DE19617111A1 - Domestic hot water heating system - Google Patents

Abstract

The heating system consists of a gas-fired boiler, with the a controlled gas supply, a secondary heat exchanger through which the output is circulated by a pump, and a storage tank for the hot water supplied by a circulation pump in the secondary circuit of the second heat exchanger. A control unit governs the circulation pumps and the gas valve in response to signals from the temperature sensors. The primary heat exchanger (5) is heated by a gas burner (4), supplied through a valve (2) which may be varied by a drive (34), controlled through the system control unit (18). The heated output water is pumped through a secondary heat exchanger (7) by a circulation pump (10), controlled by (18). The hot water storage tank (14) is fed with cold water through a pipe (24) and hot water is drawn off through an outlet (31). Water from the lower area of the tank is pumped to the upper region through pipes (25,27,29,13) and pump (28) through the secondary of the heat exchanger (12). signals from temperature sensors (20,23,16) cause the control unit (18) to operate the pumps and gas control valve to prevent water at the top of the tank becoming too hot and that at the bottom becoming cold.

Description

The invention relates to a water heating system according to the preamble of the An saying 1.

In known water heating systems of this type, the burner is only controlled depending on the signals of the two tempera arranged in the stratified storage door sensor, the burner being switched on as soon as in the central area of the Layer memory is below a certain minimum temperature and switched off if a certain minimum temperature is exceeded in the lowest area. Here the burner is only controlled on and off.

In these known solutions, there is the disadvantage that towards the end of the Aufla the stratified storage tank, even in the lowest area of the stratified tank higher temperatures prevail, there is overheating in the uppermost area of the Stratified storage tank comes because that through the secondary circuit of the secondary heat exchanger flowing water essentially heated up by a certain temperature difference becomes. This can lead to corresponding problems when drawing off domestic water, which can lead to scalding.

The aim of the invention is to avoid this disadvantage and a water heating system to propose the type mentioned above, in which an overheating of the uppermost area the stratified storage tank is reliably avoided in all operating states.  

According to the invention, this is done in a water heating system of the type mentioned at the beginning the characterizing features of claim 1 achieved.

The proposed measures ensure that the heating of the Layered storage takes place towards the end of the charging process with a lower burner output and therefore overregulation or overcharging of the stratified storage device chers is avoided. The arrangement of the additional temperature sensor in Area of the storage supply line leading to the stratified tank ensures that quickly can be recognized if the water flowing into the stratified storage tank is too high Temperature assumes, in which case the performance of the burner is reduced and thus a further increase in the temperature of the stratified storage in the the upper area of incoming water is prevented.

Due to the features of claim 2, there is the advantage that the throughput through the Secondary circuit of the secondary heat exchanger can be preset using the throttle can, whereby a corresponding difference between the tem temperature in the lowest and uppermost area of the stratified storage tank can. The proposed measures also make it possible for the fresh water directly to the desired extraction temperature, taking tolerances from for example 1 to 3 K can be heated when using the pump and burner Nominal power run.

The invention will now be explained in more detail with reference to the drawing, which schematically invent one water heater according to the invention shows.

A water heating system according to the invention in the drawings has a Durchlauferhit zer 1, the heated with a through a valve disposed in a gas line 3 Gas valve 2 can be supplied with gas burner 4 primary heat exchanger 5 is provided. A drive 34 of this gas valve 2 is connected to a controller 18 via a signal line 32 .

The primary heat exchanger 5 is connected via a flow line 6 to a secondary heat shear 7 or its primary branch 8 . This primary branch 8 is connected via a return line 9 to a circulation pump 10 , which is connected via a connecting line 11 to an inlet of the primary heat exchanger 5 . A drive motor 34 of the circulation pump 10 is connected to the controller 18 via a signal line 33 .

A secondary branch 12 of the secondary heat exchanger 7 is connected via a storage feed line 13 to the uppermost region 15 of a stratified storage tank 14 , from which an extraction line 31 leads to a nozzle 36 . In this case, a temperature sensor 16 is arranged on the storage flow line 13 and is connected to the controller 18 via a signal line 17 . This has a nominal value generator 37, with which a desired La is fixable detemperatur of the layer accumulator 14, which is monitored by a the layer memory 14 disposed in the lowermost region 19 temperature sensor 20 which is connected via a signal line 21 to the control 18th

Next, a temperature sensor 22 is net angeord in the central region of the layer memory 14 . This temperature sensor 22 is connected via a signal line 23 to the controller 18 and supplies a signal when the temperature falls below a certain value, which causes a start of a new charging cycle and thus a start of the burner 4 .

From the lowest area 19 , into which a cold water inlet 24 opens, a storage return line 25 leads away, which leads to a presettable throttle 26 . This throttle 26 is connected via a connecting line 27 to a storage circulating pump 28 , which is connected via a connecting line 29 to the secondary branch 12 of the secondary heat exchanger 7 .

The storage circulation pump 28 is connected to the controller 18 via a signal line 30 .

If the temperature sensor 22 detects a temperature that is too low, the control 18 opens the gas valve 2 via the signal lines 32 and 33 and starts the burner 4 and the circulation pump 10 . As a result, heat is supplied to the secondary branch 12 of the secondary heat exchanger 7 .

Next, the controller 18 starts the storage circulation pump 28 , whereby cool water is withdrawn from the lowermost area 19 of the stratified storage tank 14, which flows back into the uppermost area 15 of the stratified storage tank 14 after heating in the secondary heat exchanger 7 via the storage feed line 13 and from above recharges warm water.

The temperature of the water flowing into the stratified storage tank 14 is monitored by the temperature sensor 16 , and when the temperature of the water in the area of the temperature sensor 16 approaches the intended temperature adjustable to 37 to 1 to 3 K, the controller 18 controls the performance of the , for example in a range of 40 to 100% modulable operable, burner 4 reduced by reducing the opening degree of the gas valve 2 by the drive 34 , whereby an excessive temperature of the water in the uppermost region 15 of the stratified storage device 14 is avoided. As a result, scalding can no longer occur when the service water is drawn off via the extraction line 31 .

The setting of the volume flow in the secondary circuit 12 by means of the throttle 26 takes into account the minimum inlet temperature in the cold water inlet 24 and the desired outlet temperature in the extraction line 31 at the rated burner output.

The charging of the stratified storage device 14 is terminated as soon as the temperature sensor 20 detects a temperature corresponding to the predetermined target temperature in the lowest area 19 of the stratified storage device 14 . In this case, the control 18 closes the gas valve 2 and, after a corresponding follow-up time, which enables the secondary heat to be appropriately removed from the primary heat exchanger 5 , stops the two circulation pumps 10 and 28 .

Claims (2)

1. Water heating system with a burner ( 4 ) acted upon primary heat exchanger ( 5 ), which heats a stratified storage tank ( 14 ) via a secondary heat exchanger ( 7 ), with the secondary branch ( 12 ) of the secondary heat exchanger ( 7 ) via a storage flow. and a storage return line ( 13 , 25 ) is connected, which opens into the uppermost area of the stratified storage tank ( 15 ) or leads from the lowermost area ( 19 ) of the stratified storage tank ( 14 ), and in the middle and lower region of the stratified storage tank ( 14 ) a controller ( 18 ) connected temperature sensors ( 20 , 22 ) are arranged, the controller ( 18 ) having a burner ( 4 ) controlling gas valve ( 2 ) and one with the secondary branch ( 12 ) of the secondary heat exchanger ( 7 ) in connection standing storage circulating pump ( 28 ) is connected, characterized in that a modulie render burner ( 4 ) is provided and in the in the uppermost loading area ( 15 ) of the ski right memory ( 14 ) opening storage supply line ( 13 ) a further temperature sensor ( 16 ) is arranged, which is connected to the controller ( 18 ) and initiates a reduction in the burner output when the temperature in the storage supply line ( 13 ) approaches a target temperature. 2. Water heating system according to claim 1, characterized in that a, preferably adjustable throttle ( 26 ) is connected in series to the secondary branch ( 12 ) of the secondary heat exchanger ( 7 ).