DE19619566C1 - Arrangement and method for providing hot domestic water - Google Patents

Abstract

The device comprises a primary circuit (10) which has a heater (1) producing warm or hot fluid and a conveyor (14) with a regulator for the fluid. A secondary circuit (20) is for the service water to be heated up. A heat exchanger (5) transfers heat from the fluid in the primary circuit to the service water in the secondary circuit. The primary circuit in the heat exchanger or the output side pipe (13) has a first temperature sensor (17). The secondary circuit in the heat exchanger or the output side pipe (23) has a second temperature sensor (27). The regulator has a circuit which switches on the conveyor when the temperature drops below a nominal value and or exceeds a nominal value on the second temperature sensor, and switches off the conveyor when the temperature exceeds a nominal value and or exceeds an amount on the first temperature sensor.

Description

The invention relates to an arrangement and a method for providing hot domestic water with a primary circuit with a fluid, a warm or hot fluid providing means and a conveyor for the fluid, a secondary circuit for the domestic water to be heated, a heat exchanger for heat transfer from the fluid of the primary circuit to the process water in the secondary circuit, a control device for the Conveyor and a temperature sensor in the primary or secondary cycle.

The hot domestic water is conventionally provided by means of a Heat source in a hot water tank, a so-called boiler, which is there while also taking on the task of intermediate energy storage.

In many cases it makes sense and is also proven to separate the Process water on the one hand and the actually heated fluid on the other to make. This fluid is usually water as well, but for example show the water of a heating system that is not for normal consumption or use is intended.

In DE 295 19 473 U1 a flow-through water heater is featured beat. In this, a process water coil runs through a heater water storage, with a reheating during the hot water withdrawal via an associated heating device. To recognize that a Hot water is withdrawn, the hot water is in the confluence area snake a temperature sensor in the heating water tank in good heat conduction the contact with the service water snake. After the start of the tap cool fresh water flows through exactly this junction area, and the resulting small temperature drop is transferred to the tempera door sensor, which can thus be used to control the heating device.

In other cases, the domestic water is heated using an external heat exchanger heated as a continuous flow heater. The fluid or Hei  water is pumped through the heat exchanger in a primary circuit the hot water in the secondary circuit is heated. So there will be cold water in the Secondary circuit fed to the heat exchanger, there to the desired one Brought usable temperature in which the heat from the heating water from Transfer heat generator through the heat exchanger to the domestic water and, after passing through the heat exchanger, the process water is in heated form available.

To provide a reasonably constant water temperature here to be able to, a control device can be provided.

Such a control device is for example from CH-PS 285 708 known; a temperature sensor is provided there, either in the primary circuit run or is also provided in the secondary circuit and on one Three-way valve acts and so by changing the mixing ratio the heating water in the primary circuit the primary temperature in the heat controls the exchanger.

For the rest of the same mode of operation, for example, in DE 40 35 115 C2 a speed control of the pump controlled by a flow switch used in the primary circuit. However, this has the disadvantage Proven use of a flow switch in the hot water pipe. Flow monitors require considerable purchase and installation costs and are extremely prone to errors. As such, the flow monitors are supposed to recognize whether water is flowing due to a flow, hence process water is removed and, depending on this, switch the circulation pumps on or off.

The object of the invention is to provide an arrangement and a method to propose warm domestic water that without such currents control monitor and at the same time an inexpensive means of regulation creates.

This object is achieved in an arrangement in that both in the primary circuit in the heat exchanger or in relation to the heat exchanger  a first temperature sensor as well as in the secondary circuit run in the heat exchanger or in the outlet with respect to the heat exchanger side line a second temperature sensor is arranged, and that the rain tion device has a circuit that drops below a setpoint Temperature and / or a temperature exceeding a setpoint gradient amount at the second temperature sensor the conveyor switches on and when the temperature rises above a setpoint and / or a Temperature gradient amount exceeding the setpoint at the first temperature sensor switches off the conveyor.  

In one method, the object is achieved in that both in the primary circuit in the heat exchanger or in relation to the heat exchanger line on the outlet side as well as in the secondary circuit in the heat exchanger or in the temperature with respect to the heat exchanger on the outlet side is measured, and that when the temperature drops below a setpoint and / or temperature gradients in the heat rising above a setpoint exchanger or in the line leading away from the heat exchanger in the secondary circuit the conveyor begins to convey the fluid in the primary circuit, and that when the temperature rises above a setpoint and / or above a Setpoint increasing amount of temperature gradient in the heat exchanger or in the line away from the heat exchanger in the primary circuit to promote the Fluids in the primary circuit is terminated.

Through this consistent use of temperature sensors and the Ermit temperatures and / or temperature gradients can be completely applied to all Flow monitors are dispensed with.

Nevertheless, it is possible to always maintain the desired hot water temperature (hot water temperature).

First, consider the switch-on criterion for the funding facility of the Fluids, this is essentially used by the temperature sensor water cycle determined. This temperature sensor is particularly preferred arranged directly at the outlet of the heat exchanger in the secondary circuit net. Now, after a previous shutdown, the tap in the domestic water pipe is open and hot water is requested, the process water begins in the Secondary circuit to flow. The temperature that was initially on the The status of the heat exchanger, i.e. at a relatively high level, starts right to drop spontaneously when the water comes from the cold water supply of the domestic water sers runs through the heat exchanger, whose heat reserve naturally decreases.

This falling temperature is immediately recognized by the temperature sensor. This can be done in a variant that this temperature is below one Desired value falls, in a preferred variant this is simply done by the tem  temperature gradient determined. The latter also has the advantage that with one Commissioning of the control with cold storage (initial commissioning) Conveyor is not switched on, although a setpoint is not reached becomes.

One of these two criteria immediately leads to the activation of the Conveyor in the primary circuit, which is now hot fluid of the primary circuit feeds the heat exchanger and thus heat transfer within the Heat exchanger from this fluid to the domestic water.

The conveyor does not switch off yet, as there is still hot water is removed and thus there is still a need for heat supply. Is the temperature gradient at this second temperature sensor in the secondary circuit now run very little or fluctuate around a zero value and the temperature is therefore constant and also above the target value, but it is just fine here not a switch-on criterion: the conveyor is still running.

However, if the hot water supply is now stopped, the primary circuit no longer run the thermal energy of the hot fluid to the process water given because this is already at the appropriate temperature and none additional feed needed. As a result, the fluid flows in the primary circuit run through the heat exchanger without completely losing its heat have, resulting in a very rapid rise in temperature in the area of the first Temperature sensor on the output side of the heat exchanger in the primary circuit run leads. This rising temperature can either be exceeded a setpoint or also by recognizing a temperature gradient as Stop criterion are used and thus stops the conveyor.

A particularly quick response is guaranteed if the respective Temperature sensor provided on the output side of the heat exchanger are. In certain applications, it may even make sense to use the tempe temperature sensor must still be provided within the heat exchanger. The denser the Temperature sensors on the heat exchanger, the faster they can be  Detect temperature changes and thus the emergence of unwanted Prevent cold water areas in the hot water delivery.

The conveyor, in particular a pump, in the primary circuit should follow Possibility in the one leading away from the heat exchanger, i.e. in its outlet side line can be arranged. This causes the conveyor colder primary fluid flows through, especially when at a standstill, which is cheaper for their durability and ease of maintenance. It is be particularly useful if the first temperature sensor between the heat dew shear and the conveyor is arranged.

The arrangement and the method are particularly useful when the warm or hot fluid is provided by a buffer, but the flow of a boiler, a district heating network or the like are also ge is suitable.

When used in connection with a buffer memory, it is preferred if a third temperature sensor is also provided, which is either in the pouf storage tank or in the line from the buffer tank to the heat exchanger det. The control device has a further circuit with which the temperature determined by the third temperature sensor when determining the Setpoint of the temperature at the second temperature sensor is used. In this way, the case can be taken into account that is possible there is not enough warm or hot fluid in the buffer storage, for example when starting up the system for the very first time or simply after previous considerable consumption. It can then be lowered the setpoints of the temperatures on the second temperature sensor prevented be that the buffer continuously releases more content without it is possible at all, the otherwise desired by the control device To reach target values.

Furthermore, it is possible through the invention by observing the stored data temperature in relation to the desired water temperature, a thorough mixing of the memory due to an excessive flow rate of the primary circuit  prevent and maintain standby. For that a diagram of the temperature profile at various measuring points on Heat exchangers and storage in relation to a typical user behavior seeks d. H. there were different amounts of water consumed as well as that Simulated turning on and off of the tap. If the heat storage is not the has the temperature necessary for the target hot water temperature, the Target hot water temperature from the storage tank temperature minus one adjustable difference is calculated. The hot water target temperature is therefore not an absolute value, but - if the storage tank temperature is too low - also dependent on this.

If the storage temperature during operation falls below that for the warm water set point control required temperature level falls, but would Run the pump full to get as close as possible with the maximum available energy to get to the set hot water setpoint. Due to the maxi paint primary flow, the primary return temperature rises unnecessarily high on. This can lead to rapid disintegration or temperature stratification come in the store, causing a further drop in the store temperature Consequence. Therefore, the actual hot water setpoint can be taken from the Storage temperature minus the set difference can be calculated. As a result, the primary flow is exceeded above a desired one This limit is avoided and the storage stratification remains under all loads get driving conditions.

A pump runtime element is useful to after switching on Temperature fluctuations that are regarded as a switch-off criterion could bridge. Furthermore, it is normally chosen so that enough heat energy is pumped into the system to the heat exchanger and thus the hot water outlet to the required temperature bring.

It is also particularly preferred if the conveyor device has a speed-controlled pump and the control device is a circuit points depending on the temperature gradient at the second temperature  sensor also the conveyor speed of the conveyor, for example assign the speed, regulates.

It is also particularly preferred if one or both temperature sensors, preferably together with the heat exchanger within the insulation of the Buffer memory are arranged. This allows the heat exchanger to go to target temperature can be maintained, simply by heat conduction automatically from the buffer storage.

The control device can also be a special combination of various which process steps use. So for a limited period of time For example, a startup control program can be run for 30 seconds provides a constant predetermined speed of the pump, or else one special P-I-D setting that responds very quickly to changes in temperature can. This is precisely the reason why the The target temperature is maintained and cold water holes avoided.

The use of the temperature gradient amount as a switch-on criterion also proved to be useful for the following reason: After the Turning on the hot water tap is in the heat exchanger Process water at a slightly higher level than this a short one Continue the thermal sensor on the output side of the heat exchanger can determine. This effect is, among other things, that due to Kon vection currents on the primary side in the heat exchanger are quite there sets a slightly higher temperature than when the secondary circuit is not running run in the domestic water may be the case. This is usually hardly an effect measurable. However, it has the consequence that after turning on the tap for a brief moment the temperature on the second thermocouple in seconds därkreislauf increases, and very slightly, because the somewhat hotter custom amount of water from the heat exchanger now flows past the thermal sensor. This determines a temperature gradient; that this is positive, plays for the amount of the temperature gradient is irrelevant and thus leads in the re gelungseinrichtung that the conveyor is turned on. This happens at a time when there is a risk of a cold water hole  has not yet arisen, so that it is much faster than when falling below of the setpoint value of the temperature (the second switch-on criterion) dereinrichtung runs and hot fluid in the primary circuit in the heat exchanger brings.

If this effect does not occur, perhaps because there is still no con Influence influence slightly higher temperature level in the heat has set the meta-exchanger, the control device also does so in the case of the temperature gradient, its amount is fixed due to its falling and can react accordingly.

In the following, an embodiment of the invention is based on the drawing described in more detail. It shows:

Fig. 1 is a schematic representation of the invention.

The purely schematic illustration, which shows only the most essential parts of the entire arrangement, shows a primary circuit 10 in the left half and a secondary circuit 20 in the right half.

The primary circuit 10 begins on the left with a device that provides warm or hot fluid, here a buffer store 11 . A line 12 leads from this buffer store 11 to a heat exchanger 5 . After passing through the heat exchanger 5 and releasing the thermal energy therein, the fluid in the primary circuit 10 leads back to the buffer store 11 via an outlet-side line 13 . In the output line 13 , a conveyor device, here a pump 14 is provided, between the heat exchanger 5 and the pump 14 , a first temperature sensor 17 is arranged.

Usually, the hot fluid is removed from the upper region of the buffer memory 11 , fed to the heat exchanger 5 and returned by the pump 14 to the lower region of the buffer memory 11 .

The secondary circuit 20 on the right side begins with a Kaltwasserzu line 22 with which cold process water (drinking water, wash water etc.) is fed to the heat exchanger 5 . In the heat exchanger 5 , the heat energy of the primary circuit 10 running in countercurrent is absorbed. After passing through the heat exchanger 5, the process water leaves it again and flows through an outlet-side line 23 to the hot water discharge point. The promotion in the secondary circuit can take place, for example, in that the cold water supply takes place under pressure and the warm water removal point by a tap blocks this pressure if necessary.

A temperature sensor 27 is located in line 23 for the hot water or actual service water. The temperature sensor 27 thus determines the warm water temperature as close as possible to the heat exchanger 5 .

The temperature sensors 17 and 27 report their values to a control device (not shown).

The same is done by a third temperature sensor 37 , which records the temperature of the hot fluid in the upper region of the buffer store 11 .

The control device then controls the pump 14 , on the one hand the switching on and off and on the other hand also the speed or conveying speed, if applicable.

Claims (14)

1. Arrangement for providing hot water with

• a primary circuit ( 10 ) with a fluid, a device ( 11 ) providing warm or hot fluid and a conveying device ( 14 ) for the fluid,
• - a secondary circuit ( 20 ) for the domestic water to be heated,
• - A heat exchanger ( 5 ) for heat transfer from the fluid of the primary circuit ( 10 ) to the process water in the secondary circuit ( 20 ),
• - A control device for the conveyor ( 14 ) and
• - a temperature sensor ( 17 , 27 ) in the primary ( 10 ) or secondary circuit ( 20 ),

characterized,
that both in the primary circuit ( 10 ) in the heat exchanger ( 5 ) or in the line ( 13 ) on the outlet side with respect to the heat exchanger ( 5 ), a first temperature sensor ( 17 ) and also in the secondary circuit ( 20 ) in the heat exchanger ( 5 ) or in the one with respect to the heat exchanger ( 5 ) a second temperature sensor ( 27 ) is arranged on the outlet-side line ( 23 ),
and that the control device has a circuit which switches on the conveying device ( 14 ) when the temperature drops below a setpoint and / or a setpoint above the temperature gradient amount at the second temperature sensor ( 27 ) and when the temperature rises above a setpoint and / or exceeds a setpoint Temperature gradient amount on the first temperature sensor ( 17 ) switches off the conveyor ( 14 ). 2. Arrangement according to claim 1, characterized in that the conveying device ( 14 ) is arranged in the primary circuit ( 10 ) in the line leading away from the heat exchanger ( 5 ) ( 13 ), the first temperature sensor ( 17 ) between the heat exchanger ( 5 ) and Förderein direction ( 14 ) is arranged. 3. Arrangement according to claim 1 or 2, characterized in that the first and second temperature sensors ( 17 , 27 ) are arranged closely adjacent to the respective outputs of the heat exchanger ( 5 ). 4. Arrangement according to one of the preceding claims, characterized in
that the warm or hot fluid supply device ( 11 ) has a buffer store,
that a third temperature sensor ( 37 ) is provided in the buffer store ( 11 ) or in the line from the buffer store ( 11 ) to the heat exchanger ( 5 ), and
that the control device has a further circuit with which the temperature determined by the third temperature sensor ( 37 ) is used in determining the target value of the temperature on the second temperature sensor ( 27 ). 5. Arrangement according to one of the preceding claims, characterized, that the control device has delay elements, the fluctuating he bridged average temperature values at the temperature sensors. 6. Arrangement according to one of the preceding claims, characterized in that the control device has a circuit which, depending on the speed of the temperature decrease or the Temperaturgradien th on the second temperature sensor ( 27 ) controls the conveying speed of the conveying device ( 14 ) for the fluid. 7. Arrangement according to claim 6, characterized in that the regulation of the conveying speed of the conveyor ( 14 ) is carried out by changing the pump speed in a speed-controlled pump. 8. Arrangement according to one of the preceding claims 4 to 7, characterized in that the first and / or the second temperature sensor ( 17 , 27 ), preferably both, are preferably arranged with the heat exchanger ( 5 ) within the insulation of the buffer store ( 11 ) . 9. A method for providing hot process water, a fluid running in a primary circuit, a device ( 11 ) providing warm or hot fluid and a conveying device ( 14 ) conveying the fluid, - the process water to be heated running in a secondary circuit,

• - The heat from the fluid of the primary circuit ( 10 ) is transferred to the process water in the secondary circuit ( 20 ) in a heat exchanger ( 5 ),
• - The conveyor ( 14 ) is regulated, and
• - a temperature sensor ( 17 , 27 ) is provided in the primary or secondary circuit,

characterized,
that both in the primary circuit ( 10 ) in the heat exchanger ( 5 ) or in the line ( 13 ) on the outlet side with respect to the heat exchanger ( 5 ), and in the secondary circuit ( 20 ) in the heat exchanger ( 5 ) or in the line on the outlet side with respect to the heat exchanger ( 5 ) 23 ) the temperature is measured, and
that when the temperature falls below a setpoint and / or increases above a setpoint temperature gradient in the heat exchanger ( 5 ) or in the line ( 23 ) leading away from the heat exchanger in the secondary circuit ( 20 ), the conveying device ( 14 ) begins to convey the fluid in the primary circuit ( 10 ) , and
that when the temperature rises above a setpoint and / or increases the temperature gradient in the heat exchanger or in the line from the heat exchanger ( 5 ) in the primary circuit ( 10 ), the conveyance of the fluid in the primary circuit is ended. 10. The method according to claim 9, characterized in that the temperature of the warm or hot fluid in the primary circuit ( 10 ) is used in the determination of one or more of the target values. 11. The method according to claim 9 or 10, characterized, that the amount of the temperature gradient to regulate the Förderge speed of the conveyor is used. 12. The method according to any one of claims 9 to 11, characterized, that the temperature gradient amount regardless of the sign of the Temperature gradient is used even in the control.