DK200800009U3 - Ion heating system - Google Patents

Description

5

?! electric © pvarmnlri say warmest

There are different electrode tufts, which include the presence of heat dissipation

My heating system nut for heating water or for steam steam solutions Solutions, each effluent red & edter are used as heaters and electricity is converted directly into heat energy, which is described, for example, in the Russian patents PU216 & S74 and RU2i89S41.

The greatest disadvantage of electrode boilers is the instability of the electrodes due to their use.

ICE

Readings closest to the present invention are aontek © mt ~ mesystemiøsnlnger {29, G92004, ^; <% i ^ vambive, erd /% eb ^) 06f "° \ ♦ 'wwwJijdliOfeketmkiJitm) by Lsidt Ccrasulf GO fbhtpy / wwvJøk «^^ ?, Datos locks include a monocyclic system in which the electric ferric © kedaL

m mm heats rarmetranspertiiifdfet alter water, which circulates In system, is femundet food radiators, underfloor heating or a hot water tank.

The disadvantage of this or similar solutions is that when the ignition boiler isiufr tes to the heating system, the fisfe system must be redesigned separately depending on the use of radiators or an epheating heating system, which is specially made far ef heating © ksdiaa In the case of the above solution is the water as imjps as YørmetmnaponmedÉum, Ikke © gnet etc. drSikeyand, and the water as tw-ges often heating, can not be separated in the system Therefore, such a solution can be complex and ireavrerfig to brup.

the phonothermal system following the generation or the next gene ratator of the common tonic electroceflex def systems. The purpose of the preprpepteen is to tliv ©) © Oringe an epvarmnteg system II indoor run with an area up 1 30 2 DK 2008 00009 U3 400 m2 as well as for larger industrial plants, stairwells and other larger buildings. In order to heat large spaces, the solution according to the invention can be connected to larger systems, which comprise two or more ion heating systems.

A significant advantage of a solution according to the invention is that a separate boiler house is not needed to install the ion heating system. The system can be installed at the entrance in the utility room, in the basement, in the attic, in the garage or in any other room, where a central heating system inflow and outflow pipe as well as an industrial socket for supply with sufficient electrical power can be installed.

the ion heating system of the lon heating system can be used as a heat source in floor, radiator or hot air heating systems and to produce hot drinking water, the lon heating system can be connected both separately in relation to and in parallel with the existing system. Unlike known heating solutions, the ion heating system does not include heating coils, fire chambers or other heating elements, and is therefore completely fireproof and safe.

The mode of operation is based on converting electrical energy into heat directly in the heat transport medium, where the heat is generated by the movement of the electrons and the ionization of a liquid, which makes it possible to save energy and achieve the maximum possible efficiency. In principle, all spent energy is converted into heat energy, which is why the generation ideally has a greater efficiency than all other known solutions, and the entire ion heating system heats up quickly.

the ion heating system can also be used in the renovation of existing heating systems, where the water of the ion heating system and the water circulating in the existing heating system do not come into contact with each other due to a heat exchanger and the purity of the heating system is irrelevant, the ion heating system can be connected to cast iron radiators. boilers and other systems where rust, metal particles and limescale flakes can be found.

3 DK 2008 00009 The U3 ion heating system comprises two circuits: a first primary or boiler circuit and a second secondary or heating circuit, where in addition to water, a special frost-proof liquid can also be used as a heat transport medium. The advantage of this liquid over water is that it can withstand cold and that it has a high heat capacity, which guarantees the transport of a larger amount of heat with the same amount of liquid. When a special heat transport medium is used, no limescale or corrosion occurs in the ion heating system and the operating time of the ionic boiler can be significantly increased.

The entire ion heating system is designed as a complete solution, which is ready for immediate use and which allows a fast and compact installation, for which the installer does not need any special training.

The creation is explained in more detail below with reference to the drawing. The endorsement shows figure 1 the ion heating system in perspective, figure 2, seen in section, the ion heating system from fig. 1 in a first embodiment, FIG. 3, seen in section, the ion heating system according to FIG. 1 in another embodiment, FIG. 4 is a sectional view of an ion heating system according to FIG. 1 in a third embodiment, FIG. 5 is a sectional view of an ion heating system according to FIG. 1 in a fourth embodiment, and FIG. 6 is a sectional view of an ion heating system according to FIG. 1 in a fifth embodiment.

The ion heating system according to the invention, shown in Figures 1, 2 and 3, comprises a housing which comprises a front panel 1 and opposite the front panel a side 2, an upper side 3, a lower side 4, a rear side 5 and opposite to the rear side a door 6. The heating system further comprises an ionic boiler 7, an expansion vessel 8, a non-return valve 9, a circulation pump 10, a manifold divider 11, a sensor unit 12, an automatic venting device 13, which is arranged on the manifold divider 11, a pressure valve 14, a pressure manometer 15, an automatic valve 16 (for example a thermal or magnetic valve which can be controlled by means of sensors or the like at a constant temperature or a temperature setting between 30-100 ° C), and by renovation of existing heating systems: a heat exchanger 17, heat pipelines comprising pipes 18, 19,20,21,22,23,24,25,26, 27 and in case the heat exchanger 17 is present, pipes 28 and 29, upper fasteners 30, lower phase operating elements 31, a control unit 32, attached to the front panel 1 and connected to the electrical system of the ion heating system, connectors 33, a further earth connection 34, pipe openings 35, 36, 37, 38, a thermal sensor 39, arranged on the door 6, an overheating sensor 40, a locking system 41 and a sensor 42.

The heat transport is divided into two circuits by means of an automatic valve 16: a first primary or boiler circuit and a second secondary or heating circuit. The automatic valve 16 automatically selects the primary circuit, the primary circuit of the ion heating system must be heated to the preselected temperature (eg 60 ° C), after which the automatic valve 16 opens the second circuit and the ion heating system releases the heat transport medium at the predetermined temperature. In this way, it is possible to prioritize one part of the heating system over another, e.g. to use the primary circuit for hot water and radiators, and the second circuit for radiators and underfloor heating. The automatic valve 16 may be a thermal valve to be used to increase the operating temperature of the solid fuel boiler to increase the combustion rate and efficiency of the fuel. The input 43 of the automatic valve 16 is connected to the manifold divider 11 by means of a pipe 18, and the manifold divider is connected to the upper part of the ionic boiler 7 by means of pipes 19 and 20.

According to the first embodiment of the invention shown in FIG. 1 and 2, the ion heating system is intended for connection with new heating equipment. In this case, the output 44 of the automatic valve 16 is connected to a pipe 21, and the other output 45 is connected to the non-return valve 9 via a pipe 22, the non-return valve via pipes 24 and 25 and the pipe 26 of the circulation pump 10 being connected to the ionic 5 DK 2008 00009 U3 boiler 7 lower part, and where the non-return valve is connected to pipe 23, which is connected to the expansion vessel 8 and the pipe 27.

To connect the ion heating system to an existing heating system according to another embodiment of the generation, as shown in Figures 1 and 3, the heat exchanger 17 is installed in the ion heating system to prevent contaminants (lime flakes, rust, etc.) from entering the system. In this case, one output 44 of the automatic valve is connected to the upper part 171 of the heat exchanger 17 via a pipe 23, the upper part 171 is connected to a pipe 21 and the other output 45 of the automatic valve 16 is connected to the lower part 172 of the heat exchanger 17 via a pipe 22 and pipes 27 and 29. The lower part 172 is connected to the pipe 24.

The third embodiment according to the invention is shown in Figure 4, where the automatic valve 16 is provided with two inputs 46 and 47 and an output 48. The input 46 of the automatic valve 16 is connected via a pipe 50 to the non-return valve 9, which via a pipe 22 is connected to the tubes 18 and 21, and the tube 22 is connected to the expansion vessel 8 via the tube 23. The second input 47 of the automatic valve 16 is connected to the tube 24, and the output 48 of the automatic valve 16 is connected to the tube 25.

The fourth embodiment according to the invention is shown in fig. 5, where the ion heating system is supplemented by a heat exchanger 17, and the automatic valve 16 is provided with two inputs 46 and 47 and an output 48.1 in this case one input 46 of the automatic valve 16 is connected to a pipe 22, which is connected via the pipe 23 with the expansion vessel 8, via the pipe 18 with the manifold divider 11 and via the pipe 28 with the upper part 171 of the heat exchanger 17. The output 48 of the automatic valve 16 is connected via the lower part 172 of the heat exchanger 172. The second input 47 of the automatic valve 16 is connected to the pipe 27, which is connected to the tube 25.

The fifth embodiment of the ion heating system is shown in fig. 6, where the ion heat system with a heat exchanger 17 instead of the automatic valve 16 in the above embodiments is provided with a valve in the heat exchanger output points 491 or 492 or a valve at the heat exchanger input points 493 or 494 to limit the heat transport.

According to a sixth embodiment for heating large areas, such as industrial plants, storage halls, and more, ion heating systems are connected in a cascade.

the central heating system must be installed vertically, independently of the central heating system's pipelines. To prevent leakage in the warmer heats of the ion heating system, plastic pipes can be used, which can be insulated to prevent heat loss. The heating pipe can be fastened by means of upper fastening elements 30, which are connected to the inner upper side 3 of the housing, and lower fastening elements 31, which are connected to the inside of the back of the housing 5. To prevent contact between neutral and the ground connection, the fastening elements are coated.

15

To activate the ion heating system, it is pre-filled with a suitable heat transport medium. The preferred heat transport medium may be water corresponding to drinking water standard (conductivity 350-400 pS at +20 ° C) or a special frost-proof liquid. The preferred working pressure in the ion heating system is 1.5-20 2.2 bar and the preferred working temperature is 70-75 ° C. To activate the second circuit, the primary circuit must be heated to the preset temperature (preferably 60 ° C). The temperature of the primary circuit required to activate the secondary circuit can be controlled by means of a thermal relay and selected as required.

25

Table 1 shows how the nominal power of the ionic boiler 7, which is operated in the ionic heating system at a working temperature of 70 ° C as prescribed by the solution according to the first embodiment, and the preferred amount of heat transport medium depends on the heated area.

7 DK 2008 00009 U3

Nominal power for an ionic boiler at 70 ° C 6 kW 9 kW 12 kW 15 kW 20 kW 25 kW Maximum current 13 A 16 A 20 A 25 A 32 A 40 A Recommended amount of heat transport medium in the ionic heating system> 80 L> 140 L > 200 L> 260 L> 360 L> 500 L Heated area im * 90 135 180 225 300 375 The heating system is connected to the electricity grid via a 32A or 63A connector 33 on the front panel 1, and the housing and the heating circuit of the secondary circuit are connected via a additional ground connection, the lonheating system is connected to the electricity grid by means of a power plug, and this can be done by a person without special electrical training. All automatic control equipment is installed in the housing and can be controlled from the front panel 1.

The primary circuit is separated from the housing 1 and is not connected to the ground connection. An additional ground connection is provided for emergencies. The live parts are covered with insulation. All connections are made in a way where the heat transport medium moves in a closed system and does not have direct contact with conductive parts. An automatic overheating sensor 40 is installed on the ion heating system and the user does not have access to the live parts. When the door 6 of the housing is opened, the electrical system is automatically switched off by means of the sensor 42, which is connected to the ion heating system via the locking system 41. When the door 6 is closed, the heating operating state is re-established.

20 Control and regulation of the operation of the ion heating system is carried out by means of a digital thermal sensor 39, which is installed on the door of the house 6. The thermal sensor 39 controls the operation of the ionic boiler 7 and regulates the electricity consumption in accordance with the set temperature. The thermal sensor consists of a main switch, a magnetic switch, automatic fuses, phase indicators, a digital thermal relay, an overheating sensor that can be reset manually, and a sensor 42. Using the thermal relay can the system works smoothly and energy-saving by keeping the preset temperature in the primary and secondary circuits. The manually reset overheating sensor protects the system against overheating in an emergency.

The invention is not limited to the above embodiments and the components described. Those skilled in the art will appreciate that the present invention may be varied within the features set forth in the utility model requirements.

Claims (1)

9 DK 2008 00009 U3 Bruasmodelkrav 1. first heating system, which comprises a front panel (1) and a side (2) facing the front panel, an upper side (3), a underside (4), a back side (5) and at least one facing the back side door (6), an ionic boiler (7), an expansion tank (8), a non-return valve (9), a circulation pump (10), a manifold divider (11), a sensor unit (12), an automatic vent (13), which is arranged on the manifold divider (11), a pressure valve (14), a pressure manometer (15), pipelines (18, 19, 20, 21, 22, 23, 24, 25, 26, 27, 29, 50), upper fastening elements (30), lower fastening elements (31), a control unit (32), which is arranged on the front panel (1) and which is connected to the electrical system of the ion heating system, connectors (33), an additional earth connection (34), pipe openings (35, 36, 37, 38), a thermal sensor (39) mounted on the door (6), an overheating sensor (40) and a locking system (41), which are new in that the ion heating system is further provided with an automatic valve 1 (16) for distributing the heat transport to a first boiler circuit and a second heating circuit, the automatic valve (16) being provided with an input (43) and two outputs (44 and 45). A heating system according to claim 1, which is new in that the input (43) of the automatic valve (16) is connected via the pipe (18) to the manifold divider (11), which is connected to the pipe (19) and via the pipe (20). with the upper part of the ionic boiler (7) and that one output (44) of the automatic valve (16) is connected to the pipe (21) and the other output (45) is connected to the non-return valve (9) via the pipe (22), which is connected via the pipes (24 and 25) and the pipes (26) of the circulation pump (10) to the lower part of the ionic boiler (7) and to the pipe (23) which is connected to the expansion vessel (9) and the pipe (27). The ion heating system according to claim 1, which is new in that the ion heating system is further provided with a heat exchanger (17), and one output (44) of the automatic valve (16) is connected via the pipe (28) to the upper part of the heat exchanger (17). (171), which is connected to the tube (21), and where the second output (45) is connected to the tube (22), which is connected via the tube (23) to the expansion vessel (DK) and the pipe (27) and via the pipe (29) with the lower part (172) of the heat exchanger (17), which is connected to the pipe (24). The ion heating system according to claim 1, which is new in that the ion heating system is further provided with an automatic valve (16) with two inputs (46 and 47) and an output (48), the automatic valve (16) having one input (46). ) is connected via the pipe (50) to the non-return valve (9), which is connected to the pipes (18 and 21) via the pipe (22), and the pipe (22) is connected to the expansion vessel (8) via the pipe (23), and where the second input (47) of the automatic valve (16) is connected to the pipe (24), and the output (48) of the automatic valve (16) is connected to the pipe (25). A heating system according to claims 3 and 4, which is new in that one input (46) of the automatic valve (16) is connected to the pipe (22), which is connected to the expansion vessel (8) via the pipe (23), and via the tube (18) is connected to the manifold divider (11) and via the tube (28) to the upper part (171) of the heat exchanger (17), and where the second input (48) is connected via the tube (29) to the heat exchanger (17) upper part (172), and wherein the output (47) of the automatic valve (16) is connected to the pipe (27) which is connected to the pipe (25). Ion heating system according to claim 1 and claim 3, which is new in that the heat transport of the ion heating system is limited in the output points (491 and 492) of the heat exchanger (17) and input points (493 and 494). The ion heating system according to claim 1, which is new in that the automatic valve (16) is a thermal valve, a magnetic valve or a valve which is controlled by means of an electric motor and sensors. A heating system according to claim 1, which is new in that the first circuit must be heated to 30-100 ° C, preferably to 55-65 ° C, in order to activate the second circuit. The ion heating system according to claim 1, which is new in that the locking system (41) is further provided with a sensor (42), and a neutral and a ground connection are separated in the electrical system of the ion heating system, where the neutral connection is connected to the first circuit and the ground connection is connected to ground. 5