FI99052B - Procedure for control of heating/cooling - Google Patents

Abstract

The invention concerns a procedure for controlling the temperature of a room. According to the invention, the heat loss from the room is calculated and the water flow to the radiator is so controlled that the required amount of heat to the room is provided, independent of the size of the radiator.

Description

j 99052

The present invention relates to a method for controlling heating / cooling 5, in particular for controlling the liquid flow of heaters connected to a heating network in a building and of radiators connected to a cooling network so that their heating or cooling output is independent of the theoretical design temperature difference of heat exchangers.

10

The rooms in buildings are usually heated by radiators. Radiators are dimensioned according to the maximum power demand of the room, which is usually when the outdoor temperature is at its lowest. Design temperatures in Finland vary between -25 ° C and 35 ° C depending on the location -15. Radiators used for air heating are also usually selected using the same criteria, while radiators used for room or air cooling are designed on the basis of too high a temperature and the resulting heat loads.

20 The selection of all radiators for heat transfer is based on the temperature of the incoming liquid and the temperature difference between the incoming and outgoing liquids, which for radiators installed in a room: usually 20 ° C or 30® C at 90/70 ° C or 90/60 ° C. with the generalization, the design has shifted to lower temperatures, e.g. 70/40 ° C. The power of the coil is determined by the heat transfer properties of the coil of the coil and the ambient temperature shown above.

·: As different rooms usually have different heating or cooling needs, a 30 radiator should be installed in each room with the best possible power for the room's power needs. When the battery power is higher than the heat demand, it allows the internal temperature to rise, causing energy loss. Too small a radiator, on the other hand, is unable to keep the room temperature at its desired value and causes a feeling of traction and complaints about cold. Due to these issues, the power range of the radiators must be very large in order to get the best possible size of heating or cooling radiators for the different rooms.

5

Due to production and economic reasons, the range of radiators has to be limited. For this reason, the power requirement of the room and the power delivered by the radiator with the rated water flow and the rated temperature difference are rarely equal.

10

When the temperature difference between the incoming and outgoing liquid is used as the design and selection criterion for the radiators, the power of the heating coil changes by approx. 10% when moving to the next shorter or longer size. When moving to the next higher or lower size, the heat transfer changes by about 20%.

The choice of a room-specific radiator is made by selecting a radiator whose thermal output is mainly greater than the heat loss of the room, but often also taking into account the width of the window so that the installed radiator is the width of the window. It follows from the choice of radiators that they are somewhat oversized in relation to the heat loss of the rooms:.

i With an outdoor temperature of - 30® C and a room temperature of + 20 ° C, the temperature is; 25 gap between these 50® C. If the installed radiator is 10% oversized due to selection, it tends to raise the room temperature 5® • C. The error due to the selection of the radiator increases as the difference between the surface temperature of the radiator and the room temperature increases. When we know that a rise in the temperature of 1 ® C i at room temperature increases the heating energy by about 5%: 30 consumption we also understand how large the issue is.

: The basic battery network adjustment methods in use operate according to the same principle as described above for the selection of batteries.

3,99052

Once the radiators have been installed, the liquid flows circulating in the network are adjusted so that the temperature difference between their flow and return water corresponds to the design temperature difference used in the design, whereby the power of the battery corresponds to its nominal power. The general basic control method 5 in use is one in which the surface thermometer measures the temperature of the water returning from the radiator and adjusts the return temperatures of all the radiators to a value corresponding to the design temperature difference. That adjustment by this method would be possible should the outside temperature of the room be at least -5 ° C to provide a sufficient temperature difference. When using the temperature sizing method 10, the temperature difference between the flow and return lines is also measured, which is adjusted in the same way as the difference between the supply and flow water of the radiators.

Computer-based calculation methods have also been developed for dimensioning heat conductor networks and radiators and for performing basic adjustment. These also assume that the selected temperature difference between the water entering and leaving the coil is constant and the same for all coils connected to the mains. In this case, the water temperature difference between the supply and return lines is also the same as for radiators. The heat-20 output of the radiator then corresponds to its theoretical rated power.

Common to all known sizing and basic control methods is that the power of the radiators is determined by the rated temperature of the incoming and outgoing water: - and the selection of the radiators is done by selecting:: 25 the nominal power mainly higher than the room heat losses. Because the choice of radiators also often takes into account the windows: · The width can be oversized. What all known sizing and basic control methods also have in common is that they tend to retain the associated disadvantages of significantly increased energy consumption, noise nuisance caused by excessive water flow in the pipeline, excessive pumping power requirements, more difficult control of pipeline fluid flows and excessive high temperature hot water.

The object of the present invention is to eliminate the error in the room temperature due to the choice of the radiator, as well as to reduce the range of sizes of the radiators, which is easy; .a design and installation work, as well as provide a better visual result and a significant reduction in energy consumption and cost savings.

According to the invention, only the temperature of the liquid entering the radiator is kept the same for all radiators belonging to the same heating or cooling group. The power delivered by the radiators to the rooms is not determined on the basis of the nominal power based on the design temperature difference of the 10 incoming and outgoing water radiators, but each water flow is determined taking into account the coil's heat output and the heat output of the coil.

15

According to the invention, each heating or cooling coil has a different liquid return temperature, which is determined by the oversize or undersizing of the coil. In this case, the size range of the radiators can be considerably reduced, as it is no longer the case that every 20 room heat losses are matched by a radiator of the same power rating. According to the invention, the size range can be based not only on heat transfer but also on the building and the rooms * ·; interior design issues.

»· • · · • · ♦ ··· ♦ • · · ·: The advantage of the invention is also achieved by the basic adjustment of the radiator network, whereby a flow of liquid is regulated for each radiator, which, when flowing into the radiator, gives off the desired heat loss in the room '* regardless of the rated power of the radiator.

Using the method according to the invention, both in the dimensioning and in the basic control, the water flow is adjusted for each radiator, which, taking into account the heat transfer properties of the radiator, gives a power corresponding to heat losses. When the coil is oversized by 10%, the adjustable water flow of 5 99052 must be approx. 66% of the water flow adjusted according to known methods. The temperature of the water returning from the radiator is then correspondingly about 10 ° C lower than in the adjustments made according to known methods. This in turn lowers the district heating return temperature n.

5 10 ° C.

The heat demand of buildings is divided into heating, hot water and air conditioning. Of these, the heating works around the clock, the air conditioning from 8 to 24 hours a day, depending on the destination, while the consumption of hot 10 hot water is generally intermittent. Since the dimensioning and control work carried out in accordance with the invention has the effect of lowering the temperature of the liquid returning from the heating and air-conditioning radiators, its effect on the temperature of the returning district heating water is round-the-clock.

15

According to studies, a one degree decrease in the return temperature of district heating water reduces the consumption of pumping electricity in the district heating network by about 7% and heat losses by about 0.8%. In cogeneration of electricity and heat, electricity production is then estimated to increase by approx.

'·: 20 0.11%. From the above, it is clear from the fact that the reduced return temperature of the coil network • 1 regulated according to the invention saves not only its correct control but also the heat production costs: considerably.

The above and other advantages and advantages of the invention are provided as set forth in the appended claims.

• m m *

The invention will now be described in more detail with reference to the accompanying drawings, in which: Figure 1 shows the invention as applied to a conventional window: a radiator; 6 99052

Figure 2 shows a second embodiment of the apparatus now applied to an air conditioning heating coil;

Figure 3 shows another alternative embodiment of the apparatus, in which it is applied to an air conditioning cooling coil, and

Figure 4 shows graphically the occurrences of method errors in control systems according to the present invention and the prior art as a function of indoor and outdoor temperatures.

10

Figure 1 shows a radiator according to the invention installed under a window, in which the window is marked with the number 1. A heating radiator 2 is installed below the window 1, the length of which in this example corresponds to the width of the window. The temperature of the water 3 coming to the radiator 2 is the same 15 for all radiators in the same heating network. The water flow and, as a result, the temperature of the return water 4 are determined separately for the radiator to a level where the heat output given by the radiator corresponds to the heat losses in the room. The basic adjustment of the water flow is done by presetting the valve 5.

Figure 2 shows a radiator 6 in an air conditioner or air duct, through which the fan 7 transmits the desired air flow.

·· »:: The temperature of the liquid 8 coming to the radiator 6 is the same for all radiators in the» heating network. The liquid flow and, as a result, the temperature of the return liquid 9 • · ”is determined separately for the radiator to a level where the heat output given by the radiator corresponds to the heat output required by the air flow. Fluid flow. the basic adjustment is made by means of valve 10.

· • · • · · · »*» m φ

Figure 3 shows a cooling coil 11 in an air conditioner or air duct, through which the fan 12 transmits the desired air flow.

M * I

30 The temperature of the liquid 13 entering the radiator 11 is the same for all radiators connected to the same cooling network. ”· The liquid flow and, as a result, the temperature of the return liquid 14 are determined separately for the radiator to a level where the thermal power bound by the 7 99052 coils corresponds to the cooling demand required by the air flow. The basic adjustment of the liquid flow is done by means of a valve 15.

Figure 4 shows a comparison of the control errors of the prior art control systems 5 with the control according to the invention. The vertical axis has an indoor temperature and the horizontal axis has an outdoor temperature. Lines 1-7 mean the following: 1) The radiator is 20% oversized and the water flow corresponds to the nominal 10 hoa of the radiator 2) The radiator is 20% oversized, with the water flow being 80% of the nominal power of the radiator 3) The radiator is 10% oversized, the water flow corresponds to the nominal hoa 15 4) The coil has an oversize of 10%, the water flow being 90% of the flow according to the nominal power of the coil 5) The system adjusted according to the invention. The water flow corresponding to the room heat losses has been calculated for the radiators. Corresponds to a theoretically correctly dimensioned radiator in other methods • ·. '·· 20 6) The radiator has a 10% undersize and the water flow corresponds to the nominal • Λ * of the radiator:: 7) The radiator has a 20% undersize, the water flow corresponds to the nominal power of the radiator.

m • · · t · »··· · Ϊ *" ·

As can be seen from the above, the change in the dimensioning of the radiators • · · ’· * * 25 from the theoretical causes a very large deviation from the desired target,. temperature. Since radiators are usually chosen to be oversized, • «· V!.: It can be seen that the energy drop from oversizing is very large.

i:: * * · '* The adjustments made by the method according to the invention thus make it clear *. 30 savings in both control costs and operating costs for both the consumer • · \ * ·: as well as the heat generating unit. In addition, according to the invention, it is possible to carry out the adjustment at any time of the year and it can be carried out reliably and easily, even in objects which cannot be adjusted to the end result by the normal, prior art methods. Since, according to the invention, extra pumping is avoided, savings also come in the form of a reduction in pumping power in addition to saving direct heat consumption.

5

Only embodiments have been described above which do not limit the scope of the invention. The presentation relates only to such things as are necessary to understand the basic idea of the invention. The placement and installation of the radiators shown in the examples can also be different, covering the liquid circulating systems of the building. In addition to water, the heat transfer fluid can also be various liquid mixtures. Several heating or cooling radiators can also be installed in the same room or duct.

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Claims (7)

A method for setting a heat9 or cooling element to emit / bind a certain amount of heat, characterized in that the actual power of the heat / cooling element is compared with the power requirement and for the element to install such a ground fluid stream with which the power of the element corresponds to its heat transfer characteristics. the power that a room or air stream needs. Method according to claim 1, characterized in that the basis for calculating the actual power of the element is its nominal power, which is based on the design temperature difference. 3. A method according to claim 1, characterized in that the liquid stream to the element is installed independently of its nominal liquid stream. 15 Method according to claim 1, characterized in that the power requirement in the space where the element heats or cools is calculated and that the liquid stream to the element is installed so that the element with the set liquid stream can emit: heat / cool as much as necessary. • t: 20 • · · • ·. Process according to claim 1, characterized in that the necessary heating; the amount is compared with the surface content of the element and heat-emitting properties. M I • * · • · »-« «s *: 's 6. A method according to claim 1, characterized in that in calculating the power demand in said space, the size, insulation, air exchange and the other factors affecting the matter are taken into account. • t · r 9 * »fi Use of the method according to claim 1 for controlling the temperature of a room or for heating / cooling the air being exchanged. : 30 t · »'♦» 9