in with house - builder - assembly technology. These heaters are two-pipe and then one-pipe in the chronological order of technological development. The two-pipe heater is then, when the heaters (radiators) are functionally connected in parallel, so the network can be divided into distribution (flow) and collection (return). The radiators in this unit receive water at the same temperature.

A single-pipe heater, if the heaters are functionally connected in series with radiator connections following the flow of water. In single-tube design, both horizontal and vertical equipment can be provided. Vertical single-pipe equipment is the so-called "water pipe" in terms of the flow of water, so the line of the pipe bottom and so-called. upper division breath. In the upper distribution system, the heating water flows vertically from the pound downwards.

Depending on the flow of water, the single-pipe connection may be fluid or bridging. The heating system has a connecting section, if there is a bypass in front of the radiator, the so-called heating system. a cross-section is located. During this short circuit, some of the water may flow without cooling in the radiator. This design allows the individual radiators to be adjusted with minimal interference, and in the extreme case also closed.

The description outlined above covers the current state of the art of heating circuits, all of which are operational heaters.

At the time, two - pipe equipment was completely eliminated from the construction practice due to material savings and in - house building - installation technology. Local control of flow-through single-pipe heaters is not possible and is no longer installed. The current state of the art is represented by the overhead distribution equipment with a bridging section.

The design of modern heating systems, their hydraulics, dimensioning and control is comprehensively covered in the bibliography of Homonnayn - Molnár entitled "Heating technology".

We have developed a system of type elements, published by the "TR Heating", published by the Building Society. note. The TR heating system is also dealt with in Building Engineering. magazine 1980.

Issue 3 is the "Hydraulic and control engineering test of the economical tread of a single-pipe heater with a runner section" and the same page 1982. Article.

It is clear from the sources listed that due to the existing problems of building physics and control technology, even the heating system with a bridging section cannot satisfy the needs to the maximum. A very important element in the thermal balance of buildings, especially well-insulated factory buildings, is the heat load due to internal heat generation (ie the use of the building) and the solar radiation on the windows, which may affect the rooms both in terms of orientation and time.

The effect of these is twofold. On the one hand, it results in higher internal temperatures and, on the other hand, it is not favorable in terms of energy consumption.

Heating technology practice has long been a concern in this area. Obviously a logical way to go, as per room! regulatory focus. That is why thermostatic radiator valves have been developed for two-pipe installations to maintain internal temperatures. This issue is addressed in U.S. Patent No. 2,220,340. Federal Republic of Germany, No. 472,073 Swiss, 3 309 926 and 1 870 895 thousand. U.S. Pat.

The conditions for installation in the heating system are set out in DIN 3 841 Teil 2, and experience with the use of the equipment is examined in Heizung Lüftung Haustechnik 31. 31. 1980/1. issue of the “Energieeinsparung durch thermostatische Heizkörperventile”. Article.

However, it can be stated that any extensive literature on single-pipe and thermostatic radiator valves is a question of substance, namely how to make energy-efficient aspects even better suited to the already very positive benefits (material savings, small on-site installation, etc.). interconnecting single-pipe heating system, no answer.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a solution to compensate for the varying degrees of spontaneous heat generation occurring in a particular building during operation of a heater.

According to the invention, this problem is solved by passing up to 35%, preferably up to 26% of the mass flow rate of the heat carrier on each radiator and the mass flow rate of the heat carrier through the radiators, depending on the room temperature, with mi-2190115 fixed according to room design temperature.

The essence of the tie-in section according to the invention is that the nominal diameter of the vertical pipe member of the valve, preferably the thermostatic valve, is optionally smaller in nominal size than the nominal diameter of the horizontal pipe members.

The invention will now be described in more detail with reference to the drawing. In the drawing it is

Fig. 1 is a schematic diagram of a radiator for a single-pipe interconnector,

FIG. an enlarged sectional view of a detail,

Figure 3 is a top view of Figure 2.

In the circuit shown in Fig. 1, the radiator 1 is connected in series to a heating water pipe not shown in the drawing.

The connecting section is formed from the upper horizontal tube member 2, the lower horizontal tube member 3 and the vertical tube member 4 connecting them.

According to the invention, the thermostatic valve 5 is integrated in the section of the upper horizontal pipe member 2 between the radiator 1 and the vertical pipe member 4.

According to the invention, the nominal diameter of the vertical tube member 4 may be smaller than the nominal diameter of the horizontal tube members 2 and 3 in the standard size series.

On the wakes 2 and 3, an exemplary embodiment of the dipping section is illustrated. Note that the upper horizontal tube member 2 and the vertical tube member 4 have the same node, only its section is rotated 18O 'along an axis perpendicular to the tube member 4.

In our case, the diameters of the tubular members 2-4 are the same. On the horizontal pipe members 2 and 3, at the welded joints of the vertical pipe member 4, a nest 6 is formed by cold forming and fusing.

In the surface of the nest 6, a cross-sectional displacement 7 with a nominal diameter less than a nominal size is provided in the standard size series at the cross-section of the horizontal tube members 2 and 3.

The ratio of the cross-sectional ratio of the vertical tube member 4 or the trigger 7 to the horizontal tube member 2.3 is preferably 0.35-0.4.

In the following, our procedure for the operation of the dipping section will be described.

The tag 1 radiator is equipped with 1/2 ”and 3/4” horizontal 2 and 3 pipe members and 3/8 ”and 1/2” vertical 4 pipe members with brace sections. At 1/2 ”, depending on the design temperature of the room, a maximum of 26% of the mass flow at 16 'C and 16% at 20-24 ° C is fed into the radiator.

For the 3/4 "size, 25% for 16 'C and 16% for 20-24' C.

The thermostatic valve 5 maintains the temperature continuously between the specified maximum and the total shut-off. Controlling, though not continuous, can be achieved with a manual valve.

An advantage of this aspect of the invention is that the temperature of the heating water 10 passing through the radiator 1 is reduced by about 20 'C, but after mixing at the Aleo node, the temperature of the heating water decreases by no more than 1-1.5' C!

Another advantage, however, can be found in system design15, namely the precise hydraulic conditions of the false linkage section allow the designer to consider the system resistance based on the heat demand.

Claims (4)

Claims A method for individually controlling 25 radiators of a single-pipe heater as a function of room temperature, wherein a portion of the liquid heat carrier is passed through the radiators, characterized in that up to 35%, preferably up to 26%, of the and the mass flow rate of the heat carrier through the radiators as a function of the room temperature, while the maximum mass flow rate is recorded according to the design temperature of the room. A dipper section for carrying out the method of claim 1, wherein the two horizontal edges are formed by a vertical tubular member connecting them, wherein the horizontal tubular members One side 40 is connected to the liquid heat transfer line, the other side is connected to the respective radiator, and a valve is installed in the upper horizontal pipe member between the vertical pipe member and the radiator connection, characterized in that the valve is preferably a thermostatic valve (5) The nominal diameter of the tubular member (4), if any, in the standard size series is one nominal diameter less than the nominal diameter of the horizontal tubular members (2, 3). Bandage section according to Claim 2, characterized in that it is preferably cold-formed in the horizontal pipe members (2, 3), preferably at the welded joints of the vertical pipe member (4) and in the nominal diameter of the horizontal pipe members (2, 3). The cross-section (7) of the standard size series has a substitution (7) for a diameter smaller than one step 60. A tie-in section according to claim 2 or 3, characterized in that the ratio of the cross-sectional area of the vertical tube member (4) or the displacement (7) and the horizontal tube members (2, 3) 65 is between 0.35-0.4.