FI129267B - Hybrid radiator - Google Patents

Abstract

Heating element (1), comprising vertical pipes (2,3) and between them at least one horizontal pipe (7). The heating element comprises a first portion (10) and a second portion (20), of which the first portion (10) is heated by means of liquid and the second portion (20) is heated by means of electricity.

Description

HYBRID BATTERY ENGINEERING

The present invention relates to a two-part radiator, for example a drying radiator. In particular, the invention relates to a radiator according to the preamble of claim 1, which is heated by means of hot water circulating therein. The invention also relates to a connector according to the preamble of claim 12 and to a method according to the preamble of claim 14.

BACKGROUND

The conventional type of towel radiator has been known in various versions for a long time.

- The general principle is that there are usually a plurality of transverse, substantially horizontal pipe sections connecting said vertical pipes between two substantially vertical pipe sections. According to a conventional solution, the hot water fed from the lower end of the second vertical pipe passes upwards through said pipe and into said second vertical pipe section and at the end of the water returns to the circulation.

There are situations in which it is expedient to arrange the water circulation of the radiator so that the incoming water, as well as the outgoing water, passes through the pipe connections at the upper end of the radiator. If the conventional radiator is arranged in this way, the flow only takes place through the upper cross-sections, while the lower cross-sections remain cold. It is clear that the operation of the battery is then insufficient.

S 3 20 - Solutions are known in which an attempt is made to influence the internal circulation of the radiator by fitting an inner tube inside the normal tubes of the radiator, by means of which the flow E can be directed to a certain part of the battery. Examples of such solutions are given in IS 0928939 A1 and EP 1568961 A1 and FR 2842286.

The patent FI 119462 describes a radiator with upper end connections, in which - on the outlet side, an inner tube extending to the lower end of the vertical tube, extending to the level of the lowest horizontal tube, is arranged. The arrangement makes the flow such that the radiator heats evenly.

In the solution of patent FI 119462, the inlet and outlet connections are both at the upper ends of the vertical pipes. When the inner pipe is used in accordance with FI 119462, an air pocket is easily left at the top of the vertical pipe on the outlet side. Nevertheless, the arrangement works satisfactorily when the number of horizontal tubes is low. Instead, as the height of the radiator is increased and there are more horizontal tubes, a situation arises where the water does not flow evenly so that the temperature of the lowest tubes is the same as that of the others, but these tubes remain lukewarm. In other words, the lower pipes leave water that moves poorly and may also have a temperature below that required for the hot water circuit to prevent the growth of harmful microbes such as legionella.

The prior art is further represented by EP 3067638 A1, WO 20515173629 A1 and US 2010209086 A1.

SUMMARY

The present invention provides a solution which is a two-part radiator. The first part of the radiator is heated by a hot water circuit, for example - in the same way as in patent FI 127668, and the second part is heated by electricity.

According to one embodiment, the portions may be interconnected and the outward structure may appear uniform because the portions have a uniform outer sheath.

In contrast to the previously known solutions, the present invention brings surprising improvements to the radiator N. Since the radiator operates in two independent A 20 heating modes, energy can be saved because the radiator can only be heated by it? as necessary. The user is able to determine the battery temperature better 2 than with current batteries. a a

K e The radiator according to the invention can be connected to the district heating network, whereby the first part 2 heats up only when the district heating is switched on. N 25 Again, when the district heating is switched off, the coil can only be heated from the second section. However, this heat of the second portion is also due to the liquid circulating in the first portion, heating it, which prolongs its service life.

Alternatively, the first portion = can also be connected to underfloor heating, solar energy, geothermal energy or heat recovery.

In the connector part according to the invention, the connector part is adapted to connect the electric radiator to the liquid-heated radiator, the connector part comprising two male sides, the first being adapted to be connected to the vertical pipe of the liquid-heated radiator and the second to the vertical pipe of the electrically heated radiator.

In the method according to the invention, an electrically heated radiator comprising vertical pipes and at least one horizontal pipe between them is mounted in a liquid-heated radiator by means of a connecting part. More specifically, the solutions according to the invention are characterized by what is stated in the characterizing parts of the independent claims.

BRIEF DESCRIPTION OF THE DRAWINGS

Some embodiments of the invention will now be described in more detail with reference to the accompanying drawings, in which: Figure 1 shows a front view of an embodiment of a battery according to the invention, and Figure 2 shows a side view of a battery according to the invention. The internal structure of the radiator is shown in broken lines. In the figure, the corresponding parts are denoted by N with the same numbers.

O

N 2

EMBODIMENTS ™ E 20 - Fig. 1 illustrates a battery according to an embodiment as seen from the front. The battery 1 consists of two sections, a first section 10 and a second section 20, which are interconnected and connected by two substantially

O o vertical pipe sections 2 and 3. Vertical pipe sections 2, 3 have separators 15 and 16,

N by means of which the first 10 and second sections 20 are separated from each other.

The operation of the first portion 10 of the radiator will now be described. In the first section 10 of the radiator, the heating medium is fed to the first vertical pipe section 2 and the medium leaves the radiator from the second pipe section 3. Figures 1 and 2 illustrate the flows with arrows. In the following description, terms are used which - refer to the normal water cycle, although of course the medium may be more than water.

According to Figure 1, the inlet connection 4 is arranged in the wall of the vertical pipe 2, on the wall side of the room, whereby it also acts as a wall bracket for the radiator. The inlet connection 4 can be located elsewhere than in the wall of the vertical pipe 2, for example at the end of the pipe.

Reference numeral 7 denotes transverse flow channels, conventionally - horizontal pipes, and the flow passes from the inlet connection 4 through the horizontal pipes 7 and the inner pipe 8 of the vertical pipe 3 to the outlet connection 9. Deaeration valves 5, 6 are connected to the system. The inlet connection 4 and the outlet connection 9 are located above the uppermost horizontal pipe.

The upper end of the inner tube 8 is connected to a part at the upper end of the vertical tube 3 having a deaeration valve 6. The outlet connection 9 is passed through the walls of the vertical tube 3 and the inner tube 8 at the same level as the inlet connection. The outlet connection 9 can also be located elsewhere than in the wall of the vertical pipe 3, for example at the end of the vertical pipe 3.

On the outlet side of Fig. 1, in this embodiment, the passage of water in the vertical pipe 3 is prevented by the partition wall 11, so that water passes above the partition wall only through the inner pipe 8. In the embodiment shown in Figure 1, a sleeve 12 is arranged at the upper end of the upper part of the vertical tube 3, the outer diameter of which substantially corresponds to the inner diameter of the vertical tube 3. The wall of the sleeve 12 has an opening 13 at the outlet connection 9. The lower end N of the sleeve 12 is located in a plane between the upper edge of the uppermost horizontal tube 7 and the lower edge 3 together. The lower end of the sleeve is otherwise closed and forms a partition 11, but has a ™ 25 connection, for example an internally threaded opening through which the inner tube 8 is passed. The upper ends of the vertical pipes 2 E and 3 have deaeration valves 5, 6. The inner pipe 8 can extend to the upper end 5 of the vertical pipe, whereby there is an opening 14 in the wall of the inner pipe.

O N The operation of the second portion 20 of the battery will now be described. Another part of the radiator according to Figure 1 is an electrically heated radiator. In it, the electric resistor 17 heats the medium, which flows according to the arrows shown in the figure evenly, heating the second part of the radiator. The electric resistor 17 can be switched on or off from the circuit breaker 18, i.e. according to the embodiment shown in Fig. 1 the electric resistor 17 is mounted - with a semi-fixed installation. The electric resistor 17 can also be installed as a plug connection. In both mounting methods, the power of the electric resistor can be adjusted steplessly, for example between 0 and 65 ° C.

The first and second portions are separated by separators 15 and 16, which may be, for example, brass sleeves with a solder to allow the separator to be soldered to the inner surface of the vertical tubes 2 and 3.

According to one embodiment, no current is present in the second section at all, but an electrical resistor passes through the horizontal tubes 7 and the vertical tubes 2 and 3 of the second portion and thus heats the radiator.

Figure 2 shows how the water flow (indicated by arrows) passes from the lower end of the upper part of the inner tube 8 to its upper end and exits the radiator through the sleeve 12 and the opening 13 to the outlet connection 9 in the first section.

Figure 2 shows the installation of a second section electrical resistor as a plug connection according to an embodiment.

The arrangement of the radiator according to the invention in the first section provides a flow which is evenly distributed in the horizontal tubes, whereby all the horizontal tubes of the first section reach the same temperature. The electrically heated second part is also made to heat evenly by means of the arrangement according to the invention. In the second section, an electrically heated medium can be used for heating, or alternatively the entire piping of the lower part can be heated by means of a larger electric resistor. N The lower part has a stepless power adjustment, so that the temperature of the lower part of the radiator can be adjusted to 3 desired levels, for example between 0 and 65 ° C. In general, the first section is connected to the district heating network, but the radiator a is also suitable for connection to the domestic water network, underfloor heating, solar energy, geothermal energy or heat recovery. In this case, the upper part is also made to warm up all year round. The radiator normally operates at very low flows, approximately 0.01 to 0.02 1 / s N in the water circuit.

The radiator according to the invention is made of a suitable material, which for aesthetic reasons is often a chromed copper tube in such objects. Other materials are not excluded in any way.

The radiator according to the invention is preferably intended for wall mounting. In this case, the inlet and outlet connections preferably act as wall brackets for the first section and the second section has second wall brackets. The connections are then preferably located on the wall-mounted side as shown in Figures 2, but can in principle also be located elsewhere on the outer circumference of the vertical pipes.

According to an embodiment of the invention, only an element corresponding to the second portion can be produced, which can be connected to an already existing liquid-heated radiator. In this case, the electric coil of the lower part is connected to the existing liquid-heated coil by a connector part.

According to an embodiment of the invention, the connector part comprises two male sides, the first of which is connected to the vertical pipe 2, 3 of the liquid-heated radiator and the second to the vertical pipe 2, 3 of the electrically heated radiator.

According to an embodiment of the invention, the method of manufacturing a hybrid battery comprises installing an electrically heated battery in a liquid-heated battery by means of a connector part. Preferably, the electrically heated radiator is installed below the liquid heated radiator.

INDUSTRIAL APPLICABILITY N The invention is particularly suitable for use in household bathrooms N for drying wet towels and for heating a bathroom. & ™

REFERENCE NUMBER LIST i N 1 Battery © 0 LO. O 25 2 Vertical pipe

O

N 3 Vertical pipe 4 Inlet connection

Deaeration valve 6 Deaeration valve 7 Horizontal pipe 8 Inner pipe 5 9Exhaust connection First section 11 Partition wall 12 Sleeve 13 Sleeve opening 10 14 Inner pipe opening Separator 16 Separator 17 Electrical resistance 18 Switch 15 20 Second section

OF O

N co Q @ 0

T and m o

PP ©

O

LO o

O OF

Claims (15)

PATENT REQUIREMENTS Heating element (1), comprising vertical pipes (2, 3) and between them at least one horizontal pipe (7), and a first portion (10) and a second portion (20), the first portion (10) of which is heated by means of liquid and the second portion (20) is heated by electricity, characterized in that: - the first portion (10) has an inner volume, which forms part of the total inner volume, - the second portion (20) has an inner volume, which forms part of the the total inner volume, and that - the inner volume of the first portion (10) and the inner volume of the second portion (20) are separated from each other by means of separators (15, 16). Heating element according to claim 1, characterized in that the first portion and the second portion are connected to each other. Heating element according to claim 1 or 2, characterized in that the first portion and the second portion have a common outer shell, which in itself encloses the total inner volume. Heating element according to one of the preceding claims, characterized in that - the first portion (10) has an upper portion and a lower portion, S - in the upper portion of the first portion (10) there is an inlet (4) for heating medium> arranged in the rudder in the upper part of the first vertical tube (2) and that? - in the upper part of the first portion (10), an outlet (9) for heating medium = is arranged in the tube in the upper part of the second vertical tube (3). Heating element according to any one of the preceding claims, characterized in that 2 - one inner tube (8) is arranged into the second vertical tube (3), - the upper end of the inner tube (8) has a flow connection with a connection (9 ) in the second vertical tube (3) and that - the lower end of the inner tube (8) is open and extends to the lower portion of the first portion (10) of the vertical tube (3). Heating element according to one of the preceding claims, characterized in that the vertical pipe (2) of the second part (20) has an electrical resistance (17) for heating the heating medium in the pipe system of the lower part. Heating element according to Claim 6, characterized in that the electrical resistor (17) in the lower part is arranged both in the vertical pipes (2, 3) and in at least one horizontal pipe (7). Heating element according to one of the preceding claims, characterized in that the temperature of the electrical resistor (17) can be regulated. Heating element according to one of the preceding claims, characterized in that the separators (15, 16) are attached to the vertical pipes (2, 3). Heating element according to Claim 9, characterized in that the separators (15, 16) are fastened by welding. Heating element according to Claim 9, characterized in that the separators (15, 16) are fastened by means of connecting means. Connection portion for manufacturing a hybrid heating element, wherein the connection portion is arranged to connect an electric heating element to a heating element heated by means of liquid, characterized in that the connection portion comprises two male sides, of which the = first male side is arranged to be connected to the liquid heated by liquid The vertical pipe (2, 3) of the N element and the other male side are arranged to be connected to the vertical pipe (2, 3) of the electrically heated heating element. ™ 30 I Method for manufacturing a hybrid heating element, characterized in that a + heating element heated by means of electricity, comprising vertical pipes (2, 3) and at least E a horizontal pipe (7) between them, is arranged by means of a connecting portion to a liquid heated by means of liquid. radiator. N 35 Method according to Claim 13, characterized in that the heating element heated by means of electricity is arranged below the heating element heated by means of liquid. Method according to Claim 13, characterized in that the heating element heated by means of electricity is arranged above the heating element heated by means of liquid. N O N © I ™ I a a N O 0 LO O O N