DE7302520U - Electric hot air heater - Google Patents

Description

Hot air heating

The innovation concerns a hot air heater with a heating element.

The most widespread electrical heaters, such as heating walls or radiator heaters, work on the basis of convection of air, with the air being used as a heat exchanger. The Konvektorenheizunp; s, however, are sluggish in their operation and in part ineffective because the air is a good thermal insulator known and therefore poorly or not conduct heat. For this reason, such heating devices are uneconomical in their degree of utilization in relation to the power applied.

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Also the well-known warm air circulators in particular with small dimensions are limited in performance and are only suitable, for example, as transition or additional heating for individual rooms.

The known storage heaters are efficient, but have the disadvantage that they take up a large amount of space.

j may require and be heavy and therefore

• are already uneconomical for these reasons,

A common to all of the aforementioned known heating devices The disadvantage is that simultaneous air humidification is difficult and, if at all, only to a limited extent is possible.

] It is therefore the aim of the innovation to remove the disadvantages of the

to eliminate previously known heating devices and a hot air heater to create with which the applied energy is used rationelj for heating and the effort compared to conventional Heating devices can be reduced.

The hot air heating with a heating element is characterized according to the invention that the heating element extends in a cell open at the bottom and top and is surrounded by a heating duct jacket and around the heating element are arranged lamellae made of a heat-resistant, thermally conductive material, which extend radially away from the heating element and extend over the length of the same and with their part facing away from the heating element are firmly and thermally connected to the heating duct jacket and by which the cell is divided into heating channels open at the top and bottom, and that aie cell is surrounded by external insulation and one below the cell Fan is provided for conveying air through the heating ducts

The heating element can consist of one or more electric heating rods, but it can also be a gas, hot- water or steam heatable heating element are present.

The heating duct jacket and / or the lamellae can consist of one Metal with good thermal conductivity, for example made of aluminum or an aluminum alloy or copper or a copper alloy such as brass.

The part of the slats facing away from the heating element can be at least partially connected to the heating duct jacket, preferably with the largest possible area. In one embodiment of the innovation, the lamellas can be bent in an L-shape, for example, on their part facing away from the heating element and firmly connected to the bent part, for example with a side surface of the same with the heating duct jacket. In another embodiment of the hot air heater according to the invention, two or more lamellas can have a connecting wall on the part facing away from their heating element, which can be connected to the heating duct jacket in a fixed and thermally conductive manner. The connecting wall can extend vertically over the length, for example over the entire length of the heating duct. tels extend. The lamellae may V-shaped profile to be at its end facing the heating element with a profile, for example a _f-t T or provided or over. ■ the heating element have a convex profile *

In a further embodiment of the hot air heater according to the invention, the cell can be any polygonal, for example a triangular, rectangular, z. B. have a square or circular cross-section. The fan and the cell can be arranged on a frame which can be movably supported, for example, on rollers, skids or the like. The frame can, however, also be arranged firmly on the floor of a room or on or in a wall of the same.

The firing is shown below with the aid of the drawing in exemplary embodiments explained in more detail. It shows:

Fig. 1 shows a hot air heater in section,

Fig. 2 shows the hot air heater of Fig. L partly in

Section along the line II-II of FIGS. 1, 3
a - d an arrangement of cells each in a hot

air heating element in a schematic representation

in plan,
Fig. H a further hot air heater in simplified form

Representation in longitudinal section,

each one embodiment of a cell in cross section., and

one arrangement of a hot air heater each in a schematic representation.

According to FIGS. 1 and 2, a fan 1 is located in an intake and fan box 2, on which a bottom and top offe-ί ner, in cross-section hexagonal body or a cell 3 with

Side walls 4 is arranged vertically. above the fan 1 extend vertically in the center of the cell 3 electrical heating elements 5 in the form of heating rods, which ^{are fastened by means of a lower and upper base 6 and 7 via lower and upper webs 8 and 9 to the side walls 2} J, via electrical Connections Io, the heating elements 5 can be connected to an electrical power source (not shown). As shown in particular in FIG. 2, fins 11 are arranged around the heating elements 5 and extend radially away from the heating elements and vertically over the length of the same. The side 12 of each lamella Ii facing the heating elements has a cross-section T-shaped profile 13 with which the lamellae 11 are equidistant from one another and opposite the

Fig. 5 until Io Fig. 11th until 13th

Heating elements 5 are arranged. In each case two lamellas 11 have in pairs on their part Ik facing away from the heating element 5 a connecting wall 15, which is ^{firmly and thermally connected to the side walls 1} I over the largest possible area, so that heating channels 16, 17 open at the bottom and at the top are formed, which are made of one _; The heating duct jacket 18 of the cell 3 and the lamellae 11 connected to it in a fixed and thermally conductive manner.

The side walls 4 and the heating duct jacket 18 are surrounded by an outer insulation 19 and outer walls 2o, which are vertical. are arranged on the blower box 2 and are connected at the top end by outer walls 21 (only one shown). The blower box is also equipped with rollers 22 so that a mobile radiator or a mobile hot air heater with a cell 3 is present. The upper part of the hot air heater is closed with a cover insulation 23 and has lateral outlet openings 24 between the cover insulation 23 and the upper part of the side walls k for the outlet of hot air. An evaporator tray 25 for water for humidifying the air is also provided on the cover insulation 23.

The hot air heater works as follows: The fan 1, which is preferably quiet and accordingly is efficient, sucks in cold air in the direction of arrows A directly on or near the ground from the environment and conveys it upwards into the heating channels 16, 17 according to arrows B For example, a temperature of 800 C, which is absorbed by the lamellae 11 arranged close to the heating elements 5 and is quickly delivered to the heating duct jacket 18, so that the relatively thin layers of air in the heating ducts 16, 17 heat quickly and use the hot air from the fan 1

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predetermined speed exits from the outlet openings 24 in the direction of arrows C. The layers of air, for example approximately 10 mm thick, passed past the lamellae 11 heat up very quickly due to the large surface area of the lamellae 11, so that depending on the size of the heater, for example 120,000,000 air per hour or possibly more. approximately 300 ⁰ C can be heated. The circulation of the air through the fan 1 ensures a quick and even distribution of the heated air and thus for an even heating of the room or the environment .. Since the heating ducts are isolated from the environment, the outer walls 2o, 21 of the radiator remain practically cold. In contrast, the upper cover can heat up, as a result of which air humidification can take place by means of evaporation of water from the evaporator dish 25. Each radiator can be controlled via thermostats and have different heating levels (both not shown). The outer insulation 19 has two tasks * On the one hand, this insulation 19 ensures that the outer walls 2o, 21 of the radiator, pers can only heat up slightly. On the other hand, the insulation 19 ensures that the heating channels 16, 17 cannot cool down, for example between switching the thermostats off and on, so that an optimal heating output can be achieved again shortly after switching on again.

As FIGS. 3a-d show, in which those with FIG. 2 are the same Elements have the same reference numerals, due to the hexagonal cross-section or cell 3, it is possible to Manufacture radiators with several cells 3 in the modular principle in the desired shapes and dimensions in a space-saving manner. According to Fig. 3a, several cells 3 in a row in a radiator characterized by outer walls 3o to be ordered. Fig. 3b shows a heater 3 * 1, in which three cells 3 in a spatially favorable manner within

Outer walls 32 are arranged. In FIG. 3 c, several cells 3 with the heating duct jackets 18 are enclosed by an outer wall 33 of circular cross-section. Finally, FIG. 3d shows the possibility, for example, of arranging four bodies or cells 3 in such a way that a radiator with outer walls 3 ² J arranged in a square cross-section is present.

Fig. 4 shows another embodiment of a hot air heater with air humidification. Cells 4o with side walls or a heating duct jacket 41, which have a hexagonal shape in cross-section (not shown), are arranged in the same way as _{: shown} in FIG 43 'contains. The cells 4o are surrounded by outer walls 44, 44 ', with an outer insulation 45 again being provided between the latter and the heating duct jacket 41. In the center of the cells 4o there are heating elements 46, which can be, for example, electric heating rods, over the cells 4o there extends a cover insulation 47 »with outlet openings 48 being provided on both longitudinal sides of the same, through which hot air can exit in the direction of arrows D above, which sucked in as cold air by the fan 42 'according to "arrows D ¹ and according to arrows D ¹¹ into the cells open at the bottom and top. The other devices can correspond to those of FIGS on the fins 11 firmly connected to the heating duct jacket oil 41 are omitted for reasons of clarity.

A water tank is attached to the front outer wall 44 49, which has a filler neck 5o for water and at the bottom 51 has an outlet connection 52. A water line 54 is connected to the outlet connection 52 via a regulating valve 53, which leads to evaporator tubes 55, which are arranged parallel to and in the vicinity of the heating elements 46. The vapor tubes 55 are heated by the heating elements 46 in such a way that

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that the water located in the same can evaporate through openings (not shown) of the evaporator tubes 55 and can exit together with the hot air in the direction of the arrows D and thus moisten the air of the surrounding space. By means of the regulating valve 53, the refill of water 56 from the tank H9 into the evaporator tubes 55 can be adjusted according to the evaporation taking place in the same.

The shape of the slats, in particular in their part facing or facing away from the heating element, can be of any desired shape. The shape too the cell can have any shape in cross section, which can also be used in a space-saving manner let radiators be built using the modular principle.

In FIG. 5 there is a cell 6om with a hexagonal cross-section and lamellae 61 which, on one of its heating elements 62 facing end faces 63 have a / ^ - profile 64. With their bent part 63 'facing away from the heating element 62, the lamellae 61 with the heating duct jacket 65 are the Cell 6o firmly connected.

In FIG. 6, lamellae 66 have a convex profile 68 opposite a heating element 67 and are circular in cross section Cell 69 arranged. On their part 7o facing away from the heating element 67, the lamellae 66 have the radius of curvature of the circular cross-section bent accordingly and with dtr convex side surface of the bent part 7o with the heating duct jacket 71 firmly connected.

As FIG. 7 shows, a cell 72 with a triangular cross-section is also possible with a heating duct jacket 73 in which lamellae 74 are arranged around a heating element 75. Opposite the heating element 75, the fins 74 have a / profile 76 and are est'verbunden by a bent profile part 77 with the Heizkanalmantel 73 £.

In a square cross-section cell 78 of the Pip. 8th lamellae 79 with a V-shaped profile 80 are arranged opposite a heating element 8l and around the same. With a bent Part 82 are the lamellae 79 on their part facing away from the heating element 81 with the heating duct jacket 83 of the cell 78 firmly and thermally connected.

As FIG. 9 shows, they are rectangular in cross section Cell 8 * 1 alternating in cross-section S-shaped lamellae 85 and C-shaped fins 86 arranged around a heating element 87. With the heating duct jacket 84 ', the fins 85 and 86 are through a bent part 88 or 88 'firmly and thermally connected over the largest possible area.

Finally, Fig. Io shows the possibility of a cross-section octagonal cell 89 with lamellae 9o> which are parts of a correspondingly bent aluminum sheet, for example, so that compared to a heating element 91 arranged in the cell 89 there are n-profiles 92, the lamellae 90 with a the heating element 91 bent part 93 with a heating duct jacket '9 ¹ J of the cell 89 are firmly connected.

As shown in FIGS. 11 to 13, the location of hot air heaters, as described, for example, in the preceding examples, can be selected as desired.

In Fig. 11 a hot air heater is loo -immediately on one Outside wall lol below a window sill Io2 of a window I03 fixed. Cold air is sent immediately according to arrow E. above the floor lo * J of a room I05 in the hot air heater loo sucked in and exits as warm air at the top according to arrow P at the level of the window sill Io2.

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According to Pip ,. 12 is a hot / air heater Io6 with an air outlet Io7 on the inner wall 108 of a room lo9 * above the floor Ho of the same firmly arranged, whereby cold air according to arrow Q from below through the bottom 111 of the hot air heater Ιοβ » which then exits as warm air according to arrow H above.

13 shows another arrangement of a hot air heater 112 which is installed in a partition wall 113 between rooms 114 and II5. The hot air heater 112 has 114 for each room and 115 each have an air inlet opening (not shown) for drawing in cold air according to arrow K directly above the floor 116 of the room 114 and according to arrow L directly above the floor 117 of the room II5. Furthermore, there is one air outlet opening (also not shown) on the upper part of the hot air heater for the outlet of hot air according to arrow M into room 114 and provided in space 115 according to arrow N.

The advantage of the hot air heating according to the invention is that the air of a room to be heated is processed, i.e. H. is heated, whereupon the circulation ensures an even distribution of this heated air. The cold air is at the according to the innovation hot air heating sucked in directly above the floor and led into the heating ducts. Another advantage is that with the new approximately hot air heating energy, especially electrical energy with electrical heating can be used in an economical way for heating purposes, since only thin layers of air are heated in the heating duct and therefore rapid heating of the air can be achieved. The hot air heating according to the innovation can be used as permanent or as Additional heating can be used. Another advantage is that, for example, the effort involved in the hot air heating system according to the invention compared to known heating devices with heating elements is significantly lower, since the hot air heating system according to the invention requires little space.

- Protection claims -

- 1

Claims (1)

I «« t t / I t I «t I« ! Protection claims 1 »Hot air heating with a heating element, characterized in that the heating element is in a bottom and top open cell surrounded by a heating duct and arranged around the heating element around fins, the extend radially away from the heating element and over the length of the same and with one facing away from the heating element Part are firmly and thermally connected to the heating duct jacket and through which the cell is open at the bottom and top Heating channels is divided, and that the cell is surrounded by external insulation and a fan below the cell is provided for conveying air through the heating ducts. 2. Hot air heating according to claim 1, characterized in that that the fan is movably mounted with the cell on rollers or runners. 3. Hot air heater according to claim 1, characterized in that the slats with their facing away from the heating element Part are connected to the heating duct jacket over the largest possible area. 4. hot air heater according to claim 1 or 3, characterized in that that the slats are partially bent at their part facing away from the heating element and with the bent part Part are firmly connected to the heating duct jacket. 5. hot air heater according to claim 4, characterized in that that the lamellas are connected to the heating duct jacket with an entire side surface of the bent part. 6. Hot air heater according to claim 1, characterized in that the slats are made of metal. 7. hot air heater according to claim 1, characterized in _t that a plurality of cells are assembled into a radiator, 8. hot air heating according to claim 1, characterized in that that an air humidifier is provided for evaporating water. 9. hot air heater according to claim 3 »characterized in that the cell has any cross section. 10. Hot air heater according to claim 1 or 9, characterized in that that the cell is a polygon in cross-section. 11. Hot air heater according to claim 1 or 9, characterized in that that the cell is circular in cross-section, 12. Hot air heater according to claim 1, characterized in that the heating element is arranged in the center of the cell. January 23, 1973/6 ^ 8 d