DE18412C - Innovations in closed tubes for the transfer of heat - Google Patents

Description

IMPERIAL

PATENT OFFICE.

The development of the invention disclosed in patent no. 14552 has to be the constructions described below.

The heat transmission tube. In Figures 8 to 8e incl shown has two channels C for the ascending stream to the same to lead from the lower annulus to the top Cylinderraum, and two channels C ₁ to the cooled stream from the upper annular space into the lower To lead cylinder space. The arrows d through d ^h illustrate the path that the current takes. It emerges at the lower part at α from the inner tube α α ¹ , goes through the annular space and in the direction of the arrows dd _x through the channels CC into the upper part of the tube aa, and emerges at O ₁ from this in the direction of the Arrow d * d ^% into the annulus and descends through the channels C ₁ C ₁ in the direction of the arrow d _t d _{b back} to the point α , from which he started to start his way again. The upper resp. The lower edges of the channels C and C ₁ are at the distance x, Fig. 8a, so that a mixing of the ascending with the descending stream in the pipe α α ^{1 is} prevented /

The heat transmission tube shown in FIGS. 9 to 9 differs from the one shown under 8 in that the passage channels are covered by a closed tube a ₂ ^a % , which on its outer surface has the sealing ring D, FIGS. 9, 9 a and 9 b, wearing. This sealing ring completely closes off the lower and upper space. The space x, Fig. 9 a, between the upper and respectively. The lower edges of the channels C ₁ and C are closed off here by the trays W and W ₁ , and the ascending and descending currents are thereby completely separated from one another.

The heat transmission tube shown in FIGS. 10 to 10e is provided with a cast circulation tube and, like the preceding ones, has two ascending and descending channels C and C ₁ . These are, however, formed by the drawn-in and widened walls of the circulation pipe itself, and since these walls converge, as can be seen from Fig. Channels C and C _{1 are} in the same plane and between their upper and BEZW. Lower edges no distance x, as in Fig. 9 a, is arranged.

The heat transmission tube AA ₁ shown in FIGS. 11 to 11 e is provided with a circulation tube which has three ascending and three descending channels C and C ₁ . This circulation pipe is double-walled in order to prevent heat from being transferred from the ascending stream to the descending cooled stream. Here, too, the circulation takes place in the direction of the arrows dd _u d ₂ d ₃ , d ^ d · ,, as described above.

The heat transmission tube shown to 12 e in Fig. 12 differs from the above-characterized, that the same only an ascending channel and a descending channel C C ₁ <obtained. The edge rr _{according to} FIGS. 12, 12a and 12b, is placed around the mouths of the channels C and C _{1 in} such a way that it clears the annular space between the outer tube AA ₁ and the inner a Ci ₁ in a corresponding manner shown in the drawing finish up. The left side of the circulation pipe a / X ₁ is connected to the right side of the same by the wall w, FIGS. 12, 12a and 12b, and this wall, together with the edge r T _1, forms a complete closure, so that the - and the descending stream cannot touch anywhere.

The heat transmission tube shown in FIGS. 13 to 13 differs from the previous ones essentially in terms of the circulation tube. The same is formed here by two tubes a (ti, a ₂ a ₃ , which are semicircular at the point where the current crossing takes place, as can be seen from the cross section, Fig. 13d. These two semicircular tubes are thus attached to each other attached so that they form a full circle, which has the same diameter as the outer tube AA _1. The lower opening of the tube a ₂ a ₃ now forms the channel C and the upper opening of the tube a U ₁ the channel C _1. The partition w prevents the currents from touching.

The heat transmission tube AA ₁ shown in FIGS. 14 to 14a differs significantly from those previously described in that it has a larger diameter where it is in the fire than where it is in the material to be heated. If, as can be seen in Figs. 14 and 14d, the diameter of the lower part is chosen so that the walls of the individual tubes touch, a wall is formed by the lower parts which can be used both horizontally and vertically. The difference in the diameters of the upper tube A ₁ and the lower tube A also allows the space WW in the boiler or the like to be gained in order to fix the heat transmission tubes well. The circulation device can be one of those described above.

The transmission vessel shown in FIG. 15 differs from those previously described in that it emits heat for several. Part A ₁ A ₁ only a common, heat-absorbing part AA is present. It should be used especially for such a filling material that solidifies when it cools, such. B. paraffin, metal alloys etc.

The heat transmission tubes shown in FIG. 16 differ from those previously described in that they are provided with the tube connections RR ₁ , which open into the individual tubes through the connecting pieces VVm. Through the pipe connections RR ₁ , the heated flows can be forwarded for further use, or the pipes can be routed to safety valves, a manometer or a pump, the latter to replace or exchange the filling of the pipes, or to empty them before cooling and later again to fill.

The heat transmission tube shown in FIG. 17 differs from the one previously described in that it is formed from two tubes AA ₁ and A ₂ A ₃ inserted into one another. The fire goes through the inner tube A ₂ A ₃ and washes around the upper part of the outer one at A _x A ₁ . In this case the rising current is again shown by the arrows d (I ₁ , but it also absorbs heat from d-2 to d _s through the outer wall A ₁ A ₁ and carries it downwards. The current d _t d _b gives off its heat partly to the material located between the walls W and W ₁ and partly to a second material located between the walls W ₁ and W _2. The former, between W and W ₁ , can, for example, be boiler water, the second, between W ₁ and W ₂ , air.

The heat transmission vessel shown in Fig. 18 differs from the one last described in that it absorbs heat from below, from above, and from the inside. Heat is absorbed through the tube AA ₁ both at the bottom at A and at the top at A ₁ , and therefore two ascending currents form up to the wall W ₁ W ₁ , an inner and an outer one. The circulation pipe (Za ₁ is therefore formed in the lower part up to the wall W ₁ W ₁ of two tubes inserted one into the other, while in the upper part only the narrower pipe a Ci _{1 is} continued; however, the outer pipe a ₂ a can also be used instead _3. The currents are indicated by the arrows ddt in the annular spaces r and; - _2. Both unite in channel C and continue together in the annular space; - _2. Between the annular spaces r and r ₂ is the Annular space r _u and this returns the cooled stream through channel C _1.

The heat transmission vessel shown in FIG. 19 differs from the one previously described in that it only absorbs and conducts heat from within. The tubes AA ₁ and A ₂ A ₁ are joined together in the way that can be seen in the drawing, and the circulation tube a (I _{1 is} fastened in the annular space between the two. The heated stream enters the outer annular space at d ₂ d _3, to give off its warmth, and then returns to the

Direction of arrow d ± d _{% back} to new heat absorption. Here, too, the heat is fed to the material from top to bottom.

The heat transmission vessel shown in FIG. 20 is arranged in a horizontal position and absorbs heat from all seldom, which it gives off to the material which is between the walls W and W ₁ . located. In each of the walls W and W ₁ there is a circulation tube α a _lt as shown in FIG. 13, and the two circulation screens a ₂ a ₃ , FIGS. 20 and 20 b, are attached between the ends of these tubes. The direction of the currents is shown by the arrows dd _lt d ₂ d _z , d _t d- ₀ both in the case of the circulation pipes α a _x and in the case of the circulation tubes a ₂ ^a 3 .

The heat transmission tube shown in Fig. 21 is configured like that shown in Fig. 13 but different from the same. in that it conducts heat in a horizontal direction. The current dd _x to d ₂ d _% is passed through the wall WW and only gives off its heat when it passes through the wall. W _{1 has reached} W ₁ . This A heat transmission tube finds particular application in the fire boxes of the locomotives. According to the inventor, for example, with a pipe only 25 mm in diameter and 2 m in length, 1 m of which is in the fire and 1 m in the water, the heat can be conducted in such a way that the water only reaches the end furthest from the fire boils. The circulation pipe may be missing in the case of short pipes.

The device shown in Fig. 2 shows an acid concentration according to the method of heat conduction described. The heat transmission vessels AA ₁ A ₂ A ₃ are sealed in the reservoir WW in the manner shown in the figure. The heat transmission vessels are constructed in one of the ways described above and can be provided with filling material which solidifies. For this reason and to melt the filling material quickly when companies, there is a second grating R ₁ is attached besides the main grid R. The heat currents give off the highest temperature at the level of the level W ₁ W ₁ to the acid and heat it here the most. The acid arriving through Z is, however, still less concentrated, and therefore specifically lighter, and since it is also heated to the highest at the same time, it is compelled for both reasons to remain on the surface until it has given up its water as desired. The more complete separation of the concentrated acid from the dilute acid, attained by this process of heat transfer, is essential for the easing of concentration, and takes place also with other concentrations; such as B. of lye, sugar juices etc.

The heat transmission vessels shown in FIGS. 23 to 23c, which are arranged on a Cornwall tube, have the outer shape of GaIl o way tubes in the same and an expansion inside the boiler, as can be seen at A _1. This shape is given to show that the shape of the heat transmission vessels can be very varied. These vessels can be used as desired, e.g. B. for fire supply from outside and inside, as described above, or with a special filling, as shown in Fig. 23, or for a circulation of the material to be finally heated.

The heat transmission vessels shown in Fig. 24 are different from the previous ones described by the fact that they are spherical with the part that lies in the fire are. All the specified modifications of the circulation device are also with this one Construction apply.

Claims (17)

Patent Claims: To the No. 14552 protected devices for the transfer of heat in closed transmission tubes the following changes: 1. The heat transmission tube shown in Figs. 8 to 8e in its application. 2. The heat transmission tube shown in FIGS. 9 to 9 with the sealing ring D and the walls WW ₁ . 3. The formation of the channels CC ₁ through the walls of the circulation pipe and both in the same plane, FIGS. 10 to 10 e. 4. The heat transmission tube shown in FIGS. 11 to 1 ie with double wall of the circulation pipe. 5. The heat transmission tube shown in FIGS. 12 to 12e with the wall w and the edge r V ₁ , as described. 6. The heat transmission tube shown in Fig. 13 to 13 ε with a circulation tube, which at the same time forms the channels C and C ₁ in that at least at the point where the ascending and descending currents are introduced, the tube consists of two semi-cylinders, which are folded with their flat sides. 7. The heat transmission tube shown in FIGS. 14 to 14a, in which the part of it lying in the fire has a larger diameter than that in that material to be heated to form a wall of fire that conducts the heating gases. 8. The heat transmission vessel shown in Fig. 15, in which a warmth The receiving part is arranged for several heat-emitting parts at the same time. The connection of the individual heat transmission vessels by a pipe connection on their upper or lower parts, or on both, Fig. 16. The heat transmission tube shown in FIG. 17 with internal and external firing and simultaneous transfer of heat to various materials in such a way that the heat is supplied to the material from top to bottom.
The heat transmission vessel shown in Fig. 18 with two heated streams, between which the cooled stream is passed, in order to supply the heat absorbed at all parts to the material which is located between the walls WW ₁ from top to bottom. The heat transmission tube shown in FIG. 19 with a simple circulation pipe to absorb heat only from the inside and the same to the material to be heated feed from top to bottom. 13. The heat transmission tube shown in Fig. 20 with the two circulation tubes a ^ ₁ and the two circulation screens a ₂ a _{3t in} order to conduct heat, which is brought from outside and inside to the heat transmission tube, in the horizontal direction. 14. The heat transmission tube shown in FIG. 21, which receives heat only from one side, with the circulation tube a Ci ₁ , in order to slide the heat as far away from the fire as possible in the horizontal direction. 15. The device shown in FIG. 22 with heat transmission according to the method described, with the attachment of two or more heat sources R and ^ ₁ . 16. The heat transmission vessel shown in Fig. 23, which has a shape other than tubular. 17. The heat transmission vessel shown in Fig. 24, on which the part lying in the fire forms a ball. In addition 6 sheets of drawings.