DE29513958U1 - Electrical generator, in particular generator driven by an internal combustion engine for a combined heat and power plant - Google Patents

Description

R.29458

10.08.1995 Ve/S

ROBERT BOSCH GMBH, 70442 Stuttgart

Electric generator, in particular a generator driven by an internal combustion engine for a combined heat and power plant

STATE OF THE ART

The invention relates to an electric generator, in particular a generator driven by an internal combustion engine for a combined heat and power plant, according to the preamble of the main claim.

Such liquid-cooled, especially water-cooled, electrical generators are often operated at a relatively high coolant temperature of, for example, 70°C, if, for example, the water circuit is designed as a heating circuit, which requires such temperatures. However, such high temperatures mean a high load on the rotary bearings for the rotor or the rotor shaft.

ADVANTAGES OF THE INVENTION

The generator according to the invention with the characterizing features of the main claim has the advantage that, despite the high coolant temperature, a technically permissible bearing temperature is achieved at least for the bearing areas through the additional air cooling, so that the load on the rotary bearing can be reduced to an acceptable level. This is necessary above all for a high level of operational reliability and a long service life of the electric generator, especially if it is used in continuous operation or almost in continuous operation, as is the case, for example, in combined heat and power plants.

is the case. By reducing the pivot bearing temperature, the maintenance requirements can also be reduced.

The measures listed in the subclaims enable advantageous further developments and improvements of the electric generator specified in the main claim.

A particularly advantageous air cooling device consists in the fact that the rotor shaft has a longitudinal channel opening out at one of its front sides at least in the area of a rotary bearing, with at least one side channel connected to the longitudinal channel opening out at the circumferential surface of the rotor shaft in the interior of the housing. This air cooling device works independently when the rotor shaft is rotating, since the air is drawn out of the at least one side channel by centrifugal force, so that air flows axially into the longitudinal channel. No suction fan or other additional device is required here. This air cooling device is particularly suitable for the rotary bearing area where the rotor shaft has a free end or a free end face.

The longitudinal channel is expediently designed as a concentric bore and the at least one side channel as a transverse bore. Preferably, several side channels are provided distributed over the circumference so that the formation of an imbalance in the rotor shaft is prevented.

By designing the at least one side channel as an obliquely running channel, the opening direction of which points away from the front side of the rotor shaft provided with the opening of the longitudinal channel, an obliquely directed outlet air flow is achieved, which preferably

The cooling disk connected to the rotor shaft can be aligned to achieve an additional cooling effect. In addition, the slanted course of the side channels means that the air flow in the rotor shaft is only slightly deflected, creating an aerodynamically favorable arrangement.

To support the formation of a good cooling air flow, the generator housing has air outlet openings for the air drawn in from outside through the longitudinal channel. The path of the air flow in the generator housing can also be adjusted through these air outlet openings.

The cooling of the respective pivot bearing is particularly effective when this pivot bearing surrounds the longitudinal channel in the rotor shaft.

On the connection side of the generator, where it is connected to an internal combustion engine that drives it, an air cooling device is particularly suitable, in which the connection area between the generator and the internal combustion engine is surrounded by a housing that has air inlet openings and an air extraction line. The air inlet openings are preferably located substantially opposite the mouth of the air extraction line in order to achieve an air flow through the entire interior, i.e. an air flow that is guided past the bearings on both sides and the coupling area between the generator and the internal combustion engine, so that all of these components are well cooled.

The air extraction line is preferably connected to a suction fan.

For liquid cooling or water cooling of the generator, the outer surface of the generator housing is advantageously

Typically double-walled or surrounded by a liquid cooling tube.

The liquid cooling device for the generator is particularly suitable as a component of a heating circuit in a combined heat and power plant, whereby the generator is a component of this combined heat and power plant. The heat generated in the generator during its operation can therefore be used.

DRAWING

An embodiment of the invention is shown in the drawing and explained in more detail in the following description. The single figure shows as an embodiment a longitudinal sectional view of a generator connected to a partially shown internal combustion engine.

DESCRIPTION OF THE IMPLEMENTING EXAMPLE

In the embodiment shown in the single figure, an electric generator 10 is driven by an internal combustion engine 11, which is only shown schematically and partially, which is, for example, a diesel or gasoline engine that can be operated with liquid or gaseous fuel. In order to non-rotatably couple the generator 10 to the internal combustion engine 11, an output shaft 12 of this internal combustion engine 11 is connected to a rotor shaft 14 of the generator 10 via a coupling device 13, which is only shown schematically.

The generator 10 has a cylindrical housing 15, on the front sides of which the rotor shaft 14 is rotatably mounted in rotary bearings 16, 17. These can be ball bearings, roller bearings, needle bearings or other known bearings

The rotor shaft 14 carries a rotor 18 which, in a manner known per se, rotates within a stator 19 fixed to the inner circumference of the housing 15 in order to generate electrical energy.

To cool the generator 10 or the stator 19, the housing 15 is designed with a double wall on the circumference, i.e. a tubular wall 20, against which the stator 19 rests on the inside, is surrounded by a pipe 21 with a larger diameter, forming an annular space 22 for cooling water. This annular space 22 has a water inlet connection 23 and a water outlet connection 24 on the front side, whereby the connections can also be arranged radially. These connections are connected to a heating circuit (not shown), whereby the waste heat from the generator is used to heat a heating system. Of course, other heat sources are connected to this circuit when designed as a cogeneration plant, such as a cooling circuit through the internal combustion engine 11 as well as an exhaust gas heat exchanger and possibly further heat exchangers.

Of course, the double-walled area of the housing 15 can also extend over the front sides. It is also possible to attach a cooling pipe to the generator housing, which can be laid in turns around the generator. Cooling channels can also be provided in the stator.

To cool the rotary bearing 17, which is arranged in the area of the free end of the rotor shaft 14 facing away from the internal combustion engine 11, the rotor shaft 14 has a concentric axial longitudinal bore 25 there, which opens out at the front side of the rotor shaft 14.' The rotary bearing 17 thus encompasses this longitudinal bore 25. At the opposite end area of the longitudinal bore 25 inside the housing

15, inclined side bores 26 run from the longitudinal bore 25 to the circumferential surface of the rotor shaft 14. The incline points away from the free end face of the rotor shaft 14, i.e. is directed towards the interior of the housing 15, where a cooling disk 27 is fixed in a rotationally fixed manner next to the rotor 18 on the rotor shaft 14. The corresponding end wall 28 of the housing 15 has air outlet openings 29 at the radially outer end area.

When the rotor shaft 14 rotates quickly when the generator 10 is in operation, the air in the side holes 26 is drawn outwards by centrifugal force and is directed diagonally against the cooling disk 27. At the same time, air is sucked in through the longitudinal hole 25. The air thus sucked into the interior of the housing is released back out through the air outlet openings 29. This results in automatic air circulation, which cools the rotary bearing 17 and the cooling disk 27 to such an extent that a technically permissible bearing temperature is reached, for example when working with a very high coolant temperature of, for example, 70°C in the cooling circuit. The cooling disk 27 can, for example, serve for additional cooling of the rotor shaft 14 or can be omitted in individual cases.

The intermediate area between the internal combustion engine 11 and the generator 10 is surrounded by a tubular housing 30. This has air inlet openings 31 at the bottom and an air suction line 32 at the top, to which a suction fan (not shown) can be connected. When the suction fan is in operation, air is sucked out through the air suction line 32 so that outside air flows through the air inlet openings 31 into the interior of the housing 30 and flows past the rotary bearing 16, the clutch device 13 and a rotary bearing 33 for supporting the output shaft 12 of the internal combustion engine 11 and cools these components. This means

the coupling device 13 and the pivot bearings arranged there are also kept at a permissible storage temperature.

It is of course also possible to pass the air extracted through the air extraction line 32 through a heat exchanger in order to be able to recover residual heat from this air. The operation of the suction fan on the air extraction line 32 can also be temperature-dependently controlled, i.e. the suction fan is only switched on when the temperature of the coupling device 13 or the pivot bearings 16, 33 exceeds a predetermined limit value.

Claims (1)

R.29458 10.08.1995 Ve/S ROBERT BOSCH GMBH, 70442 Stuttgart Electric generator, in particular a generator driven by an internal combustion engine for a combined heat and power plant Expectations 1. Electric generator, in particular a generator driven by an internal combustion engine for a combined heat and power plant, with a liquid-cooled stator and/or generator housing and a rotor shaft mounted in rotary bearings and carrying a rotor, characterized in that an air cooling device (25, 26; 30 - 32) is additionally provided. 2. Generator according to claim 1, characterized in that the rotor shaft (14) has a longitudinal channel (25) opening out at one of its end faces at least in the region of a rotary bearing (17), wherein in the interior of the housing (25) at least one side channel (26) connected to the longitudinal channel (25) opens out at the circumferential surface of the rotor shaft (14). 3. Generator according to claim 2, characterized in that the longitudinal channel (25) is designed as a concentric bore and the at least one side channel (26) is designed as a transverse bore. 4. Generator according to claim 2 or 3, characterized in that the at least one side channel (26) is designed as an obliquely extending channel, the opening direction of which is from the opening of the longitudinal channel 9
(25) facing away from the front side of the rotor shaft (14). 5. Generator according to one of claims 2 to 4, characterized in that several side channels (26) are provided distributed over the circumference. 6. Generator according to one of claims 2 to 5, characterized in that the mouth of the at least one side channel (26) is directed towards a cooling disk (27) connected in a rotationally fixed manner to the rotor shaft (14). 7. Generator according to one of claims 2 to 6, characterized in that the generator housing (15) has air outlet openings (29) for the air sucked in from outside through the longitudinal channel (25). 8. Generator according to one of claims 2 to 7, characterized in that the rotary bearing (17) surrounds the longitudinal channel (25). 9. Generator according to one of the preceding claims, characterized in that the connecting area between the generator (10) and an internal combustion engine (11) driving it is surrounded by a housing (30) which has air inlet openings (31) and an air suction line (32). 10. Generator according to claim 9, characterized in that the air inlet openings (31) are substantially opposite the mouth of the air suction line (32). 11. Generator according to claim 9 or 10, characterized in that the air suction line (32) is connected to a suction fan. 12. Generator according to one of the preceding claims, characterized in that the outer surface of the generator housing
(15) is double-walled for liquid cooling or is surrounded by a liquid cooling tube (21)
is encompassed. 13. Generator according to claim 12, characterized in that the liquid cooling device for the generator (10) is part of a heating circuit of a combined heat and power plant, the generator (10) forming part of the combined heat and power plant.