DE2326676A1 - STORAGE STONE FOR HEAT STOVE - Google Patents

Description

DR.- ING. HH WILHELM - DI PL ₀ - IN GH D AU STE R

D-7000 STUTTGART 1 - G Y M N A S I U M S TR A S S E 31 B - TELEPHONE (0711) 291133

Stuttgart, May 24, 1973 Dr .W / Wo

Re: Patent and utility model auxiliary application D 4464

Apia .: · Malag works

Adolf Muckenfuß & Sons

7518 B r e t t e η

Storage stick for heat storage stoves

Me invention "relates to a storage stone for heat storage stoves, which is provided with recesses for receiving electrical heating elements. . .

It is known for Wärmespeicheröfen, .insbesondere for electrical night storage furnace ^ Speicher'steine of ceramic material j to use the content of MgO has a decisive Hollenbach for the heat storage capacity "For example, so-called Olivinsteine with 50% MgO and ForsteritsteiBe with

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50 % MgO is known, but its heat capacity is exceeded by magnesite bricks with 90% or blast furnace magnesite bricks with 95% MgO. Blast furnace magnesite is too expensive for use in heat storage stoves, so that today generally only magnesite bricks with about 90% MgO are used as storage stones for night storage stoves. These stones have the advantage of a high storage capacity and can be equipped in the desired manner with the recesses for producing the ventilation openings and with the recesses for receiving the heating elements.

The endeavor now goes to the heat content of a charged To get the storage heater as high as possible. But it has been shown that the heating elements themselves are the weakest point here because they usually cannot get hotter than around 800 degrees Celsius due to material reasons. The memory charging are therefore limited by the maximum temperature of the heating elements, because it is due to the known memory stones remaining heat gradient between the heating elements and the adjacent storage stone is not possible, more heat away from the heating elements and into the stone.

The present invention is based on the object of creating a storage stone that dissipates heat from the heating elements promotes to the stone volume, so that either by reducing the previously unavoidable heat gradient a lowering of the temperature on the heating element or a corresponding increase in the heat capacity of the storage stone is possible is.

The invention is based on the knowledge that the previously known, relatively light magnesite bricks, the absorption capacity is not used, indicated by at least Black paint bag provided in the area of the Heizelemeote. This measure brings the in an extremely simple way

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more surprising! The result is that the heat transfer from the heating elements to the storage stone mass is obviously much better and measurements have shown that the temperatures at the heating element could be kept about 4-5 ° Celsius lower with the same electrical heating output as compared to stones ₅ in which such a coloring was not available o It has proven to be extremely simple and advantageous - if the Speiciierstein consists of magnesite and the coloring is applied as a layer of color that is applied to all outer surfaces of the Speiciierstein. As a color layer, a black, temperature-resistant and commercially available stoving lacquer has proven to be particularly advantageous, as is used for coloring hotplates p the like. is used «, The advantageous results described above were achieved with a magnesite storage stone with an MgO content of 92 % » It is conceivable that similarly good results can also be achieved with another, inherently dark storage material with similar physical properties as magnesite that does not need to be colored separately »Such materials are not yet known today.

In the drawing is the arrangement of the temperature measuring points indicated on a storage stone, taking the measurement once with one uncolored and once with one with, stoving varnish colored magnesite memory stone was carried out.

In Fig. 1 is a perspective view of a Storage stone made of magnesite is shown, once without coloring and once with a black layer of baked enamel all outer surfaces was provided and at points 1 to 6 under the installation conditions shown in Fig. 2 within an externally insulated heat storage furnace housing was measured.

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409850/013

From the Pig. 1 and 2 it can be seen that the magnesite storage stone provided with groove-shaped recesses 7 on its upper side is, in each case in the Pig. 1 tubular, not shown electrical heating elements 8 are inserted during assembly. By stacking several storage stones on top of one another then comes the one from Pig. 2 visible inner storage core, which is surrounded by air ducts 9, which through the lateral Recesses are formed on the individual storage stones. The memory core assembled in this way is then used by a outer insulating layer 10 surrounded in the usual way Stone can be composed with an additional fiberglass insulation.

During the measurement, a magnesite memory stone of the following composition was found used:

MgO 92%

O Λ oL

Pe ₂ O ₃ 2
CaO 3
SiO2 2

This magnesite brick had a

Density of 3.0 kg / dm,

This corresponds in its appearance in about light bricks Memory stone was in the assembled state

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409850/0130

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according to Jig. 2 charged with night power under normal conditions, over the full available charging time of around 8 hours. The memory "then has a recorded Heat quantity of about 38,500 kcal and the temperature distribution on the measuring points is as follows:

Measuring points 1 2 3 4th 5 6th 810 ⁰ C 730 ° C 710 ° C 700 ° C 680 ° E 685 ° G

The same experiment was carried out with the same heating elements and the same rest of the composition of the storage heater with storage stones same analysis (magnesite) carried out, but according to the invention were provided with a black stoving varnish on all outer surfaces, as is usually used for coloring Stovetops is used. After the same charging time of 8 hours and the same heat content of around 38,500 kcal the temperature distribution was as follows:

Measuring points 1 2 3 4th 5 6th 765 ° C 720 ° G 705 ° C 695 ° G 680 ° C 690 ° C

This temperature distribution shows that apparently due to the Better heat dissipation from the heating element, a more even distribution and a rise in the temperature inside the storage stone has occurred when a dark coloration of the outer surfaces and at least the surfaces in the area of the heating elements is provided. The decisive factor is above all the drop in temperature on the heating element by around 4-5 compared to the test version, without coloring. This lower temperature on Heating element allows the entire storage core around

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409850/0130

heat up around 4-0 to 45 Celsius more, so that the total heat content of the memory can be correspondingly higher.

The present invention thus surprisingly results in a considerable increase in the heat capacity of storage stoves achieved without expensive means or new and expensive storage materials having to be provided.

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Claims (5)

Patent and protection claims .! Storage stone for heat storage stoves, the one with recesses is provided for receiving electrical heating elements, characterized by at least one in the area of the heating elements (8) intended black coloring. 2. Storage stone according to claim 1, characterized in that the storage stone consists of magnesite and. the coloring is applied as a color layer (11). 3 storage stone according to claims 1 and 2, characterized in that that the color layer (11) is applied to all outer surfaces of the storage stone. 4 ·. Storage stone according to claims 1 to 3? characterized, that a black stoving lacquer is provided as the color layer (11), as is usually used for coloring Stovetops is used. 5. Storage stone according to claims 1 to 4, characterized in that that magnesite with the following composition is used as the material for the storage stone: MgO 92% Al ₂ O ₅ 1 % Fe ₂ O ₃ 2 % CaO 3 % SiO2 2 % 409850/0130 Blank page