EP1496319A1 - Heat exchanger having a ceramic bottom - Google Patents

Abstract

A heat exchanger is supported on an insulating base (24) shaped to collect condensed water. A heat storage element (25) is incorporated into the base, in contact with the collected water in order to evaporate same and prevent the accumulation of impurities, fungus etc. The heat storage element can be made from a variety of materials including ceramic, glass and metals and is positioned centrally under the heat exchanger. The specific thermal capacity of the heat storage element is at least 0.7 kilo Joules per Kg per deg. K. The insulating base and the heat storage element can be joined by clip fastening.

Description

The invention relates to a heat exchanger with ceramic floor according to the preamble of the main claim 1.

There are already such a standing heat exchanger, for example, with the DE 101 21 805 A1, and it is also known, standing Place heat exchanger on a ceramic floor. With seizure of Condensation is also known, the condensation in a pot-shaped Derive ceramic floor.

The use of a ceramic floor is therefore known in the art Preferably, to prevent the condensation water corrosion phenomena exercises. Now it has been shown that in the cup-shaped ceramic floor the Condensation stops and undesirable effects unfold. On the one hand There forms a swamp with corresponding odor nuisance, and on the other can also form dangerous germs.

The invention is therefore based on the object, a known per se Insulation floor, in particular a ceramic floor for a heat exchanger so educate that settling a swamp and the formation of harmful Germs is avoided.

To achieve the object, the invention is characterized in that the insulation floor at least one insulation element with reduced specific Thermal conductivity and at least one heat storage element with increased includes specific heat storage capacity, wherein the at least one Heat storage element is located closer to the heat exchanger, as the at least one isolation element.

Advantageous developments of the invention are the subject of the dependent claims.

In a first preferred embodiment it is provided that at least in Bottom area of the ceramic floor is arranged a heat-storing disc, which is at least partially wetted by the settling liquid.

With the given technical teaching results in the significant advantage that by Arrangement of a heat-storing disc, although condensation is still in the cup-shaped ceramic floor flows, but that because of the Heat storage capacity of this disc (which consists, for example, of a firebrick) now there is a possibility that the firebrick by the previously heated Heat exchanger has heated up so much that he then there in the bottom area incoming condensed water heats and evaporates.

So it is a heat storage stone in the bottom of the Ceramic disc is arranged and which ensures that eventually in the Floor area flowing condensate immediately evaporates again. So it will be avoiding the formation of an undesirable swamp in this area, so also a corresponding odor nuisance and the development of corresponding disease-causing germs.

In a preferred embodiment, the heat-storing disc preferably from a firebrick. However, the invention is not limited. It can also consist of other materials, such. B. the known lava stones or other high heat storage capacity Material, in particular a metal material.

Incidentally, the invention is not limited to the heat-storing Material is arranged only in the bottom region of the ceramic disc. It can be in one other design also be provided that the entire floor area a heat-storing material is formed or that instead of the Ceramic disk as such, which the collecting container for the condensed water forms, from home already a heat-storing material is used.

The flame of the flame generator of the heat exchanger acts down, and Although centered on the bottom area, with the ceramic disc below the bottom horizontal connection pipe is arranged, or below the bottom plate. The Ceramic disc is thus just below the bottom horizontal Connecting tube disposed, or below the bottom plate, and the flame is now focused exactly on the center of this ceramic pot and thus exactly centric on the heat-storing disc, which is arranged in the middle. Therefore warmed up This heat-storing disc as a firebrick to red hot and holds its stored heat for a long time upright, even if the surrounding Ceramic material has long since cooled down.

This leads to because of the high heat storage capacity of the Heat accumulator possibly reaching the ground area Condensation liquid evaporates quickly, leaving a deposit of Condensate is avoided with certainty.

A further preferred embodiment of the invention provides that no heat-storing disc is arranged approximately in the middle region of the ceramic pot, but that the ceramic pot has different dense areas, wherein preferably, a dense heat-storing area in the central area of the Ceramic pot is arranged and this is a material compression is.

So there is no other kind of material in this further embodiment Form of a heat-storing disc can be used, but also the Ceramic pot as such can be formed heat-storing by being Material as such in the center area with higher heat storage property is formed, as comparatively in the edge region.

Advantage of the measure that the heat storage directly in the material itself is the fact that there is a smooth transition from the heat-storing denser interior to the exterior less heat-storing area results, allowing a more continuous heating of the entire ceramic disk is given. By the way, this part is also off manufacturing reasons easier to produce, as a two-piece part with a middle inner heat-storing disc.

In the following, the invention is based on several execution paths explaining illustrative drawings. Here are the drawings and its description further features, advantages and applications of the invention out.

Figur 1:

Schnitt durch einen Wärmetauscher ohne Einbauten;

Figur 2:

Schnitt durch den Keramiktopf mit eingelegtem Schamottstein nach Figur 1;

Figur 3:

Perspektivische Darstellung des Schamottsteins nach Figuren 1 und 2;

Figur 4:

Schnitt durch den Keramiktopf mit verdichtetem Mittenbereich gemäß einer anderen Ausführungsform.

Show it:

FIG. 1:

Section through a heat exchanger without internals;

FIG. 2:

Section through the ceramic pot with pickled firebrick to Figure 1;

FIG. 3:

Perspective view of the firebrick according to FIGS. 1 and 2;

FIG. 4:

Section through the ceramic pot with compressed center region according to another embodiment.

FIG. 1 schematically shows a stationary heat exchanger. On the Further explanations, the function and the other installations will be published again refer to the disclosure of DE 101 21 805 A1, the full content of the The disclosure of the present application is intended to be encompassed.

The heat exchanger of Figure 1 consists essentially of a radially inner Heating coil 2, which defines an approximately cylindrical interior 13. This inner Heating coil 2 is placed and supported on a bottom plate 1, which here also serves as a baffle element for deflecting the hot gases.

At a distance from the inner heating coil 2 is radially outwardly an outer Heating coil 3 is arranged.

About a flame, not shown, which is approximately in the direction of arrow 14 in Figure 1 in the interior of the heat exchanger acts, the hot gases now flow into the Arrow directions 19 around the lower part of the inner heating coil 2 around, are deflected and then flow in the direction of arrow 9 upwards and through the Space 11 between the inner heating coil 2 and the outer Heizwicklung 3. The deflection takes place here in the area of the bottom plate. 1

In the area of the flame deflection section, the outer heating coils 3 are still arranged vertically one above the other, and they form no intermediate gap. she form in this area a continuous wall around the still possibly existing heating flame in this area to maintain. Only at a distance of the bottom plate 1 captures the baffle-like arrangement of the heating coils outer heating coil 3 on.

Between the inner and the outer heating coil 2, 3 evenly on the circumference distributed web plates 4 arranged.

The connection between the inner heating coil 2 and the outer heating coil 3 via connecting tubes 7, 8. The two heating coils 2, 3 are with each other via the connecting pipes 7, 8 and in each case by connections 5, 6 with Hot and cold water connected. The cold water flows over the Cold water connection 5 in the heat exchanger, flows through the radially inner Heizwicklung 2 up to the bottom plate 1 and occurs in this area already preheated in the radially outer heating coil 3, then flows through the Heating coil 3 under further heating, and enters via the hot water connection 6 again from the heat exchanger. Alternatively, of course, one reverse flow direction possible, in which the cold water over the Connection 6 is switched on and the hot water flows out via connection 5. Depending on which, whether predominantly DC heat exchange or countercurrent heat exchange should be present, the flow direction of the water is chosen, in the first case the DC heat exchange predominates, in the second case the countercurrent heat exchange.

As already mentioned, the heating gas flows in the direction of arrow 10 in the flow channel 11, which is bounded by the inner heating coils 2 and the outer Heizwicklungen 3. It comes here to a first, smaller heating of the in Arrow direction 10 flows and a larger and more intense heating current, which, the formed between the heating coils of the outer heating coil 3 Flow channels 23 baffled interspersed and approximately in the direction of arrow 20 flows through. This leads to a longer residence time of the hot gases the respective outer periphery of the heating coils of the outer heating coil 3 and thus to an improved heat transfer. The efficiency of the Heat exchanger is thus significantly increased.

The web plates 4 have a straight end edge 18 which faces radially inwardly, at the associated, radially outwardly facing surfaces of the inner heating coil 2 is present. In this area welded joints 21 are made. Of the rectilinear front edge 18 in the web plate 4 are correspondingly opposite lying recesses 15, 16, 17 assigned to which the radially outer Heizwicklung 3 also with the web plate 4 by means of welds 22nd are connected.

Below the bottom plate 1 or instead of the bottom plate 1 is now the Insulation plate 24 according to the invention arranged for thermal insulation after down to collect the condensate from the heating coils dripped down, but also for evaporation or evaporation of this condensate.

The insulation plate 24 is here as a heat-insulating cup-shaped ceramic plate executed, in the center of a heat-storing heat storage disc 25th is introduced. The pot-shaped insulation plate 24 has an edge 26 which extends axially from a vertical bottom portion 27 rises, creating a receiving space 28 for Condensation is defined.

The insulation plate 24 is shown in more detail in Figures 2 and 3, wherein all components and components of the insulation plate 24 are rotationally symmetrical. This but is not to be construed restrictive, so that the shape of the insulation plate 24th and their components and components can be formed almost arbitrarily. The cylindrical shape but has cost advantages in manufacturing and assembly, so that this is preferred.

The vertical edge 26 here has about the same absolute height as the bottom 27 and is connected to this via a ring-circumferential slope 32 in a Rounding rounding passes 29, so that the dripping from above Condensation can run better into the center of the receiving space 28 and In addition, the evaporation / evaporation is improved. In addition, it will Corners between bottom 27 and edge 26 are avoided, in which germs adhere could.

The heat-storing heat storage disk 25 is integrated centrally in the bottom 27, here glued all-round, whereby also pressings are possible or all kinds friction or positive connection method. Also, the Heat storage disk 25 even with play in the receiving opening of the soil be inserted so that then depending on the application, different Heat storage discs 25 with different heat storage capacity can be introduced and these are also exchanged if necessary can.

The height of the heat storage disk 25 corresponds to about half the height of the Bodens 27, the diameter of the heat storage disc 25 corresponds approximately to one Third of the diameter of the bottom 27 of the insulating plate 24th

Of course, all of the above dimensions can vary widely and are described here only as an example.

At the upper edge 26 of the insulation plate 24, the outer diameter is a diameter-reducing circumferential radial groove 30 introduced, the one heat-resistant sealing ring 31 receives, for tight connection with the Heat exchanger in place of or below the bottom plate 1 of the heat exchanger.

In Figure 3 it can be seen that the entire insulation plate 24 and also in it embedded heat storage disk 25 are rotationally symmetrical.

The insulation plate 24 is preferably provided as Isokeram 1250C. The Heat storage disk 25 is preferably provided as firebrick, class A35pSt3, and is re-pressed. The sealing ring is preferred as Isokeram cord provided and in particular six times on the outer circumference of the insulation plate 24th stapled.

Figure 4 shows yet another embodiment of the invention, in which a Isolation plate 33, the properties of the two components 24 (insulation plate) and 25th (Heat storage disc) united within a single element, namely the Heat insulation and heat storage. This is due to different density Achieved areas 34, 35, wherein the central center region 35 of higher density for the Heat storage and evaporation / evaporation of condensed water responsible is the annular region 34 arranged annularly around this center region 35 lower density is responsible for the thermal insulation. The two areas 34, 35 are preferably made of the same material, in particular ceramic consists.

Furthermore, it can be seen that the denser region 35 is not up to the bottom surface 36 of the Insulation plate 33 is sufficient, but that here the material 34 with lower density is present. The higher density material 35 is thus provided approximately in the area as well as the heat storage disk 25 in the first embodiment.

The insulating plate 33 in turn has the same or similar shape, as the insulating plate 24 of the first embodiment, namely a Receiving space 28, rounding 29 with bevel 32, groove 30 for receiving the Ring cord 31, but the recess is missing to accommodate the heat storage disc 25th

In summary, the invention thus relates to a heat exchanger with bottom, the partly increased heat-insulating and partly increased heat-storing, and the in particular from an annular, increased insulating ceramic pot with a centrally contained therein increases heat-storing firebrick. This will ensure that by evaporating the bottom of the soil Trapped condensate of the heat exchanger whose heating coils always remain dry and corrosion of the heating coils is avoided, as well as the Soil is freed from condensate, allowing germination but also overflowing is avoided and thus a related maintenance is not necessary.

drawing Legend

1

baseplate

2

inner heating coil

3

outer heating coil

4

web plate

5

connection

6

connection

7

connecting pipe

8th

connecting pipe

9

arrow

10

arrow

11

Flow channel (between 2 and 3)

12

front edge

13

inner space

14

arrow

15

recesses

16

recesses

17

recesses

18

front edge

19

arrow

20

arrow

21

welded joint

22

welded joint

23

Flow channel (between turns of 3)

24

insulation plate

25

Heat storage disc

26

edge

27

ground

28

Storage room for condensation

29

curve

30

groove

31

seal

32

slope

33

insulation plate

34

Low density area

35

High density area

36

floor area

Claims (18)

Heat exchanger having an insulating floor, characterized in that the insulating floor (24, 25; 33, 35) comprises at least one insulating element (24, 33) with reduced specific thermal conductivity and at least one heat storage element (25, 35) with increased specific heat storage capacity, wherein the at least one heat storage element (25, 35) is arranged closer to the heat exchanger, as the at least one insulation element (24, 33). Heat exchanger according to claim 1, characterized in that the specific thermal conductivity of the insulating element (24, 33) is approximately in the range of 1.0 W / m * K or less, and the specific heat storage capacity of the heat storage element (25, 35) is approximately in the range of 0.7 kJ / kg * K or above. Heat exchanger according to claim 1 or 2, characterized in that the specific heat storage capacity of the insulating element (24, 33) is approximately in the range of 0.7 kJ / kg * K or above and the specific thermal conductivity of the heat storage element (25, 35) is also approximately in the range of 0.7 kJ / kg * K or below. Heat exchanger according to claim 1 to 3, characterized in that are used as materials for the insulating element (24, 33) ceramic, porcelain, fireclay brick or other earthenware or glass. Heat exchanger according to claim 1 to 4, characterized in that as materials for the heat storage element (25, 35) ceramic, porcelain, fireclay brick, other earthenware, glass or metal materials are used. Heat exchanger according to claim 1 to 5, characterized in that the insulating base (24, 25, 33, 35) is mounted approximately axially aligned below the interior (13) of the heating coils (2, 3) of the vertically arranged heat exchanger. Heat exchanger according to claim 1 to 6, characterized in that the heat storage element (25, 35) approximately centrally located below the interior (13) of the heating coils (2, 3) of the standing arranged heat exchanger is mounted. Heat exchanger according to claim 1 to 7, characterized in that the insulating floor (24, 25, 33, 35) is mounted below or instead of a bottom plate (1) of the standing heat exchanger arranged. Heat exchanger according to claim 1 to 8, characterized in that the insulation element (24, 33) and heat storage element (25, 35) consist of a single or two different materials. Heat exchanger according to claim 9, characterized in that insulation element (24) and heat storage element (25) consist of two different materials which are interconnected via a joint connection. Heat exchanger according to claim 9, characterized in that insulation element (33) and heat storage element (35) consist of a single material, but have different densities. Heat exchanger according to claim 1 to 11, characterized in that the insulation element (24, 33) is cup-shaped with a vertical edge (26) and a horizontal bottom portion (27) defining a receiving space (28) in which the heat storage Element (25) is introduced. Heat exchanger according to claim 1 to 12, characterized in that the heat storage element (25, 35) is arranged approximately centrally in the center of the receiving space (28) of the insulation element (24). Heat exchanger according to claim 13, characterized in that the heat storage element (25) is pressed or glued into a receiving opening of the insulating element (24). Heat exchanger according to claim 14, characterized in that the receiving opening of the insulating element (24) for the heat storage element (25) is a material not completely breaking through the recess (eg blind bore). Heat exchanger according to claim 1 to 15, characterized in that the heat storage element (25, 35) is disc-shaped. Heat exchanger according to claim 1 to 16, characterized in that the insulation element (24, 33) and heat storage element (25, 35) are formed substantially rotationally symmetrical. Heat exchanger according to claim 1 to 17, characterized in that the volume ratio between the insulating element (24, 33) and the heat storage element (25, 35) is about 5: 1 to 10: 1.

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