DE102007063314B4 - Device for generating electricity - Google Patents

Abstract

Apparatus for generating electricity with an internal combustion engine (1) cooled by a cooling circuit, with a generator (2) driven by the internal combustion engine (1) and with a counterflow heat exchanger connected on the one hand to an exhaust pipe (14) of the internal combustion engine (1) and on the other hand to a heat transfer medium characterized in that the countercurrent heat exchanger comprises a coiled tube (11) of two coaxial corrugated tubes (12, 13), of which the inner corrugated tube (12) with the exhaust pipe (14) and the annular flow channel (15) between the inner and the outer corrugated tube ( 12, 13) are connected at one end to the return (16) of the heat transfer circuit and at the other end to the inlet (17) of the cooling circuit, whose outlet (18) is connected to the flow (19) of the heat transfer circuit.

Description

The invention relates to a device for generating electricity with a cooled over a cooling circuit engine, with a generator driven by the internal combustion engine and with a connected on the one hand to an exhaust pipe of the engine and on the other hand to a heat transfer medium countercurrent heat exchanger. A device for power generation according to the preamble of claim 1 is, for example. From the EP 1 273 785 A2 known.

The sensible heat of the exhaust gases of an internal combustion engine can not only be used for preheating the cooling water during a cold start ( DE 197 36 606 A1 ), but also in devices for generating electricity with a driven by an internal combustion engine generator to be used to increase the overall efficiency by a heat transfer to a heat exchanger connected to the hot engine exhaust gases is applied to heat the heat transfer medium of this heat transfer, usually water ( EP 1 273 785 A2 ).

In order to provide a sufficient heat exchanger surface, plate heat exchangers connected as countercurrent heat exchangers are available for this purpose. A disadvantage of the use of plate heat exchangers in devices for power generation is, in particular, that plate heat exchanger find hardly any space within an enclosure provided for sound insulation, without increasing the housing forming the housing. In addition, the heat exchanger is exposed to stresses induced by the engine vibrations that limit the life of such heat exchangers.

For preheating combustion air for hot gas engines heat exchangers are known ( DE 26 02 211 A1 ) consisting of two coaxial tubes, which flow through the inner tube, the hot exhaust gases and the air to be heated is passed through the annular gap between the inner and outer tube in countercurrent.

In a similar structure is in another known heat exchanger for the preheating of water for a steam boiler ( GB 684 602 A ) the inner, tube with hot flue gases, while the water to be heated flows through the annular gap between the corrugated inner tube and the smooth outer tube. However, due to the vibration loads, such heat exchangers are not suitable for power generation devices with a generator driven by an internal combustion engine.

The invention is therefore an object of the invention to provide a heat exchanger for a device of the type described, which can be arranged in a space-saving manner, ensures a sufficient heat exchanger surface and has a long service life.

The invention achieves the stated object in that the countercurrent heat exchanger comprises a coiled tube of two coaxial corrugated tubes, of which the inner corrugated pipe with the exhaust pipe and the annular flow channel between the inner and outer corrugated pipe at one end to the return of the heat transfer circuit and at the other end are connected to the inlet of the cooling circuit, whose outlet is connected to the flow of the heat transfer medium.

The formation of the countercurrent heat exchanger as a coiled tube of two coaxial corrugated pipes initially brings with it the advantage that the space available for the accommodation of the heat exchanger can be advantageously used, because the coil must follow any predetermined course and therefore can be laid according to the space conditions. With the length of the coil, an adaptation to the required heat exchanger surface can be made in a simple manner, the corrugation of the corrugated pipes not only provides for an enlargement of the heat exchanger surface and an advantageous for the heat transfer turbulence of the media flows, but also essential for the vibration damping, so can be expected with a long service life of these heat exchangers. Since the annular flow channel between the inner and outer corrugated tube of the coil are connected in the region of the cold end of the heat exchanger to the return of the heat transfer circuit and in the region of the warm end to the inlet of the cooling circuit of the engine, the cooling circuit forms part of the heat transfer circuit, the Flow is connected to the flow of the cooling circuit. This means that the heat transfer medium of the heat carrier circuit serves as a coolant for the cooling circuit of the internal combustion engine and is adapted via the countercurrent heat exchanger to the operating temperature of the internal combustion engine. The dissipated via the coolant heat is thus used directly for the heat transfer medium.

In order to ensure simple connection conditions, at the ends of the outer corrugated pipe of the coil can be attached to a smooth pipe socket with a radial connection on the one hand for the return of the heat transfer circuit and on the other hand for the inlet of the cooling circuit. This avoids the need to connect a radial pipe connection tightly to a corrugated pipe. A compound of a radial Pipe connection with a smooth pipe socket offers no difficulties in this regard.

As already stated, the coil of the countercurrent heat exchanger can be laid differently depending on the space available. Particularly advantageous construction conditions arise in this context when the coil is laid below a combustion engine and the generator receiving base plate in at least one loop, because in this case the countercurrent heat exchanger does not have to be accommodated within the internal combustion engine and the generator housing receiving. The usually given by a socket space below the base plate can be advantageously used by laying the countercurrent heat exchanger in this base area, with simple connection conditions for the heat transfer medium and an exhaust pipe arise, especially if the base plate protrudes over the base, so that in the above part of the Base plate provides sufficient space for connection fittings, even if the patch on the base plate housing connects to a wall.

• 1 eine erfindungsgemäße Vorrichtung zur Stromerzeugung in einem schematischen, blockschaltbildartigen Längsschnitt und
• 2 die Rohrschlange des Gegenstromwärmtauschers ausschnittsweise im Bereich eines Endes in einem Axialschnitt in einem größeren Maßstab.

In the drawing, the subject invention is shown, for example. Show it

• 1 a device according to the invention for power generation in a schematic, block diagram-like longitudinal section and
• 2 the coil of the countercurrent heat exchanger fragmentary in the region of one end in an axial section on a larger scale.

The in the 1 shown device for generating electricity has one of an internal combustion engine 1 and one of this internal combustion engine 1 powered generator 2 made up building on a base plate 3 is mounted. This base plate 3 forms part of one on a pedestal 4 resting housing 5 , which is a soundproof enclosure of the assembly of internal combustion engine 1 and generator 2 represents. To cool this unit fresh air is through a housing passage 6 by means of a fan wheel of the generator 2 sucked, wherein the promoted by the generator housing cooling air flow in a motor chamber 7 exiting through a partition 8th from a generator chamber 9 of the housing 5 is disconnected, so in the motor chamber 7 and in the generator chamber 9 different cooling conditions can be met. The exhaust air from the engine chamber 7 is through a passage 10 in the bottom plate 3 blown out.

To utilize the waste heat of the internal combustion engine 1 is a countercurrent heat exchanger in the form of a coil 11 provided, the two coaxial corrugated pipes 12 and 13 includes. The inner corrugated tube 12 is with the exhaust pipe 14 of the internal combustion engine 1 connected. The annular flow channel 15 between the inner and outer corrugated tube 12 . 13 is in the area of the cold end to the return 16 a heat circuit, not shown, for example, a heating circuit, and in the region of the warm end to the inlet 17 the cooling circuit of the internal combustion engine 1 connected. About the process 18 the cooling circuit is the flow 19 the heat transfer circuit fed. The heat transfer medium of the heat carrier circuit thus forms the coolant for the cooling circuit of the internal combustion engine 1 , The arrangement is made such that the coil 11 the countercurrent heat exchanger below the base plate 3 in the area of the base 4 is laid in at least one loop, so that the countercurrent heat exchanger no space within the housing 5 claimed. The laying in a loop provides a sufficient length of the coil for the heat transfer 11 for sure. Because the connections 20 . 21 for the return 16 and the lead 19 the heat transfer circuit has a peripheral wall of the base 4 prevail, stays below the above the pedestal 4 protruding base plate 3 sufficient space for corresponding connection connections. The same applies to the connection 22 for exhaust gas discharge.

Again 2 can be taken are at the ends of the corrugated pipes 12 . 13 the pipe coil 11 Smooth pipe connections 23 set up to facilitate connection to secondary lines. For this purpose, the smooth pipe socket 23 of the outer corrugated tube 13 in the area of the cold end with the connection 20 for the return 16 the heat transfer circuit and in the region of the warm end with a radial connection 24 provided with the inlet 17 the cooling circuit of the internal combustion engine 1 through a hose 25 connected is. The smooth pipe socket 23 of the inner corrugated tube 12 carries a flange 26 for connection to the exhaust pipe, which also has a connection flange 14 of the internal combustion engine 1 ,

For completeness, it should be mentioned that the coil 11 with one in the 2 dash-dotted line indicated coat 27 is enclosed by a heat-insulating material to prevent heat loss.

LIST OF REFERENCE NUMBERS

1

internal combustion engine

2

generator

3

baseplate

4

base

5

casing

6

Housing passage

7

motor chamber

8th

partition wall

8th

generator chamber

10

passage

11

coil

12

corrugated pipe

13

corrugated pipe

14

exhaust pipe

15

flow channel

16

returns

17

Intake

18

procedure

19

leader

20

connection

21

connection

22

connection

23

Smooth pipe connections

24

connection

25

tube

26

flange

27

coat

Claims (3)

An apparatus for power generation with a cooled via a cooling circuit internal combustion engine (1), with a driven by the internal combustion engine (1) generator (2) and with a one hand, to an exhaust line (14) of the engine (1) and on the other hand connected to a heat carrier circuit countercurrent heat exchanger, characterized characterized in that the countercurrent heat exchanger comprises a coiled tube (11) of two coaxial corrugated tubes (12, 13), of which the inner corrugated tube (12) with the exhaust pipe (14) and the annular flow channel (15) between the inner and the outer corrugated tube ( 12, 13) are connected at one end to the return (16) of the heat transfer circuit and at the other end to the inlet (17) of the cooling circuit, whose outlet (18) is connected to the flow (19) of the heat transfer circuit. Device after Claim 1 , characterized in that at the ends of the outer corrugated tube (13) of the tube coil (11) each have a smooth pipe socket (23) with a radial connection (20, 24) on the one hand for the return (16) of the heat transfer circuit and on the other hand for the inlet (17 ) of the cooling circuit is attached. Device after Claim 1 or 2 , characterized in that the tube coil (11) of the countercurrent heat exchanger below a combustion engine (1) and the generator (2) receiving base plate (3) is laid in at least one loop.

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