DE9418815U1 - Energy rotator for heating hot water heating and domestic water systems - Google Patents

Description

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752 G2

Energy rotator, for heating hot water heating systems and service water systems

The invention relates to an energy rotator for heating hot water heating systems and domestic water systems.

The object of the present invention is to create a device by means of which energy conversion can be generated with high efficiency in order to supply, for example, hot water heating systems and domestic water systems with hot water.

The object is achieved according to the invention according to the features specified in claim 1. Advantageous embodiments of the invention are specified in the subclaims.

With the system according to the invention, water can be heated, for example for hot water heating systems or domestic water systems, with comparatively low energy consumption, i.e. with comparatively high efficiency.

According to the invention, a so-called energy rotator is set in rotation by means of a conventional drive device. The liquid medium contained therein is heated by the specific design of the energy rotator. For this purpose, a rotating disk is provided inside the drum-shaped energy rotator, which is preferably machined like the front inner walls of the housing drum of the energy rotator in such a way that the liquid is heated due to the friction that occurs inside.

The heated water can be fed to the hot water heating system or the domestic water system, for example, via a liquid return. The fresh water to be heated can be heated again via an inlet.

The invention is explained in more detail below with reference to drawings. In particular:

Figure 1: a schematic side view of the cylindrical turbine according to the invention with an electric motor as a drive unit;

Figure 2 : a schematic axial cross-sectional view through the drum-shaped turbine

according to Figure 1;

Figure 3 : a schematic plan view of the

rotating disc inside the drum;
30

Figure 4 : a schematic partial circumferential

Wall development of the rotating disk shown in Figure 3; and

Figure 5 : an enlarged detail through

the crater-shaped holes provided in the disc

moderate breakthroughs.

In Figure 1, reference numeral 1 indicates an electric motor which is connected via a drive belt 3 to a corresponding rotating outer disk 5 of a cylindrical turbine 7.

As can be seen from the cross-sectional view according to Figure 2, the cylindrical turbine 7 consists of a cylindrical housing 9 with two opposite housing end faces 11, which are formed in the manner of two fixed disks.

The outer disk 5, driven by a drive belt 3, sits on an axle 15, together with a friction disk 13 housed in the turbine 7. The common axle 15 occupies at least the housing end wall 11 located between the outer disk 5 and the friction disk 13 located inside the cylindrical turbine 7.

From the top view and the partial peripheral edge development according to Figure 4, it can be seen that the friction disk 13 is provided with a large number of crater-shaped openings 19, which are also referred to below as resistance projections.

These resistance projections 19 are each arranged offset from one another on several breakthrough lines 27 running through the center M of the friction disk 13, whereby several breakthrough lines 27 are each arranged offset from one another by an angle α running through the center M.

5 From the edge development according to the partial representation in Figure 4 it is also clear that in each case a through-

fracture line 27 ' is bent in the opposite direction to an adjacent breakthrough line 27" and is slightly folded so that two sector elements 31 are each designed in the shape of a roof on either side. The resistance projections 19 are inserted so as to protrude outwards on the respective projecting breakthrough edge 27. These resistance projections 19 can be produced by means of a piercing tool so that the protruding material produced thereby serves to increase the resistance in interaction with the liquid.

Accordingly, the front inner wall surfaces 11 of the cylindrical turbine are designed with resistance projections 19.

The friction disk 13 located inside the cylindrical turbine 7 is then set in rotation via the electric motor 1, the drive belt 3 and the outer disk 5, whereas the drum-shaped inner front wall sides, which are also provided with resistance projections 19, are fixed. Liquid can now be fed in continuously via an inlet 3 3, which then leaves the turbine heated via a return 3 5. The resulting friction between the rotating inner wheel 13 and the fixed cylinder wall sides 11 can heat the liquid in the turbine to such an extent that the liquid heated in this way can be used to heat hot water heaters or for a domestic water system through permanent circulation.

Claims (6)

752 G 2 claims; 1. Energy rotator for heating hot water heating systems and domestic water systems, characterized by the following features - a turbine (7) which can be filled with a liquid is provided inside, - the turbine (7) has inside a friction disc (13) rotatable about an axis (15), - the turbine (7) is provided with a liquid inlet (33) and a liquid return (35), - a drive motor (1) is provided, by means of which the friction disc (13) can be set in rotation relative to two fixed discs (11) in the liquid, and - the friction disc (13) and the fixed discs (11) are provided with resistance devices (19) to increase the 0 fluid friction. 2. Energy rotator according to claim 1, characterized in that the resistance devices (19) are formed from crater-shaped openings in the material of the friction disk (13) and/or the fixed disks (11). 3. Energy rotator according to claim 1 or 2, characterized in characterized in that the resistance projections (19) are arranged offset from one another on several diameter lines (27) running through a center point (M) of the friction disc (13).
5 4. Energy rotator according to claim 3, characterized in that the friction disc (13) is shaped when viewed in the friction disc plane such that the individual friction disc segments (31) between two diameter lines (27) are each aligned at a slight angle to one another with respect to the common diameter line (27). 5. Energy rotator according to one of claims 1 to 4, characterized in that the friction disc (13) in the interior of the cylindrical turbine (7) can be driven via an outer disc (5) which rotates on a common axis (15) as the friction disc (13). 6. Energy rotator according to one of claims 1 to 5, characterized in that the two fixed disks (11) are formed by the housing end walls of the cylindrical turbine (7).