DE4031187A1 - METHOD AND DEVICE FOR CONTROLLING THE CONTINUOUS STORAGE OPERATION WITH DRAINAGE - Google Patents

Abstract

Method of and device for controlling the continuous flow storage working during tapping of domestic hot water on a wall heating device with domestic hot-water preparation and room heating, with a secondary heat exchanger (17), by means of which the domestic water is heated by the heating water, with a tapping fitting (20) with water switch (21) and with a three-way valve (9) for switching over from heating to domestic water operation via a control unit (8). The continuous flow accumulator consists of an accumulator (14) with the secondary heat exchanger (17) and an additional accumulator (19), these accumulators (14, 19) being connected parallel via a hot water connecting pipe (33) and via a cold water connecting pipe (36). Moreover, there is arranged in the cold water connecting pipe (36) a three-way reverse valve (37) which is connected downstream of the water switch (21) in the cold water pipe (25). The three-way reverse valve (37) is provided with a valve drive (38) which can be controlled electrically or thermally.

Description

The present invention relates to a method for Controlling the continuous storage operation for hot water tap on a wall heater and on a device for this, consisting of a heatable from a heat source flow storage for a combination water heater with Process water treatment and space heating, especially for a gas wall heater, with a secondary heat exchanger, through which the hot water is heated by the heating water with a tap with water switch as well as with a Dreiwe ge valve for switching from heating to hot water powered via a control unit.

In such systems with continuous storage, one can have three Differentiate between operating phases.

The start-up mode, which starts with the minimum tap quantity starts and when the full heat exchanger level is reached unit ends, the continuous operation, which is the thermal Start-up follows and an unlimited water discharge  guaranteed and the reloading operation, the Spei content within specified limits thermally in Willingness to take the missing lei at the start of the tap balance of the heat exchanger.

These devices are used for domestic water heating Secondary heat exchanger in which the domestic water is heated by heating water. When tapping domestic water the electrical three-way Valve actuated and the heating water over the secondary heat exchanger directed. To bridge the performance deficit at the start of the tap during the thermal start-up must be off Sufficiently large storage room with service water from sufficient accordingly high temperature are available. Great storage However, they are not both in terms of construction and heating technology particularly advantageous.

The present invention is therefore based on the object to develop a method and a device by which is a hot water supply for wall heaters results in a minimum of storage space, sensors and Actuators ensure a hot water display that is due to quick availability, a high outlet temperature door consistency and an unlimited withdrawal quantity.

This problem is solved with a method for Controlling the continuous operation with tap water  a wall heater, preferably on a combi Water heater with process water treatment and room heating tongue, which has a secondary heat exchanger and at least has a memory, characterized in that during the thermi the incoming cold water flow with continuous Nuclear increasing share of the heat exchanger area and with continuously decreasing share of the storage area is supplied, the sum of the partial flows being constant will measure that the continuous operation in a known manner is carried out over the heat exchanger area and that at Reload operation a circulation flow between heat accumulation shear area and storage area due to the density below of the water in the respective areas becomes.

Through these measures, despite relatively small storage space range from the start of the tap to a substantially constant Hot water temperature achieved, which also over a length re tap duration can be easily maintained.

If necessary, it is according to a further measure by the Er finding useful that the constant switching of the Partial flows during thermal start-up only after one defined start-up delay. These delays depends on the respective device data, such as memory card capacity, heating capacity and the like.  

An apparatus for performing the method on a Combi water heater of the type mentioned above in that the flow memory consists of two parts, one Storage with the secondary heat exchanger and another Storage tank, there is a storage tank with hot water Connection line and a cold water connection are connected in parallel, that in the cold water Connection line arranged a three-way reversing valve which is the water switch in the cold water pipe is connected downstream and that the three-way reversing valve with is provided with a valve drive which is electrical and / or is thermally controllable.

The measure according to the invention can be effective Bridging the initial delay during thermal start-up be achieved. With a minimum of storage space, one quick availability and high hot water temperature door constancy reached.

In a possible embodiment of the invention, in which the the flow of cold water flowing into the storage tank during thermal start-up with continuously increasing start-up part for the heat exchanger side and decrease to the same extent is divided for the storage side the closure part and / or the body of the reversing valve Recesses on when the reversing valve is at rest the direction of flow from the cold water pipe to the storage tank  release, however, when tapping operation by pressing the Valve drive on the one hand continuously the flow reduce flow to the storage and on the other hand in the same Measures the flow flow to the reservoir with the secondary Increase heat exchanger so that the sum of the partial flows to the remains constant in both memories.

For continuous operation looks according to another feature the invention that the closure part and / or the body of the reversing valve has or have recesses, which is the flow direction from the cold water pipe to the storage tank fully release with the secondary heat exchanger, however, is the position of the reversing valve in the reload mode Cold water connection line between the two tanks released and, if necessary, the flow direction of the Cold water pipe blocked.

To better cope with the inertia during the start-up phase according to a further embodiment of the Erfin tion upstream of the valve actuator, whereby reversing the reversing valve during thermal start-up with a defined initial delay.

Further details, features and advantages of the invention are based on the following description with reference me explained in more detail on the drawing. The drawing shows schematically an embodiment of a combination water heater.

The combi water heater has a be heated by a burner 1 primary heat exchanger 2 , which is connected to a return line 4 provided with a circulation pump 3 and a flow line 5 , the latter having a flow temperature sensor 6 , which to a measuring line 7th is connected, which leads to an input of a control unit 8 . In the return line 4 there is also a three-way valve 9 which can be actuated by a motor drive 10 . The motor drive 10 of the three-way valve 9 draws its actuating energy via a line 11 from the re gel unit 8th In the three-way valve 9 open the heating water return line 12 , the heating system from a heating system, not shown, for. B. from radiators, and the Wärmetau shear return line 13 , which returns a secondary heat exchanger 17 in the memory 14 to the water heater. The supply line 5 is divided into a T-piece in the heating supply line 15 and the heat exchanger supply line 16 , which leads to the heat exchanger 17 in the flow storage 14 .

The burner 1 is supplied with gas via a gas line 27 , via a Gasven valve 28 , which is controlled by a magnetic drive 29 , and via a gas control device. The magnetic drive 29 is connected by a line 31 , a Bren ner blower 30 through a line 32 with the control unit 8 . Furthermore, the burner 1 , not shown, such as ignition device, flame detection device etc., are assigned.

In the memory 14 , which is designed as a hot water tank with appropriate insulation, the secondary heat exchanger 17 , for example in the form of a smooth coil of copper pipes, is arranged. Coaxial in the smooth tube snake internals 18 are attached for flow control. The connection for the cold water supply line is in the lower loading area of the memory 14 .

In addition to the store 14 with the secondary heat exchanger 17 , a further store 19 is arranged. A temperature sensor 34 of this memory 19 is connected via a line 35 to the control unit 8 . The two stores 14 and 19 are connected in their upper region by a hot water connection line 33 and in their lower region by a Kaltwas water connection line 36 and thus between the cold water line 25 and the hot water line 24 connected in parallel. The hot water line 24 is connected directly to the hot water connection line 33 , weighed against the cold water line 25 via a three-way reversing valve 37 is connected to the cold water connection line 36 . The changeover valve 37 is actuated by an electrically and / or thermally controlled via a line 39 valve driving 38th In the cold water line 25 , a water switch 21 with temperature selector and microswitch 23 , which is connected via a line 40 to the control unit 8 , is arranged. During tap operation, ie when hot water is drawn from a tap of the domestic water line 24 , cold water flows through the cold water line 25 via the water switch 21 . Due to the pressure difference, the microswitch 23 of the water switch 21 triggers the process water operation by signals via the line 40 to the control unit 8 .

The dimensioning of the two stores 14 and 19 depends above all on the maximum possible tap quantity, on the start-up time on the heating side and on the characteristics of the three-way reversing valve 37 .

The continuous storage mode with the two parallel-connected stores 14 and 19 works as follows:

In a dispensing operation by opening the dispensing valve 20 and exceeding the minimum dispensing throughput, the hot water operation is triggered via the micro switch 23 of the water switch 21 . The three-way valve 9 is reversed from the motor 10 to the charging circuit via the control unit 8 . At the same time, the burner blower 30 is actuated via the control unit 8 and, after the flushing time has elapsed, the gas valve 28 and the ignition device are actuated and the burner 1 goes into operation. The downstream of the water switch 21 Umsteuerven valve 37 is at the start of the tap in the flow direction to the memory 19 , so that the full tap flow first flows through the Spei cher 19 to the tap. With a defined initial delay by a timer in the control unit 8 , the valve drive 38 controls the flow direction continuously and within a predetermined time to the memory 14 with the secondary heat exchanger 17 . The flow resistances within the cable routing are matched so that the sum of the partial currents remains the same. The Ven tilantrieb 38 of the reversing valve 37 can be both electrical, z. B. by means of a motor or an electrically heated expansion body, as well as thermally, for example by fluid sensors, expansion body or the like, or from a combination of both.

Above the heat exchanger 17 in the storage 14 there is also a storage space 22 which, like the space in the storage 19, serves to bridge the power deficit at the start of the tap. In addition, it performs the function of a damper in the Durchlaufbe, which reduces the inevitable temperature fluctuations of the hot water to an acceptable level when the burner 1 is operating.

After the tap operation has ended, the store 19 is first loaded. The reloading operation is triggered and ended by the temperature sensor 34 in the memory 19 . During the reload operation, the Umsteuerven valve 37 is in a central position, so that the memories 14 and 19 are connected via the cold water connecting line 36 . Since the stores 14 and 19 are permanently connected in their upper region via the hot water connecting line 33 , a circulation flow sets in due to the density differences of the respective water contents, which allows the hot water heated in the store 14 to flow into the additional store 19 and the cooler water of the Memory 19 feeds the memory 14 from below. At the end of the reloading process, the valve 37 returns to the initial rest position. The heater operates the heating again or goes into standby mode in summer.

Claims (7)

1. A method for controlling the continuous operation with tap water on a wall heater, preferably on a combination water heater with Brauchwas water treatment and space heating, which has a secondary heat exchanger and at least one memory, characterized in that the inflowing cold water flow during the thermal start-up continuously increasing share of the Wärmetau shear area and with continuously decreasing part of the storage area is supplied, the sum of the partial flows being dimensioned constantly, that the continuous operation is carried out in a known manner via the heat exchanger operation and that in the after-loading operation a circulation flow between the heat exchange area and the storage area due to the density differences of the water of the respective areas. 2. The method according to claim 1, characterized in that that the continuous switching of the partial streams during the thermal start-up according to a defined th delay, which depends on the respective Device data such as storage capacity, heating capacity and Like. Depends is carried out. 3. Device for performing the method according to claim 1 or 2, with a heatable from a heat source continuous storage for a combination water heater with domestic water treatment and space heating, in particular for a gas wall heater, with a secondary heat exchanger through which the domestic water heats from the heating water is, with a tap fitting with a water switch and with a three-way valve for switching from heating to domestic water operation via a control unit, characterized in that the flow memory consists of two parts, a memory ( 14 ) with the secondary heat exchanger (17) and an auxiliary memory (19), in that the memory (14, 19) connecting line via a hot-water Ver (33) and connecting line through a cold water Ver (36) are connected in parallel, that in the cold water connection line (36 ) a three-way reversing valve ( 37 ) is arranged, which the water switch ( 21 ) in the cold water line ( 25 ) is connected downstream and that the three-way reversing valve ( 37 ) is provided with a valve drive ( 38 ) which is electrically and / or thermally controllable. 4. The device according to claim 3, characterized in that the closure part and / or the body of the order control valve ( 37 ) has recesses or on which release the flow direction from the cold water line ( 25 ) to the additional store ( 19 ) when the changeover valve is at rest . 5. Apparatus according to claim 3 or 4, characterized in that the closure part and / or the body of the reversing valve ( 37 ) has or have recesses which on tap operation with actuation of the valve drive ( 38 ) on the one hand continuously the flow flow to the additional memory ( 19th ) diminish and on the other hand increase the flow rate to the store ( 14 ) with the secondary heat exchanger ( 17 ) so that the sum of the partial flows me to the two stores ( 14, 19 ) remains constant. 6. Device according to one of claims 3 to 5, characterized in that the closure part and / or the body of the reversing valve ( 37 ) when in position in continuous operation has recesses or aufwei sen that the flow direction from the cold water pipe ( 25 ) to the memory ( 14 ) with the secondary heat exchanger ( 17 ) fully release. 7. Device according to one of claims 3 to 6, characterized in that the closure part and / or the body of the reversing valve ( 37 ) when in position in the recharging operation has recesses or aufwei sen, the flow direction of the cold water connec tion line ( 36 ) released between the two stores ( 14, 19 ) and, if necessary, block the flow direction from the cold water pipe ( 25 ).