EP0931988A2 - Method and installation for reducing the waiting time for the tapping of hot water - Google Patents

Abstract

The primary heat exchanger (7) is part of a primary circuit (10,11,12) incorporating at least one hot water heating body and a circulating pump (5). The secondary heat exchanger (3) is part of a secondary circuit (13) incorporating at least one hot water tap point. When required, the secondary heat exchanger can be connected to the primary circuit via a connecting conduit (9) between the forward flow (11) and back flow (12) of the primary circuit. The secondary heat exchanger can be bridged over by a bypass conduit (8) and a valve (2) is provided for the connecting conduit (9), by means of which the throughflow can be interrupted or at least reduced to a leak flow so that the secondary heat exchanger is uncoupled from the primary circuit.

Description

The invention relates to a method and a device for Reduction of the waiting time for dispensing hot domestic water, with or with an intermittent worker Burner, primary heat exchanger and secondary heat exchanger comprehensive combination heater, especially gas combination water heater, the primary heat exchanger being part of a at least one space heater primary circuit and the secondary heat exchanger part of at least one Hot water tap comprehensive secondary circuit is. Of the Secondary heat exchanger is further if necessary Primary circuit can be activated.

In the present case it is a matter of shortening the heating-up times for the provision of hot water in gas combination water heaters.

• Die an der Warmwasserbereitung beteiligten Bauteile werden in der Startphase aufgeheizt. Ein Teil der Brennerleistung wird für die Aufheizung dieser Bauteile entzogen. Die Energiemenge, die für die Aufheizung der Bauteile entzogen wird, und damit die Aufheizzeit des Warmwassers verlängert, ist abhängig von den Wärmekapazitäten der beteiligten Bauteile.
• Während des Aufheizvorgangs wird bereits ein Teil der Brennerleistung auf das Warmwasser übertragen. Dieses Warmwasser wird vom Verbraucher aber nicht genutzt, da die gewünschte Warmwassertemperatur unter der für den Verbraucher nützlichen Temperatur liegt. Der Energieinhalt des ungenutzt auslaufenden Warmwassers geht somit verloren.

During the standstill phases of the burner, the components of a gas combi water heater partially cool down to room temperature. If hot water is then drawn off, the consumer has to accept a certain waiting time until hot water with the desired temperature level is available. The waiting time has two causes:

• The components involved in water heating are heated up in the start-up phase. Part of the burner output is withdrawn for heating these components. The amount of energy that is extracted for the heating of the components, and thus increases the heating time of the hot water, depends on the heat capacities of the components involved.
• During the heating process, part of the burner output is already transferred to the hot water. This hot water is not used by the consumer, however, since the desired hot water temperature is below the temperature useful for the consumer. The energy content of the unused hot water is therefore lost.

100 =

Primärkreis

111 =

Vorlauf

112 =

Rücklauf

50 =

Umlaufpumpe

60 =

Brenner, insbesondere Gasbrenner

70 =

Primär-Wärmetauscher

30 =

Sekundär-Wärmetauscher

90 =

Verbindungsleitung zwischen Vor- und Rücklauf des Primärkreises

20 =

Dreiwege-Ventil

32 =

thermostatisch gesteuertes Ventil

130 =

Sekundärkreis.

A known principle for reducing the waiting time for the provision of hot water is explained with reference to FIG. 6. The reference numerals in FIG. 6 mean

100 =

Primary circuit

111 =

leader

112 =

Rewind

50 =

Circulation pump

60 =

Burners, especially gas burners

70 =

Primary heat exchanger

30 =

Secondary heat exchanger

90 =

Connection line between the flow and return of the primary circuit

20 =

Three-way valve

32 =

thermostatically controlled valve

130 =

Secondary circuit.

Flow and return 111, 112 is with at least one space heater connected. The secondary circuit 130 comprises at least a hot water tap. Neither radiator nor tap are shown in Fig. 6. If hot water is required, jumps the gas burner 80 to the primary heat exchanger 70 to heat up water in the primary circuit, which by the circulation pump 50 is circulated, among other things by the connecting line 90 through. The three-way valve 20 switched so that the flow 111 is blocked. The Circulation pump 50 thus rolls what is heated by gas burner 80 Water only via the connecting line 90 um. The secondary circuit 30 is only fully opened when there is a leakage current through the thermostatically controlled valve 32 experiences sufficient temperature rise, the Temperature rise is due to the transfer of heat from the primary circuit in the connecting line 90 via the secondary heat exchanger 30 on the secondary circuit. If the water in the Secondary circuit 130 the opening temperature of the thermostatic has reached controlled valve 32, this opens; the Hot water is then available to consumers. The waiting time when heating the water in the secondary circuit shortened that apart from the leakage current through the thermostatically controlled valve 32 no hot water through the Device or the secondary circuit flows; with it less energy discharged through the hot water or process water. Disadvantageous is, however, that when you first open the hot water tap only the leakage current drips from the tap. Only when that thermostatically controlled valve 32 opens A larger amount of hot water is available to consumers.

This principle is used in conjunction with a water heater described z. B. in DE-U 90 12 654.

In another known method for reducing the waiting time the gas combination water heater is used for hot domestic water permanently at a warming temperature in the range of the set DHW temperature maintained. Especially with those dependent on indoor air Gas combination water heaters cause high standby losses to avoid. In terms of this prior art is based on the EP 0 427 121 A2.

The object of the present invention is a method and a device of the type mentioned at the beginning create that while avoiding Readiness losses to a noticeable reduction in the waiting time guaranteed for dispensing hot domestic water.

This task is procedurally characterized by the Features of claim 1 and device technology the characterizing features of claim 5 solved.

The essence of the present invention is therefore that Start of hot water tapping during a heating phase of the secondary heat exchanger, the part of the secondary circuit is, at first interrupted, at least severely throttled until the water from the secondary heat exchanger Primary circuit is heated to a predetermined temperature. Then the secondary heat exchanger can be fully switched back to the primary circuit become. In this way, the heating phase can be done reduce time considerably.

So that this is always guaranteed in both summer and winter operation is heating up the water in the short-circuited Primary circuit to the predetermined temperature at the beginning a hot water tap always has priority. This is especially true in winter operation of the primary circuit.

For summer operation, it is conceivable that the primary circuit under Bypassing the secondary heat exchanger for a predetermined time or short-circuited predetermined periods of time, so that the Water during this predetermined time predetermined standby temperature is maintained. So that can the heating-up phase is also considerably reduced in summer become.

The water is preferably in the short-circuited primary circuit at a standby temperature of around 30 to 50 degrees celsius, especially about 40 degrees celsius.

Fig. 1

eine erste Ausführungsform einer erfindungsgemäß ausgebildeten Einrichtung in schematischer Darstellung;

Fig. 2

eine zweite Ausführungsform der erfindungsgemäßen Einrichtung in schematischer Darstellung;

Fig. 3

eine dritte Ausführungsform einer erfindungsgemäß ausgebildeten Einrichtung in schematischer Darstellung;

Fig. 4

eine vierte Ausführungsform einer erfindungsgemäß ausgebildeten Einrichtung in schematischer Darstellung;

Fig. 5

eine fünfte Ausführungsfrom einer erfindungsgemäß ausgebildeten Einrichtung in schematischer Darstellung; und

Fig. 6

eine Einrichtung zur Verkürzung der Wartezeit beim Aufheizen von Warmwasser nach dem Stand der Technik in schematischer Darstellung

With regard to constructive details of the device according to the invention, reference is made to claims 6 to 11 in addition to claim 5 and to the following description of several embodiments of the device according to the invention with reference to the accompanying drawing. This shows in:

Fig. 1

a first embodiment of a device designed according to the invention in a schematic representation;

Fig. 2

a second embodiment of the device according to the invention in a schematic representation;

Fig. 3

a third embodiment of a device designed according to the invention in a schematic representation;

Fig. 4

a fourth embodiment of a device designed according to the invention in a schematic representation;

Fig. 5

a fifth embodiment of a device designed according to the invention in a schematic representation; and

Fig. 6

a device for reducing the waiting time when heating hot water according to the prior art in a schematic representation

3 =

Sekundär-Wärmetauscher

5 =

Umlaufpumpe

6 =

Gasbrenner

7 =

Primär-Wärmetauscher

8 =

Bypass-Leitung

9 =

Primärkreis-Verbindungsleitung

10 =

Primärkreis

11 =

Vorlauf (Heizung)

12 =

Rücklauf (Heizung)

13 =

Sekundärkreis.

In all embodiments, the following identical parts are identified by the following reference numerals:

3 =

Secondary heat exchanger

5 =

Circulation pump

6 =

Gas burner

7 =

Primary heat exchanger

8 =

Bypass line

9 =

Primary circuit connection line

10 =

Primary circuit

11 =

Flow (heating)

12 =

Return (heating)

13 =

Secondary circuit.

The function of the aforementioned parts of the facility has already been 6 with the exception of the bypass line 8. The importance of this bypass line 8 is shown below discussed in more detail.

If hot water is drawn off in the embodiment according to FIG. 1, circulation pump 5 and gas burner 6 start up. During the heating phase of the hot water becomes the primary circuit connection line 9, which is assigned to the secondary heat exchanger 3, as long blocked until the heating water temperature at the connecting line 9 has reached a predetermined setpoint. During this The heating water is heated up by the burner output and from the circulation pump 5 in a the secondary heat exchanger 3 immediate bypass line 8 circulated. Accordingly no burner output to the process water in the secondary circuit 13 transfer. The total burner output is used to that water in the short-circuited by the bypass line 8 Bring primary circuit 10 to the target temperature. Is this target temperature on the connecting line 9, it is opened with the result that the heating power via the secondary heat exchanger 3 transferred to the domestic water in the secondary circuit 13 becomes. Accordingly, the secondary circuit is opened 13 associated taps when opening the same hot water immediately with a temperature useful for the consumer Available.

For shutting off the connecting line 9 and accordingly the decoupling of the secondary heat exchanger 3 from the primary circuit 10 and for the design of the bypass line 8 are the following Variants possible:

The first variant is shown in Fig. 1. There is the Connecting line 9 to the primary circuit 10 via an electric motor operated three-way valve 2 in connection. This can be placed either in the forward 11 or return 12. At the start of the tap, valve 2 moves to a middle position of both the heating flow 11 and heating return 12 as also the connecting line 9 via the secondary heat exchanger 3 is cordoned off. Due to the generated by the circulation pump 5 Delivery pressure creates a differential pressure before and after you arranged in the bypass line 8 overflow valve 4, through that this is opened. The water in the primary circuit 10 will accordingly circulated via the bypass line 8. The one there losses incurred are minimal. Much of the Heating capacity of the gas burner 6 is via the primary heat exchanger 7 transferred to the water in the primary circuit 10. The heating accordingly, the water takes place quickly. As soon as the Desired setpoint temperature in the bypass line 8 short-circuited primary circuit 10 and thus on the three-way valve 2 is reached, this is switched to water heating. The connecting line 9 takes priority over the heating circuit open.

The secondary heat exchanger is immediately fully heated Water available. That will be correspondingly fast Domestic water heated in the secondary circuit 13, so that at the Hot water is available. As soon as the three-way valve 2 is opened, the pressure difference goes lost on the overflow valve 4, so that this again closes.

The heating water temperature at the three-way valve 2 is determined by a temperature sensors positioned there. This stands in connection with the motor control for the three-way valve 2.

The alternative solution, in which the three-way valve 2 in the return 12 is placed, d. H. between connecting line 9 and return 12 of the primary circuit 10, is in Fig. 1 with a dotted line shown.

2 is between lead 11 and Connecting line 9 an electric motor operated four-way valve 2 'arranged. The bypass line is also on this 8 connected. At the start of the tap, the four-way valve 2 'opened the bypass line 8 and thus the primary circuit 10 short-circuited via the bypass line 8. As soon as the Set temperature at the four-way valve 2 'by a corresponding one If the temperature sensor is detected, the four-way valve switches 2 to water heating. This is done by the bypass line 8 closed and the connecting line 9 in priority to the flow 11 of the primary circuit 10 opened. If the tap in the Secondary circuit 13 is closed, both in winter through the three-way valve 2 according to FIG. 1 as well as by the Four-way valve 2 'according to FIG. 2, the flow 11 of the Primary circuit 10 while shutting off the Connection line 9 opened so that the heating power of the gas burner 6 the heating circuit or those not shown here Space heaters are provided. In summer operation will also be after the hot water tap Connection line 9 through the valves 2 and 2 'again closed when the temperature of the primary circuit is below the Switching temperature drops.

The embodiment according to FIG. 3 largely corresponds to that 1. It differs from this essentially only in that in the connecting line 9 before or behind the secondary heat exchanger 3 is an electric motor or solenoid-controlled two-way valve 1 arranged is. Through this the flow in the connecting line 9 locked at the start of the tap. The result is that the spill valve 4 in the bypass line 8 opens, so that the primary circuit 10th via the bypass line 8 according to the embodiment according to Fig. 1 is short-circuited. As soon as the desired temperature the water in the short-circuited primary circuit has been reached, the two-way valve 1 is opened so that the heating power transmitted to the secondary circuit 13 via the secondary heat exchanger 3 can be. Otherwise, this embodiment the three-way valve 2 is always open. It is either in the open position to the connecting line 9 or in the open position to lead 11.

The alternative solution, in which the two-way valve 1 behind the Secondary heat exchanger 3 is arranged, is dotted in Fig. 3 Line shown.

The variant according to FIG. 4 differs from that according to Fig. 3 only in that that before (or behind) the secondary heat exchanger 3 arranged two-way valve 1 as a thermostatic Valve is formed. When the device has cooled down Heating water circuit is the thermostatic valve 1, apart of a defined leakage current, closed. The heating water is in this position on the bypass line 8 and the overflow valve 4 arranged in this circulates. By the leakage current mentioned is the thermosensitive area of the thermostatic valve 1 from the heating water washed around at the start of the tap. The heating water has the opening temperature reached the thermostatic valve 1, this is complete open. The overflow valve 4 closes due to the pressure drop caused by the opening of the two-way valve 1 into the bypass line 8. The heated heating water of the primary circuit flows through the connecting line 9. This will Domestic water in the manner described via the secondary heat exchanger 3 heated.

The thermostatic valve 1 can be used as a memory metal or as Expansion body, as in the cooling circuit of a motor vehicle is used to be executed. Contains an expansion body a thermosensitive material, e.g. B. paraffin, which is in Temperature rise expands. The volume increase becomes Exploited movement of a valve plug or the like. The Opening characteristics of the thermostatic valve 1 can be so be designed so that at low flow temperatures of approx. 50 degrees Celsius, as with a water heater a target hot water temperature of around 40 degrees Celsius is still fully open. On the other hand, the valve 1 but only open so late that after opening the consumer immediately hot water at the desired high temperature level is available.

5 differs from the aforementioned Embodiments essentially in that the Bypass line 8 branches off from the primary circuit connecting line 9, namely directly in front of or behind the secondary heat exchanger 3. For this purpose is in front of or behind the secondary heat exchanger 3 in the connecting line 9 an electric motor or thermally controlled three-way valve 1 ' arranged. In the heating phase, the valve mentioned 1 'the flow in the connecting line 9 in the Secondary heat exchanger 3 comprising the same section interrupted. The bypass line 8 is opened so that the Primary circuit 10 is shorted again with the result that the heating water in the short-circuited via the bypass line 8 Primary circuit brought to target temperature relatively quickly becomes. As soon as the target temperature is present at the three-way valve 1 ', this valve 1 'is opened with simultaneous shut-off the bypass line 8. This means that the secondary heat exchanger 3 the desired hot water temperature within a very short time on. The embodiment with a behind the secondary heat exchanger 3 arranged three-way motor valve 1 ' shown in Figure 5 with a dotted line.

In addition, the gas combination water heater can be used in the variants described above 6.7 at a warming temperature of about 40 degrees Celsius can be kept. At this temperature level are the readiness losses compared to a holding temperature low from 60 to 65 degrees Celsius; the waiting time at water heating is further reduced. This operation is particularly beneficial in summer.

All features described in the registration documents are claimed as essential to the invention, insofar as they are individually or are new in combination with the prior art.

Claims (11)

Method for reducing the waiting time for dispensing hot domestic water, in the case of a combination heater comprising an intermittent burner (6), primary heat exchanger (7) and secondary heat exchanger (3), in particular a gas combination water heater, the primary heat exchanger being part of a at least one space heater primary circuit and the secondary heat exchanger is part of a secondary circuit comprising at least one hot water tap, and wherein the secondary heat exchanger can be connected to the primary circuit if necessary.
characterized in that
at the start of hot water tapping during a heating phase, the connection of the secondary heat exchanger is initially interrupted, at least is strongly throttled, until the water in the primary circuit is heated to the predetermined temperature bypassing the secondary heat exchanger and short-circuiting the primary circuit, and then the secondary heat exchanger to the primary circuit switch on again. Method according to claim 1,
characterized in that
the heating of the water in the short-circuited primary circuit to the predetermined temperature at the start of hot water tapping always has priority, especially in winter operation of the primary circuit. The method of claim 1 or 2,
characterized in that
bypassing the secondary heat exchanger, the primary circuit is short-circuited for a predetermined time or predetermined time intervals, in particular in summer operation, so that the water is kept at a predetermined standby temperature during this predetermined time or time interval. Method according to claim 3,
characterized in that
the water in the short-circuited primary circuit is kept at a standby temperature of approximately 30 to 50 degrees Celsius, in particular approximately 40 degrees Celsius. Device for reducing the waiting time for dispensing hot domestic water with a combination heater comprising an intermittent burner (6), primary heat exchanger (7) and secondary heat exchanger (3), in particular gas combination water heater, the primary heat exchanger (7) Part of an at least one hot water radiator and a circulation pump (5) comprising a primary circuit (10, 11, 12) and the secondary heat exchanger (3) is part of a secondary circuit (13) comprising at least one hot water tap, and the secondary heat exchanger (3 ) can be connected to the primary circuit if required via a connecting line (9) arranged between the flow (11) and the return (12) of the primary circuit,
characterized in that
the secondary heat exchanger (3) can be bridged by a bypass line (8), and that the connecting line (9) is assigned a valve (2; 2 '1;1') by means of which the flow through it can be interrupted or at least opened a leakage flow can be reduced in such a way that the secondary heat exchanger (3) is decoupled from the primary circuit (10, 11, 12). Device according to claim 5,
characterized in that
the valve associated with the connecting line (9) is a three-way valve (2) which is arranged between the connecting line (9) on the one hand and either the flow (11) or return (12) of the primary circuit (10) on the other, and that in the Bypass line (8) an overflow valve (4) is provided, which opens at a predetermined differential pressure (Fig. 1). Device according to claim 5,
characterized in that
the valve associated with the connecting line (9) is a four-way valve (2 ') which is arranged between the connecting line (9) on the one hand and either the flow (11) or return (12) of the primary circuit (10) on the other, and of which furthermore branches off the bypass line (8) so that the bypass line (8) can be opened at the start of the tap while shutting off the connecting line (9), while after reaching a target temperature, in particular on a temperature sensor assigned to the valve (2 '), the The connecting line (9) opens by shutting off the bypass line (8) (Fig. 2). Device according to claim 6 or 7,
characterized in that
the three- or four-way valve (2; 2 ') is operated by an electric motor and is coupled to a flow or return temperature sensor in such a way that when the set temperature at the valve is reached, the connecting line (9), which is closed at the start of the tap, which connects the secondary Heat exchanger (3) is assigned, opens so that the secondary heat exchanger (3) is connected to the primary circuit. Device according to claim 5 or 6,
characterized in that
In the connecting line (9) upstream or downstream of the secondary heat exchanger (3) assigned to this, a two-way valve (1) is arranged, which blocks the flow in the connecting line (9) at the start of the tap or at least strongly throttles until the target temperature is reached in the short-circuited primary circuit, in order then to open the connecting line (9) again, so that the secondary heat exchanger (9) is connected to the primary circuit (FIGS. 3, 4). Device according to claim 9,
characterized in that
the two-way valve (1) upstream or downstream of the secondary heat exchanger (3) is either an electric motor (M) operated and coupled with flow or return temperature sensors, in particular a temperature sensor assigned to the valve (1) (Fig. 3 ) or a thermostatically (T) controlled valve (Fig. 4). Device according to claim 5,
characterized in that
the bypass line (8) branches off from the connecting line (9) to which the secondary heat exchanger (3) is assigned, the branch either upstream or downstream of the secondary heat exchanger (3) through a three-way valve (1 ') is defined, which is either operated by an electric motor (M) or controlled thermostatically (T), in such a way that at the start of tapping after reaching a predetermined target temperature in the primary circuit or on the originally opened bypass line (8), the latter is closed and that of the secondary heat exchanger (3) assigned, originally closed section of the connecting line (9) is opened (Fig. 5).

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