DE4400344A1 - Electric water heating system with forced, multi-circuit, circulation - Google Patents

Abstract

The heating system comprises separate electrically heated boilers for each circuit, in which an exact amount of water is heated to an exact temperature, with an economy not available to oil and solid fuel systems. Each circuit consists of an electric heating element (14) within a small boiler (10). Circulated water enters the heater through inlet (11) and is restored to the reference temperature, controlled by a thermostat (16). Water is returned to the system (40).

Description

The invention relates to a modification and further development development in the field of hot water heating with forced circulation.

In the known oil and coal heaters, this takes place Heating up the water in a boiler on average a flow temperature of 90 ° C. The number and size the radiator is usually sized so that the Temperature of the water flowing back, the return temperature, 70 ° C. All hot water heaters can be controlled automatically, d. H. the ge The desired room temperature is constantly set to one real value. This is done in the heated rooms Thermostats installed on which the desired room temperature temperature is set. They give when the rate drops or Rise in temperature pulses to the intended Control elements of the system, more or less heat respectively. The regulatory bodies in question are either the control valves of the individual radiators, with which you set the desired temperature in each room can put, or the boiler system, where one at Oil firing contributes to the burner or the amount of oil Coal firing metered the amount of combustion air.  

For hot water heaters with forced circulation, as before are preferably used in multi-storey buildings, can also set the flow rate of the water pump and thus regulates the amount of water transported (see, for example, "How does it work? The technology in give from today ", 2nd completely revised edition, Bibliographic Institute, Mannheim / Vienna / Zurich, 1978).

For such on the principle of heat convection based heaters are accordingly a variety of sensors and control elements required. A right a relatively large amount of energy must be reached when heating up the required flow temperature and its Maintenance will be provided. With oil and Coal heating systems also lead to exhaust gases and residues Environmental pollution. The required boilers are right relatively voluminous.

After the tendency goes there, the emissions emissions and reduce energy consumption and the Energy generation in the form of electricity if possible it turns out to concentrate a few power plants u. a. the question of alternatives, especially to with cheap night electricity storage heaters.

The invention has for its object the advantages the hot water operated with oil or coal firing heaters with those of the electrically operated heater such as storage heaters and radiant heaters, the construction costs of the heating devices for hot water to reduce water heating and at the same time as the  put energy in a more targeted and effective way.

To solve the problems, an electrically powered one Hot water heating with forced circulation suggested how them in the claims, which also form part the description are under protection. Erfin In principle, the procedure is such that a certain amount of water in the circulatory system certain temperature is heated and only when the target temperature of the branched-off quantity has been reached, is released into the fluid circuit again. For Acceleration of the heating phase and / or depending the total amount of liquid in the system can several such heating components together be switched. Is the set temperature to be heated the system automatically regulates back into the rooms such that the desired temperature is maintained becomes. By heating small liquids quantities taken from the circuit during the heating phase can be the temperature control of the overall system and thus of the rooms to be heated dosed and made specifically become. This is not least due to the fact that the temperature rise of small amounts of liquid is achieved faster and better in application can be brought under control than with large liquid quantities in widely ramified systems.

The heating proposed to carry out the process device is characterized in that its essential cher component of a heating component, the heating element  ment is operated electrically and from the existing 220 V network can be supplied. Furthermore, only few, robust and simple in their nature standardized components and functional parts needed. Because of the compactness of the heater can be installed directly in / on the liquid circuit system are made so that they are also for Flats and mobile units. Further Advantages are that the heater proposed emission-free, user-friendly and largely maintenance-free free is. A boiler is not required, which is under cost viewpoints and spatial aspects are also important falls.

The invention is based on an embodiment example explained in more detail. Show it

Fig. 1 shows a heating component of the heating device according to the invention

Fig. 2 shows schematically the structure and arrangement of the heating device in conjunction with the heating system and

Fig. 3 is a schematic diagram of the electrically operated components for series connection and group connection of the heating components.

The proposed heating component ( FIG. 1) consists essentially of a pressure vessel 10 with inlet 11 and outlet 12 , a vent 13 , a heating element 14 , thermometer 15 , thermostats 16 and a valve 17 in the outlet 12 . Heating element 14 and valve 17 are operated electrically. Since the principle of the invention is based on the fact that part of the amount of liquid in the heating system is branched off, stopped and heated to the desired temperature before it is conveyed back into the circulatory system, the heating component must be switched as a bypass if the Heizvor direction is part of all conventional Warmwasserhei tongues with forced circulation, since it must be guaranteed in operation that liquid can constantly circulate. The heating components are preferably of identical construction and are designed, for example, for 1 liter capacity.

Fig. 2 shows schematically the arrangement and structure of an example of 4 heating components 1 , 2 , 3 and 4 existing heating device in conjunction with a heating system, with hints for the forward 40 and return 41 for intervening and not shown heating body. Since in the example it is a system with forced circulation, as indicated by the water pump 42 , the heating device is designed in such a way that at least 1 heating component is always switched to flow when there is no separate bypass 36 .

For commissioning, the valve 31 is opened and the heating system is filled with water via the supply line 20 . Using a pressure reducer 34 , the operating pressure in the circulatory system is set to the pressure (3.0-3.5 atm) usual in hot water heating systems and checked by means of a pressure gauge 37 . With the main switch 50 ( FIG. 3) the electrical system is activated and the circulation pump 42 is started. In the example, the circuit for a heating device with four heating components 1 , 2 , 3 and 4 is designed (Fig 3 in conjunction with Fig. 2) that the heating elements 14.1 , 14.2 , 14.3 , 14.4 , 14.1. . . are applied sequentially, further that the heating components 1 and 2 and 3 and 4 groups open and close and the outlet valves 17.1 and 17.2 of the heating components 1 and 2 are closed, while the adjacent outlet valves 17.3 and 17.4 are open, so that the liquid both can circulate through the bypass 36 and the heating components 3 and 4 . - If there is not enough pressure in the system, the safety switch 30 prevents the system from starting.

In the heating-up phase, the liquid stopped in the heating component 1 is first selected according to the selected circuit by means of an electrical heating element 14.1 , for example designed for 2 kW / 220 V, to the desired temperature, for. B. 65 ° C, heated, which is also the flow temperature of the system. 1 liter of water is heated to 65 ° C in about 1 minute using a 2 kW heating element. The temperature to be set on the thermostat 16 can be monitored with the thermometer 15 . If the target temperature is reached, the heating element 14.1 is automatically switched off and the heating element 14.2 of the heating element 2 is acted upon. Only when the liquid in the heating component 2 has reached the desired temperature, do the outlet valves 17.1 and 17.2 open, so that the inflowing liquid conveys the heated liquid into the system. As soon as the valves 17.1 and 17.2 open, the valves 17.3 and 17.4 of the heating components 3 and 4 close and the heating element 14.3 is switched on, then 14.4 . This is repeated cyclically, the intervals becoming longer as the temperature in the overall system increases. Vent 13 and pressure relief valve 38 ensure that on the one hand the entrained air when filling the system can escape, on the other hand that the pressure increase associated with heating remains limited to the value set with the pressure reducer 34 . Otherwise, an expansion vessel 60 is provided for the volume change associated with heating and cooling.

If the pressure set with the pressure reducer 34 falls below what can be tracked with the pressure gauge 37 , the valve 33 is automatically opened via the pressure switch 35 , so that water can flow in again. In the event that the water should be shut off so that the supply line 20 does not carry water, the safety switch 30 switches the system off automatically. Otherwise, the system is switched off or on again via the main switch 50 .

Of course, other circuit variants are also conceivable, as long as it is ensured that the liquid circulation is maintained during operation if it is a system with forced circulation. Except for the pressure vessel 10 , all suitable, known switching, adjusting, control, monitoring elements with the usual setting ranges and tolerances, as are commercially available, can be used. The pressure vessel 10 itself, if it is suitable for a pressure of 3.5 atm, can be made, for example, from a 2 1/2 inch tubular casing with screw-on caps.

So far in the example, the electrical circuit from is placed that only 1 heating component is formwork tet, whose capacity is 1 l, shows yourself that this is with a total amount of liquid 40 l in the system, such as in Zen apartments tral or underfloor heating is required. As for the heating components, heating elements with a Power of 2 kW can be used with a 220 V connection, can the heater to the existing and more common network installed wisely in all apartments be connected. Because there is a dependency between tempe temperature and pressure can be determined, the heating takes place the amount of liquid diverted and stopped preferably in the range between 65-70 ° C at 3-3.5 atü and 40-45 ° C at 1-2 atü.

Reference list

1; 2; 3; 4 heating component (s)
10 pressure vessel
11 supply line
12 derivative
13 ventilation
14 electr. Heating element
15 thermometers
16 thermostat (e.g. temperature controller from Landis & Gyr)
17 solenoid (outlet) valve (e.g. from FESTO)
20 supply line
30 safety pressure switches (e.g. from Suco)
31 shut-off valve
32 check valve
33 electromagnetic valve
34 pressure reducer
35 pressure switches
36 bypass
37 pressure gauge
38 pressure relief valve
40 lead
41 return
42 water pump
50 electrical main switches
51-54 Relay for thermostats 16.1-16.4
60 expansion vessel

Claims (12)

1. A method for heating water in a heating system with forced circulation, characterized in that in each case a portion of the amount of liquid in the circulatory system is branched off, stopped and heated to the desired temperature and then conveyed further into the system, with (re) flowing to he heating liquid. 2. The method according to claim 1, characterized in that a quantity of approx. 1 l is branched off. 3. The method according to claims 1 and 2, characterized in that the heating of the branched and halted NEN amount of liquid by electrically operated, switched as a bypass heating components ( 1 , 2 , 3 , 4 ) preferably in the range between 65-70 ° C. 3-3.5 atü and 40-45 ° C at 1-2 atü. 4. Method according to one or more of the preceding Claims 1-3, characterized in that parallel or several times in succession a quantity of liquid is branched off, which one after the other or simultaneously is heated side by side. 5. Heating device for performing the method according to one or more of the preceding claims 1-4 consisting of:
one or more electrically operated heating components ( 10-17 ; 1 , 2 , 3 , 4 ) connected as a bypass, in which a part of the liquid circulating in the heating system is stopped during the heating process and heated to the desired temperature and then conveyed to the circulatory system as a flow is used in conjunction with switches ( 50 ; 51-54 ; 30 ; 35 ), controllers ( 16 ; 34 ), valves ( 31 ; 17 ; 33 ) and monitors ( 15 ; 32 , 37 ; 38 ) that are known in their function and application. 6. Heating device according to claim 5, characterized in that an additional bypass ( 36 ) is provided. 7. Heating device according to claim 5, characterized in that the heating component ( 1 ; 2 ; 3 ; 4 ) consists essentially of an electrically heatable pressure vessel ( 10 ) with corresponding functional parts, in particular supply line ( 11 ), discharge line ( 12 ), ventilation ( 13 ), electric heating element ( 14 ), thermometer ( 15 ), thermostat ( 16 ) and solenoid valve ( 17 ). 8. Heating device according to claims 5 and 7, characterized in that the pressure vessel ( 10 ) is designed for 1 l of Fassungsvermö conditions. 9. Heating device according to one or more of the preceding claims 5-8, characterized in that the pressure vessel ( 10 ) consists of a 2 1/2 inch casing tube with screw-on caps. 10. Heating device according to one or more of the preceding claims 5-9, characterized in that a plurality of heating components ( 1 ; 2 ; 3 ; 4 ) are switched so that their heating elements ( 14 ) are applied individually and one after the other, further so that the exhaust valves ( 17.1 and 17.2 as well as 17.3 and 17.4 ) open or close in groups. 11. Heating device according to one or more of the preceding claims 5-10 as part of a hot water system ( 20 ; 40 , 41 ; 60 ) with forced circulation ( 42 ) and intermediate heating lines / radiators. 12. Use of the heater after one or more of the preceding claims 5-11 as a radiator or underfloor heating in apartments, houses, halls and in mobile facilities.