DE19924758A1 - Consumable water heater has controller that reduces thermal energy supply to consumable water and delivery power of heating pump for low thermal demand - Google Patents

Abstract

The water heater has a heater, esp. with calorific value utilisation, contg. a closed hot water circuit with a gas-heated primary heat transfer device (12), a heating pump (20) and a secondary heat transfer device (36) that transfers thermal energy to the consumable water. A controller (30) influences the burner (14) power depending on the thermal demand at consumable water taps. The delivery power of the heating pump is variable and the controller reduces the thermal energy supply to the consumable water and the delivery power of the heating pump for a low thermal demand.

Description

State of the art

The invention is based on a device for heating of industrial water according to the genus of the main claim. At Is the efficiency of the heaters Heat exchanger load and the heating return temperature dependent. Low load and low return temperature lead to heaters with condensing boiler use, provided that Condensation range is reached, good efficiencies. The overall efficiency of the facility is also from Heating pump power consumption dependent. With the known Institutions of the generic type are used for The heating pump always with the same Conveyance operated, so that the demand for return temperature as low as possible not in all Operating cases is satisfactorily fulfilled.

Advantages of the invention

With the features of the main claim, a Condensing boiler also for domestic water heating in the operated favorable condensation range and thereby the Energy consumption of the facility can be reduced.  

By the features listed in the subclaims advantageous refinements and developments of Arrangement possible according to the main claim.

For devices with a storage tank heated by the heater for the domestic water is used to save energy or Avoid frequent short-term switching on of the device proposed that the control unit to supply heating energy Does not release hot water or storage tank until that Storage withdrawn a predetermined amount of water or heat has been.

The release of the heating energy supply to the domestic water barge for example via a quantity sensor, which the Control unit the amount of hot water withdrawn from the storage tank reports.

It is particularly advantageous if the release of the Heating energy supply to the domestic water or storage through the Heat demand signal in the lower storage area arranged temperature sensor takes place.

After the release of the heating energy supply, this can be advantageous Control unit draws off the hot water quantity with the difference the cold water inlet temperature and a set or multiply a measured hot water temperature and according to the result the burner output and the Set the delivery rate of the heating pump. With smaller Heating power, the heating pump conveys less water the heat exchanger. The heating return temperature drops and the efficiency of the heater increases.

A particularly good efficiency of the device results itself if the memory is designed as a stratified charge memory and from the secondary heat exchanger via a secondary  Heating water circuit is heated, which is also a charge pump contains.

With such a facility will continue suggested that a cold water supply line and a Hot water tap line to the secondary heating circuit are connected that from their connection points starting one over the charge pump, one Backflow preventer, a flow limiter and leading first through the secondary heat exchanger Line branch and a second leading through the memory Line branch of the secondary heating circuit results, and that the Flow resistances of the two line branches so are coordinated that when tapping one under the Response point of the flow limiter Flow rate the domestic water essentially alone the secondary heat exchanger in the first line branch is promoted and then flows over both line branches.

This ensures that at only a small or weaker Tapping the water alone is taken from the store in a middle area with higher heat requirements, however still with below the response value of the Flow rate limiter taps that Heating energy directly from the secondary heat exchanger to the Process water is transferred and in one, both in terms of temperature as well as flow rate conditional upper performance range of both Secondary heat exchanger as well as the storage the required Amount of heat delivers.

Through the parallel connection of the heater and the storage tank the computation of the required energy can Hot water performance of the facility without enlarging the Storage volume can be increased significantly.  

For the accuracy of the control can be advantageous in the Cold water supply line and a temperature sensor Flow sensor and at the outlet of the secondary heat exchanger additional temperature sensor may be provided.

For the maintenance operation, d. H. reloading the memory there is an advantageous ratio of Energy consumption or efficiency of the heater to the Charging time when the memory is released via a Energy supply to the domestic water introductory first Thermostats a second thermostat is provided and that Control unit releases the full burner output when the Storage temperature at the second thermostat below one predetermined value has decreased.

In some cases there is also a so-called eco circuit recommended that after charging Industrial water withdrawal the services of the gas burner, the Heating pump and possibly a charge pump to a given Value limited.

drawing

Four embodiments of the invention are in the Drawing shown schematically and in the following Description explained in more detail.

In the drawings Fig. 1 is a combined device for heating and domestic water heating without hot water storage tank, and Figs. 2 to 4 three different embodiments of devices with a combined unit and a hot water heater.

Description of the embodiments

All of the exemplary embodiments shown have a condensing boiler with a primary heat exchanger 12 , which is heated by a gas burner 14 and is located in a heating water circuit 16 to which an expansion vessel 18 is connected, as the heating source. The heating water circuit 16 also contains a heating pump 20 and leads via a secondary heat exchanger, which will be described in more detail below, and which transfers the heating energy to the process water. The heating water circuit 16 is connected to a flow connection 22 and via a reversing valve 24 to a return connection 26 of a heating system. A gas valve 28 , the heating pump 20 and the reversing valve 24 are connected to a control unit 30 , which influences the burner output as a function of the heat requirement when drawing off hot water.

The reversing valve 24 allows the water heated in the primary heat exchanger 12 to flow through the secondary heat exchanger as soon as and as long as a heat requirement is reported from the service water part, which begins with a cold water connection 32 and ends with a hot water connection 34 . The delivery rate of the heating pump 20 is changeable and the control device 30 influences the gas valve 28 and the heating pump 20 so that, in addition to the heating energy supply to the secondary heat exchanger, the delivery rate of the heating pump 20 is reduced in addition to the heating energy supply.

The device according to FIG. 1 has a secondary heat exchanger 36 , which transfers the heating energy to a service water line 38 , which leads from the cold water connection 32 via a quantity sensor 40 and via a flow limiter 42 to the hot water connection 34 . When tapping hot water quantity sensor 40 outputs corresponding to the tapped amount of electrical impulses to the control unit 30th There, these are multiplied by the built-in computer by the difference between the desired hot water temperature and the cold water temperature, which is determined by temperature sensors 44 , 46 at the corresponding points. The delivery rate of the heating pump 20 is also controlled in accordance with the invention in accordance with the determined burner output and the characteristic field programmed in the control unit 30 .

The device according to FIG. 2 has a secondary heating water circuit which, through a secondary heat exchanger 50 , leads a flow line 52 , a store 54 designed as a stratified charge store and a return line 56 . The store 54 is located in a line drawing leading from the cold water connection 32 to the hot water connection 34 and in the return line 56 there is a charge pump 58 and a flow limiter 60 . In addition to the gas valve 28 , the heating pump 20 , the reversing valve 24 and the charge pump 58, two temperature sensors 62 , 64 , which are attached to the reservoir 54 at different heights and are preferably designed as NTC resistors, are connected to the control unit 30 .

If a certain amount of heat has been removed from the storage 54 when tapping domestic water, the temperature sensor 62 emits a signal to switch on the condensing boiler with low power. If the temperature at the temperature sensor 64 also drops below a predetermined setpoint within a defined time, the condensing boiler is switched to full power. A charging process is ended when the lower temperature sensor 62 reaches the setpoint temperature. If the burner output is low, the delivery capacity of the heating pump 20 and possibly also the charge pump 58 is also reduced in order to save electricity and reduce the return temperature in the heating water circuit 16 .

The device according to Fig. 3 differs from the previously described, inter alia, that a cold water supply line 68 and a hot water supplying pipe 70 are connected to the outside of the memory 54 Sekundärheizkreis. This results in, starting from the two connection points 72 , 74 , a first line branch 78 leading via the charge pump 58 , a backflow preventer 76 , the flow rate limiter 60 and the secondary heat exchanger 50 and a second line branch 80 of the secondary heating circuit going through the store 54 . A temperature sensor 82 and a quantity sensor 84 are provided in the cold water supply line 68 . A further temperature sensor 86 is attached to the output of the secondary heat exchanger 50 .

The flow resistances of the two line branches 78 , 80 are coordinated with one another such that when a flow quantity below the response point of the flow rate limiter 60 is tapped, the process water is conveyed essentially solely via the secondary heat exchanger 50 in the first line branch 78 and then flows over both line branches 78 , 80 . This results in three phases of hot water heating: in the first phase, with a small hot water tap determined by the quantity sensor 84 , only the storage tank 54 is discharged. The gas burner 14 , the heating pump 20 and the charge pump 58 remain switched off.

In the second phase, with larger hot water tapping, the heat requirement is calculated in the manner already described in connection with the device according to FIG. 1 and the gas burner 14 with the corresponding power, as well as the heating pump 20 and the charge pump 58 are put into operation.

As long as the draw-off quantity is below the response value of the flow rate limiter 60 , the heating energy is supplied to the process water solely via the secondary heat exchanger 50 .

The third phase occurs when the tapping quantity exceeds the response value of the flow limiter 60 . Then the overlying amount of hot water is removed from the storage tank 54 .

For the purpose of storage charging after the removal of process water, two temperature sensors 88 , 90 are attached to the storage tank 54 at different heights, the gas burner 14 and the functional elements determining the energy supply being influenced accordingly when the value falls below or exceeds the set value. In both devices according to FIGS. 2 and 3, an eco-circuit may also be provided for the storage charge, in which the entire storage charge takes place with a small calorific value.

The device of FIG. 4 has a secondary heat exchanger 92 which is arranged directly in a memory 94. When hot water is drawn from the store 94 , a temperature sensor 96 gives the signal to switch on the condensing boiler with low output. If the target temperature drops at a second, higher-placed temperature sensor 98 within a defined time, the condensing boiler is either operated at high output or, as an eco-alternative, is further operated at low output.

Claims (8)

1.Heat for heating domestic water, with a heater, in particular with condensing use, which contains a closed heating water circuit that leads via a gas-heated primary heat exchanger, a heating pump and a secondary heat exchanger, which transfers the heating energy to the domestic water, and also with a control unit that depending on the heat demand in the hot water tapping influences the burner output, characterized in that the delivery rate of the heating pump ( 20 ) can be changed and the control unit ( 30 ) reduces the delivery rate of the heating pump ( 20 ) in addition to the heating energy supply to the domestic water when the heating requirement is lower. 2. Device according to claim 1, characterized in that the heater heats a memory ( 54 , 94 ) for the process water, the control unit ( 30 ) only releasing the heating energy supply to the process water or store ( 54 , 94 ) when the store ( 54 , 94 ) a predetermined amount of water or heat is withdrawn. 3. Device according to claim 2, characterized in that the release of the heating energy supply to the domestic water or storage ( 54 , 94 ) by the heat demand signal of a temperature sensor arranged in the lower storage area ( 62 , 88 , 96 ). 4. Device according to claim 2 or 3, characterized in that the memory ( 54 ) is constructed as a stratified charge accumulator and is heated by the secondary heat exchanger ( 50 ) via a secondary heating water circuit, which also contains a charge pump ( 58 ). 5. Device according to claim 4, characterized in that a cold water supply line ( 68 ) and a hot water tap line ( 70 ) are connected to the secondary heating circuit in such a way that from their connection points ( 72 , 74 ) starting from the charge pump ( 58 ), a backflow preventer ( 76 ), a flow limiter ( 60 ) and through the secondary heat exchanger ( 50 ) leading first line branch ( 78 ) and one through the memory ( 54 ) leading second branch branch ( 80 ) of the secondary heating circuit, and that the flow resistances of the two Line branches ( 78 , 80 ) are matched to one another in such a way that when a flow quantity below the response point of the flow rate limiter ( 50 ) is tapped, the process water is conveyed essentially solely via the secondary heat exchanger ( 50 ) in the first line branch ( 78 ) and then via both line branches ( 78 , 80 ) flows. 6. Device according to claim 5, characterized in that in the cold water supply line ( 60 ) a temperature sensor ( 82 ) and a quantity sensor ( 84 ), and at the output of the secondary heat exchanger ( 50 ) a further temperature sensor ( 86 ) are provided. 7. Device according to one of claims 3 to 6, characterized in that a second thermostat ( 64 , 98 ) is provided on the memory ( 54 ) via a first thermostat ( 62 , 88 , 96 ) initiating the release of energy supply to the process water and that Control unit ( 30 ) releases the full burner output when the storage temperature on the second thermostat ( 64 , 98 ) has dropped below a predetermined value. 8. The device according to claim 7, characterized by an eco-circuit, which limits the performance of the gas burner ( 14 ), the heating pump ( 20 ) and possibly a charge pump ( 58 ) to a predetermined value when charging storage after hot water.