CH626716A5 - Planar heat exchanger - Google Patents

Description

The invention relates to a surface heat exchanger, 'A. T .., ... r,,, •. T M

.... 5 J i7 Fig. 4 is a longitudinal section similar to Fig. 3, but with Luftka-

which should be used in particular as an underfloor heating. ^ redits

Underfloor heating systems are available in various versions 55 pTg. 5 'a vertical cross section through a heating wall, knows the antique floor heating of the Romans used p * ß ^ horizontal section according to m_m in Fi 7

Warm air or the exhaust gases from wood fires for heating the. ®

Stone floors and often also a hollow room wall. emen ac o e or,

These space heaters were very comfortable, but had a section through a roof collector in FIG. 7,

Disadvantage that the operation is complex and that in particular a section through a roof collector.

are too expensive especially for multi-storey buildings. In Fig. 1, 1 is a concrete floor. Cork strips

Newer floor heating systems use water as heat transfer or wooden strips 2 and are laid at intervals of approx. 80 cm, which flows through plastic pipes placed in the screed of a galvanized trapezoidal sheet 3. Are embedded between the Lei floors. These heaters promise a best 2 and between the ribs 4 of the trapezoidal sheets is little corrosion and less susceptible to damage, the 65 hardening insulating material, e.g. Insulated concrete, introduced, result from thermal expansion. Earlier underfloor heating with The conduit pipes 5 are corroded by fine metal particles 6 um copper pipes or galvanized iron pipes often give to the trapezoidal sheet 3 for the purpose of good heat conduction. The extremely fast or the pipes broke due to the metal particles themselves are thinly coated with cement.

3rd

626 716

The rib channels are filled with a sand / cement mixture. An adhesive is scraped onto the trapezoidal sheets and a 2 mm thick nylon carpet 14 'is glued on.

Other embodiments are described below. 5

In Fig. 2, 10 represents the bare floor on which insulation, e.g. Cork plates 11, rest. These carry the trapezoidal sheets 12 with ribs 13. In the rib channels, conduit pipes 5 'are arranged, encased by fine metal particles. The metal particles are thinly coated with glue. io The rib channels are filled with a sand / glue mixture. A floor covering is glued to the trapezoidal sheets, e.g. Parquet panels 14. Warm air can be conducted in the channel-shaped spaces 15 between the sheet metal ribs 13. So you can heat the floor with this embodiment, both by means of warm water in the pipes 5 'and by means of warm air. The heat transfer is excellent, the inertia is low due to the low heat storage capacity. The heating can optionally be done with hot water and hot air at the same time. In Fig. 3, a section along I-I in Fig. 2, the channel feed is shown. One or more distribution channels 16, which are recessed in the insulation, lead the warm air to the channels 15. The fin ends are cut off at an angle to enable the pipe bends 5 "to be arranged in the channel 16 ' A space of, for example, 2 mm is provided in order to allow thermal expansion of the sheet, and the gap in the space is covered with a skirting board 18.

30th

FIG. 4, a section according to II-II in FIG. 2, shows the return duct 18, similar to duct 16. The now somewhat cooled air flows out of ducts 15 into collecting duct 18. Here, the normally small space 17 is somewhat larger provided so that air with a nozzle effect can escape past the 35 adjustable skirting board 19. This special version can e.g. be beneficial for indoor pools. In such cases, it is advisable to keep the window fronts dry by warm air rising. Usually an ordinary baseboard is placed here. 40

General.

The proposed surface heat exchanger can be used as floor as well as wall and ceiling heating. It can be designed as hot water heating or air heating, or both at the same time. It can also be used for cooling.

The cheapest solution is warm air heating, i.e. without the tubes 5.5 '. In this case, the rib channels are filled with a cheap sand-cement mixture (Fig. 2-4)

The floor heating according to FIG. 1 is somewhat more complex because 50 pipes are installed. These can advantageously consist of known plastic which has been tried and tested for this purpose. Such pipes are practically corrosion-proof and pipe breaks are not to be feared due to the low flow temperature and the material elasticity. The laying of the pipes 55 does not require high precision. Before laying, a small amount of the metal-cement mixture can be introduced into the sheet metal ducts. Then the tubes 5 are inserted and possibly held down with weights. The remaining metal-cement mixture is then introduced and scraped off with a knife, just above the pipe. The channels are then filled with a sand-cement mixture and smeared. If you coat the pipes with a very inexpensive metal cement mixture, e.g. When using fine filing or sawdust, which are usually provided free of charge by factories, you can completely fill the channels with it, without a sand-cement mixture.

After the metal-cement mixture has hardened, the final floor covering can now be laid, e.g. Linoleum, carpet, ceramic or stone slabs, thin-layer materials or good heat conductors are advantageous.

The pipe guide can be arranged as a register or as a meander. Depending on the overall construction of the heater, copper, steel or aluminum pipes can be used. It is the responsibility of the specialist to assess the corrosion, temperature resistance, etc., and accordingly to make the choice of material in each individual case. The profiled sheets can also be made of appropriate metal.

The heat exchangers described above can be used not only as floor heating, but also as wall heating. However, instead of a trapezoidal sheet, a sheet profile according to FIG. 5.6 is advantageously used for wall heating, known commercially as HOLORIB or MONTANARIB. Similar to Figs. 1 and 2, tubes 5 are fixed in the fins 4 '.

Another embodiment is shown in Fig. 5: the ribs are not completely filled in this embodiment, "shadow gaps" are left. Fastening the “dovetail-shaped” ribs to the building wall does not pose any difficulties for the person skilled in the art. Example: sheet metal bracket 20, fastened to the building wall, takes up the ribs 22 in the cutouts 21 and is wedged in by means of wedges 23 after the hooking. The heating wall can be surrounded by a frame 24 with a U-shaped cross section.

If you want good convection and the building wall is well insulated, thermal insulation between the building wall and the heat exchanger can be omitted. The room air then sweeps past the heat exchanger on the front and rear.

Fig. 6-8: The heat exchanger can also be used as an inexpensive solar energy collector. Fig. 6 shows a section III-III in Fig. 7, which shows the heat exchanger as a roof skin. Similar to FIG. 5, HOLORIB sheets 30 are provided with tubes 5 in the ribs, the ribs here being snapped into resilient holders 31. The outer sheet metal surface facing the sun is colored dark or has a coating that is selective for the sun's rays. Selective coatings absorb solar radiation particularly well and emit little radiation, especially in the infrared band. The holders 31 are screwed onto the purlins 32 using teaching. The purlin spacing is about 80-120 cm. At 33 the arrangement for an orifice plate is indicated and at 34 the heat insulation. Collectors without a cover reach 55 ° C idle temperature in winter and 75 ° in summer.

If higher temperatures are desired, a plastic or glass cover can be attached over the roof skin. However, the performance then drops somewhat due to the absorption and reflection of these covering materials.

As an example, FIGS. 6-8 show a glass cover made of glass profiles 35, between which a distance of 2 mm must remain for joint sealing and thermal expansion. These glass profiles, known under the brand name PROFILIT, were previously used as glass walls on industrial and gymnasiums. They are used both as single and double walls. The joints are sealed with a permanently elastic seal. Similar to known glass walls, the glass profiles are only attached to their ends (Fig. 7,8). Depending on the snow load and wind pressure, different profile types are available, 50cm, 30cm, 25cm wide, and also with various web heights and glass thicknesses. The glass cover and the solar panel together form a real double roof. Should a seal 36 fail, the penetrating water runs off on the collector without causing any damage.

If you use glass profile widths that correspond to the rib division of the metal profile, you can set it up

626 716 4

(see Fig. 6) that the glass webs near the ribs of the no. However, there is an addition of hardening accelerators and sheet metal profiles. Plastics that improve elasticity and adhesive strength,

It is easily possible to use other known glass.

to install covers. It is also possible to use plastic pro- A very inexpensive mass is also an iron particle /

file, or to combine both. The cover 5 bitumen mixture. The bitumen coating prevents the cork from being attached directly to the colector or by means of iron rosion and glues the particles similarly to the sand profiles, which facilitate the attachment. in road construction. Cold emulsions, both such, are advantageous

6 is particularly as a balcony broth as a water emulsion as well as with alcohol dilution.

suitable, provided with appropriate thermal insulation. The advantages of the invention are low gestures

7 and 8 show the attachment of a glass cover at 10 costs, improved heat transfer, lower front of a roof collector. Fig. 7 shows the attachment to the lower running temperatures and low maintenance costs.

Roof edge, where a strong sheet metal profile 36, screwed to the purlin 32 When using plastic pipes instead of metal, the glass profiles 35 holds down. At 37 is a tube, the susceptibility to corrosion is almost completely eliminated. This permanently elastic seal is appropriate. Similarly, in Fig. 8 holds a particularly advantageous in heating systems, where the heat transfer profile 38 firmly holds the glass cover and at the same time the ridge cap 15 flows through different materials, thereby creating an electro-pe 39th Iytic gradient. Plastic pipes also allow additional

This solar energy collector can be used as a roof membrane or as ze to the water to prevent freezing, e.g. Glycol or facade can be used. It can also be used as a coating of park salt.

squares, sidewalks, terraces or streets. Costs.

In the latter cases, it is advantageous to carry out the sheet coating 20 with hot air heating according to the invention, similar to FIG. 2, with a tough, hard material, e.g. with a dun without pipes, comes to about CHF 30 per m2, fully laid, no epoxy paint. Suitable epoxy paints bear a stand. In comparison, a conventional Bodenhei million kicks until they show the first weak signs of wear with pipes embedded in a cement screed, for about CHF. The rear thermal insulation can be advantageous with Iso 50 to 55 per m2.

lierbeton, especially those containing polystyrene pearls, 25 floors according to the invention as shown in FIG. 1. This also serves as an attachment. Plastic pipes, comes to about Fr. 45. - per m2, finished dimensions for attaching the pipes. j t> to steijen.

This mass should be a good heat conductor for heat conduction. According to the invention, solar energy collectors similar to FIG.

from the pipe to the sheet. It should harden quickly enough, 6> each (calculated yoke without glass cover, without insulation,

be inexpensive, corrosion-inhibiting and ensure good mechanical properties such as pr 55 _ ^ finished see connection. Fine metal particles, above all filings and metal sawdust, solar energy collectors according to the invention are particularly suitable for this, as long as they are not curled. Mixtures Fig. 6, calculated with glass cover, without insulation, are well suited and cost from aluminum particles with epoxy resins, the resin approx. CHF 95.– per m2, completely laid.

part should be kept low. Other multi-component solar energy collectors according to the invention for terrace polymer are also suitable. Sen, sidewalks etc. with insulation cost around Fr. 60. - per

Cement is also suitable as an addition to the metal part, completely laid.

C.

2 sheets of drawings

Claims (12)

626 716 2nd PATENT CLAIMS different material expansions of pipe and environment. The 1. Surface heat exchanger, which profiled sheet metal repairs were then extremely expensive. with ribs, characterized in that the profiling - now that the worst disadvantages are almost eliminated, is arranged in parallel and only in one direction, and there are others: the center distance of the fins (4) is greater than the width of the fins, s 1. the heat transfer from the plastic pipes to the 2. Use of the surface heat exchanger according to Pa- surrounding concrete and from the concrete to the room air still leaves claim 1 in construction. much to be desired. To achieve the desired room temperature 3. Avenge heat exchanger according to claim 1, ren to achieve flow temperatures for these new Bo-characterized in that the ribs (4) approximately V, the heating of 35 ° C and above required. Even if the trapezoidal or dovetail-shaped cross-section had the plastic pipes laid closer, which was complex and expensive and the remaining sheet metal surface was in one plane. is therefore expensive, the flow temperature would not be 4. Surface heat exchanger according to claim 3, wall can be reduced accordingly. Low flow - characterized in that in the fins (4,22) there are tubes (5) temperatures, in particular for hot solar energy, which tongues with a heat-conducting mass (6) and for the use of otherwise unusable waste -hooked in are very interesting for the transfer of heat from the heat. ger on the sheet (3), in particular with a mass (6) which 2. The effort for a known floor heating is always fine metal particles and binders. still too high. One is placed on the concrete floor provided by the customer 5. Surface heat exchanger laid according to claim 4, plastic film. Thereupon holding devices are characterized in that the metal particles are attached to waste from the plastic pipe register. Above that the screed is metalworking and the binder multi-component 20 of a few cm thick is poured and smoothed. The cost includes plastics, especially polymerizing ones. CHF 50.- to CHF 55.- per m2, fully installed. The total cost 6. Surface heat exchanger according to claim 4, for such floor heating are usually higher than one characterized in that the metal particles are heating with the usual wall radiators. and the binder contains cement. 3. The floor heating can only with a liquid (in the 7. surface heat exchanger according to claim 4, thereby 25 rule water) are operated as a heat transfer medium. The choice characterized that the tubes (5) consist of plastic, wise use of air as a heat carrier is impossible, especially from cross-linked polyethylene. against the narrow cross sections of the pipes. The uncertain 8. Surface heat exchanger according to one of the patent arrivals on economy and availability of energy claims 3 to 7, characterized in that it uses springs (wood, coal, oil, gas, hydropower, nuclear energy) to make the holder (31 ) can be attached. 30 it is advisable to use heaters that are easily 9. Surface heat exchangers can be adapted according to one of the patented energy sources. This can also say Proverbs 3 to 8, characterized in that it uses a different heat carrier, e.g. Make water and / or air neparous cover, especially with U-shaped tig. Glass profiles, which have stiffening webs on the longitudinal edges 4. Known floor heating systems with pipes and concrete cover have provided. 35 lung cannot be used as wall heating. 10. Use according to claim 2, characterized. It is the aim of the invention to record the disadvantages mentioned that the heat exchanger as warm air bottom heating or to eliminate completely, and additional new advantages tongue is used, the sheet metal ribs (4) offer down. are arranged above, and the intermediate spaces (15) between the surface heat exchanger according to the invention, which are designed as air ducts, which have 40 profiled sheet metal with ribs in the distribution, identifies and collecting ducts (16). in that the profiling is parallel and only in one direction 11. Use according to claim 2, characterized is arranged, and that the center distance of the fins is greater that the surface heat exchanger as solar energy than the fin width. Collector is used. The invention is illustrated in the accompanying drawings. 12. Use according to claim 2, characterized thereby 45 spjejswejse shown. shows that the surface heat exchanger shows as solar energy gs: 1 collector and as a covering for surfaces that can be walked on or driven over, det. 2 shows a cross section through a floor heating for loading 50 drifted with water and / or air, Fig. 3 shows a longitudinal section according to I-I in Fig. 2, with the air duct on the left