DE102021133807A1 - Building technology system, in particular home station - Google Patents

Abstract

A building technology system, in particular a home station (100) with a primary connection (PA), is provided. The primary connection (PA) has a flow connection (VL) and a return connection (RL). A branch (12) in front of a first valve (121) is provided on the flow connection (VL). A heating flow (HVL) is coupled to the first valve (121). A heat exchanger (130) is also provided, which is coupled to the flow connection (VL) via the branch (12). A flow heater (140) is used to reheat water from the flow connection (VL). Furthermore, a mixing point (MP) is provided, which is coupled to the outlet of the flow heater (140). Furthermore, a hot water line (WW, 16) is provided as the output connection of the home station (100). The hot water line (WW, 16) connects to the mixing point (MP). Furthermore, a temperature sensor (113) is provided in or on the hot water line (16) behind the mixing point (MP) for detecting a temperature of the water behind the mixing point (MP).

Description

The present invention relates to a building technology system, in particular a home station.

DE 10 2016 010 386 A1 shows a hot water supply system for the central supply of a consumer network. For this purpose, a transition connection (home station) is provided for connecting the hot water supply system to a water network, in particular to a home station. By means of the home station, preheated water is fed into an apartment, for example, where the preheated water can be used as hot water. A flow heater can be provided for reheating. A bypass can be provided parallel to the flow heater.

It is an object of the present invention to provide a building services system that enables hot water to be provided more efficiently based on a central hot water supply system.

This object is achieved by a home automation system according to claim 1.

A building technology system, in particular a home station, is thus provided. The home station has a hot water flow, a hot water return and a flow heater for reheating the hot water flowing through the flow.

A building technology system, in particular a home station with a primary connection, is thus provided. The primary port has a flow port and a return port. A branch is provided on the flow connection in front of a first valve. A heating flow is coupled to the first valve. Furthermore, a heat exchanger is provided, which is coupled to the flow connection via the branch. A flow heater is used to reheat water from the flow connection. Optionally, a mixing point is provided, which is coupled to the outlet of the instantaneous water heater. A hot water pipe is also provided as the outlet connection for the home station. The hot water pipe can connect to the mixing point. Furthermore, a temperature sensor is provided in or on the hot water pipe (optionally behind the mixing point) for detecting a temperature of the water in the hot water pipe. Optionally, the recorded temperature can be used to control the instantaneous water heater.

According to one aspect, the water flows completely through the instantaneous water heater when no bypass is provided. According to one aspect of the present invention, the home automation system has a bypass with a valve in parallel with the instantaneous water heater. The mixing point is linked to the bypass and the flow heater.

In an advantageous building services system, the water can flow through the continuous-flow heater and/or the bypass, in particular controlled by the bypass valve or a motorized valve of the continuous-flow heater. According to one aspect of the present invention, there is provided a valve assembly having at least a first input port coupled to the hot water line. The valve unit also has at least one outlet connection, which is coupled via a single line to a tap for providing hot and/or cold water.

According to one aspect of the present invention, the valve unit has a further inlet connection for cold water. The hot water from the hot water line and the cold water are mixed in the valve unit to provide water at a set temperature at one of the outlet ports of the valve unit.

According to one aspect of the present invention, a valve is provided between the mix point and a cold water supply for providing cold water at the mix point to provide water at a desired temperature in the hot water line at the mix point.

According to a further aspect of the present invention, the valve unit has at least one engine valve at one of the output ports for opening or closing the output ports.

According to one aspect of the present invention, a motor valve is provided in the hot water line and a motor valve is provided in the water heater.

According to another aspect of the present invention, an engine valve is provided in the water heater. The valve in the bypass is designed as an engine valve.

Further configurations of the invention are the subject matter of the dependent claims.

• 1 zeigt eine schematische Darstellung einer Wohnungsstation gemäß dem Stand der Technik,
• 2 zeigt eine schematische Darstellung einer Wohnungsstation gemäß einem ersten Ausführungsbeispiel,
• 3 zeigt eine schematische Darstellung einer Wohnungsstation gemäß einem zweiten Ausführungsbeispiel,
• 4 zeigt eine schematische Darstellung einer Wohnungsstation gemäß einem dritten Ausführungsbeispiel,
• 5 zeigt eine schematische Darstellung einer Wohnungsstation gemäß einem vierten Ausführungsbeispiel,
• 6 zeigt eine schematische Darstellung einer Wohnungsstation gemäß einem fünften Ausführungsbeispiel,
• 7 zeigt eine schematische Darstellung einer Wohnungsstation gemäß einem sechsten Ausführungsbeispiel,
• 8 zeigt eine schematische Darstellung einer Wohnungsstation gemäß einem siebten Ausführungsbeispiel,
• 9 zeigt eine schematische Darstellung einer Wohnungsstation gemäß einem achten Ausführungsbeispiel,
• 10 zeigt eine schematische Darstellung einer Wohnungsstation gemäß einem neunten Ausführungsbeispiel,
• 11 zeigt eine schematische Darstellung einer Wohnungsstation gemäß einem zehnten Ausführungsbeispiel,
• 12 zeigt eine schematische Darstellung einer Wohnungsstation gemäß einem elften Ausführungsbeispiel,
• 13 zeigt eine schematische Darstellung einer Wohnungsstation gemäß einem zwölften Ausführungsbeispiel,
• 14 zeigt eine schematische Darstellung einer Wohnungsstation gemäß einem dreizehnten Ausführungsbeispiel,
• 15 zeigt eine schematische Darstellung einer Wohnungsstation gemäß einem vierzehnten Ausführungsbeispiel,
• 16 zeigt eine schematische Darstellung einer Wohnungsstation gemäß einem fünfzehnten Ausführungsbeispiel,
• 17 zeigt eine schematische Darstellung einer Wohnungsstation gemäß einem sechzehnten Ausführungsbeispiel, und
• 18 zeigt eine schematische Darstellung einer Wohnungsstation gemäß einem siebzehnten Ausführungsbeispiel.

Advantages and exemplary embodiments of the invention are explained in more detail below with reference to the drawing.

• 1 shows a schematic representation of a home station according to the prior art,
• 2 shows a schematic representation of a home station according to a first embodiment,
• 3 shows a schematic representation of a home station according to a second embodiment,
• 4 shows a schematic representation of a home station according to a third embodiment,
• 5 shows a schematic representation of a home station according to a fourth embodiment,
• 6 shows a schematic representation of a home station according to a fifth embodiment,
• 7 shows a schematic representation of a home station according to a sixth embodiment,
• 8th shows a schematic representation of a home station according to a seventh embodiment,
• 9 shows a schematic representation of a home station according to an eighth embodiment,
• 10 shows a schematic representation of a home station according to a ninth embodiment,
• 11 shows a schematic representation of a home station according to a tenth embodiment,
• 12 shows a schematic representation of a home station according to an eleventh embodiment,
• 13 shows a schematic representation of a home station according to a twelfth embodiment,
• 14 shows a schematic representation of a home station according to a thirteenth embodiment,
• 15 shows a schematic representation of a home station according to a fourteenth embodiment,
• 16 shows a schematic representation of a home station according to a fifteenth embodiment,
• 17 shows a schematic representation of a home station according to a sixteenth embodiment, and
• 18 shows a schematic representation of a home station according to a seventeenth embodiment.

The building services system according to the invention is designed as an apartment transfer station and is coupled to a central water heating system.

1 shows a schematic representation of a home station according to the prior art. The home station 100 has a primary connection PA with a flow connection VL and a return connection RL, via which the home station is connected to a central hot water supply system 150, e.g. B. is coupled in the form of a heat pump. The flow connection VL is coupled to a first valve 121, which is designed as a three-way valve. The three-way valve 121 is coupled to the flow line VL, to the heating flow line HVL via a line 11 and to a heat exchanger 130 via a line 12 . With a corresponding setting of the three-way valve 121, the heat exchanger 130 thus receives the preheated water from the flow line VL. The heat exchanger 130 also receives a cold water supply via the line 14. The cold water flows out via a line 15 together with the heating return via the line 10 from the return RL. In the heat exchanger 130, the heat present in the cold water return is transferred to the hot water from the flow, where the hot water from the flow is thus further heated. The hot water then flows to a combination of a flow heater 140 and a bypass in which a valve 123 is provided. At a mixing point MP, the water from the bypass 20 flows together with the water from the continuous-flow heater 140 and then through the line 16. The continuous-flow heater 140 serves to reheat the hot water. The output of the instantaneous water heater and the output of valve 123 represent the hot water connection WW.

The heat exchanger 130 has a first and second temperature sensor 131, 132. The valves 121, 122 are controlled according to the temperature detected by the first or second temperature sensor 131, 132.

Thus, the water from the flow VL, for example, a central heat pump 150 is preheated in the heat exchanger 130 and possibly reheated by the flow heater 140 to come to the desired target temperature of the hot water at the hot water outlet WWzu. The target temperature of the hot water can be set by a user. The valve 123 in the bypass 20 can be used to route the hot water preheated by the heat exchanger 130 past the continuous-flow heater when the desired hot water temperature is already present.

2 shows a schematic representation of a home station according to a first embodiment. The home station 100 according to the first embodiment can be based on the home station 1 based. The home station 100 thus has a first valve 121 which is coupled to the flow VL and the heating flow HVL via the line 11 . The home station 100 has a primary connection PA with the flow VL and the return RL. The home station also has a heat exchanger 130 and a flow heater 140 . Optionally, a bypass 20 (optionally with a valve 123) can be provided parallel to the flow heater 140. If no bypass 20 is provided, the mixing point is omitted. The water from the bypass 20 and the water from the instantaneous water heater 140 can flow together in the mixing point MP. The preheated water from the flow VL flows both to the first valve 121 and via a branch 12 to the heat exchanger 130. When the valve 121 is open, the hot water flows from the flow VL to the heating flow HVL. The heating return HL then flows via line 10 to the return RL of the home station 100. A cold water supply KWZ flows to the heat exchanger 130, from there through a second valve 122 via line 15 to the return RL.

At the hot water outlet of the heat exchanger 130, d. H. A first temperature sensor 111 is provided in or on the line 13 . A second temperature sensor 112 is provided in or on the heat exchanger 130 . A third temperature sensor 113 can be in or on the line 16, i. H. be provided on the hot water pipe WW. The flow heater 140 has an inlet temperature sensor 141 and an outlet temperature sensor 142 .

The first valve 121 is controlled depending on the temperature determined by the first temperature sensor 111 . The second valve 122 is controlled according to the temperature detected by the second temperature sensor 112 .

For example, the outlet temperature of the heat exchanger 130 is approximately 38°C. In the first embodiment of 1 the continuous-flow heater 140 has an inlet temperature sensor 141 and an outlet temperature sensor 142 . The third temperature sensor 113 is provided in the hot water line WW to detect the actual outlet temperature. This third temperature sensor 113 can be connected to the flow heater 140 . The flow heater 140 can thus have a connection for the third temperature sensor 113 . The third temperature sensor 113 is thus provided both (from a hydraulic point of view) behind the flow heater 140 and behind the bypass with the valve 123, so that it is ensured that the outlet temperature of the water in the hot water pipe WW can always be detected. This means that the temperature of the mixed water can always be recorded. Thus, an exact setting of the target temperature can be guaranteed at the mixing point.

3 shows a schematic representation of a home station according to a second embodiment. The home station 100 according to the second embodiment can be based on the home station according to the first embodiment. Therefore, the design of the home station according to the second embodiment with the first valve 121, the second valve 122, the third valve 123, the heat exchanger 130 and the flow heater 140 can correspond to the design of the home station according to the first embodiment. In addition to the configuration of the home station 100 according to the first exemplary embodiment, a fourth valve 124, in particular a motor valve, is then provided in the line 16, ie the hot water line, according to the third exemplary embodiment.

4 shows a schematic representation of a home station according to a third embodiment. The home station 100 according to the third exemplary embodiment can be based on a home station according to the first or second exemplary embodiment. In particular, the home station 100 according to the third exemplary embodiment is based on a home station according to the second exemplary embodiment. In contrast to the home station according to the second exemplary embodiment, the third valve 123 is designed as a motor valve.

5 shows a schematic representation of a home station according to a fourth embodiment.

The home station 100 according to the fourth exemplary embodiment can in particular be based on the home station according to the first exemplary embodiment. Thus, a third temperature sensor 113 is provided in the hot water line. The flow heater 140 can then be regulated or controlled according to the temperature detected by the temperature sensor 113 .

In addition to this, a fifth valve 125, in particular an engine valve, can be provided in the continuous-flow heater 140, in particular in its housing. Thus, the throughflow of the continuous-flow heater 140 can be regulated or controlled with the fifth valve 125 .

6 shows a schematic representation of a home station according to a fifth embodiment. The home station 100 according to the fifth exemplary embodiment can be based on a home station according to the first, second, third or fourth exemplary embodiment. In particular, the home station 100 according to the fifth exemplary embodiment is based on a home station according to the fourth exemplary embodiment. Here, in particular, the third valve 123 is designed as an engine valve.

7 shows a schematic representation of a home station according to a sixth embodiment. The home station 100 according to the sixth exemplary embodiment can be based on a home station according to one of the previous exemplary embodiments one to six. In particular, the home station 100 according to the sixth embodiment on a home station according to the first embodiment of 2 based. In contrast to the home station according to the first exemplary embodiment, the continuous-flow heater 140 has an inlet temperature sensor but no outlet temperature sensor. The third temperature sensor 113 in or on the hot water line or line 16 is then used to control the flow heater 140 in order to achieve the desired target temperature at the outlet of the flow heater 140 or at the mixing point. This is advantageous because it means that a temperature sensor within the continuous-flow heater can be saved.

8th shows a schematic representation of a home station according to a seventh embodiment. The home station 100 according to the seventh exemplary embodiment can be based on a home station according to the first to sixth exemplary embodiments. In particular, the home station 100 according to the seventh embodiment is based on a home station according to the second embodiment. In this case, however, the continuous-flow heater 140 only has an inlet temperature sensor 141, but not an outlet temperature sensor. The third temperature sensor 113 in the hot water line is used to control the instantaneous water heater.

Furthermore, a fourth valve (e.g. a motor valve) can be provided in the line 16 after the mixer MP.

9 shows a schematic representation of a home station according to an eighth embodiment. The home station 100 according to the eighth exemplary embodiment can be based on a home station according to one of the first to seventh exemplary embodiments. In particular, the home station 100 according to the eighth embodiment is based on a home station according to the third embodiment. In this case, the continuous-flow heater 140 only has an inlet temperature sensor 141, but not an outlet temperature sensor. The third temperature sensor 113 in or on the hot water line WW is then used to control or regulate the instantaneous water heater 140 . The third valve 123 in the bypass 20 can be configured as an engine valve.

10 shows a schematic representation of a home station according to a ninth embodiment. The home station 100 according to the ninth embodiment can be based on a home station according to the first to eighth embodiments. In particular, the home station according to the ninth embodiment is based on a home station according to the fourth embodiment. In this case, however, the continuous-flow heater 140 only has an inlet temperature sensor 141 but not an outlet temperature sensor 142 . The output signals of the third temperature sensor 113, which is connected in or on the hot water line WW, is used to control or regulate the instantaneous water heater 140. A fifth valve (eg, an engine valve) 125 is provided in the water heater 140 . The sensor 113 detects the water temperature at the mixing point MP.

11 shows a schematic representation of a home station according to a tenth embodiment. The home station 100 according to the tenth exemplary embodiment can be based on a home station according to the first to ninth exemplary embodiments. In particular, the home station according to the tenth embodiment is based on a home station according to the fifth embodiment of FIG 6 . In this case, the continuous-flow heater 140 only has an inlet temperature sensor 141, but not an outlet temperature sensor. The third temperature sensor 113 in or on the hot water line WW is then used to regulate or control the flow heater 140 . The third valve 123 in the bypass 20 and the fifth valve 125 is designed as an engine valve.

12 shows a schematic representation of a home station according to an eleventh embodiment. The home station 100 according to the eleventh exemplary embodiment can be based on a home station according to one of the first to ten exemplary embodiments. The home station 100 also has a valve unit 160 . The valve unit 160 is connected to the hot water outlet line or the line 16 of the instantaneous water heater 140 . The valve unit 160 has an input 161 and a first and second output 162, 163 and a third output 164.

Various consumption units 200 can be provided in an apartment. The consumption units can represent a bathtub 210, a shower 220 or a washbasin 230, for example. The first outlet 162 can be coupled via a line 17 to a bathtub 210 , the second outlet 163 can be coupled to a shower 220 via a line 18 and the third outlet 164 can be coupled to a sink 230 via a line 19 . Furthermore, the home station can have a sixth and seventh valve 126, 127, which can each be designed as motor valves. The sixth engine valve 126 may be coupled to a cold water port as well as to the first outlet port 162 . The seventh valve 127 can be coupled to the cold water connection and to the second outlet connection 163 of the valve unit 160 . According to the settings of the engine valves 126, 127, cold water can flow from the cold water connection KWA into the lines at the first and second connection 162, 163 of the valve unit.

In the eleventh embodiment of FIG 12 a further temperature sensor is preferably provided in each of the outgoing lines in order to enable the desired temperature to be provided as accurately as possible. Furthermore, two further motor valves 126, 127, for example, must be provided in order to set the desired setpoint temperature if the desired setpoint temperature is below the temperature present at the mixing point. According to the embodiment of 12 the temperature sensors and the solenoid valves 126, 127 can be integrated into the valve unit 160 or into the housing of the valve unit 160.

13 shows a schematic representation of a home station according to a twelfth embodiment. The home station 100 according to the twelfth exemplary embodiment can be based on a home station according to one of the first to eleventh exemplary embodiments. The home station 100 according to the twelfth embodiment has a valve unit 160 with an input 161 which is coupled to the hot water line WW. The valve unit 160 has a first and second outlet port 162,163. According to the twelfth embodiment, the first and second output ports 162, 163 may be coupled to a shower 220, respectively. A third port 164 may be coupled to a sink 230 . The valve unit 160 can also be coupled to an eighth valve 128 . The eighth valve 128 (e.g. an engine valve) can be coupled to a cold water connection KWA.

In the twelfth embodiment according to 13 a valve (motor valve) 128 is provided between a cold water connection KWA and the valve unit 160 . A temperature sensor 117 is also provided in or on the valve unit 160 . In the twelfth embodiment of FIG 13 a solenoid valve and a temperature sensor can be dispensed with. The advantage of the twelfth embodiment of 13 compared to the eleventh embodiment of FIG 12 is that there is no further mixing point and no temperature sensor at the outlets 162, 163, 164 of the valve unit 160. Thus, only the respective lines are provided between the valve unit 160 and the respective tapping points 210, 220, 230.

According to the twelfth embodiment of FIG 13 the lines 162, 163 can be coupled to a shower tap 220. These two lines can be used, for example, for an overhead shower and a hand shower in the shower.

Optionally, the washbasin 230 and the bathtub 210 can have both a hot water pipe and a cold water pipe, so that a commercially available fitting with a cold water connection and a hot water connection can optionally be used.

14 shows a schematic representation of a home station according to a thirteenth embodiment. The home station 100 according to the thirteenth embodiment can be based on the home station according to the twelfth embodiment. For this purpose, a ninth valve 129 can be provided between the mixing point MP and a cold water connection.

In the thirteenth embodiment of FIG 14 the valve 129 is not provided between the cold water connection KWA and the valve unit 160, but rather between the cold water connection KWA and the mixing point MP. Cold water can thus be supplied from the cold water connection KWA at the mixing point MP. A temperature sensor 117 can then also be provided on the valve unit 160 . This temperature sensor 117 can be provided in or on the valve unit 160 .

According to the thirteenth embodiment of FIG 14 the valve unit 129 can thus be moved into the home station and coupled to the mixing point M. With the configuration of the mixing point M according to the thirteenth embodiment of FIG 14 A lower water temperature can also be set at the mixing point M by adding cold water from the cold water connection than the outlet temperature of the heat exchanger 130.

15 shows a schematic representation of a home station according to a fourteenth embodiment. The home station 100 according to the fourteenth embodiment can be based on the home station according to the thirteenth embodiment. In addition to this, a fourth valve 124 can be provided at the outlet of the continuous-flow heater 140 or on the hot water line WW and a fifth valve (motor valve) 125 in the continuous-flow heater 140 .

In the fourteenth embodiment of FIG 15 a valve, in particular an engine valve 124, is additionally provided between the mixing point MP and the valve unit 160.

16 shows a schematic representation of a home station according to a fifteenth embodiment. The home station 100 according to the fifteenth exemplary embodiment can be based on a home station according to the first to fourteenth exemplary embodiments. In particular, the home station according to the fifteenth embodiment can be based on the home station according to the thirteenth embodiment. In addition, the valve assembly 160 may include two engine valves.

In the fifteenth embodiment of FIG 16 no valve is provided between the mixing point MP and the valve unit 160. However, engine valves can be provided at the outlets of the valve unit 160 for this purpose.

17 shows a schematic representation of a home station according to a sixteenth embodiment. The home station 100 according to the sixteenth embodiment can be based on the home station according to the fifteenth embodiment. In addition to this, a fifth valve 125 can be provided in the water heater, a fourth valve 124 can be provided at the outlet of the water heater and a ninth valve 129 can be provided between the cold water connection and the outlet of the water heater.

In the sixteenth embodiment of FIG 17 a valve unit 124 is provided between the mixing point and the valve unit. Furthermore, a motor valve 145 is provided in the continuous-flow heater 140 .

18 shows a schematic representation of a home station according to a seventeenth embodiment. The home station 100 according to the seventeenth embodiment can be based on the home station according to the sixteenth embodiment. In this case, the fourth valve 124 between the outlet of the flow heater 140 and the valve unit 160 can then be omitted. The third valve 123 in the bypass can then be designed as an engine valve.

The home station 100 according to the invention has a cold water inlet KWZ and a flow connection VL and a return connection RL. The flow connection VL and the return connection RL are coupled to a central water heating system such as a heat pump (150). Thus, for example, a central heat treatment for several apartments in a building can be provided. A home station is then provided in each residential unit as an interface between the central water heating system and the hot water taps in the residential unit and a heating system in the residential unit.

The home station 100 also has a heating flow connection HVL, a heating return connection HRL, a cold water connection KWA and a hot water line WW. The preheated water from the flow line VL can be used both for the heating flow HVL and for the hot water line WW. The heat exchanger 130 can have a temperature sensor 112 which detects the temperature of the cold water KW. Based on this temperature, a two-way valve can be provided between the heat exchanger and the return line RL. The temperature of the water in the flow VL can be 38° C., for example. This means that the water at the inlet of the instantaneous water heater can also be 38°C. The continuous-flow heater 140 can then reheat the water in accordance with the desired setpoint temperature. The instantaneous water heater 140 can have an inlet temperature sensor 141 and optionally an outlet temperature sensor 142 . A bypass 20 can be provided in parallel with the flow heater. The continuous-flow heater 140 can be activated according to the desired setpoint temperature and/or the bypass 20 can let water through in order to be able to provide hot water at the hot water connection WW or the line 16 .

The apartment station 100 according to the invention is advantageous because the hot water provided by the flow line VL (which is generated, for example, by a heat pump) can be further reheated only if necessary by means of the flow heater in a very energy-efficient manner. By means of the home station according to the invention, the energy-efficiently heated hot water from the flow VL can be used for showering, for example. The less the water heater 140 has to be reheated, the more energy-efficient the home station is. However, the instantaneous water heater 140 also gives the user the option of tapping hot water at a higher temperature. This can be necessary at a sink 230 in the kitchen, for example, to wash dishes, for example. In this relatively rare case, reheating by the instantaneous water heater can be used without sacrificing the general energy efficiency of the home station (in connection with the central hot water preparation).

According to one aspect of the present invention, the home station has a display unit and an operating element. A user can set the desired target temperature by means of the display unit and the operating element. The display unit and the operating element can be designed as a remote control and/or as an integrated display element.

With the home station according to the invention, the hot water temperature can thus be set to the exact degree.

According to one aspect of the present invention, the valve 123 in the bypass can be opened, for example, from a volume of 7 l per minute.

In accordance with one aspect of the present invention, the maximum water temperature at the outlet of the instantaneous water heater may be 45°C or some other set allowable temperature. This serves, for example, as protection when showering, so that the user does not scald himself.

The instantaneous water heater 140 according to one aspect of the present invention can be designed in such a way that it delivers the desired hot water temperature to the exact degree up to the maximum possible temperature (for example 60° C.).

In the first to seventeenth embodiments, a three-way valve as in FIG 1 be waived. The three-way valve from 1 is replaced by a simple valve, which is used to interrupt a water flow from the flow line VL to the heating flow HVL. According to one aspect of the present invention, a branch 12 for the water from the supply line VL can be provided in front of this valve. This branch is then coupled to the heat exchanger 130 . A first temperature sensor can be provided in the line for hot water downstream of the heat exchanger 130 . The temperature detected by the first temperature sensor is used to control the first valve 121. The valve 121 can be used to stop a volume flow in the direction of the heating flow HVL.

According to the first exemplary embodiment, a commercially available fitting can optionally be provided between the hot water line WW and, for example, a shower, which has both the hot water line WW and a cold water connection KWA, in order to enable showering at a lower temperature than the hot water in the hot water line WW .

The first to fifth exemplary embodiment relates to a home station with a flow heater 140 with an inlet temperature sensor 141 and an outlet temperature sensor 142 and a temperature sensor 113 behind the mixing point (flow heater and bypass) in the hot water pipe WW. The sixth to tenth exemplary embodiment shows a continuous-flow heater 140 with only one inlet temperature sensor 141. The outlet temperature sensor 142 can be removed. Here, the temperature values of the temperature sensor 113 behind the mixing point in the hot water line WW can be used to control or regulate the continuous-flow heater 140 .

In the eleventh to seventeenth exemplary embodiments, the home station also has a valve unit 160 . The valve unit 160 is provided behind a mixing point M of the home station and the hot water taps 210, 220, 230.

In the eleventh embodiment of FIG 12 two motorized valves 126, 127 are provided behind the valve unit 160 and are used to add cold water to the hot water from the home station, if required, when this is required at the taps 210, 220, 230.

In the twelfth embodiment of FIG 13 a motor valve 128 is provided on the input side of the valve unit 160, so that cold water can be added to the hot water from the hot water line WW in the valve unit 160 if required.

In the thirteenth to seventeenth exemplary embodiments, a motor valve 129 is provided in or at the mixing point MP in order to add cold water from the cold water connection KWA into the hot water pipe WW, for example at the mixing point M, as required.

The thirteenth to eighteenth exemplary embodiment is advantageous because, for example, only one line is provided between the respective tap and the valve unit, which supplies water at the desired temperature. This means that a standard fitting with a hot water connection and a cold water connection can be dispensed with. Rather, for example, a setpoint temperature entered by means of the display unit and the operating elements can be output to the degree. According to the invention, a single water line is thus provided between the valve unit and a tap.

In the seventeenth embodiment, which is based on the sixteenth embodiment, no valve is provided between the mixing point MP and the valve unit. For this purpose, the valve unit 123 in the bypass B is designed as an engine valve.

In the fifteenth embodiment of FIG 16 the outputs 162, 163 can have a controllable volume limitation, for example by means of an engine valve. The flow for the shower tap 220 in the valve unit can thus be controlled or regulated.

Reference List

10

Management

11

Management

12

Management

13

Management

14

Management

15

Management

16

Management

100

home station

111

first temperature sensor

112

second temperature sensor

113

third temperature sensor

117

temperature sensor

121

first valve

122

second valve

123

third valve

124

fourth valve

125

fifth valve

126

sixth valve

127

seventh valve

128

eighth valve

129

ninth valve

130

heat exchanger

131

first temperature sensor

132

second temperature sensor

140

water heater

141

inlet temperature sensor

142

outlet temperature sensor

145

engine valve

150

heat pump

160

valve unit

161

Entry

162

first exit

163

second exit

164

third exit

200

consumption units

210

Bathtub

220

Shower

230

Bathroom sink

B

bypass

HL

heating return

HRL

heating return connection

HVL

heating flow

week

cold water

KWA

cold water connection

KWZ

cold water inlet

MP

mixing point

PA

primary port

RL

return

VL

flow connection

ww

hot water connection

QUOTES INCLUDED IN DESCRIPTION

This list of documents cited by the applicant was generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Patent Literature Cited

• DE 102016010386 A1 [0002]

Claims (10)

Building technology system, in particular home station (100), with a primary connection (PA) with a flow connection (VL), a branch (12) being provided on the flow connection (VL) in front of a first valve (121), a heating flow (HVL) being coupled to the first valve (121), and a return connection (RL), a heat exchanger (130), which is coupled to the flow connection (VL) via the branch (12), a flow heater (140) for reheating water from the flow connection (VL), , and a hot water line (WW, 16) as the output connection of the home station (100), the hot water line (WW, 16) being coupled to the flow heater (140), and a temperature sensor (113) in or on the hot water pipe (16) for detecting the temperature of the water in the hot water pipe. Home automation system (100) according to claim 1 , Furthermore, with a mixing point (MP), which is coupled to an output of the instantaneous water heater (140) and the temperature sensor (113) in or on the hot water line (16) behind the mixing point (MP) for detecting the temperature of the water is provided. Home automation system (100) according to claim 2 , With a bypass (20) parallel to the water heater (140), wherein the mixing point (MP) with a bypass (20) and the water heater (140) is coupled. Home automation system (100) according to claim 3 , with a bypass valve (123) in the bypass (20). Home automation system (100) according to claim 1 until 4 , wherein a valve unit (160) has a first inlet connection (161) on the hot water line (WW, 16) and at least one outlet connection (162, 163, 164), which each have a single line (17, 18, 19) with a tap (210, 220, 230) for providing hot and/or cold water. Home automation system (100) according to claim 5 , The valve unit (160) having a further inlet connection for cold water, the hot water from the hot water line (WW) and the cold water being mixed in the valve unit (160) in order to supply water with a desired provide temperature. Home automation system (100) according to one of claims 2 until 6 , also with a valve (129) between the mixing point (MP) and a cold water connection (KWZ) for providing cold water at the mixing point (MP) to supply water at the mixing point (MP) with a target temperature in the hot water pipe (WW, 16 ) to provide. Home automation system (100) according to one of Claims 5 until 7 , wherein the valve unit (160) has at least one engine valve at one of the output ports (162, 163, 164) for opening or closing the output ports (162, 163, 164). Home automation system (100) according to one of Claims 5 - 8th , Furthermore, with a motor valve (124) in the hot water line (WW, 16) and a motor valve (145) in the water heater (140). Home automation system (100) one of Claims 5 - 9 , Furthermore, with a motor valve (145) in the continuous-flow heater (140), wherein the valve (123) in the bypass (20) is designed as a motor valve.

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