DE10064174C2 - Heater for electric heating - Google Patents

Description

The invention relates to a heating device according to the preamble of Claim 1.

Electric heaters are usually made with heating resistors operated from metals, graphite or conductive non-metals and metal ceramics exist. However, it is difficult to use such heating resistors training low heating outputs and / or over large areas spread. Such heaters are for lighting purposes neither intended nor suitable.

It is also already known to use optical radiation sources from the ultraviolet Range over the visible range up to the infrared range for one Use radiant heating of objects on which the beam energy is converted back into heat. Such radiation source len are exemplary in the medical-therapeutic area, in Sola rien, for paint drying and curing, plastic curing u. Like. Used. For purposes of lighting and / or heating rooms such radiation sources are neither intended nor suitable.

It is also known that a very large part of the filament lamps absorbed electrical energy converted into unwanted heat and that the light output in relation to the power consumption only is relatively small. In addition, the life of such filament lamps relatively low.  

To save electricity, therefore, will increase for lighting purposes the size of fluorescent lamps used in which the light generation through a gas discharge and implementation with an inner coating the lamp tubes are done. These fluorescent lamps have many longer lifespan, and with them the heat development is opposite the luminous efficacy is significantly reduced. Fluorescent lamps, often also as "Neon tubes" are called, but are not for heating rooms intended.

DE 10 58 650 B is an electrical heat radiation device known, in the case of sheaths (tubes) made of silicon dioxide heating wires usual heat conductor alloys are arranged that are either smooth straight, single or multiple coiled and for the through knives from 0.2 to 0.7 mm are specified. As clear width for the covers 0.3 to 8 mm are given and common operating temperatures of about 1000 ° C. The spotlights are designed for specific services from Send 1 kW / m to 3 kW / m of infrared rays and for treatment of materials. The ultraviolet rays are for human Invisible eye, so the spotlights are not light sources. The use for the space heating is not addressed, nor is it suggested.

DE 11 92 804 B is working with radiation or convection the space heater known, the radiation sources are not closer are described. Rather, it's about the ratio of radiation to influence convection through adjustable panels or slats.

DE 18 61 668 U is a combined radiation and convection oven known in which the variable air flow through cross-flow blowers or Tangential fan is in the foreground. It's mainly about the fjord very hot air. As heating elements are heating rods with inside gender heating coil specified, or a resistance heater.

DE 42 14 141 C2 is a device for generating a guided air flow known for intensive cooling, which is also a  has elongated radiation source. This is as a UV or infrared emitter described. Again, it is not a room heater, but a radiation source for the treatment of materials. The Space heating is not addressed.

DE 196 07 817 A1 discloses a display device, in particular for Passenger information at train stations, known to the rear Illumination of flat panel displays has fluorescent tubes. stations are always open on at least one side, and their interior is full Exposed to climate fluctuations. An adjustable facility for circulation The cooling air is used for temperature control or to compensate for temperature fluctuations in the temperature of the entire display device outdoors. By a heat exchanger with primary and secondary side is ensured that only the excess heat is dissipated to the environment, and this excess heat is transferred to the free environment in the train station hall removed. As control devices are to reduce performance Electronic ballasts specified that are usually practical do not develop any heat loss that can be used for heating purposes. About the on the primary side of the heat exchanger arranged fluorescent tubes there is no forced circulation of blower air, rather it should Primary side of the housing expressly dust and moisture proof be trained. Forced ventilation takes place exclusively on the Secondary side of the heat exchanger, and only from there is excess Heat is given off to the open station concourse. For room heating the known device is neither provided nor suitable, especially since the Heat dissipation is lowest when the heat requirement for Temperature control of the flat screens is greatest. This display device tion is in particular alien to the species.

From the generic US 6 160 956 A published just before the filing date shows that even the author did not consider this has gone, a fluorescent tube could only hint at one Contribute to space heating. The ceiling fan known in this way has a combined heating and lighting device, but clearly separated components and functions: It pulls like  a common thread running through the entire script that in addition to the phosphor lamp at least one heating element is provided. As heating elements are various electrical heating resistors specified such as PTC resistors stands that regulate themselves automatically by increasing the temperature. metal films or conventional oven heating elements. Special funds for the Surface enlargement for the distribution of the heating resistors generated heat may be provided, such as the reflector Fluorescent tube. This necessarily suggests that the heating resistor would generate large amounts of heat and that without special means for Heat distribution and heat dissipation cause the device to overheat that would.

The invention is therefore based on the object of a heating device to specify the genus described above, the Heat source and / or as Light source can be used.

According to the invention, the object is achieved by Features in the characterizing part of patent claim 1.

The object is fully achieved by the invention, in particular a heating device of the type described at the beginning Genus created that simultaneously or alternatively as a moderate or large area heat source and / or as intense and large area light source can be used. In a further embodiment of the invention by there is also a housing with light exit openings of variable size the ratio of heat and light energy can also be changed.

The invention is based on the consideration that fluorescent lamps and their associated chokes still develop enough heat that can be used for heating purposes, especially if one several fluorescent lamps in greater "packing density" used. It was surprisingly found that fluorescent lamps in heating up close proximity considerably, especially in housings,  and that part of the light energy that is not from the housing emerges through multiple reflection and interaction with the housing walls and the other fluorescent lamps as thermal energy can win, which is added to the usual waste heat.

Without a fan, the housing takes on after only a short period of operation on the upper side a considerable temperature, so that the upper side can hardly be touched with the bare hand. This is already the case when two or more fluorescent lamps of 25 each up to 50 watts of power can be accommodated in one housing. When used Six or eight fluorescent lamps can be used in this way Achieve heating outputs of 200 to 400 watts, which for heating Spaces or zones within rooms are quite sufficient.

With a fan, a significantly better temperature distribution can be achieved also reach within the housing. So a heat build-up between avoid the fluorescent lamps even with an airtight housing and the heat faster on the housing walls and from there to the opposite exercise. For a housing with openings for air intake and air leakage, the distribution effect to the environment is even better and more effective.

Further advantages result from the subclaims and from the Detailed description.

In the course of further refinements of the invention, it is particularly advantageous if, either individually or in combination:

• - the fluorescent lamps touch each other linearly,
• - The fluorescent lamps by spacers at a distance are kept apart
• - The spacers are designed as horizontal plates,  
• - The spacers are designed as opaque plates,
• - The spacers are designed as radiation-permeable plates are,
• - Vertical partition walls arranged between the fluorescent lamps are,
• The housing is provided with at least one light exit opening,
• - The at least one light exit opening with a grating or Rust is provided,
• - The at least one light exit opening with a closure element is provided
• - The closure element as a transparent or translucent disc is trained,
• - The cross section of the light exit opening (s) can be changed and / or if
• - The housing as a light exit opening with an overhead window a grate for storing food.

Exemplary embodiments of the subject matter of the invention are explained in more detail below with reference to FIGS. 1 to 11:

Show it:

Fig. 1 is a heater with a cuboid housing,

Fig. 2 is a heater having a housing with a trapezoidal cross-section Wesent union,

Fig. 3 shows a cross section through an arrangement of two nebeneinan the underlying tubular fluorescent lamps,

Fig. 4 shows a cross section through an array of six fluorescent lamps röhrenförmi gene with a virtual envelope surface in the form of a regular triangular prism,

Fig. 5 shows a cross section through an arrangement of eight röhrenförmi gen fluorescent lamps with a virtual envelope surface in the form of a horizontal parallelepiped,

Fig. 6 shows the arrangement according to Fig. 3, within a cylindrical housing

Fig. 7 shows the arrangement according to FIG. 4 within a prismatic housing,

Fig. 8 shows the arrangement of FIG. 5 shaped lying within a cuboid housing,

9 shows a cross section through an assembly of two spaced adjacent tubular fluorescent lamps.,

Fig. 10 shows a cross section through an arrangement of six tubular fluorescent lamps with spacers and a virtual envelope surface in the form of an approximately regular triangular prism and

Fig. 11 shows a cross section through an arrangement of eight röhrenförmi gen fluorescent lamps with spacers and partitions, and a virtual envelope surface in the form of a horizontal parallelepiped,

In Fig. 1, a heater is shown with a cuboid housing 1 , the smallest wall elements 2 and 3 are placed upright. The front wall 4 (and possibly also the rear wall) is provided with a rectangular light outlet opening 5 , behind which a stack of tubular fluorescent lamps 6 is arranged, which for example can correspond to the arrangement according to FIGS. 5 or 8, but rotated by 90 degrees erected location. The housing has a base region 7 , in which - not particularly emphasized here - the chokes required for the operation of the fluorescent lamps 6 are arranged. Both the fluorescent lamps 6 and the chokes develop heat which is removed from the housing 1 by means of circulating cooling air. For this purpose, there is a blower 8 behind the wall element 2 , which is designed as a cross-flow fan with a vertical axis A, which is only indicated by dashed lines and blows cooling air in the direction of the arrows 9 over the fluorescent lamps 6 .

Grating elements 10 extend over the light exit opening 5 and allow the heated air to exit. Alternatively, the light outlet opening 5 can also be covered by a pane made of transparent or translucent material. If all of the energy is to be converted into heat, the light exit opening or the light exit openings 5 can also be covered by a wall element made of a non-translucent material, whereby these wall elements can also be movable to influence the light emission (see also FIG. 7). , If an air outlet through the light outlet opening is not possible or is not provided, the housing 1 is provided with corresponding air outlet openings, not shown. The cooling air is of course also routed through the throttles. The cooling air can also be circulated only within the housing 1 , so that the heat is given to the housing walls and the housing cover and from here to the environment.

FIG. 2 shows an analog heating device with a housing 11 with an essentially trapezoidal cross-section, which continues downwards in a base region 7 , in which the chokes are also arranged here. In such a cross section, for example, a stack of fluorescent lamps 6 according to FIG. 4 can be arranged.

FIGS. 3, 4 and 5 show cross sections through different Anord voltages of two, six and eight tubular fluorescent lamps 6, which all touching linear. In the arrangements of FIGS. 4 and 5, 6 air channels are formed between the fluorescent lamps 12 and 13, the lamps a to the cylindrical surfaces of the phosphor 6 have respective gore-shaped cross-section and are traversed by the cooling air. This avoids a build-up of heat, which is after all considerable.

FIG. 6 shows the arrangement of the fluorescent lamps 6 according to FIG. 3 within a rectangular housing 14 with two (above and below) opposite light exit openings 5 .

FIG. 7 shows the arrangement of the fluorescent lamps 6 according to FIG. 4 within a regular, triangular prismatic housing 15 . In the roof surfaces 15 a and 15 b there are in turn two light exit openings 5 , which can be more or less closed by closure elements 15 c and 15 d of the nature described above. The closure elements 15 c and 15 d can also be replaced by laterally guided or non-guided blinds. In the base area 7 are below an intermediate floor 15 e the chokes already described but not shown.

The heaters shown in FIGS. 1 to 7 may equipment as Raumheiz with and are used without light leakage and on the ground, o on shelves. Like. Parked be attached to the wall or suspended from the ceiling, wherein all structural elements are interchangeable ,

FIG. 8 shows the arrangement of the fluorescent lamps 6 according to FIG. 5 within a lying cuboid housing 16 with two (above and below) opposite light exit openings 5 . The lower light outlet opening can be omitted if necessary. By an intermediate wall 16 a, a chamber 16 b is delimited for accommodating the chokes, not shown. This heating device is designed for use as a food warming device (rechaud) and is placed on feet 17 . A grid 18 is used to place the food inside or above the upper light exit opening 5 . Such a heater is used for particularly gentle warming of the food and at the same time as an interesting light source for illuminating the food container from below. At the bottom of the food containers, further radiation energy is converted into heat.

The fluorescent lamps 6 , the number of which is not limited at the top, are preferably arranged in the greatest possible “packing density”, but do not necessarily have to touch: gaps for passing cooling air in the transverse direction to the lamps can also be provided in between.

FIG. 9 shows a cross section through an arrangement of two tubular fluorescent lamps 6 lying next to one another at a distance "d". In this case, the air can also be blown perpendicular to the fluorescent lamps 6 through the gap "S".

Fig. 10 shows a cross section through an arrangement of six tubular fluorescent lamp 6 with two spacers 19 in the form of horizontal plates and a virtual envelope "H" in the form of a regular roughly triangular prism.

Fig. 11 shows a cross section through an arrangement of eight tubular fluorescent lamps 6 with spacers 19 in the form of horizontal plates and with vertical partitions 20 , which - as shown - do not have to be present in each plane and with a virtual envelope surface in the form of a, not shown lying cuboid.

The following applies to FIGS. 10 and 11: The fluorescent lamps 6 also have spacings "d", but they do not have to be the same everywhere. Air channels 12 are formed by these plates, which are formed continuously over the entire length of the fluorescent lamps 6 . On the plates, which can be transparent (glass) or impermeable (opaque, metal, ceramic) to the light radiation, part of the radiation energy is in turn converted into heat, which is dissipated by the air.

Instead of the continuous over the length of the fluorescent lamps 6 plates can also be used as a spacer 19 strip-shaped elements, so that the air can also be blown perpendicular to the fluorescent lamps 6 through the distances "d".

The arrangements according to FIGS . 9, 10 and 11 can be accommodated in similar or analog housings, as is shown with reference to FIGS . 6, 7 and 8.

The location of all heating devices can be chosen practically arbitrarily become. Transparent or translucent material can also be made entirely or partially used for the housing walls, so that the lights openings match the housing walls.  

LIST OF REFERENCE NUMBERS

1

casing

2

wall element

3

wall element

4

front wall

5

Light opening

6

fluorescent lamps

7

plinth

8th

fan

9

arrows

10

grid elements

11

casing

12

air ducts

13

air ducts

14

casing

15

casing

15

a roof area

15

b roof area

15

c closure element

15

d closure element

15

e mezzanine

16

casing

16

a partition

16

b chamber

17

feet

18

rust

19

spacer

20

partitions
A axis
d distance
H envelope surface
S gap

Claims (13)

1. Heating device with a heat source for the electrical heating of closed rooms, with a fluorescent lamp ( 6 ) and with means for air guidance, characterized in that

• a) as a heat source, several tubular fluorescent lamps ( 6 ) in a housing ( 1 , 11 , 14 , 15 , 16 ) parallel to each other and arranged in such a neighborhood that between the fluorescent lamps ( 6 ) channels ( 12 , 13 ) or column ( 5 ) are formed for an air flow that
• b) in the housing for the operation of the fluorescent lamps Necessary chokes and at least one blower ( 8 ) for an air flow over the fluorescent lamps ( 6 ) and the chokes are arranged, and that
• c) the exhaust air heated by the fluorescent lamps ( 6 ) and the chokes serves as heating air for the room heating.

2. Heating device according to claim 1, characterized in that the fluorescent lamps ( 6 ) touch each other linearly. 3. Heating device according to claim 1, characterized in that the fluorescent lamps ( 6 ) by spacers ( 19 ) are held at a distance "d" from each other. 4. Heating device according to claim 3, characterized in that the spacers ( 19 ) are designed as horizontal plates. 5. Heating device according to claim 3, characterized in that the spacers ( 19 ) are designed as opaque plates. 6. Heating device according to claim 3, characterized in that the spacers ( 19 ) are designed as radiation-transparent plates. 7. Heating device according to claim 1, characterized in that vertical partition walls ( 20 ) are arranged between the fluorescent lamps ( 6 ). 8. Heating device according to claim 1, characterized in that the housing ( 1 , 11 , 14 , 15 , 16 ) with at least one light exit opening ( 5 ) is provided. 9. Heating device according to claim 8, characterized in that the at least one light exit opening ( 5 ) is provided with a grating ( 10 ) or a grate ( 18 ). 10. Heating device according to claim 8, characterized in that the at least one light outlet opening ( 5 ) with a closure element ( 15 c, 15 d) is provided. 11. Heating device according to claim 10, characterized in that the closure element ( 15 c, 15 d) is designed as a transparent or translucent disc. 12. Heating device according to claim 8, characterized in that the cross section of the light exit opening (s) ( 5 ) is variable. 13. Heating device according to claim 8, characterized in that the housing ( 16 ) as a light exit opening ( 5 ) has an overhead window with a grate ( 18 ) for the storage of food.