DE102009022704B4 - System comprising a supply line through which a fluid flows, a heat exchanger and a connecting line - Google Patents

Abstract

System comprising a supply line (1) through which a fluid flows, a heat exchanger (2) communicating with a section of the supply line (1), and at least one connecting line (3) for removing part of the fluid flowing through the supply line (1), characterized in that the connecting line (3) has at least two connecting pieces (4a, 4b), one of which in the flow direction and in the flow direction behind the heat exchanger (2) opens into the supply line (1), wherein each of the connecting pieces (4a , 4b) is shut off as required by means of a valve element.

Description

The invention relates to a system having a supply line through which a fluid flows, a heat exchanger connected to a section of the supply line, and at least one connecting line for removing part of the fluid flowing through the supply line.

It is known that laid in the ground supply lines, such. B. fresh water, sewage or natural gas lines to gain energy in the form of heat. For this purpose, a heat exchanger through which a heat exchange medium flows, connected to a portion of a supply line. If the temperature of the heat exchange medium is below the temperature of the fluid flowing in the supply line, heat is transferred from the supply line or from the fluid flowing therein to the heat exchange medium. The thus heated heat exchange medium can then be supplied to a heat pump in which it is further heated for further use, for example for heating residential buildings.

The use of ground-based utility power supply lines, sometimes referred to as "hydrothermal", has the advantage that not only the waste heat from those fluids that are already being fed into the utility line at a relatively high temperature level (e.g. Wastewater), but also the waste heat of fluids, the temperature level at the feed is so low that it is actually not suitable for heat recovery by means of heat exchangers. This suitability results from the fact that the fluid originally fed at a low temperature into the supply line as it flows through the supply lines laid below the earth's surface is brought to a higher temperature level by the absorption of geothermal energy, which can be used accordingly. For this reason, a plurality of heat exchangers (in a defined minimum distance) can be integrated into a single supply line, since the lowering of the temperature of the fluid caused by the heat exchanger is reversed during further flow through the supply line by the absorption of geothermal energy. Thus, hydrothermia is basically a special form of geothermal energy use ("geothermal energy") because, in the end, it mainly uses geothermal energy.

A significant advantage of hydrothermal compared to conventional geothermal energy is the fact that it is not necessary first of all to introduce a large number of geothermal probes into the ground at great expense in terms of work and expense, but recourse is made to already laid or already laid supply lines. The supply lines then only have to be connected to a suitable heat exchanger, which is usually associated with a considerably lower cost than the laying of geothermal probes.

Conventional Hydrothermiesysteme have at least one heat exchanger which is connected to a portion of a supply line, so that a heat transfer from the supply line or from the supply line flowing through the fluid flowing in the heat exchanger medium takes place. Such a system is for example from the DE 10 2007 054 472 A1 known, in which the heat exchanger is modularly integrated into the supply line.

An alternative system is out of the DE-OS 28 34 442 known. In this is provided not to integrate the heat exchanger in the supply line, but to divert a portion of the water from the supply line and supply this part of a heat exchanger.

Since the waste heat of the supply line is usually intended for domestic use, the heat exchangers are regularly integrated directly in the vicinity of the respective building in the supply lines in order to avoid the higher installation costs associated with a supply line over long distances. It follows that the heat exchanger of a building intended for a Hydrothermieanlage is regularly arranged in the vicinity of the connecting line with which this building is supplied with a part of the fluid flowing through the supply line. In particular, in the hydrothermal use of a fresh water supply line care must be taken in the integration of the heat exchanger that this is not integrated directly in front of the connecting line for the corresponding building in the supply line. The drop in the temperature level of the fresh water flowing through the supply line due to the heat exchanger would in fact lead to the building being supplied with correspondingly cooled fresh water. This temperature difference of the fresh water would have to be at least partially compensated by heating before use in the building, whereby the energy savings that is sought with the use of waste heat from the supply line, would at least be reduced. For this reason, the heat exchangers are regularly integrated in the flow direction behind the connecting cable for the respective building in the supply line.

Thereby, the part of the fresh water transported in the supply line to be used for the building is branched off before it is cooled by the heat exchanger. However, such an arrangement of the connecting line and the heat exchanger to each other in a supply line is only possible if a constant flow direction of the fluid is provided in the supply line.

Based on this prior art, the present invention seeks to provide an improved system of a supply line, a communicating with a section of the supply line heat exchanger and at least one connecting line, in which a meaningful use of the waste heat of the supply lines even with changing flow directions of the Fluids is given by the supply line.

This object is solved by the subject matter of independent claim 1. Advantageous embodiments of the system according to the invention are the subject of the dependent claims and will become apparent from the following description of the invention.

A system according to the invention which has at least one supply line through which a fluid flows, a heat exchanger connected to a section of the supply line and at least one connecting line for removal of part of the fluid flowing through the supply line, characterized in that the connecting line has at least two connecting pieces each of which opens in the flow direction before and in the flow direction behind the heat exchanger in the supply lines, wherein each of the connecting pieces is shut off by means of a valve member, if necessary.

The inventive arrangement of at least one connecting piece on each side of the integrated heat exchanger in the supply line and the ability to shut off each of these fittings by means of a valve member, it can be achieved that regardless of the present in the supply line flow direction of the fluid part of the Fluids, which is to be removed via the connecting line, can be removed before the fluid flows through the portion of the supply line, in which the heat exchanger is integrated. In this way, for example, regardless of the direction of flow of fresh water through a fresh water supply line can be ensured that a part of the fresh water to be removed is not diverted until it has been brought by the heat transfer from the fresh water to the heat exchanger to a lower temperature level.

In an advantageous embodiment of the system according to the invention can be provided to integrate at least one valve element in each of the connecting pieces. These valve elements may be simple shut-off valves which either release or shut off the respective connection piece.

Alternatively, however, it can also be provided to connect two connecting pieces to the connection line by means of a three-way valve (eg 3-way ball valve), so that only one valve element is required to control the two connecting pieces.

In a preferred embodiment of the present invention, control means may further be provided which, preferably automatically, shut off the respective connection piece by means of the valve element (s) on whose side, with respect to the heat exchanger, the temperature of the fluid flowing through the supply line is lower. As a result, the effort that would be associated with a manual reversal of the / the valve element / -e be avoided, and which additionally precludes the risk of incorrect operation or at least reduced.

The control means can, for example, rely on measured values of (electronic) temperature sensors, of which, for example, at least one can be integrated into the supply line on each side of the heat exchanger. Based on a difference formation of the measured values of the two temperature sensors, the flow direction of the fluid through the supply line can be determined in a simple manner by means of a computer system, which makes it possible to control the valve element (s) accordingly. Such a mechatronic solution is easy to implement and has a high level of operational reliability.

However, it is also possible to design the control means substantially or exclusively mechanically. For example, a bimetallic element may be provided to control the valve element (s) which more or less deforms depending on the temperature level of the fluid in the respective section and thereby either open or close the associated valve element.

The invention will be explained with reference to exemplary embodiments illustrated in the drawings.

In the drawing shows:

1 in a schematic representation of an inventive system in a first embodiment and

2 in a schematic representation of an inventive system in a second embodiment.

The 1 shows a system according to the invention from a supply line 1 , which is traversed by a fluid, such as fresh water, a heat exchanger 2 and a connection cable 3 about which part of the supply line 1 is diverted fluid to be used, for example, in a building (not shown) for heating purposes.

The connection cable 3 opens into two connecting pieces 4a . 4b , one of which in the flow direction before and one downstream of the heat exchanger 2 into the supply line 1 empties. This applies regardless of the respective flow direction of the fluid through the supply line 1 that can change, as indicated by the arrow 5 is shown. When changing the direction of flow, the relative position of each of the fittings changes 4a . 4b with respect to the heat exchanger 2 , so that the connector 4a . 4b that at a flow through the supply line 1 in a first direction in front of the heat exchanger 2 into the supply line 1 opens, after changing the flow direction now behind the heat exchanger 2 into the supply line 1 empties.

In each of the fittings 4a . 4b is a shut-off valve 6a . 6b and a temperature sensor 7a . 7b integrated, with the temperature sensor 7a . 7b is arranged in each case in that portion of the connecting piece between the shut-off valve 6a . 6b and the mouth of the fitting 4a . 4b into the supply line 1 lies. Regardless of whether the respective shut-off valve 6a . 6b opened or closed, can by means of the two temperature sensors 7a . 7b the temperature of the fluid in the corresponding section of the supply line 1 be measured.

In a first flow direction, the fluid flows through the supply line 1 for example, from left to right (in the 1 ). When flowing through the section of the supply line 1 coming from the heat exchanger 2 is surrounded, finds a heat transfer from the supply line 1 or the fluid flowing therein to a heat exchanger 2 via an inlet 8th supplied heat exchange medium instead, whose temperature is below the temperature of the supply line 1 flowing fluid is located. The heat transfer from the supply line 1 on the heat exchange medium takes place while the heat exchange medium, the heat exchanger 2 flows through. The heated heat exchange medium is then over a drain 9 discharged again and can for example a heat pump (not shown) are supplied, in which this is brought to further use to a further increased temperature level.

Due to the heat transfer from the fluid in the supply line 1 on the heat exchange medium in the heat exchanger 2 the fluid is at the exit from the area of the supply line 1 that of the heat exchanger 2 is surrounded, have a lower temperature than when it enters. This temperature difference can be controlled by means of a control unit 10 by an evaluation of the measured values of the two temperature sensors 7a . 7b determines and from this the flow direction of the fluid through the supply line 1 be determined. The control unit 10 can thereby each the shut-off valve 6a . 6b open, in the flow direction of the fluid through the supply line 1 in front of the heat exchanger 2 lies. As a result, regardless of the respective flow direction of the fluid, always via that connector 4a . 4b a portion of the fluid is branched off and over the connecting line 3 dissipated, in which the temperature is not yet a heat transfer to the heat exchanger 2 was lowered.

The in the 2 illustrated embodiment of a system according to the invention differs from that of 1 only in the nature of the valve element used. While in the embodiment according to 1 in each of the fittings a shut-off valve 6a . 6b is provided in accordance with the embodiment 2 a 3-way valve 6c for use, the two fittings 4a . 4b with the connecting cable 3 combines. The 3-way valve 6c includes a pivotable closure element 11 , Which in the two end positions of the pivoting movement in each case one of the mouths of the connecting pieces 4a . 4b in the 3-way valve 6c closes and the connection of the other connector 4a . 4b with the connecting cable 3 releases. An adjustment of the closure element 11 can manually or - according to the embodiment of 1 - automatically by means of a control unit based on measured values of the temperature sensors 7a . 7b resorted to.

Claims (6)

System with a supply line through which a fluid flows ( 1 ), one with a section of the supply line ( 1 ) associated heat exchangers ( 2 ) as well as at least a connecting cable ( 3 ) for the removal of part of the supply line ( 1 ) flowing fluid, characterized in that the connecting line ( 3 ) at least two fittings ( 4a . 4b ), of which in each case one in the flow direction before and one downstream of the heat exchanger ( 2 ) into the supply line ( 1 ), each of the fittings ( 4a . 4b ) Is shut off as required by means of a valve element. System according to claim 1, characterized in that in each of the fittings ( 4a . 4b ) at least one shut-off valve ( 6a . 6b ) is integrated. System according to claim 1, characterized by a 3-way valve ( 6c ), with which the connection line ( 3 ) with the fittings ( 4a . 4b ) connected is. System according to one of the preceding claims, characterized by control means which automatically automate that fitting ( 4a . 4b ) by means of the / the valve element / -e shut off, on its side, relative to the heat exchanger ( 2 ), the temperature of the supply line ( 1 ) flowing fluid is lower. System according to claim 4, characterized in that on each side of the heat exchanger ( 2 ) a temperature sensor ( 7a . 7b ) into the supply line ( 1 ) whose measured values are used by the control means for controlling the valve element (s). System according to claim 4, characterized in that the control means comprise a bimetallic element for controlling the valve element (s).

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