DE10237681B4 - Plate heat exchanger for gravity circulation in heat storage tanks - Google Patents

Abstract

Plate heat exchanger, in a heat storage with liquid Storage medium is arranged, wherein the plate heat exchanger from a stack of the same size, a grid pattern profiled, flat and rectangular plates exists and respectively two adjacent plates form pairs of plates separated by the each heat storage medium and heat exchange medium flow, wherein the edges the channels, through which heat storage medium flows, are open at the top and bottom, so that the heat storage medium is vertical flows through the dot matrix (1) and discharges into a collection room, the a guide tube for the outflowing Heat storage medium (4), and the adjacent channels, through the heat exchange medium flows (2), each by a arranged at one end inlet pipe and one at the opposite End disposed drain pipe fluid-tightly interconnected and on the edges are closed and have horizontal barriers, the meandering running form horizontal flow channels (3).

Description

The The invention relates to plate heat exchangers, which in heat storage with liquid Heat storage medium be installed and there for the supply or removal of heat energy in countercurrent or Cross-counterflow heat exchanger work, being the liquid Heat storage medium is moved by gravity.

Are known from DE 42 21 668 C2 for stratified storage tank for water heating built-in heat exchanger for energy and / or discharge consisting of a vertical axis and to be heated by the hot water or cooled by solar fluid to be flowed through finned tube coils which are embedded between two closely fitting separation surfaces, so that the heat storage medium flows through the interstices between the coiled tubing and the parting surfaces in the cross-counterflow through the heat exchanger, wherein the channel formed by the separating surfaces opens into a discharge channel, which leads up to a hot water flowing from zuwendendem coiled tubing down and for a traversed by cooled solar fluid coiled tubing upwards , These heat exchangers, in addition to their advantages also some disadvantages. Due to their bulky geometric shape, they are no longer revisable in a closed storage container. If such a heat exchanger is defective or only dirty, it can often only with disproportionate effort again, be repaired. The finned tubes used are made of copper and therefore limited to the chemical usability of copper. The interfaces around the finned tubes are large and must be made of poor thermal conductivity material. For this purpose, plastics are used whose use is limited to temperatures up to 90 ° C. The heat exchangers together with their parting surfaces and the guide tube are multi-part constructions with a relatively high assembly cost and accordingly many malfunctioning options.

Are known from the FR 2 323 119 A also plate heat exchangers, which consist of a stack of equal and uniformly profiled plates in which adjacent plates turn alternately their front sides or their backs and in which the plates in the places where they touch and support against each other, welded or soldered. Such plate heat exchangers made of stainless steel or other metals allow very high heat transfer power densities due to low heat transfer resistance and short heat transfer paths. In this case, the thermal conductivity of the thin plate material plays a much more subordinate role than in heat exchangers, where for the heat flow longer routes through the metal are necessary, as is the case with rib heat exchangers. Feature and at the same time cause their high heat transfer capacity is shear in conventional plate heat exchanger, a relatively high pressure drop between the inlet and outlet of the heat transfer fluids. Therefore, electrical pump power is usually required to pump the heat exchanging fluids between the plates through the plate heat exchanger. Since the flow direction of the liquids can be selected very individually by the arrangement of the connections and by the stamping of the plates, plate heat exchangers can be produced as a DC, cross-flow or countercurrent heat exchanger.

task The invention was to promote the heat storage medium only by gravity Plate heat exchanger Easy to install and remove in a storage tank and despite a very high heat transfer power density Completely made of stainless steel and therefore usable for much higher temperatures than 100 ° C is.

One embodiment The invention will be described with reference to the drawings. Showing:

1 : Plate heat exchanger for gravity circulation, here to remove heat from storage. In the plate heat exchanger for supplying heat, all the arrows are reversed and the guide tube to the collector faces upwards

For this purpose, a plate heat exchanger after 1 and 2 selected, which consists of a stack of equal, uniformly profiled, rectangular plates and in which the plates in the places where they touch and support against each other, welded or soldered.

Through this plate heat exchanger, the heat storage medium flows only by gravity ( 1 ), ie by the density difference of the heat storage medium, which arises when it is warmer or colder within the heat exchanger than outside the heat exchanger. For this purpose, this heat exchanger is arranged in the heat storage interior. The plate pairs through which the heat storage medium flows are open at the top and bottom ( 1 ). The pressure loss at the intended flow rate must not be greater than the resulting due to the density difference and the flow height back pressure, the flow of heat storage medium causes. Due to a special profiling of one side of the panel ( 6 . 7 ) results for the spaces between each two pairs of plates a point connection grid ( 8th ). The heat storage medium flows the shortest vertical path from top to bottom or vice versa through the dot matrix.

Due to the special profiling of the other side of the plate results for the spaces between the other plate pairs in addition to a point connection grid also closed ne horizontal locks ( 9 ) as well as a complete sealing of the plate edges. Thereby, a partial or complete flowing back and forth of the heat exchange medium through the dot matrix along meandering collecting channels ( 3 ) transversely and counter to the flow direction of the heat storage medium ( 2 ), So forced a cross-countercurrent to the heat storage medium.

In order to be able to carry out various optimizations by different distances between the plate pairs through which the heat storage medium flows and those through which the heat exchange medium flows, the plates are profiled at different depths on both sides ( 5 ). With the choice of tread depths and tread shapes, the pressure loss of the heat storage medium can be minimized, the pressure loss of the heat exchange medium limited, the heat transfer capacity maximized, and the total volume of the heat exchanger and heat exchanger contents of both media minimized.

On the one hand to produce a thermal stratification in the heat storage by the operation of the heat exchanger or to obtain an existing stratification and on the other hand to strengthen the gravity drive, the heat storage medium empties after the heat exchange in a collecting space ( 4 ), which merges into a guide tube. The guide tube forces the heat storage medium to flow downwardly from the heat exchanger after cooling and, after being heated, away from the heat exchanger to flow upwards.

1

Heat storage medium flows autosiphonic in the space between each 2 plates of a plate stack

2

the Memory heat removing medium flows in the heat storage medium adjacent space with auxiliary energy along meandering channels

3

Channels for that with Auxiliary power flowing, the memory the heat feeding or withdrawing medium

4

collection device and guide tube for the outflowing Wärmespeichennedium

5

different plate spacings by different embossing depths on both sides

6

Coinage of a Plate type, e.g. the odd one

7

Imprint of the another type of plate, e.g. B. the even-numbered

8th

Flow path between odd and even plate

9

Flow path between even-numbered and odd-numbered plate

Claims (2)

Plate heat exchanger, which is arranged in a heat storage with liquid storage medium, wherein the plate heat exchanger consists of a stack of equal, grid-shaped profiled, flat and rectangular plates and two adjacent plates form pairs of plates through which separate heat storage medium and heat exchange medium flow, the edges the channels through which heat storage medium flows, are open at the top and bottom, so that the heat storage medium flows vertically through the dot matrix ( 1 ) and opens into a collecting space, which has a guide tube for the outflowing heat storage medium ( 4 ), and the adjacent channels through which heat exchange medium flows ( 2 ), fluid-tightly connected to each other by a respective inlet pipe arranged at one end and an outlet pipe arranged at the opposite end, and closed at the edges, and having horizontal barriers which form meandering horizontal flow channels ( 3 ). Plate heat exchanger according to 1, characterized in that the distances between the plate pairs may be different from each other by a different depth of profiling on each plate ( 5 ).