AT513841B1 - Method for heating buildings - Google Patents

Abstract

The invention relates to a method for heating buildings, comprising a heating boiler (1), a buffer store (4) and at least one consumer (9), in which a heat transfer medium from a boiler feed line (2) is led into an upper area of the buffer store (4) and the consumer (9) is supplied with heat carrier medium from the upper area of the buffer store (2). According to the invention, this is achieved by guiding the return (13) of the consumer (9) to a branching point (6) connected on one side to a boiler return (7) and on the other side to a multi-way valve (14) connected between several return ports ( 15a, 15b, 15c, 15d) of the buffer memory (4) is switchable, which are arranged on the buffer memory (4) at different levels.

Description

Austrian Patent Office AT 513 841 B1 2014-08-15

The invention relates to a method for heating buildings, with a boiler, a buffer tank and at least one consumer, in which a heat transfer medium from the boiler flow in the upper part of the buffer memory is performed and the consumer with heat transfer medium from the upper Area of the buffer memory is supplied.

It is desirable or necessary in many cases to equip heating systems with buffer storage. By using a buffer storage, increased flexibility in the operation of the boiler is achieved. It is also possible to integrate alternative heat sources, such as solar systems in the heating system. The use of log boilers also requires operation using a buffer tank.

The requirements of a buffer memory are that in the various operating conditions each undisturbed temperature stratification is maintained so that on the one hand in the uppermost area always heat transfer medium with high temperature is available, but on the other hand in the lower area - apart from the state full Charge - Low temperature heat transfer medium.

In order to disturb this temperature stratification as little as possible so-called stratified charge systems have been developed in which the return to the buffer by flow internals, such as layer tubes or the like is solved so that the recycled heat transfer medium is primarily conducted in the areas of the buffer memory, the have about the temperature that has the recycled heat transfer medium. A major disadvantage of such layer loading systems is that there is a dependence of the layer function of mass flow or of the flow velocity of the heat transfer medium. If this flow rate is too high, then the temperature zones are mixed and thus disturbed or destroyed the stratification.

Another constraint of heating systems with buffer memory is that it is usually necessary to take measures for corrosion protection in the boiler. When using non-condensing boilers, it may happen due to the large volume of heat transfer medium that in certain operating conditions too low exhaust gas temperature is reached, so that on the heat exchanger surfaces condensate occurs, resulting in corrosion. This considerably reduces the service life of boilers. Modern heating systems are therefore often equipped with special control devices, which have the task of not lowering the temperature of the recirculated heat transfer medium to avoid condensation in the boiler. This causes due to the required mixers and control devices increased structural complexity and thus increased costs.

The object of the present invention is to avoid these disadvantages and to provide a method which requires a low structural complexity of the heating system, the buffer memory optimally uses, in particular the lowest possible disruption of temperature stratification, and in the separate measures to avoid of condensation in the boiler are not required.

According to the invention it is provided that the return of the consumer is guided to a branch point, which is connected on the one hand with a boiler return and on the other hand with a multi-way valve which is switchable between a plurality of return ports of the buffer memory, which are arranged on the buffer memory at different heights ,

Essential to the present invention that both the return of the consumer return and the removal of heat transfer medium from the buffer storage for the heating return can be actively controlled by the multi-way valve, on the one hand to maintain the best possible temperature stratification and on the other hand to avoid condensation in the boiler safely to be able to. This represents an advantage over known solutions with baffles or the like.

It is particularly advantageous if the switching of the multi-way valve is temperature-controlled. By detecting the temperature at different heights of the buffer memory, optimal operation can be ensured.

A particularly efficient maintenance of the temperature stratification can be carried out in that the return of the heat transfer medium from the consumer return is in each case to a location of the buffer memory whose temperature corresponds approximately to the recirculated heat transfer medium.

The present invention also relates to a heating system for heating buildings, with a boiler, a buffer tank and at least one consumer, with a boiler flow, which leads from the boiler to a flow connection in the upper part of the buffer tank, flow of the consumer, the from leading to the consumer, and with a boiler return.

According to the invention it is provided that the boiler return is connected to a branch point from which branches off a return line which is connected to a multi-way valve having a plurality of terminals which are each connected to a return port in the buffer memory, and that the return ports are arranged at different heights in the buffer memory. Such a device is best suited to carry out the method described above.

Preferably, a lower return port is provided at the lowest point of the buffer memory and an upper return port is provided at the level of the flow port of the buffer memory. In this way, the entire contents of the buffer memory can be used as needed.

Optionally, a plurality of buffer memory may be provided and that a plurality of return ports are provided in each buffer memory, which are connected to the multi-way valve. In this way it is possible to increase the buffer capacity while optimally utilizing the available temperature levels.

As a result, the present invention will be explained in more detail with reference to the embodiment shown in FIG.

A boiler 1 powered by a boiler feed line 2, in which a boiler pump 3 is arranged, a buffer 4. The boiler feed line 2 opens into the buffer memory 4 in a flow connection 5, in the upper part of the buffer memory 4 lies.

From a branch point 6, a boiler return line 7 leads back to the boiler. 1

Also in the upper part of the buffer 4, a consumer flow connection 8 is provided, from which a consumer 9 is supplied via a flow 12 of the consumer 9 and a mixing valve 11 and a consumer pump 10 with hot heat transfer medium. Via a return line 13 of the consumer 9, the heat transfer medium is returned to the branching point 6.

From the branch point 6 is further a return line 16 to a multi-way valve 14, from which a plurality of return ports 15a, 15b, 15c, 15d are supplied, which are arranged at different heights in the buffer memory 4.

In the following, the operation of the device according to the invention is explained in more detail: Basically, the temperature of the heat transfer medium in the buffer memory 4 is continuously monitored at different heights by temperature sensors, not shown.

If the buffer is charged by the boiler, without any significant heat demand at the consumer, then the multi-way valve 14 is controlled so that over the 2/5 Austrian Patent Office AT 513 841 B1 2014-08-15

Boiler return 7 Heat transfer medium is sucked from a return port, which is sufficiently cool to ensure proper operation of the boiler 1, but on the other hand is sufficiently warm to prevent formation of condensate in the boiler 1. Optionally, the multi-way valve 14 can be brought into an intermediate position to suck heat transfer medium from two adjacent return ports, so that return temperatures can be displayed, which lie between the respective temperatures at the return ports. In this operating state, the heat transfer medium flows from the multi-way valve 14 in the return line 16 to the branch point.

When the consumer 9 is supplied with heat from the buffer memory 4 and the boiler 1 is not in operation, the heat transfer medium is removed from the flow connection 8, placed in the mixing valve 11 with the return to a suitable temperature and ultimately through the return 13 of the Consumer 9 led to the branching point 6. The multi-way valve 14 is controlled so that the heat transfer medium is appropriately returned to the buffer memory 4, i. if possible at the point where the temperature corresponds to that of the returned heat transfer medium.

In this way, an optimal operation can be ensured. 3.5

Claims (7)

Austrian Patent Office AT 513 841 B1 2014-08-15 Patent 1. A method for heating buildings, comprising a heating boiler (1), a buffer store (4) and at least one consumer (9), in which a heat transfer medium from a boiler feed ( 2) is guided into an upper region of the buffer reservoir (4) and the consumer (9) with heat transfer medium from the upper region of the buffer memory (2) is supplied, characterized in that the return (13) of the consumer (9) to a branch point (6) is connected, on the one hand with a boiler return (7) and the other with a multi-way valve (14), which is switchable between a plurality of return ports (15a, 15b, 15c, 15d) of the buffer memory (4), the Buffer memory (4) are arranged at different heights. 2. The method according to claim 1, characterized in that the switching of the multi-way valve (14) is temperature-controlled. 3. The method according to any one of claims 1 or 2, characterized in that the return of the heat transfer medium from the return line (13) of the consumer (9) in each case to a location of the buffer memory (4), whose temperature corresponds approximately to the recirculated heat transfer medium. 4. Heating system for heating buildings, with a boiler (1), a buffer memory (4) and at least one consumer (9), with a boiler flow (2) from the boiler (1) to a flow connection (5) in leading the upper portion of the buffer memory (4), flow (13) of the consumer (9), which leads from the upper portion of the buffer memory (4) to the consumer (9), and with a boiler return (7), characterized in that the Boiler return (7) to a branch point (6) is connected, from which a return line (16) branches, which is connected to a multi-way valve (14) having a plurality of terminals, each with a return port (15a, 15b, 15c , 15d) in the buffer memory (4) are connected, and that the return ports (15a, 15b, 15c, 15d) are arranged at different heights in the buffer memory (4). 5. Heating installation according to claim 4, characterized in that a lower return port (15d) at the lowest point of the buffer memory (4) is provided and that an upper return port (15a) in the height of the flow port (5) of the buffer memory (4) is provided , 6. Heating installation according to one of claims 4 or 5, characterized in that at least three return connections (15a, 15b, 15c, 15d), preferably four return connections (15a, 15b, 15c, 15d) are provided. 7. Heating installation according to one of claims 4 to 6, characterized in that a plurality of buffer memory (4) are provided and in each buffer memory (4) a plurality of return ports (15a, 15b, 15c, 15d) are provided, which with the multi-way valve (14 ) are connected. 1 sheet of drawings 4/5