DE102009047751A1 - Burner arrangement for production of electricity, has volume burner, whose combustion chamber is formed from porous body - Google Patents

Abstract

The burner arrangement has a volume burner (V1,V2), whose combustion chamber is formed from a porous body (2a,2b). A thermoelectric element arranged in thermal effect connection (5a,5b) is provided with the volume burner. The combustion chamber is surrounded by a burner housing (1a,1b), which has an inlet (E1,E2) for supplying fuel (G) and a discharge opening (AL1,AL2) to discharge incineration gases (A).

Description

The The invention relates to a burner assembly according to the preamble of Claim 1.

Such a burner arrangement is for example from the DE 43 22 109 C2 known. In this case, a porous body is arranged in a cylindrical burner housing. The porous body has an open porosity. An average pore size is chosen so that a surface-stabilized combustion of a fuel can take place within the pore body. Such volume burners are characterized by high efficiency, efficient and homogeneous combustion and high power density. Apart from that, a power generated thereby can be modulated in a wide range of, for example 1:10.

The known burner arrangement can be operated with a fuel which, for example, from a mixture of air and combustible gas or flammable liquid fuel. You can in particular for heating purposes, in particular also as a heat radiator, be used.

at Applications using the conventional burner assembly a part of the heat generated usually remains unused and is lost as waste heat. It is that Need, the efficiency of the conventional burner assembly continue to improve.

task The invention is to the disadvantages of the prior art remove. In particular, a burner arrangement is to be specified, with the with improved efficiency the heat generated with it can be exploited.

These The object is solved by the features of claim 1. Expedient embodiments of the invention result from the features of claims 2 to 12.

To According to the invention, it is proposed that at least a thermoelectric arrayed in thermal communication with the volume burner Element is provided. - This can be surprising high efficiency electric power can be produced. measurements on the volume burner proposed according to the invention have surprisingly revealed that its temperature over a wide power range only in a relative narrow range changes. As a result, a thermoelectric Element by the action of such a volume burner permanently be kept in the range of a temperature, which with high efficiency enables the production of electrical energy. there can the amount of electrical energy gained - independently from the respective performance of the volume burner - in one relatively narrow range to be kept constant. The proposed Burner arrangement is suitable for example for gas heating, where the volume burner in the "standby" mode operated with a low power and only as needed delivers a high performance.

in the For the purposes of the present invention, a "thermoelectric Element "in particular a" Peltier element "understood. In a Peltier effect, two metallic conductors with different electronic heat capacities brought into contact. If the two conductors by heat supply and heat dissipation be kept at a different temperature leads this leads to a flow of current in the conductors. This effect is called also as "Seebeck effect".

Under the term "thermal active compound" is used in Meaning of the present invention understood that the thermoelectrically Element is arranged relative to the volume burner so that in the thermoelectric Element provided different metallic conductors on one different temperature can be maintained and so that the generation of electrical energy is possible.

To an advantageous embodiment is the thermoelectric element on a side facing away from the combustion chamber outer wall of the burner housing intended. The burner housing can be tubular, in particular be round, oval or rectangular designed. Conveniently, is the burner housing made of a metal with a high Thermal conductivity formed. This can be relative a lot of heat on the burner housing the thermoelectric element provided thereon are decoupled.

According to a further embodiment, a heat-insulating layer is provided between the outer wall and the thermoelectric element. The heat-insulating layer may be formed of a conventional heat-insulating material such as a heat-insulating fiber mat, fiberboard or the like. With the proposed heat-insulating layer, which may have a thermal conductivity of, for example, 5 to 15 W / mK, preferably 10 W / mK, the heat draining to the thermoelectric element can be adjusted if a suitable thickness is selected. In this case, the heat flow is advantageously adjusted so that under normal operating conditions of the volume burner, the efficiency of the thermoelectric element is maximum. The thermoelectric element may, for. B. in a temperature range of 210 ° to 250 ° C are operated. A thickness of the heat-insulating layer can at For example, 5 to 20 mm, preferably 8 to 12 mm.

To a further advantageous embodiment of the invention is thermoelectric element facing away from one of the outer wall Side with a cooling device in thermal operative connection. With the cooling device is one for generating a thermoelectric Current required temperature difference between the two the Continuously maintaining thermocouple forming conductors. It can thus be a continuous generation of a thermoelectric Electricity can be guaranteed. The temperature difference is suitably 180 ° to 220 ° C.

To a particularly advantageous embodiment is the cooling device a through-flow of a fluid heat exchanger. The fluid may be ambient air or else one Liquid, such as water, oil or the like., Act. If the heat exchanger, for example, flows through with water the heated water can be used for heating purposes become. At the same time serves the heat exchanger flowing through Water for cooling the thermoelectric element.

To a structurally particularly simple embodiment is the thermoelectric Element in the form of a heat exchanger through which a fluid can flow educated. Ie. in this case, the heat exchanger formed of two different metallic conductors, so that thus thermoelectric power can be generated. - To Another constructive simplification may be that the heat exchanger at least partially the burner housing forms. For example, in a tubular heat exchanger, which simultaneously forms a thermoelectric element, a be absorbed porous body, which is a Combustion chamber for combustion of a fuel forms.

advantageously, is the pore body by means of a thermally insulating Fiber mat held clamped in the burner housing. This allows a particularly simple assembly of the porous body. simultaneously is undesirable due to the thermal insulation effect of the fiber mat high heat flow to the burner housing avoided.

To A further embodiment of the invention may also be that the thermoelectric element is provided in the combustion chamber. For example the pore body can consist of a lower and an upper one Able to be formed. The two layers can be different be made of metallic conductors. The metallic conductors can in the form of a metallic wool, a braid, a knitted fabric or the like. About a suitable setting of Porosity of the two layers can be achieved that one Combustion, for example, takes place only in the upper position. By the then adjusting temperature difference between the two In turn, a thermoelectric current can be generated.

To In a further embodiment, it may also be that the thermoelectric Element on a combustion chamber facing the inner wall of the burner housing is provided. In this case, a mean pore size of the porous body in the direction of the inner wall of the burner housing increase. This can be an increased in the area of the inner wall convective heat transfer and a higher one Heat radiation entry on the thermoelectric element be achieved.

To A further embodiment of the invention may also be that the thermoelectric element downstream of the outlet opening is arranged in an exhaust path of the volume burner. It will the one conductor of the thermoelectric element by the flowing past Heated exhaust gases. The other conductor is expediently arranged so that it is at a low temperature than the one Head can be held.

following Embodiments of the invention with reference to the drawings explained in more detail. Show it:

1 a sectional view through a first burner assembly,

2 a sectional view through a second burner assembly,

3 a sectional view through a third burner assembly,

4 a sectional view through a fourth burner assembly,

5 a partially broken perspective view through a fifth burner assembly,

6 a schematic partial sectional view through a variant according to 5 and

7 a schematic partial sectional view through a further variant according to 5 ,

At the in 1 shown first burner assembly two volume burner V1 and V2 are provided. Each of the volume burners V1, V2 has a burner housing made, for example, of metal 1a . 1b on which rectangular or also zy can be trained lindrisch. With the reference number 2a . 2 B are each called pore body, by means of a heat-insulating elastic fiber mat 3a . 3b clamped in the burner housing 1a . 1b are held. A diameter of the pores 2a . 2 B For example, 10 to 100 mm and its height 10 up to 20 mm. The pore bodies 2a . 2 B may be made of a ceramic foam, a packing made of ceramic ball, a metal wool, a metal fleece, a metal knit or the like. With the reference number 4a . 4b In each case, an optionally provided heat-insulating layer is referred to, which is in contact with thermoelectric elements 5a . 5b is. A the burner housing 1a . 1b opposite side of the thermoelectric elements 5a . 5b is in contact with a cooling element 6 ,

The function of the first burner arrangement is as follows: A mixture G produced from combustible gas and air passes via an inlet E1, E2 of the burner housing 1a . 1b in the pore body 2a . 2 B , The mixture G is burned there. In this case formed exhaust gas A escapes from the burner housing 1a . 1b over outlets AL1, AL2. By the combustion in the porous body 2a . 2 B generated heat is applied to a first conductor (not shown here) of the thermoelectric elements 5a . 5b transfer. The first conductor is via the optional thermal insulation 4a . 4b in contact with a porous body 2a . 2 B remote from the outside of the burner housing 1a . 1b , A second conductor (not shown here) of the thermoelectric elements 5a . 5b is in contact with the cooling element 6 , Because of the temperature difference applied to the first conductor and the second conductor, it forms in the thermoelectric elements 5a . 5b a thermoelectric current, which flows through not shown in detail here conductor.

With the reference number 7a . 7b compensation layers are designated, which can be optionally provided for setting a suitable temperature gradient. Due to the optionally provided heat-insulating layers 4a . 4b as well as the leveling layers 7a . 7b may be one for operation of the thermoelectric elements 5a . 5b optimal temperature can be adjusted.

2 shows a second burner assembly. The second burner arrangement differs from that in 1 shown first burner assembly characterized in that in the porous bodies 2a . 2 B a pore size to an inside of the burner housing 1a . 1b increases. This allows increased heat transfer by means of convection and radiation to the burner housing 1a . 1b be achieved. The heat extraction on the thermoelectric elements 5a . 5b can be increased with it.

The in the 3 and 4 shown third and fourth burner assemblies are similar to the second burner assembly constructed. In the third burner arrangement, the burner housing extends 1a . 1b at one of the thermoelectric elements 5a . 5b facing side in the region of the outlets AL1, AL2 via an outlet-side surface of the pore body 2a . 2 B out. By a supernatant 8a . 8b of the burner housing 1a . 1b becomes the burner housing 1a . 1b additionally heated by radiation S in this area. This can be a heat input to the thermoelectric elements 5a . 5b be further increased.

4 shows a fourth burner assembly, which is configured similar to the third burner assembly. In this case, the supernatant 8a . 8b of the burner housing 1a . 1b an angled portion which projects into an exhaust stream A emerging from the outlets AL1, AL2. With this configuration, it succeeds again, the heat input from the burner housing 1a . 1b on the thermoelectric elements 5a . 5b to increase.

At the in 5 shown fifth burner assembly is the pore body 2 again in a burner housing 1 held, which is designed here in the form of a metal frame. The burner housing 1 is from a heat exchanger 9 surrounded, which is constructed double-walled and can be flowed through with a cooling fluid. The heat exchanger 9 is constructed of a first and a second metallic conductor (not shown here) and thus at the same time fulfills the function of a thermoelectric element.

At the in 6 shown variant is on an outside of a burner housing 1 optionally the heat-insulating layer 4 provided, which in contact with the thermoelectric element 5 is. With the reference number 10 is a, for example, made of a metal, heat-compensating layer, which in contact with a coolant-flowed tubes 11 another heat exchanger is. At the in 6 shown variant, the tubes 11 a circular cross section, in which 7 shown variant, the tubes 11 a rectangular cross section.

1, 1a, 1b

burner housing

2, 2a, 2b

porous body

3a, 3b

elastic fiber mat

4, 4a, 4b

thermal insulation layer

5a, 5b

thermoelectric element

6

cooling element

7a, 7b

leveling layer

8a, 8b

Got over

9

heat exchangers

10

Further leveling layer

11

pipe

A

exhaust

AL1, AL2

outlet

E1, E2

inlet

G

Fuel gas / air mixture

V1, V2

volume burner

QUOTES INCLUDE IN THE DESCRIPTION

This list The documents listed by the applicant have been automated generated and is solely for better information recorded by the reader. The list is not part of the German Patent or utility model application. The DPMA takes over no liability for any errors or omissions.

Cited patent literature

• - DE 4322109 C2 [0002]

Claims (12)

Burner arrangement, comprising a volume burner (V1, V2) whose combustion chamber consists essentially of a porous body ( 2 . 2a . 2 B ), characterized in that at least one with the volume burner (V1, V2) arranged in thermal operative connection thermoelectric element ( 5a . 5b ) is provided. Burner assembly according to claim 1, wherein the combustion chamber of a burner housing ( 1 . 1a . 1b ) having an inlet (E1, E2) for supplying a fuel (G) and an outlet (AL1, AL2) for exhausting combustion gases (A). Burner arrangement according to one of the preceding claims, wherein the thermoelectric element ( 5a . 5b ) on a combustion chamber facing away from the outer wall of the burner housing ( 1 . 1a . 1b ) is provided. Burner arrangement according to one of the preceding claims, wherein between the outer wall and the thermoelectric element ( 5a . 5b ) a heat-insulating layer ( 4 . 4a . 4b ) is provided. Burner arrangement according to one of the preceding claims, wherein the thermoelectric element ( 5a . 5b ) on a side facing away from the outer wall with a cooling device ( 6 . 11 ) is in thermal operative connection. Burner arrangement according to one of the preceding claims, wherein the cooling device ( 6 . 11 ) a through-flow of a fluid heat exchanger ( 9 ). Burner arrangement according to one of the preceding claims, wherein the thermoelectric element ( 5a . 5b ) in the form of a heat exchanger through which a fluid can flow ( 9 ) is trained Burner arrangement according to one of the preceding claims, wherein the heat exchanger ( 9 ) at least in sections, the burner housing ( 1 . 1a . 1b ). Burner arrangement according to one of the preceding claims, wherein the porous body ( 2 . 2a . 2 B ) by means of a thermally insulating fiber mat ( 3a . 3b ) clamped in the burner housing ( 1 . 1a . 1b ) is held. Burner arrangement according to one of the preceding claims, wherein the thermoelectric element ( 5a . 5b ) is provided in the combustion chamber. Burner arrangement according to one of the preceding claims, wherein the thermoelectric element ( 5a . 5b ) on a combustion chamber facing the inner wall of the burner housing ( 1 . 1a . 1b ) is provided. Burner arrangement according to one of the preceding claims, wherein the thermoelectric element ( 5a . 5b ) is arranged downstream of the outlet opening (AL1, AL2) in an exhaust path of the volume burner (V1, V2).