DE102014106155B4 - Control heating - Google Patents

Abstract

Control heating (1), with an internal heating circuit (5), which can be connected to a district heating network via a flow (3) and a return (4), with one between the flow (3) and the return (4) in the heating circuit ( 5) connected electric heater (2) for direct heating of the heat transfer medium circulating in the heating circuit (5) and with a control element (6) with which the composition of the heat transfer medium circulating in the heating circuit (5) can be influenced.

Description

The invention relates to a control heating system, in particular for use in connection with a combined heat and power unit (CHP) or combined heat and power (CHP) systems for the control energy market.

The expansion of renewable energies leads to higher fluctuations in the power grid. In order to compensate for these fluctuations, the network operators need so-called balancing energy. If there is a higher demand for more electricity, additional electricity must be fed in (positive control energy). If more electricity is available than is currently being used, electricity must be taken from the grid for a short time (negative control energy). This can be done either by withdrawing or reducing the feed.

Operators of CHPs can provide this “negative control energy” by taking the CHP off the grid and thus relieving the power grid. However, since CHP systems are usually designed for continuous operation, they are unnecessarily burdened with such short-term shutdowns.

From the DE 10 2012 108 496 A1 an energy converter device and a method for providing control power is known, with which energy carriers electricity and gas are converted into final energy electricity and heat a heat transfer medium is heated to the heat, and / or a gas heating device for heating a heat transfer medium. A control device is also provided. The control device controls the supply of energy to the electric heating device, the power heat coupling device and / or the gas heating device in such a way that the intensity of the operation of the electric heating device, the combined heat and power device and / or gas heating device is automatically controlled in order to provide the desired amount of heat and / or electricity. The control device is designed in such a way that the desired amount of heat and / or electricity can be provided with different ratios of the energy carriers, so that at least the consumption of one energy carrier can be increased or decreased if necessary.

One object of the present invention is to make it possible to provide negative control energy in continuous operation. This object is achieved by a control heater according to claim 1 or a CHP plant according to claim 8.

Advantageous embodiments of the invention are specified in the subclaims.

The control heating according to the invention works according to the “power to heat” principle and is used for flexible removal of excess energy from the power grid. It therefore makes an important contribution to grid stability in the case of strongly fluctuating renewable energies, in particular wind energy and photovoltaics.

With regular heating, excess electricity from the grid can be converted into heat in a meaningful way in a few seconds. Fluctuations in the power grid can be compensated. The control heating is used to provide negative energy capacities on the control energy market. In particular, operators of CHPs can undertake to provide negative control energy and receive a corresponding remuneration for this.

With the help of the invention, the CHP does not have to be switched off completely. Instead, it can continue driving with a reduced load. However, the electricity that continues to be generated does not enter the supply network, but is taken from the control heating system according to the invention and ensures continuous operation of the connected district heating network. In other words, with the aid of the invention, the CHP unit can permanently provide hot water, which is of central importance for the reliable operation of district heating networks. At the same time, the CHP technology is spared, since complete shutdowns are no longer required.

It is of particular advantage that it is possible with the help of the control heating according to the invention to always feed the district heating network with a defined flow temperature.

At the same time, the material of the electric heater used is spared.

In summary, the invention relates to a control heating in which only a certain amount of a heat carrier is taken from the district heating network, sent with a high volume flow through an electric heater, gradually heated in an internal circuit of the control heating and released back to the district heating network when the desired flow temperature is reached becomes. The volume of heat transfer medium taken from the district heating network and fed into the internal circuit of the standard heating system is varied in such a way that a preset flow temperature can be achieved with a defined spread regardless of the return temperature.

These and other advantages are illustrated below using an exemplary embodiment of the invention explained in more detail with reference to the drawings. Here, the only figure shows a control heater according to the invention. The figure shows the invention not to scale, only schematically and only with its essential components. The same reference symbols correspond to elements with the same or comparable function.

In conventional electrical heating systems, which are used as a power-to-heat system, the heat transfer medium, for example water, flows from the district heating network through an electrical heater and leaves the heater through the flow after a single pass through the heater. In order to achieve the desired temperature spread between return and flow, the volume flow through the electric heater is often very low, which results in high surface temperatures on the individual heating elements of the electric heater. As a result, these heating elements are energetically heavily loaded. If the heat transfer medium begins to boil, air bubbles form on the heating elements, so that the heat transfer medium loses contact with the heating elements. The "hot spots" that then occur can lead to negative changes or damage to the material of the heating elements.

With regular heating 1 According to the present invention, on the other hand, there is usually not just a single pass of the heat transfer medium through the electric heater 2 . The heater according to the invention 1 is designed in such a way that the heat carrier can circulate in the heating system. In other words, the heat carrier can be the electric heater 2 also run through several times. For this purpose, there is a lead time 3 and rewind 4th an internal, self-contained heating circuit 5 intended. The heat transfer medium is heated for as long, ie as often by the electric heater 2 until the desired flow temperature Tv (target temperature) is reached. This means that the volume flow must go through the electric heater 2 no longer be set so low that a single pass is sufficient to reach the flow temperature Tv. Instead, such a large volume flow can go through the electric heater 2 can be set so that there are no significant thermal loads on the heating elements in the electric heater 2 comes. The volume flow through the electric heater 2 is typically in the order of about 0.2 cubic meters per hour and kilowatt of heating power. High volume flows in a range of 0.1 to 0.3 cubic meters per hour and kilowatt of heating output are particularly advantageous. In a system with a heating output of 300 kW, the volume flow through the electric heater is 2 typically around 50 cubic meters per hour. The surface temperatures on the heating elements are reduced accordingly. Overall, this significantly extends the service life of the heating elements. At the same time, the individual heating elements are loaded very evenly and the heat is evenly removed as the heat transfer medium flows along the heating elements.

Operation preferably takes place at a constant temperature difference (spread) between the return temperature Tr and the flow temperature Tv. With the help of a rule element 6 only so much of the heat transfer medium in the internal circuit 5 the heater 1 let in, as required to achieve the desired flow temperature Tv.

If the return temperature Tr is particularly low, only a comparatively small amount of the heat transfer medium is removed from the return 4th into the internal heating circuit 5 introduced while the bulk of itself in the heating circuit 5 located heat transfer medium already one or more times the electric heater 2 has flowed through. The amount of heat transfer medium used by the heater is correspondingly low 1 over the forward 3 is returned to the district heating network. If, however, the return temperature Tr is close to the desired flow temperature Tv, the control element can 6 continuously a large amount of the heat carrier from the return 4th into the internal heating circuit 5 record and there will only be a small proportion of already heated heat transfer medium in addition to the newly added heat transfer medium before passing through the electric heater 2 mixed in. In this case, a large part of the heat transfer medium runs through the electric heater 2 so only once.

The volume of heat transfer medium that is passed through the electric heater 2 runs through is, in other words, always greater than the heat transfer volume that the control heater according to the invention 1 to the district heating network or the heat transfer volume that comes from the district heating network of the regular heating 1 is fed.

As an electric heater 2 An electric flange heater is preferably used, designed for direct heating of the heat transfer medium. This heating element, designed in the manner of a flow heater, consists of a flow housing through which the heat transfer medium can flow and a bundle of heating elements that work as resistance heating. The operation of the electric heater 2 takes place with the electricity generated by the CHP or CHP system, which is not to be fed into the power grid.

The entrance 8a of the electric heater 2 is via an intermediate pump 7th with the rewind 4th connected. The exit 8b of the electric heater 2 is in connection with the advance 3 . Between exit 8b and forward 3 branches off a connector 9 off that the forerunner 3 with the rewind 4th about the regulation 6 in the form of a 3-way valve with actuator 10 connects and the internal cycle 5 closes. The rule element 6 regulates the amount of the return flow 4th in the heating circuit 5 the volume of the heat transfer medium to be admitted and thus the temperature of the heat transfer medium according to the flow temperature Tv specified as the target temperature.

The regulation of the regulating element 6 takes place, for example, by a PLC control (not shown) which controls the control element 6 and with it the regular heating 1 regulates according to the control energy quantities requested by an electricity marketer.

When the required flow temperature Tv is reached, the flow 3 a defined amount of the heat transfer medium is returned to the district heating network. At the same time, the control element 6 a corresponding amount of heat transfer medium via the return 4th from the district heating network into the internal circuit 5 the regular heating 1 brought in.

In contrast to the solutions known from the prior art, in the invention only a certain amount of the heat transfer medium is taken from the district heating network, with a high volume flow through the electric heater 2 skillfully and thereby, in the internal cycle 5 the regular heating 1 , gradually heated and returned to the district heating network when the desired flow temperature Tv is reached. The heat transfer medium is drawn from the return again 4th only when the desired flow temperature Tv is reached and only to the extent that the heat transfer medium is returned to the district heating network.

The rule element 6 changes its position according to the prevailing conditions of the power grid in such a way that the desired temperature spread of, for example, 5K can be achieved. The one taken from the district heating network and into the internal circuit of the standard heating 1 The heat transfer volume fed in thus varies in such a way that the preset flow temperature Tv can be achieved with this spread (e.g. 5K).

The control of the control heating is preferably designed in such a way that the desired flow temperature Tv (setpoint temperature) is raised as soon as the return temperature Tr corresponds to the flow temperature Tv or approaches it too closely. This ensures that heating output from the electric heater 2 can be carried out. It can be provided that the flow temperature Tv is always set so that there is a defined minimum temperature difference to the return temperature Tr.

The use of the control heater according to the invention is not linked to the operation of a CHP unit. Other areas of application are also possible, especially in energy supply systems without a CHP.

All of the features shown in the description, the following claims and the drawing can be used individually. and be essential to the invention in any combination with one another.

List of reference symbols

1

Control heating

2

Electric heater

3

leader

4th

Rewind

5

Heating circuit

6

Control element, 3-way valve

7th

pump

8a

entrance

8b

output

9

Connector

10

Actuator

Claims (8)

Control heating (1), with an internal heating circuit (5), which can be connected to a district heating network via a flow (3) and a return (4), with one between the flow (3) and the return (4) in the heating circuit ( 5) connected electric heater (2) for direct heating of the heat transfer medium circulating in the heating circuit (5) and with a control element (6) with which the composition of the heat transfer medium circulating in the heating circuit (5) can be influenced. Control heating (1) Claim 1 , in which the composition of the heat transfer medium can be influenced with the control element (6) in such a way that the heat transfer medium circulating in the heating circuit (5) is composed of a portion of the flow stream leaving the control heating (1) and a portion of the flow entering the control heating (1) Return flow composed. Control heating (1) Claim 1 or 2 , in which the composition of the heat transfer medium entering the electric heater (2) can be influenced with the control element (6). Control heating (1) after one of the Claims 1 to 3 , in which the composition of the heat carrier flow can be influenced by the control element (6) in such a way that a desired flow temperature (Tv) can be achieved independently of the return temperature (Tr) with a constant spread. Control heating (1) Claim 4 , at which the flow temperature (Tv) is increased as soon as the return temperature (Tr) corresponds to the flow temperature (Tv) or approaches it beyond a minimum distance. Control heating (1) after one of the Claims 1 to 5 , in which a volume flow through the electric heater (2) in a range of 0.1 to 0.3 cubic meters per hour and kilowatt of heating power can be set to avoid thermal loads on the heating elements. Control heating (1) after one of the Claims 1 to 6 , designed to provide negative control energy for a CHP or CHP system or the like. CHP or CHP system with a control heater (1) according to one of the Claims 1 to 7th .

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