The invention is about a dynamic radiator which uses hydro energy for the purpose of providing faster transmission of air through the panels and fins in the radiator.

Status of the Art:

Radiators are heat exchange systems which are used for heating and cooling an environment. Nowadays, it is observed that it is frequently used in almost every home. Water and suchlike fluids and air circulations are carried out inside the radiators. This fluid and the heat of the air are released to the environment by the heat exchange panels. The invention which is the subject of the description is related to a dynamic radiator for the purpose of providing energy saving and efficiency by increasing the circulation speed of the air in the radiator.

In the dynamic radiators, the air circulation inside the radiator panel is provided by the heat exchange of hot air and cold air in the familiar art. Warm air rises, cool air descends. In such a case, the speed of the air circulating between the radiator panel cavity and the fins is low. The lowness of air circulation speed causes high energy consumption.

The energy which will be used by the air blowing fan in the dynamic radiators used in the familiar art is drawn from the electricity network. This case causes the radiators to use high energy.

Consequently, there is a need for dynamic radiators that exceeds the state of the art and eliminates its disadvantages.

Short Description of the Invention:

The invention is a dynamic radiator and the familiar state of the art is resolved, its disadvantages are eliminated in it an it also has additional features.

The goal of the invention is to provide a dynamic radiator which uses hydro energy for the purpose of increasing the circulation speed of the air circulating between its panels and fins.

The other goal of the invention is to identify a new dynamic radiator which takes the energy to be used by the fan providing air circulation from the torque taken from the water pressure of a rotor installed in the water circulation pipes.

The present invention whose all purposes that are mentioned above and will be clarified in the detailed description below is a dynamic radiator that uses hydro energy to deliver air faster through the radiator heat exchange panels and heat exchange fins inside the radiator; and its features are; it includes at least one rotor wheel positioned in the hot water return pipe, which rotates with the pressure of the water in the hot water return pipe and generates a torque, it includes at least one rotor main shaft where the rotor wheel and fan blades are positioned and transmits the torque obtained by the rotor wheel to the fan blade, it includes at least one fan propeller located on the rotor main shaft, rotating with the torque coming from the rotor main shaft, taking air from the fan air intake opening during its rotation and transmitting it to the radiator through the blown air discharge, it includes at least one fan air intake opening located on the front surface of the fan and rotor cover, where the fan blade supplies the air given into the radiator, it includes at least one blown air discharge which directs the air taken from the fan air intake which opens with the rotation of the fan blade to the spaces between the radiator heat exchange panels and the heat exchange fins.

Description of the Figures:

The present invention will be described with reference to the accompanying figures, so that the features of the invention will be more clearly understood. However, it is not intended to limit the invention to these particular embodiments. On the contrary, it is intended to cover all alternatives, modifications and equivalents that may be included within the scope of the invention as defined by the appended claims. It should be understood that the details shown are illustrated solely for the purpose of illustrating preferred embodiments of the present invention, and are presented to provide the most useful and easy to understand description of both the embodiment of the methods and the rules and conceptual features of the invention. In these drawings:

Figure - 1 is the dynamic radiator front view, which is the subject of the invention.

Figure - 2 is the partial section view of the dynamic radiator which is the subject of the invention.

Figure - 3 is the dynamic radiator different part section view, which is the subject of the invention. Figure - 4 is the dynamic radiator side view, which is the subject of the invention.

Figure - 5 is the dynamic radiator top view, which is the subject of the invention.

Figure - 6 is the dynamic radiator detailed view, which is the subject of the invention.

Figure - 7 is the dynamic radiator rotor and fan section view, which is the subject of the invention. Figure - 8 is the partial rotor view of the dynamic radiator which is the subject of the invention. Figure - 9 is the dynamic radiator rotor cover section view, which is the subject of the invention.

Figure - 10 is the rotor blasted mounting of the dynamic radiator which is the subject of the invention. Figure - 11 is the dynamic radiator rotor and fan perspective view, which is the subject of the invention.

Figure - 12 is the dynamic radiator fan and rotor cover perspective view, which is the subject of the invention.

Figure - 13 is the dynamic radiator fan and rotor cover view, which is the subject of the invention, blasted mounting view.

Figure - 14 is the partial section view of the dynamic radiator fam and rotor, which is the subject of the invention. Figure - 15 is the dynamic radiator fan and rotor, which is the subject of the invention, is a different partial section view.

Figures that will help to understand this invention are numbered as indicated in the attached picture and are given below with their names.

Description of the References:

1 . Radiator heat exchange panel

2. Temperature sensor

3. Cooling control valve

4. Radiator control valve

5. Thermostat control valve

6. Air valve

7. Water distribution connection

8. Fan air intake opening

9. Fan air discharge cover

10. Hot water return pipe

11 . Rotor and fan

12. Hot water supply pipe

13. Rotor main shaft

14. Fan propeller blades

15. Fan and rotor guard

16. Water direction in the return pipe

17. Rotor cover

18. Fleat exchange fins

19. Blown air discharge

20. Mechanical seal

21 . Rotor blades

22. Rotor wheel rotation direction

23. Rotor wheel

24. Fan propeller

25. Fan body Description of the Invention:

In this detailed description, the dynamic radiator subject to the invention is explained only for a better understanding of the subject, with examples that do not create any limitation. In the description, a dynamic radiator which uses hydro energy is described to provide a faster transmission of air through the radiator heat exchange panels (1 ) and heat exchange fins (18) which are installed in the radiator. in Figure 1 , the dynamic radiator front view which is the subject of the invention is given, in Figure 2 and Figure 3, the partial cross-section views are given, in Figure 4, the side view is given and in Figure 5, the top view is given. Accordingly, the dynamic radiator involves heat exchange fins (18) which are located between the radiator heat exchange panels (1 ), hot water return pipe (10), hot water supply pipe (12) and water distribution connections (7).

Furthermore, it also includes a temperature sensor that sends a signal to the solenoid to open or close the valve depending on the desired room temperature (2), a cooling control valve which controls the water flow when the radiator is used for cooling (3), a general-purpose radiator control valve located on the upper part of the radiator (4) and thermostat control valve which provides thermostatic control (5). The necessary air pressure for the radiator is provided through the air valve (6).

The dynamic radiator which is the subject of the invention includes a rotor and a fan (11 ) that accelerates the air circulation between the radiator heat exchange panels (1) and the heat exchange fins (18) by using hydro energy. The rotor and the fan (11) are positioned inside the fan and rotor cover (15). There is the fan air intake opening (8) in which the air required for the fan is supplied on the front surface of the blower and rotor cover (15). The air blown by the fan is released into the heat exchange fins (18) through the blown air discharge (19) in the blower air discharge cover (9).

Figure 6 shows the dynamic radiator detailed view. Accordingly, a rotor cover (17) is inside the dynamic radiator hot water return pipe (10). There is a rotor wheel (23) which includes a large number of rotor blades arranged on the rotor main shaft (13) inside the rotor cover (17). The rotor wheel (23) rotates with the effect of the hot water return pipe (10) water pressure. The direction of the water (16) in the hot water return pipe can be observed on figure 6. The direction of the rotation of the rotor wheel (22) can be observed on figure 8. The rotor wheel (23) is linked with the rotor main shaft (13) and the fan propeller (24). Thereby, as the rotor wheel (23) rotates, also the fan blades (14) on the fan propeller (24) rotate and the air taken from the fan air intake opening (8) is transferred to the radiator heat exchange panel (1 ) space and heat exchange fins (18) through the blown air discharge (19) in the fan air discharge cover (9) and the air circulation rate is increased. A cross-sectional view showing this situation is given in Figure 7. Accordingly, the water flowing through the hot water return pipe (10) rotates the rotor blades (21 ), the rotation movement of the rotor blade (21 ) is transferred to the fan propeller (24) over the rotor main shaft (13) and the blower blades (14) rotate. The fan propeller blades (14) give the air taken from the fan air intake opening (8) into the radiator through the fan air discharge cover (9) and accelerate the circulation during this rotation.

In Figure 9, a cross-sectional view of the dynamic radiator rotor section is given. Accordingly, there are mechanical seals which provide sealing between the rotor propeller (23) and the fan blades (24). The rotor wheel (23) is placed inside a rotor cover (17) (Figure 10) in the invention.

The view which shows the rotor wheel (23) and the fan propeller (24) is given in Figure 11 . Accordingly, a fan blade (24) is located on both sides of the rotor wheel (23) in the invention. As the rotor wheel (23) rotates, it also rotates the fan propeller (24). The rotor wheel (23) and the fan blades (24) are placed on the rotor main shaft (13). The rotor wheel (23) and the fan blades (24) are covered in the fan body (25) and the rotor cover(17) that are modularly configured to each other (figures 12, 13, 14, 15)

A rotor cover (17) is placed inside the hot water return pipe (10) in the invention. There is a rotor wheel (23) which includes multiple rotor blades (21 ) placed on the rotor main shaft (13) inside the rotor housing (17). The rotor blades (21 ) of the rotor wheel (23) take a torque using the water pressure in the hot water return pipe (10). This torque is transferred to the fan propeller (24) over the rotor main shaft (13). Thereby, the fan propeller blades (14) of the fan propeller (24) inside the fan body (25) rotate and the it gives the air it took from the air intake opening (8) through the blower air discharge (19) in the blower air discharge cover (9) between radiator heat exchange panel (1 ) space and heat exchange fins (18). The flow rate of the air given between heat exchange panel (1 ) space and heat exchange fins (18) from the blower air discharge (19) in the blower air discharge cover (9) is shown in Figure 2.