DE424888C - Heat accumulator for thermal engines - Google Patents

Description

GERMAN EMPIRE

ISSUED ON
FEBRUARY 10, 1926

REICH PATENT OFFICE

PATENT LETTERING

CLASS 46 d GROUP

(M ₇₇₅ I ₅

Michael Martinka in Räkosszentraihäly, Ung.

Heat storage for heat engines. Patented in the German Empire on April 25, 1922.

In the case of heat accumulators that are used in heat engines to reduce the consumption warm gaseous working medium to extract heat, to store it and to use it To return the fresh, cold work equipment, there is the requirement, in one as possible Small space to accommodate the largest possible storage surface, so that the storage from the thinnest possible plates or bands with the narrowest possible flow gaps.

In the case of gap widths greater than ι mm, the heat transfer is mainly due to the Convection from the inner parts of the gap against the gap walls into account, so that it would have to be ensured by a correspondingly high flow velocity that eddies arise that the

bring gas particles inside the gap cross-section to the channel walls, on the other hand, in this case, the very poor thermal conductivity of the jammed Gases can be neglected.

If, on the other hand, the width of the smallest gaps is less than 0.6 mm, then due to the thermal conductivity of the dammed gas that of the middle parts

to of the cross-section of the flow channel located gas parts in the unit of time The amount of heat transferred to the wall is so great that it is caused by a convective transfer caused by eddies the warmth can be ignored. So z. B. at a gap width of about 0.5 mm, the thermal conductivity of the resting Gas to increase the heat transfer coefficient ά above the value 300, which is approximately as the minimum value for memory to be used in heat engines.

The thermal conductivity λ of a gas is namely the number of calories that migrate per hour in a cross section of 1 m ² through a static gas layer 1 m thick at a temperature difference of ^{I 0 C.} For air it is x Atm. Pressure at the mean temperature of 600 ° (according to information in the pocket book "Hut"), which is considered for such storage systems, 0.0448. The number of calories transferred every hour over an area of 1 m ² with a thickness δ of the air layer, i.e. the heat transfer coefficient of this air layer is

λ
ι. α = -

If the gap width is denoted by .v, so is the greatest length of the gas path through which the heat must be conducted,

merely - and the mean value 1, so -.

2 ^ '24

2

As a result, the number of calories transferred per hour from the gas to the wall or vice versa over ^{an area of rm 2 of the gap walls is for the gas at rest}

or

2.

4_ ^λ

ie for air « ₌ W

0.0005

== 35S.4.

if the gap width is 0.5mm, i.e. 0.0005m amounts to.

The conditions do not change if, instead of resting, the gas flows through the gaps at such a low speed that an orderly, laminar flow occurs. Since the heat conduction of the dammed or laminar flow y ₀ gas already ensures sufficient heat transfer in the case of storage units with such gap widths, the! the latter the gases at a low speed of about 4 to 3.5 m / sec, if possible, borrowed less than -5 m / sec, never over 20 m / sec through the channels of the memory, so that only small, the efficiency j pressure losses that are less detrimental to the problem arise, so despite the narrow gaps such an accumulator can be used even in cases in which pressure losses are to be avoided as far as possible.

In order to achieve such small velocities that ensure a low flow resistance, the reservoir must have a large flow cross-section, which corresponds to a small overall length given the required reservoir surface. This reduces the flow resistance on the one hand, but also the harmful g ₀ space of the storage device on the other. Since there is now a significant temperature difference of around 600 ° C between the warm and cold ends of the storage tank that is in operation, there is a significant loss of heat conduction between the two ends of the storage tank in view of the small overall length and the large cross-section of the tank. To reduce these losses, the storage unit is subdivided into so many sections in the flow direction by gaps of the same order of magnitude as the gap widths that a maximum temperature gradient of 20 ^° C. does not apply to two successive sections of the storage unit.

As a result of the small gap width, the heat transfer coefficient due to the conductivity of the stationary gas very becomes large, so in spite of the large number of memory sections can at low Strömungsgeschwin- ₀ speeds n is the total length of the memory to be relatively small, since the individual portions of memory very fail short and only a length of z. B. must have 2 to 5 mm.

The following advantages are achieved through the extensive subdivision of the memory.

A temperature gradient arises between every two successive sections, the (due to the large number of sections) despite the large temperature difference of the

both ends of the memory is less than 20 ^° C. The gas layers present in the company in the spaces between the individual sections have an extremely low thermal conductivity, so that they greatly prevent the flow of heat through conduction between each two successive sections of the storage tank. Without these sections, the thermal conductivity of the building material would result in a significant heat exchange between the cold and the warm end of the storage tank.

The small temperature difference between two successive sections of less than 20 ^° C. also reduces the heat losses caused by radiation.

It is also known that when the gases from a room with even the slowest speed enter a limited canal, at the point of entry eddies develop - which only after a certain distance, the so-called calming section, disappear to accommodate the laminar flow close. At the existing low speed this vortex occurs there is no significant increase in the flow resistance, but the heat transfer coefficient increases within the calming section significantly above the value due to the pure conductivity. Now are the individual sections of the store dimensioned so short that they are no longer than the calming section, it can be done in spite of this the low flow velocity does not lead to laminar flow, because at Entering each section the calming section begins anew. As a result of this That fact, the heat transfer number can even at flow velocities that be a small fraction of the critical, rise substantially “above the value”. ;

This sets the upper limit of the gap width for the minimum value of the heat transfer; number 300 moved up to about 1 mm. That, temperature gradient within a section: is practically zero. The length of the rested! distance decreases with the gap width ^:

and so the length of the sections is e.g. B. with ^: Gap widths of 0.1 mm useful about! 2 to 3 mm.

The result of the inclusion of the inter-section spaces Caused increase in the flow resistance of the storage ■ can because of the short length of the spaces as well as due to the low flow velocity of the gases are neglected.

So that the capacity for heat absorption and release is as large as possible with the lowest flow resistance, the gap width in the individual sections of the storage tank is expediently proportional to the absolute temperatures prevailing in the individual sections. When the temperature rises, the thermal conductivity λ of the gases increases with otherwise the same conditions, and since the heat transfer coefficient α according to the given formula α = - is directly proportional to the thermal conductivity and the gap width, the gap width in the warmer sections can be increased if the heat transfer coefficient α remains the same the greater thermal conductivity can be taken accordingly larger and the flow resistance can be reduced as a result. In such a memory, the gap width at the cold end z. B. be only 0.1 mm and gradually increase to 0.22 towards the warm end. In this way, every section of the accumulator is fully utilized and the desired performance of the accumulator is achieved with the lowest flow resistance and volume, so that the accumulator has the best efficiency and the least harmful space.

Nickel is expediently used as the material for the warm parts of the storage tank, since tests have shown that this metal is best suited for this purpose. It has been found that at the higher temperatures, around 900 to 930 °, the nickel does combine with the oxygen in the gases. However, the oxidation penetrates only to a certain depth, and the rate of oxidation decreases asymptotically, so that the service life can extend to over 1000 operating hours. In addition, but the unoxydierte nickel inside the oxidized coating having a sufficient strength to withstand the stresses to which the heat accumulator is subjected to in an internal combustion engine even at a temperature of about 900 to 950 ⁰ C.

Several exemplary embodiments of the subject matter of the invention are shown in the drawing illustrated.

Fig. Ι shows part of a heat accumulator composed of parallel straight strips in front view,

Fig. 2 the same in section along the line 2-2 of Fig. 1.

The memory shown in these figures has thin, e.g. 0.1 mm thick, straight metal strips 1 having a width of z. B. have about 2 to 3 mm and the spacing of the strips 1 with the intermediate layer securing thin, e.g. B. 0.06 to 0.1 mm thick strip 4 in grooves 2 of the heat poorly conductive frame 3 inserted in this way

are that in each groove 2 of the frame a grate with very tight, z. B. 0.06 to 0.1 mm wide gaps arises, which are delimited by parallel walls. In frame 3 is as can be seen from Fig. 2, a large number of such grids arranged one behind the other, so that the grids forming the individual sections of the memory by thin, z. B. 0.06 to ι mm thick spaces 5 are separated from each other. The gases flow alternately in the direction of arrows 6 and 7 through the grids of the store.

To secure the gap between the individual layers of the metal strips 1 can instead of special spacers, any ones made from the bands themselves Serve spacers.

Fig. 3 shows z. B. how the gap 9 between the individual layers of the metal strips 1 is secured by in the same pressed warts 8.

The grids forming the individual sections of the store can be produced in a simple manner by winding a spiral 10 (Fig. 4) from a thin and narrow metal band, securing the required distance between the individual turns of the spiral (not shown). A correspondingly large number of such flat spirals, e.g. B. 100 spirals, each 2 mm wide, is with the interposition of spacers, for. B. thin (about 0.1 mm thick) wires, lined up in a poorly thermally conductive housing.
Fig. 5 shows such a memory in longitudinal section. In the housing 3, which is made of refractory, poorly heat-conducting materials, the spirals 10 are lined up one behind the other in such a way that the spaces S are created between the individual spirals.

It should be noted that in Fig. S only 16 spirals are drawn for the sake of clarity while in reality there are at least twice that number.

The cold gases flow in the direction of the arrow 6 and the warm gases in the Direction of arrow 7 through the memory, as the former heat up and the latter cool down.

Instead of the spirals, the grids shown in Fig. 1 and 2 could also be used in the in Fig. 5 can be arranged one behind the other.

From Fig. 5 it can be seen that the cross section of the memory from the cold end 11 the same gradually increases towards the warm end 12; it is not evident that either the gap width in the individual sections of the storage tank increases in the same way.

Claims (2)

Patent Claims: i. Heat accumulator for heat engines, which is composed of individual sections in the direction of flow, which consist of parallel layers of metal strips, characterized in that the entire flow cross-section and the gap width between the individual metal strip layers from the one end at which the gap width is less than 0.6 mm, gradually increases towards the other end, the individual sections being separated from one another by gaps of the same order of magnitude as the gap widths of the respective sections and being arranged in such a large number that the temperature gradients between the two ends of the storage unit lead to two successive ones Sections of the memory a maximum temperature gradient of 20 ⁰ C is omitted. 2. Heat accumulator according to claim 1, characterized in that at least the warmest sections of the memory are made of nickel. 1 sheet of drawings.