DE102008016191A1 - Device for heating and storage of drinking water, comprises a hot water feed line, a hot water discharge, a hot water storage, a pump for hot water storage, a mixing point for hot water, and a feed pipe for drinking cold water - Google Patents

Abstract

The device for heating and storage of drinking water, comprises a hot water feed line (1), a hot water discharge (2), a hot water storage (3), a pump for hot water storage (13), a mixing point (5) for hot water, feed pipe for drinking cold water, a discharge for drinking warm water, a drinking water storage, a pump for drinking water storage, a mixing point for drinking water, a pump of heat exchanger and a heat exchanger. A mixing point is formed in the second arrangement between the connection of drinking water storage and the mixing point of drinking water. The device for heating and storage of drinking water, comprises a hot water feed line (1), a hot water discharge (2), a hot water storage (3), a pump for hot water storage (13), a mixing point (5) for hot water, feed pipe for drinking cold water, a discharge for drinking warm water, a drinking water storage, a pump for drinking water storage, a mixing point for drinking water, a pump of heat exchanger and a heat exchanger. The first arrangement of the hot water feed line, the hot water discharge, the hot water storage, the pump for hot water storage and the mixing point for hot water is connected with a second arrangement of the feed pipe for drinking cold water, the discharge for drinking warm water, the drinking water storage, the pump for drinking water storage, and the mixing point for drinking water over a third arrangement of the pump of heat exchanger and the heat exchanger over its connection. The connection of the arrangement takes place over the connection of hot water storage to pump heat exchanger, mixing point of hot water to heat exchanger, heat exchanger to drinking water storage and another heat exchanger to another drinking water storage. A mixing point is formed in the second arrangement between the connection of drinking water storage and the mixing point of drinking water. In the third arrangement, the pump heat exchanger is arranged between the connection of the heat exchanger and the mixing point of the hot water. The connection of the heat exchanger with the pump of heat exchanger, the pump of heat exchanger with the mixing point of the hot water and the hot water storage with the heat exchanger are connected. The mixing point of circulation water exists between the connection of heat exchanger and the drinking water storage or between the drinking water storage and the warm water discharge or between the pump of drinking water and the heat exchanger, or exists between the drinking water storage and the warm water discharge or exists between the pump of drinking water and the heat exchanger. The pump of hot water storage is arranged between the hot water feed pipe and the storage of hot water. The connection of the hot water feed pipe to the pump of hot water storage, the pump of hot water storage to the storage of the hot water and the mixing point of the hot water to the hot water discharge are connected. The pump of drinking water storage is arranged between the connection of heat exchanger and the drinking water storage and the connection of heat exchanger to the pump of drinking water or to the drinking water storage and the mixing point of drinking water to the heat exchanger are connected. Between the heat exchanger and the drinking water storage, an assembly for disinfection, recooling and/or preheating of drinking water.

Description

The The invention relates to a device for heating and storing of drinking water.

Out Known in the art are devices that provide drinking water Heat in a storage with integrated heating surface.

Farther Devices are known, the drinking water in the flow over heat a heat exchanger. Such devices can also know their peak demand from a memory cover on the primary side.

Known are also devices that are in a charging circuit, consisting of charge pump, Heat exchanger and storage to warm the drinking water and to save.

That's how it describes DE 41 36 959 C2 a device that also heats and stores drinking water. When Zapfruhe this device forms a water cycle, are operated in the charge pump, drinking water heater and storage in the high temperature range.

The Cold water supply leads there at the charge pump and at the same time at the cold water inlet / outlet port of the accumulator. The heated Drinking water is taken from the hot water connection of the storage tank. In this device, however, the extracted hot water has a high temperature and can not be led directly to the taps become.

Known is also the integration of various storage areas, such as disinfection area and lace area, in a combination memory. The functionally different However, areas are also structurally separated there.

In DE 42 35 038 C2 a device is described which in addition to the function of DE 41 36 959 C2 still contains the necessary cooling of the withdrawn hot water.

The the circuit of charge pump, drinking water heater and storage removed hot water is from the incoming cold water over a preheater / recooler at tapping temperature cooled.

described there are the integrations of circulation. These devices determine in different variations, especially the design of the Concerning circulation, the state of the art for drinking water heating.

In DE 10 2005 034 021 a device is described which, as in DE 42 35 038 C2 Heated drinking water, the necessary cooling to tapping temperature but before the peak storage performs.

Out In the prior art devices are also known which heated the Bring drinking water into two different temperature zones and there to save. A temperature zone lies in the disinfection area, the other below or equal to the tapping temperature. Both memory areas are located on the secondary side.

In DE 100 34 513 C2 a device is described, the circulation water is preheated and heated separately, then opens into the charging circuit in front of the memory and is partially recooled after the memory.

2 and 3 show exemplary conventional devices according to the known prior art.

In 2 the drinking water is heated to the tapping temperature in the storage loading process, in 3 via the flow method. In the flow process, the heat energy for the peak demand from Heizwasserspeicher is often covered. Both methods are state of the art.

In 2 occurs when tapping and pump off 9 a zap volume flow driven by the external water pressure over the distance drinking cold water supply line 6 , Mixing point drinking water 10 , to the drinking water storage 8B and 8C , for hot water drainage 7 and on to the external taps. This pushes incoming drinking cold water in the drinking water tank 8th stored domestic hot water via the hot water drainage 7 to the external taps.

When the drinking water reservoir cools down 8th the pump turns off 9 one. The result is a charge volume flow from the pump 9A via heat exchangers 14A . 4B and about the store 8C and 8B , about the mixing point drinking water 10 back to the pump 9B , This charge volume flow overlaps the bleed volume flow.

is the bleed volume flow is greater than the charge volume flow, is the drinking water storage by inflowing drinking cold water In the opposite case, it is charged by drinking hot water.

The heating of the drinking cold water in the charge volume flow takes place via the heat exchanger 14 , The heat energy of the heat exchanger from heating water, which via the Heizwasserzuleitung of an external heat source on the pump 13A and 13B through the heat exchanger 14C . 14D for heating water drainage 2 and flows back to the external heat source.

Due to the integrating function of the drinking water storage tank 8th for the heat power requirement, the external heat source, the primary components pump 13 , Heat exchanger 14 and the secondary pump 9 be designed for a lower average heat demand over a period of time, as it requires the short-term peak demand.

The circulation water, driven by the pump circulation 15 , binds circulation water at the entrance 12 and forms over drinking water storage 8B and 8C , Drinking water drainage 7 and external drinking water network a volume flow circuit back to the circulation pump 15 ,

The same function has the arrangement after 3 , The storage of heat energy for the peak demand is done here but a Heizwasserspeicher.

When tapped, a tapping volume flow driven by the external water pressure is created via the drinking water supply line 6 , Mixing point drinking water 10 , Heat exchanger 14A and 14B , Hot water drainage 7 and on to the external taps. Here, the incoming drinking cold water in the entire power range to peak taps in the heat exchanger 14 heated continuously and via the hot water drainage 7 led to the external taps.

The heat energy of the heat exchanger from the Heizvolumenstrom, powered by pump 13B via heat exchangers 14C and 14D to the heating water tank 3B and 3C back to the pump 13A ,

When the heating water storage tank cools down 3 the pump turns off 4 one. The result is a charge volume flow from the pump 4A via the external heat source to the heating water storage 3A and 3B back to the pump 4B , This charge volume flow overlaps the heating volume flow.

If the heating volume flow is greater than the charge volume flow, the Heizwasserspeicher 3 through the connection 3B inflowing cold water from the heat exchanger 14D In the opposite case, it will pass through the connection 3A inflowing hot water from the external heat source loaded.

Due to the integrating function of the heating water storage tank 3 for heat output requirements, the external heat source and the pump 4 be designed for a lower average heat demand over a period of time, as it requires the short-term peak demand. pump 13 and heat exchangers 14 must be designed for peak demand.

The circulation water, driven by pump circulation 15A , binds circulation water in the mixing point 12 and forms via heat exchangers 14A and 14B , Drinking water drainage 7 and external drinking water network a volume flow circuit back to the circulation pump 15B , This circulation volume flow overlaps the bleed volume flow.

All of these devices have different disadvantages. The device after 2 requires large drinking water storage tanks to store the entire heat energy requirement for the peak load. These stores cause high capital and operating costs due to the material and hygiene requirements.

The device after 3 creates high pressure drops in the drinking water, because the peak volume flow is passed through the heat exchanger. In addition, the large variation range and rapid changes in the bleed volume flow make higher demands on the control technology and produce undesirable temperature fluctuations. Furthermore, designed for peak demand large heat exchanger generates high investment and operating costs.

From Based on this prior art, the invention has the object to create a device that is considerably more economical Operation in terms of both investment and operating costs Drinking water is heated and stored.

According to the invention this object is achieved by a device according to claims 1 to 10. Below, this device is based on the embodiment and the 1 be explained in more detail.

Of the basic idea of the solution according to the invention consists in that according to the prior art known view that drinking water either in store charging circuit or heated in the flow with possible Heizwasserspeichern, to break through. This is done by the assemblies, which the different positive functions of the two known devices generate, in a new device according to the invention be sensibly united.

In the inventive device according to 1 occurs when tapping and pump off 9 a zap volume flow driven by the external water pressure over the distance drinking cold water supply line 6 , Mixing point drinking water 10 . through the drinking water storage 8B / 8C , for hot water drainage 7 and on to the external taps. This pushes incoming drinking cold water in the drinking water tank 8th stored domestic hot water via the hot water drainage 7 to the external taps.

When the drinking water reservoir cools down 8th the pump turns off 9 one. The result is a charge volume flow from the pump 9A , through the heat exchanger 14A / 14B , through the store 8C / 8B , about the mixing point drinking water 10 back to the pump 9B , This charge volume flow overlaps the bleed volume flow.

If the tap volume flow is greater than the charge volume flow, the drinking water storage tank is replaced by a connection 85 In the opposite case, it is discharged through connection 8A incoming drinking warm water loaded.

The heating of the drinking cold water in the charge volume flow takes place via the heat exchanger 14 , The heat energy of the heat exchanger from heating water, which via the pump 13B through the heat exchanger 14C / 14D , through the heating water storage 3B / 3C back to the pump 13A flows.

Due to the integrating function of the drinking water storage tank 8th for the heat demand can the Heizwasserspeicher 3 pumping the primary components 13 , Heat exchanger 14 and the secondary pump 9 be designed for a lower average heat demand over a period of time, as it requires the short-term peak demand of the bleed flow.

When the heating water storage tank cools down 3 the pump turns off 4 one. The result is a charge volume flow from the pump 4A via the external heat source to the heating water storage 3A / 3B back to the pump 4B , This charge volume flow overlaps the heating volume flow.

If the heating volume flow is greater than the charge volume flow, the Heizwasserspeicher 3 through the connection 3B inflowing cold water from the heat exchanger 14D In the opposite case, it will pass through the connection 3A inflowing hot water from the external heat source loaded.

Due to the integrating function of the heating water storage tank 3 for heat output requirements, the external heat source and the pump 4 be designed for a lower average heat demand over a period of time, as it requires the short-term peak demand of Heizvolumenstromes. pump 13 and heat exchangers 14 are designed for the already lower average heat demand required by the assembly on the drinking water side.

This device has all the expected benefits and avoids all the undesirable disadvantages. The pressure loss of this device, formed by drinking cold water supply 6 , Drinking water storage 8th and domestic hot water drainage 7 , is very low.

The demand on the control technology is low and the temperature fluctuations of the domestic hot water are low, because of the pump 9 driven charge flow has a small range of variation and is not subject to rapid changes during operation.

The drinking water storage 8th is small, because energy for peak demand in Heizwasserspeicher 3 is stored. The peak load of the external heat source is due to the integrating function of the memory 3 and 8th low, which leads to lower investment costs.

The sizing of the components pump 9 , Heat exchanger 14 and pump 13 can be over the sizing of the ratio of memory 3 and 8th optimize, which contributes to the favorable choice of components and thus to low investment and operating costs.

at same function can be several device elements within Arrange the device deviating.

So it is possible to use the pump heat exchanger 13 also between heat exchangers 14D and mixing point heating water 5 to arrange.

The mixing point circulation water 12 can also be between the connections heat exchanger 14B and drinking water storage 8A or between pump drinking water 9A and heat exchangers 14A or drinking water in the store 8th between the connections 8B and 8C or he can completely be omitted.

Furthermore, an arrangement of the pump heating water storage is possible 4 between heating water supply line 1 and storage heating water 3A ,

The pump drinking water storage 9 can also be between heat exchangers 14B and storage drinking water 8A to be ordered.

For functional extension drinking water disinfection and / or waste heat utilization can be between heat exchangers 14 and drinking water storage 8th Subassemblies for preheating, disinfection and return be arranged cooling.

In further forms of embodiment of this device according to the invention, a plurality of device elements such as memory 3 or 8th be used multiple times, without thereby changing the basic device structure.

Such Solutions are part of the inventive concept consider.

1

Heizwasserzuleitung

2

Heizwasserableitung

3

Heizwasserspeicher

4

pump Heizwasserspeicher

5

mixing point heating water

6

Drinking cold water supply line

7

Domestic hot water drainage

8th

Storage Drinking water

9

pump drinking water storage

10

mixing point Drinking water

11

entrance circulation water

12

mixing point circulation water

13

pump heat exchangers

14

heat exchangers

15

pump circulation

QUOTES INCLUDE IN THE DESCRIPTION

This list The documents listed by the applicant have been automated generated and is solely for better information recorded by the reader. The list is not part of the German Patent or utility model application. The DPMA takes over no liability for any errors or omissions.

Cited patent literature

• - DE 4136959 C2 [0005, 0008]
• - DE 4235038 C2 [0008, 0011]
• - DE 102005034021 [0011]
• - DE 10034513 C2 [0013]

Claims (10)

Device for heating and storing drinking water, characterized in that it comprises at least one heating water supply line ( 1 ), at least one heating water discharge ( 2 ), at least one heating water storage ( 3 ), at least one pump Heizwasserspeicher ( 13 ), at least one mixing point heating water ( 5 ), at least one drinking cold water supply line ( 6 ), at least one drinking water drainage ( 7 ), at least one drinking water reservoir ( 8th ), at least one pump drinking water storage ( 9 ), at least one drinking water ( 10 ), at least one pump heat exchanger ( 13 ) and at least one heat exchanger ( 14 ), wherein a first arrangement of Heizwasserzuleitung ( 1 ), Heating water drainage ( 2 ), Heating water storage ( 3 ), Pump heating water storage ( 4 ) and mixing point heating water ( 5 ) with a second arrangement of drinking cold water supply line ( 6 ), Domestic hot water discharge ( 7 ), Drinking water storage ( 8th ), Pump drinking water storage ( 9 ), Mixing point drinking water ( 10 ) via a third arrangement of a pump heat exchanger ( 13 ) and a heat exchanger ( 14 ), connected to each other via their connections ( 13B ) and ( 14C ), wherein the connection of the arrangements via the connections Heizwasserspeicher ( 3C ) to pump heat exchanger ( 13A ), Mixing point heating water ( 5 ) to heat exchangers ( 14D ), Heat exchangers ( 14B ) to drinking water storage ( 8A ) and heat exchangers ( 14A ) to drinking water storage ( 9A ) he follows. Apparatus according to claim 1, characterized in that in the second arrangement between the terminal drinking water storage ( 8B ) and the mixing point drinking water ( 10 ) a merge point ( 12 ) is formed, in which a circulation water supply ( 11 ). Apparatus according to claim 1, characterized in that in the third arrangement, the pump heat exchanger ( 13 ) between connection ( 14D ) of the heat exchanger and mixing point heating water ( 5 ) is arranged, in which case the connections heat exchanger ( 14D ) with pump heat exchanger ( 13A ), Pump heat exchanger ( 13B ) with mixing point heating water ( 5 ) and heating water storage ( 3C ) with heat exchanger ( 14C ) are connected. Apparatus according to claim 2, characterized in that the mixing point circulation water ( 12 ) between the connections heat exchanger ( 14B ) and drinking water storage ( 8A ) or between drinking water storage ( 8C ) and hot water discharge ( 7 ) or between pump drinking water ( 9A ) and heat exchangers ( 14A ) is located. Apparatus according to claim 2, characterized in that the mixing point circulation water ( 12 ) between drinking water storage ( 8C ) and hot water discharge ( 7 ) is located. Apparatus according to claim 2, characterized in that the mixing point circulation water ( 12 ) between pump drinking water ( 9A ) and heat exchangers ( 14A ) is located. Apparatus according to claim 1, characterized in that the pump Heizwasserspeicher ( 4 ) between heating water supply line ( 1 ) and storage heating water ( 3A ) is arranged, in which case the connections Heizwasserzuleitung ( 1 ) to pump heating water storage tank ( 4B ), Pump heating water storage ( 4A ) to store heating water ( 3A ) and mixing point heating water ( 5 ) to heating water drainage ( 2 ) are connected. Apparatus according to claim 1, characterized in that the pump Heizwasserspeicher ( 4 ) is replaced by a valve. Apparatus according to claim 1, characterized in that the pump drinking water storage ( 9 ) between the connections heat exchanger ( 14B ) and drinking water storage ( 8A ) is arranged, in which case the connections heat exchanger ( 14B ) to pump drinking water ( 9B ) / ( 9A ) to drinking water storage ( 8A ) and mixing point drinking water ( 10 ) to heat exchangers ( 14A ) are connected. Apparatus according to claim 1, characterized in that between heat exchanger ( 14 ) and drinking water storage ( 8th ) is an assembly for disinfection, recooling and / or preheating the drinking water is.