AT10457U1 - ANNEX FOR SUPPLYING CONSUMERS WITH HEAT ENERGY OF DIFFERENT ENERGY LEVELS - Google Patents

Description

2 AT 010 457 U1

The invention relates to a system for supplying consumers with thermal energy of different energy levels.

Renewable energy sources are becoming increasingly important. As regenerative energy sources, the use of solar energy is becoming increasingly widespread. For example, thermal energy is gained from solar energy via solar collectors. In addition, such systems can be coupled with memories, which are arranged in the form of relatively long pipes in the ground or in the walls of buildings. A significant problem in the use of solar energy in the form of heat energy is that io be achieved by means of, for example, a solar collector or a solar collector system depending on the sun's intensity and season different energy levels of a circulating in the system support medium. The achievable energy levels often do not match the energy levels desired in certain consumers. With conventional systems, therefore, it is attempted to allocate the energy levels logically to the consumers or to allocate 15 which correspond most closely to these energy levels. Higher energy levels of a carrier medium heated in a solar collector can be used, for example, for heating purposes or for hot water supply, whereas a carrier medium with a lower or lower temperature can be raised again to a higher energy level by means of heat pumps.

It is known for example from AT 405 680 B that the efficiency of solar collectors in particular is higher, the lower the temperature of the carrier medium, which is supplied to the solar collector. At the lowest possible temperature of the supplied carrier-25 medium so the largest possible temperature difference can be exploited. It is therefore necessary to deliver as much as possible of the energy transferred to a carrier medium by means of a solar collector to one or more consumers in a targeted manner. For complex installations it has to be taken into account that in buildings of any kind not only high-level energy is needed for heating, domestic water heating, cleaning, swimming pools, air conditioning of rooms and the like, but also low-level energy for cooling, air-conditioning or for cooling purposes, for example, for the storage of food is needed. For example, AT 405 680 B discloses a system for supplying consumers with thermal energy with a carrier medium heated in at least one heat source, in which a controllable distributor is fed via an input line to the carrier medium, which is provided with a plurality of outputs. This controllable distributor controls the supply line of consumers as needed and thus supplies the corresponding 40 consumers. The carrier medium with the highest energy level is thereby fed to the consumer, which currently has the highest energy requirement. Depending on the demand for energy from this consumer, after returning the carrier medium from that consumer to the input line to the distributor, the distributor drives the next consumer whose demand speaks to the remaining energy level. Such energy charging takes place as long as the carrier medium can supply energy to a consumer via an effective temperature difference. By means of the additional connection of heat pumps, when the energy level of the carrier medium has been charged, it can be lifted again to a height which is tailored to a specific consumer demand. 50

In this known system, although there is a high degree of flexibility with respect to the control of a respective consumer according to its energy requirements; However, this high flexibility must be paid for with a high piping cost and a relatively complicated control of the distributor. 55 3 AT 010 457 U1

In contrast, the object of the present invention is to provide a system for supplying consumers with thermal energy with a heated in at least one heat carrier medium, in which with respect to known systems reduced piping targeted temperature-time profiles in consumers different energy levels can be achieved.

This object is achieved by a system having the features according to claim 1. Advantageous developments are defined in the dependent claims.

According to the invention, the system for supplying a number of consumers with heat energy of different energy levels to a heat source, a main line and a return line, which are flowed through by a heated in the heat source carrier medium. From the heat source enters via an outlet line, the flow of the carrier medium in a main line, in which a plurality of flow divider in series, for each consumer a controllable flow divider, are arranged. From a respective controllable flow divider, the respective consumers are provided parallel to the main line with a flow line and a return line.

From the flow divider, such a partial flow of the carrier medium is diverted to the respective consumer in the flow line, that the consumer a desired amount of heat per unit time can be fed. But it is also possible that such a partial flow is passed into the flow line of the consumer, that at a downstream of the flow divider mixing point, in which the return line opens from the consumer, targeted a desired energy level for a subsequent consumer is adjustable.

According to the invention, the respective flow diverters are designed so that a partial flow can be diverted to a consumer, that optionally the complete stream of carrier medium in the main line is routed to a consumer or that a consumer for which a certain energy level of the carrier medium is not present or which just for the prevailing energy level of the support medium has no need, no power at all receives carrier medium, so that in such a case, this parallel switched consumer receives no stream of carrier medium, so that in the flow divider the complete flow of the carrier medium to a subsequent flow divider is directed.

Such a system can be mixed in an advantageous manner by deliberate mixing of partial streams of the carrier medium, which are not yet energy-dissipated, with energy-dissipated partial streams of the carrier medium, that for subsequent consumers targeted energy levels can be achieved just by mixing these partial streams. Thus, a high degree of flexibility and very accurate adjustment of the demand of the connected consumers is possible without a highly complex piping system would be provided.

The controllable flow divider is controllable according to an embodiment of the invention based on temperature or temperature difference signals, wherein temperature sensors are arranged in the main line before each flow divider and in the flow line before each consumer and in the return line after each consumer. However, it is also possible to provide a temperature sensor in the region of the mixing point in which the return line from the consumer opens into the main line. Furthermore, flow meters are additionally provided at the points in the system at which partial streams are branched off from the main flow of the carrier medium or brought together again at mixing points.

The controllable flow divider is preferably controlled according to an embodiment of the invention by a signal based on a temperature difference between the entry into the consumer and the exit from the consumer. By means of this signal, the partial flow of the carrier medium supplied to the consumer is controlled as a function of the temperature difference between entry and exit from the consumer or in dependence on a temperature desired at the mixing point of return line and main line.

According to a further embodiment of the invention, a pump is preferably arranged in the flow line to the respective consumer. This pump leads the diverted from the respective flow divider to the consumer from the main stream of the carrier medium in the main part of the flow to the consumer, pumps this stream through the consumer in the return line, which is connected via a bypass line to the flow line to the consumer. Thus, the pump circulates the partial flow which is conducted from the flow divider via the feed line to the consumer and the latter from the consumer into the return line and from there via the bypass line via the feed line to the consumer. The flow rate of the pump is regulated by its speed by means of a signal based on a temperature difference between entry into the consumer and exit from the consumer. The circulation of the current of the carrier medium by the consumer can thus be controlled so that the diverted from the flow divider partial flow is repeatedly circulated through the consumer, wherein at least a portion of the still energieauf-charged partial flow from the flow distributor is added to the circulation at each circulation, so that, depending on the desired temperature-time curve of the charging of the consumer, more or less of the partial flow is added to the circulating current.

At the mouth of the bypass line in the flow line, a mixture between the partial flow from the flow divider and the recirculated, in the consumer energiemäßig discharged partial flow. At the same time, the volume flow of the pump is adjusted or the pump is controlled or regulated so that a part of the energized unloaded partial flow through the return line again the main line at the mixing point, in which the return line opens into the main line is supplied.

Preferably, the flow divider control signal is identical to the pump control signal. The flow divider and the pump are preferably controlled so that either a predetermined temperature-time curve in the consumer, d. H. whose time-dependent energy charging according to predetermined curve, is achieved or that at the mixing point at which the return line from the consumer opens into the main line, a predetermined temperature, d. H. an energy level of the stream of the carrier medium in the main line is achieved, which is tailored to the needs of the subsequent consumer or consumers.

Preferably, the flow divider and the pump are controlled so that a predetermined maximum temperature is not exceeded in the consumer. This is particularly advantageous, for example, if the consumer is a hot water storage tank with a heat exchanger in which scale formation is prevented or greatly reduced by the limitation of charging up to the maximum temperature.

For this purpose, for example, serve the control of the flow divider and the pump in such a way that at the mixing point, a predetermined desired temperature can be achieved. The predetermined target temperature may for example have such a height that just for a subsequent consumer, especially at a high energy level of the carrier medium, this scale formation is avoided, for example, in a case in which a subsequent consumer is a hot water tank, whereas the consumer upstream this other Serves purpose.

According to the invention, the system generally has a plurality of consumers, in which an energy charge of the energetically charged current of the carrier medium coming from the heat source is realized in a stepwise manner by mixing certain partial flows of the carrier medium. Depending on the energy demand in the individual consumers, d. H. Depending on the degree of energy charge in the respective consumers, it is possible that after the last in the system such consumers arranged the carrier medium still has an energy level, which is still useful. For this purpose, an additional flow divider is provided according to a development prior to the entry of the carrier medium in the return line to the heat source, by means of which the carrier medium is passed through an additional high-capacity pump through a consumer forming a brine. Ie. the according to the corresponding consumers in the carrier medium still existing energy level is to charge a memory preferably Erdspeichers in solid or liquid form such. B. a brine used. The return line from the reservoir then opens in the part of the return line immediately behind the additional flow divider. Due to the high capacity of the pump can be achieved that a complete energy charge of the carrier medium takes place in the memory and within the memory also a very uniform distribution of the introduced via the carrier medium into the memory energy. Preferably, therefore, the carrier medium is completely circulated through the memory, wherein the power of the additional pump is greater than that of the pump for the consumer. This additional pump is in turn controlled by signals from corresponding temperature sensors in the region of the additional flow divider and before entry into the brine and after exiting the brine and possibly also at the point at which the return line from the memory into the return line. Due to the preferably significantly greater power of this additional pump compared to the pumps of the consumer and even with respect to the main pump, a bypass line is not required, because the hydraulic compensation of the amounts of water and the pushers takes place in the additional flow divider. For circulating the carrier medium through the system according to the invention, a main pump is preferably provided in the return line to the heat source, by means of which the carrier medium from the heat source via the main line and the return line is circulated back to the heat source. Preferably, this main pump is also controllable, depending on the respective volume flows or temperature differences, which are required in the corresponding consumers to achieve a predetermined temperature-time course.

In particular, for maintenance and repair purposes shut-off valves are provided in the respective flow lines to the consumers and the respective return lines of the consumers, these shut-off valves are preferably manually operable.

Preferably, the heat source is a solar collector or a solar collector system. Preferably, the solar panels are designed so that they can be carried along with the sun depending on the season, in order to achieve the highest possible energy yield, d. H. to achieve the highest possible energy charge of the carrier medium. In addition, preferably a Erdspeicher be provided, the Erdspeicher is particularly advantageous, if in addition a heat pump with evaporator, compressor, desuperheater and condenser is provided. The evaporator of the heat pump may additionally be connected to a consumer for cooling energy, so that a further high flexibility of the system for different energy levels can be realized.

According to another embodiment of the invention, a bypass control valve is arranged in the bypass line from the return line from the consumer to the flow line to the consumer, which in cooperation with the pump and the flow divider an additional influence on the mixture of fresh, from the main line originating energy-charged current to carrier medium and the energy in the consumer discharged energy stream of carrier medium. At the mouth of the bypass in the flow line, a mixing chamber is preferably provided. This mixing chamber serves to ensure that the current of the carrier medium energy-laden by the consumer is completely mixed with the energy-laden partial flow which has been diverted from the main line from the flow separator into the supply line to the consumer. Preferably, the mixing chamber is formed horizontally or vertically.

Further advantages, features and applications of the invention will now be explained in detail with reference to the accompanying drawings. In the drawing show:

Figure 1 is a schematic diagram of a system according to the invention with three each parallel to the main line connected consumers;

Figure 2 shows a system in the basic circuit of Figure 1, but with the possibility of connecting four consumers, the flow divider each having different positions, and in addition a flow divider for a circuit with a pump for charging energy of a Erdspeichers, in particular in the form of a brine; and

Figure 3 shows a detail X of Figure 1 with flow divider in the main line for a first consumer and mixing chamber in the flow line to this consumer with connection of the bypass line from the return line from the consumer in the flow line.

In Figure 1, the basic arrangement of a system according to the invention is shown. From a heat source, not shown, in the form of, for example, a solar collector, the energy medium charged therein is transferred to a main line 5. In this main line 5, three flow splitters 8, 9, 10 are arranged in series one behind the other, to each of which a respective consumer 1 via a supply line 6, 2, 3 is connected. In the flow divider 8, 9, 10 are so-called switching-mixing valves, which are similar in their basic structure that of a rotary valve. The rotatably mounted in the flow divider rotary valve element is arranged in the flow divider 8 so that the entering of the main line 5 in the flow divider 8 stream is divided into carrier medium, in a first partial stream, which in the flow line 6 to the first consumer. 1 is guided, and a second partial flow, which exits from the flow divider 8 in a further region of the main line 5.

In the flow line 6, which leads from the flow divider 8 to the first consumer 1, a pump 15 is further arranged. In the flow direction in front of the pump opens a bypass line 18, which leads a return line 7 from the consumer 1 to the region of the main line 5 between the flow divider 8 and 9. Depending on the set or controlled or regulated volume flow of the pump 15 of the flow divider 8 flowing into the flow line 6 partial flow of carrier medium through the consumer 1 and back via the return line 7 and the bypass line 18 again in the partial flow of the carrier medium before Pump 15 fed. The return line 7 from the consumer 1 opens at a mixing point 11 in the region of the main line 5 between the first flow divider 8 and the second flow divider 9.

Before the flow divider 8, before entering the consumer 1 and after exiting the consumer 1 and at the mixing point 11 at least one temperature sensor is mounted in each case. For temperature and / or maintenance purposes, a shut-off valve V is arranged both in the flow line 6 and in the return line 7. The preferably manually operable shut-off valves V lock in the closed state, a supply of carrier medium from the main line 5 in the consumer 1 from.

In the area between the flow divider 8 for the consumer 1 and the flow divider 9 for the consumer 2 is a mixing point 11, at which the return line 7 from the consumer 1 in the piece of main line 5 between the flow divider 8 and the flow divider 9 opens. At this area of the mixing point 11, a mixture of the consumer 1 recirculated stream of carrier medium in an energy-unloaded state with the non-energy-dissipated stream of carrier medium in the main line 5, which leaves the flow divider 8 as a partial flow. The flow divider 8 can now be controlled so that the guided into the flow line 6 to the consumer 1 partial flow of carrier medium has a size such that in the consumer 1, a desired temperature-time behavior is achieved with high accuracy. The partial flow can also be varied during the energy loading in the consumer 1 via the change in the position of the flow divider 8, in particular if in the consumer 1, for example, in addition to a removal of hot water. Furthermore, the partial flow, which is diverted from the flow divider 8 in the flow line 6 to the consumer 1, be chosen so that in addition to a certain temperature-time behavior in the consumer 1, a desired temperature of the carrier medium at the mixing point 11 is reached. Furthermore, the partial flow can be adjusted or regulated in the flow line 6 so that a certain maximum temperature in the consumer 1 is not exceeded. This is particularly useful if the upper limit of the temperature is a value at which, for example, scale formation is just substantially avoided. With this possibility of mixing and / or recirculating a stream / partial flow of carrier medium can be met with high accuracy the needs of one, several or all consumers very well, and indeed and especially for energy levels for the respective consumers, which is not those of inflowing , energy-charged available partial currents correspond to carrier medium.

The flow divider 9 is provided in the main line 5 to supply a consumer 2 with a corresponding partial flow as needed or depending on the desired temperature-time behavior. The consumer 2 is provided analogously to the consumer 1 parallel to the main line 5 with a flow line 6 from the flow divider 9 to the consumer 2 and a return line 7 from the consumer 2 to the part of the main line 5, which between the flow divider 9 and the following Flow divider 10 is located, the return line 7 from the consumer 2 opens into a mixing point 12. Analogous to the function for the consumer 1, a pump 16 and a bypass line 19 of the return line 7 to the flow line 6 in the flow direction in front of the pump 16 is provided in the flow line. Temperature sensors are in turn arranged at the inlet into the flow divider 9 and at the inlet to the consumer 2 and at the outlet from the consumer 2. For maintenance and repair purposes, in turn, in each case a shut-off valve V in the flow line 6 and in the return line 7 is arranged. At the mixing point 12 is also a temperature sensor.

According to the illustrated example, the flow divider 9 is regulated or adjusted so that no partial flow is passed into the flow line to the consumer 2 of the flow divider 9, but this flow line is completely shut off in the flow divider 9. As a result, the entire stream of carrier medium entering the main line between the mixing point 11 and the inlet into the flow divider 9 passes through the flow splitter 9. This stream of carrier medium is fed to the mixing point 12, at which no mixing with a partial flow from the return line takes place because of the blocked feed line he follows.

In the flow direction after the mixing point 12, a further flow divider 10 is provided, which can conduct a partial flow to a consumer 3. The basic structure or the basic arrangement corresponds to the or for the consumer 1 or the consumer 2. A feed line 6 with a pump 17 is connected to the entrance to the consumer 3, whereas a return line from the outlet from the consumer into a Mixture point 13 in a piece of the main line 5 opens, which is arranged after the flow divider 10. Similarly, a bypass line 20 is arranged as a connection between the return line 7 and the flow line 6 so that the bypass line enters the flow line in the flow direction in front of the pump 17 in the flow line 6. Temperature sensors are arranged at the inlet into the flow divider 10, at the inlet to the consumer 3 and at the outlet from the consumer 3 and at the mixing point 13. Likewise, 8 are AT010 457U1

Shut-off valves V arranged in the flow line 6 and the return line 7. According to the illustrated position of the flow divider 10, for example, the entire power-loaded in the consumer 1 current to carrier medium of the main line in the flow line 6 and thus the consumer 3 is passed. This is achieved in that the passage through the flow divider 10 is blocked by the present in the flow divider 10 rotary valve. From the mixing point 13 reaches the consumer 3 further energy-dissipated carrier medium via the return line 14 by means of the pump 25 back into the inlet of the heat source, not shown.

The respective positions of the rotary valve in the flow divider 8, 9, 10 are shown only as an example; it is possible such positions of the rotary valve in the flow divider that any flexibility in terms of the mixture of partial streams back from consumers and streams of carrier medium in the main line and mixture of recirculated energy-discharged partial streams from a consumer with new, not yet energy-dissipated in each consumer streams to a consumer are feasible. However, it is also possible in principle to divert any part of streams to a consumer, namely when this has no need, for example, or to send the complete stream to a consumer, if this should meet this need or its temperature-time behavior just ,

FIG. 2 shows a further exemplary embodiment, in which first four flow dividers 8, 9, 10,... Are provided in the main line 5, which are each arranged for a connected consumer. For simplicity, the individual consumers are not shown, in the detail X, which is shown in an enlarged scale in Figure 3, only the flow line 6 with the pump 15 and the return line 7 with the bypass line 18 from the return line 7 to Supply line 6 in the flow direction in front of the pump 15 and the mixing point 11 characterizing the mouth of the return line 7 in the main line 5 shown.

By way of example, four different positions of the rotary valve in the respective flow divider 8, 9, 10, ... are shown. Thus, in the flow divider 8, the rotary valve is arranged or regulated or so controlled that the current to carrier medium from the main line 5 in proportion to 50 percent to 50 percent in a partial flow for the consumer 1 (not shown) and a partial flow the flow divider 8 is divided in the direction of the mixing point 11.

The rotary valve in the flow divider 9 is designed such that zero percent of the stream entering the flow divider 9 is diverted to the second consumer support medium (not shown) so that 100 percent of the stream of carrier medium coming from the mixing point 11 is from the flow divider 9 flow to the flow divider 10. In this case, the 100 percent of the stream of carrier medium due to, for example, a removal of hot water in the consumer 1 may be less than that of the heat source via the main line 5 entering the flow divider 8 stream of carrier medium.

The flow divider 10 is exemplified with its rotary valve so that 100 percent of the entering into the flow divider 10 stream of carrier medium to the flow divider 10 associated consumers are supplied. From this consumer, the energized in the consumer stream of carrier medium via the discharge point of the return line from this consumer in the section of the main line 5 between the flow divider 10 and this subsequent fourth flow divider (not labeled) initiated. This mouth point corresponds in the case of passage of a partial flow through the flow divider 10 of the mixing point thirteenth

In the fourth unspecified flow divider, the rotary valve is shown as supplying 10 percent of the incoming carrier power flow to a fourth consumer, whereas 90 percent of the flow entering the flow divider passes therethrough, 90 percent are mixed with the energized in the fourth flow divider associated consumer power to carrier medium in the also not shown mixing point.

From the mixing point enters the energetically in three consumers (the flow divider 9 associated consumer does not contribute to the energy charge due to its barrier) loaded carrier to another additional flow divider 21, the rotary valve is shown so that the flow of carrier medium via a pump 22 high Capacity, for example, a brine (not shown) is supplied, in which the final energy charge of the carrier medium or this stream of the carrier medium is carried out by mixing. From the brine there is a return flow of energetically discharged from, for example, 30 ° C to 15 ° C stream of carrier medium via the return line 24 for mixing with the stream which the flow divider 21 from the previous consumers 1,2,3, ... flows. From the mixing point of the return line in the return line 14, the energetically discharged carrier medium flow is fed back to the heat source by means of the pump 25.

It can be seen from FIG. 2 that a high degree of flexibility is made possible for a variety of consumers and consumer functions and consumer needs corresponding to any application requirements, wherein energy levels defined for defined consumers by means of the principle of partial flow mixing can be precisely and precisely set for subsequent consumers.

In Figure 3, the detail X shown in Figure 2 is shown enlarged. From the main line 5, a carrier medium flow at a temperature of, for example, 80 ° C. enters the flow divider 8, which is also referred to as a mixed-switching valve, for example. The rotary valve in the flow divider 8 is adjusted in accordance with FIG. 2 such that the flow of carrier medium entering from the main line 5 is split 50% into the feed line 6 and 50% through the flow divider 8 into the main line after the flow divider 8. The feed line 6 leads to the consumer, not shown, of which the return line 7 opens at the mixing point 11 in the section of the main line 5 after the flow divider 8. The return line 7 is connected via the bypass line 18 to the supply line 6, wherein at the discharge point of the bypass line 18 into the supply line 6, a mixing chamber 27 is provided. The mixing chamber is preferably arranged horizontally or vertically. The mixing chamber 27 serves that the recirculated via the bypass line 18 from the return line 17 in the flow line 6, not shown in the load energetically discharged stream of carrier medium with the 50 percent partial flow of the flow divider 8, which has not been energetically unloaded , can be mixed completely. On the one hand via the volume flow control of the pump 15 also not shown in Figure 3 and the other in a bypass line 18 additionally provided bypass regulator 28, the recirculation is adjusted so that, for example, behind the mixing chamber before entering the consumer a defined temperature of 50 ° C can be achieved.

Thus, it is possible with the invention provided on the basis of the mixture of partial flows plant system to achieve defined by mixing energetically charged partial streams of the support medium with energetically discharged partial streams to support medium temperatures. Any type of consumer demand can thus be achieved in a cost effective manner with a relatively low cost of piping and fittings.

It is understood that additional temperature sensors or flow sensors are attached to control certain temperatures for consumers or at certain points of the system, in addition to the previously mentioned in connection with the description of Figure 1 and Figure 2 sensors. According to FIG. 3, only temperature sensors are arranged after the mixing chamber 27 and after the mixing point 11. Preferably

Claims (18)

10 AT 010 457 U1 the bypass controller via the same signal, which is used for the control of the flow divider 8 and the pump 15. To illustrate the flexibility of the system, the control of a desired heating process of a boiler without hot water withdrawal as well as an example with hot water withdrawal and a further example of an equally possible consumer are shown below by way of example. Claims: 1. Plant for supplying consumers (1, 2, 3, ...), in particular heat accumulators, with heat energy of different energy levels, which is flowed through by a heated in a heat source carrier medium, via a discharge line from the heat source, a main line (5) flows through, in which for each parallel to the main line (5) with respective flow line (6) and return line (7) arranged consumers (1, 2, 3, ...) in series in each case a controllable flow divider (8, 9 , 10, ...) and from which via the flow divider (8, 9, 10, ...) in at least one consumer such a partial flow of the carrier medium in the flow line (6) of the consumer (1) is branched off, that a desired amount of heat per unit time can be supplied to a preceding consumer in the order (1) or that fed to one of the return line (7) of this consumer (1) and behind the flow division he (8, 9, 10, ...) lying mixing point (11, 12, 13, ...) in the main line (5) targeted a desired energy level for a subsequent consumer (2, 3, ...) is adjustable , And the carrier medium after the energy charge via a return line (14) enters the heat source again. 2. Plant according to claim 1, wherein at least in the main line (5) before each flow divider (8, 9, 10, ...) and in the flow line (6) before each consumer and in the return line (7) of each consumer a temperature sensor (T) are arranged. 3. Plant according to claim 1 or 2, wherein the controllable flow divider (8, 9, 10, ...) a signal based on a temperature difference between entry and exit from the consumer (1, 2, 3, ... ) is supplied, by means of which the consumer (1, 2, 3, ...) supplied partial flow of the carrier medium in dependence on the temperature difference is controllable. 4. Plant according to claim 1 or 2, wherein in the flow line (6) to the respective consumer (1, 2, 3, ...) a pump (15, 16, 17, ...) is arranged, which the of the respective flow divider (8, 9, 10, ...) to the consumer (1, 2, 3, ...) branched off from the main stream of the carrier medium in the main line (5) partial stream the consumer (1, 2, 3, .. .) and via a supply line (6) to this consumer (1, 2, 3, ...) with its return line (7) short-circuiting bypass line (18, 19, 20, ...) by the consumer ( 1, 2, 3, ...), wherein the pump (15, 16, 17, ...) by means of a signal based on a temperature difference between the inlet and outlet from the consumer (1, 2, 3,. ..) is controllable and wherein at the mouth of the bypass line (18, 19, 20, ...) in the flow line (6) a mixture between the partial flow from the flow divider (8, 9,10, ...) and a recirculated (circulated) partial flow takes place. 5. Plant according to claim 3 or 4, wherein the signal for controlling the flow divider (8, 9, 10, ...) and the signal for controlling the pump (15, 16,17, ...) are identical. 6. Plant according to claim 5, wherein the flow divider (8, 9, 10, ...) and the pump (15, 16, 17, ...) are controlled so that in the consumer (1, 2, 3 , ...) a given maximum temperature is not exceeded. ^ AT010 457U1 7. Plant according to claim 5, wherein the flow divider (8, 9, 10, ...) and the pump (15, 16, 17, ...) are controlled so that at the mixing point (11, 12, 13 , ...) a predetermined target temperature can be achieved. 8. Installation according to one of claims 4 to 7, wherein in the bypass line (18, 19, 20, ...), a bypass regulator is provided. 9. Plant according to claim 8, wherein the bypass regulator (26, ...) in particular in dependence on the temperature / temperature difference in the carrier medium is controllable. 10. Installation according to one of claims 4 to 9, wherein the bypass line (18, 19, 20, ...) in a in the flow line (6) arranged mixing chamber (27) opens. 11. Plant according to one of claims 3 to 10, wherein prior to entry of the carrier medium in the return line (14) to the heat source, an additional flow divider (21) is arranged, by means of which the carrier medium via an additional pump (22) by a memory, in particular a brine (23) forming consumer passes whose return line (24) in the part of the return line (14) immediately behind the additional flow divider (21) opens. 12. Plant according to claim 11, wherein the additional pump (22) is designed so that the carrier medium is completely circulated through the brine (23), wherein the power of the additional pump (22) is greater than the power of the pump (15 , 16, 17, ...) for the respective consumers (1,2, 3, ...). An apparatus according to any one of claims 1 to 12, wherein in the return line (14) to the heat source, a main pump (25) for circulating the carrier medium from the heat source via the main line (5) and the return line (14) back to the heat source is. 14. Plant according to one of claims 1 to 13, wherein the respective flow line (6) to the consumers (1, 2, 3, ...) and the respective return line (7) from the consumers (1, 2, 3, ...) are each provided with a shut-off valve (V). 15. Plant according to one of claims 1 to 14, wherein the heat source is a solar collector. 16. Installation according to one of claims 1 to 15, wherein in addition a Erdspeicher is provided. 17. Plant according to one of claims 1 to 16, wherein in addition a heat pump with evaporator, compressor, desuperheater and condenser is provided. 18. Plant according to claim 17, wherein a consumer is connected to the evaporator for cooling energy. For this purpose 3 sheets of drawings