DE20009289U1 - Heat transfer system - Google Patents

Description

Eugene Gerster

Untere Ortsstr. 13

88524 Uttenweiler

HEAT TRANSPORT SYSTEM

The invention relates to a heat transport system with at least one heat generating device for heating a liquid medium, a pipe system for transporting the liquid medium, a pump for conveying the liquid medium contained in the pipe system and at least one heat dissipation device for dissipating the heat stored in the liquid medium, wherein at least one heat generating device, the pump and the at least one heat dissipation device in conjunction with the pipe system form a main flow circuit.

Heat transport systems of the type mentioned above have been known in the state of the art for some time. Since, particularly in designs in which a plurality of parallel-connected heat emitting devices can be activated, the heat removal from the system can be so high at times that a single heat generating device

not enough heat to adequately heat all heat-emitting devices, it is known in the prior art to arrange a plurality of heat generating devices, but usually only two heat generating devices, either in cascade one behind the other or in parallel to one another, wherein the second heat generating device can be activated in addition to the first heat generating device at times of heat extraction peaks.

In the case of a series arrangement of two heat generating devices, however, this is associated with the disadvantage that in a non-activated state of the second heat generating device, the liquid medium heated by the first heat generating device flows through it, whereby a considerable amount of heat energy is extracted from the liquid medium. Connecting two heat generating devices in parallel is associated with the disadvantage that in the event of activation of the second heat generating device, the first heat generating device is flowed through by a smaller amount of liquid medium and therefore adaptation to this new operating state is required in such a way that a power adjustment is made to this lower flow rate of liquid medium by reducing the heat production. Although such a power adjustment is carried out automatically in modern heat generating devices with the aid of sensors and suitable control systems, such a power adjustment causes at least a temporary reduction in the efficiency of such a heat generating device. In the two examples above

the respective heat generation devices are provided in a main flow circuit of the corresponding heat transport system.

Heat transport systems are also known in the prior art in which a plurality of heat generating devices are arranged in respective secondary flow circuits of the main flow circuit, with the plurality of heat dissipation devices being provided in the main flow circuit. Such an arrangement of heat generating devices has the advantage that no heat losses occur at the heat generating devices that are deactivated in each case, since liquid medium does not flow through them. Furthermore, such heat transport systems have the advantage that in the event of activation of a further heat generating device, the flow rate of liquid medium through the heat generating devices that have already been activated remains constant and in particular does not decrease, as a result of which no adaptive measures are necessary to adjust the performance of the heat generating devices that have already been activated. However, these known heat transport systems have the serious disadvantage that, due to incomplete coupling of the liquid medium of a secondary flow circuit into the main flow circuit, the temperature in the main flow circuit is lower than the temperature in a respective activated secondary flow circuit. This means that the heat generation devices in the respective bypass circuits must be designed for higher temperatures and can generate a higher temperature

than can be made available to the heat dissipation devices in the main flow circuit. This also results in poor efficiency in the operation of these known heat transport systems.

The object of the invention is to provide a heat transport system in which the efficiency is improved compared to the known heat transport systems.

For a heat transport system of the type mentioned at the outset, this object is achieved in that a second pipe system forming a secondary flow circuit to the main flow circuit with a second heat generating device and a second pump can be connected to the main flow circuit via a distributor valve in such a way that a section of the secondary flow circuit is integrated into the main flow circuit.

Preferred embodiments of the invention are the subject of the subclaims.

In the heat transport system according to the invention, the feature that a second pipe system forming a secondary flow circuit to the main flow circuit with a second heat generating device and a second pump can be connected to the main flow circuit via a distributor valve in such a way that a section of the secondary flow circuit is integrated into the main flow circuit ensures that the second heat generating device arranged in the secondary flow circuit is not flowed through by liquid medium in the deactivated state and thus does not absorb any heat from the liquid medium and

contributes to heat losses from the heat transport system and, on the other hand, in the activated state, i.e. in periods in which peak values are recorded in the heat emission from the heat emission devices, enable very precise temperature control of the liquid medium in the main flow circuit by changing both the delivery rate of the second pump arranged in the secondary flow circuit and the heat emission, i.e. the degree of heat generation in the second heat generation device arranged in the secondary flow circuit.

According to a preferred embodiment of the heat transport system according to the invention, the distributor valve is designed as a three-way valve. This allows a section of the secondary flow circuit to be integrated into the main flow circuit in a very simple and effective manner. Alternatively, the distributor valve can contain two through valves.

According to a further preferred embodiment of the transport system according to the invention, it is provided that the integration of the section of the secondary flow circuit into the main flow circuit is provided downstream of the first heat generating device of the main flow circuit. This ensures that the heat generating device of the main flow circuit is flowed through by liquid medium that has already passed through the heat dissipation devices and thus has the lowest temperature in the pipe system of the heat transport system, so that the liquid medium when passing through the first

Heat generating device of the main flow circuit experiences maximum heat absorption, whereby the efficiency of the heat generating device of the main flow circuit is maximized.

According to a further preferred embodiment of the heat transport system according to the invention, the first heat generating device arranged in the main flow circuit is designed as a condensing boiler. According to the invention, this is a heat generating device in which the exhaust gases generated during a combustion process in this heat generating device are additionally used to heat the liquid medium of the main flow circuit.

According to a further preferred embodiment of the heat transport system according to the invention, it is provided that the heat dissipation device arranged in the main flow circuit is designed as a combined heat and power plant.

According to a further preferred embodiment of the heat transport system according to the invention, it is provided that the heat generating device provided in the secondary flow circuit can be selectively introduced into the main flow circuit via at least one changeover valve.

According to a further preferred embodiment of the heat transport system according to the invention, pumping devices are provided which ensure that the volume flow of the secondary flow circuit is 10% higher than the volume flow of the main flow circuit.

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According to an alternative preferred embodiment of the heat transport system according to the invention, pumping devices are provided which cause the volume flow of the secondary flow circuit to be 50% higher than the volume flow of the main flow circuit.

According to a further alternative preferred embodiment of the heat transport system according to the invention, it is provided that pumping devices are provided which cause the volume flow of the secondary flow circuit to be 100% higher than the volume flow of the main flow circuit.

According to a further alternative preferred embodiment of the heat transport system according to the invention, it is provided that pumping devices are provided which cause the volume flow of the secondary flow circuit to be 150% higher than the volume flow of the main flow circuit.

The heat transport system according to the invention is explained below using a preferred embodiment, which is shown in the figure of the drawing. Therein shows:

Fig.l shows a preferred embodiment of the heat transport system according to the invention in a schematic view.

The preferred embodiment of the heat transport system 10 according to the invention shown in Figure 1 comprises a heat generating device 11 for heating a liquid medium 13 circulating in a pipe system 12, wherein a pump 14 for conveying the liquid medium 13 in the pipe system 12

The heat transport system 10 according to the invention contains two heat dissipation devices 15, 15' for dissipating the heat stored in the liquid medium 13, wherein the heat generating device 11, the pump 14 and the two heat dissipation devices 15, 15' in conjunction with the pipe system form a first main flow circuit.

A second pipe system 16, which forms a secondary flow circuit to the main flow circuit and contains a second heat generating device 17 and a second pump 18, can be connected to the main flow circuit via a distributor valve 19 such that a section 20 of the secondary flow circuit is integrated into the main flow circuit. The section 20 of the secondary flow circuit integrated into the main flow circuit is provided downstream of the first heat generating device of the main flow circuit. In the embodiment shown, arrows indicate the flow direction of the liquid medium 13 in the pipe systems 12 and 16.

In the illustrated heat transport system 10 according to the invention, the distribution valve 19 is designed as a three-way valve.

The first, arranged in the main flow circuit

Heat generating device 11 is in the illustrated

The heat transport system 10 according to the invention is designed as a condensing boiler.

The embodiment of the invention explained above serves only for the purpose of a better understanding of the

the inventive teaching given in the claims, which as such is not limited by the embodiment.

Claims (11)

1. Heat transport system with at least one heat generation device for heating a liquid medium, a pipe system for transporting the liquid medium, a pump for conveying the liquid medium contained in the pipe system and at least one heat emission device for emitting the heat stored in the liquid medium, wherein at least one heat generation device, the pump and the at least one heat emission device in conjunction with the pipe system form a main flow circuit, characterized in that a second pipe system forming a secondary flow circuit to the main flow circuit with a second heat generation device and a second pump can be connected to the main flow circuit via a distributor valve in such a way that a section of the secondary flow circuit is integrated into the main flow circuit. 2. Heat transport system according to claim 1, characterized in that the distribution valve is designed as a three-way valve. 3. Heat transport system according to claim 1, characterized in that the distribution valve contains two through valves. 4. Heat transport system according to one of the preceding claims, characterized in that the section of the secondary flow circuit integrated into the main flow circuit is provided downstream of the first heat generating device of the main flow circuit. 5. Heat transport system according to one of claims 1 to 4, characterized in that the heat dissipation device arranged in the main flow circuit is designed as a condensing boiler. 6. Heat transport system according to one of claims 1 to 4, characterized in that the heat dissipation device arranged in the main flow circuit is designed as a combined heat and power plant. 7. Heat transport system according to one of the preceding claims, characterized in that the heat generating device provided in the secondary flow circuit can be selectively introduced into the main flow circuit via at least one changeover valve. 7. Heat transport system according to one of claims 1 to 6, characterized in that pumping devices are provided which cause the volume flow of the secondary circuit to be 10% higher than the volume flow of the main circuit. 8. Heat transport system according to one of claims 1 to 6, characterized in that pumping devices are provided which cause the volume flow of the secondary circuit to be 50% higher than the volume flow of the main circuit. 9. Heat transport system according to one of claims 1 to 6, characterized in that pumping devices are provided which cause the volume flow of the secondary circuit to be 100% higher than the volume flow of the main circuit. 10. Heat transport system according to one of claims 1 to 6, characterized in that pumping devices are provided which cause the volume flow of the secondary circuit to be 150% higher than the volume flow of the main circuit.