JPH11350918A - Gas turbine power generating unit - Google Patents

Abstract

PROBLEM TO BE SOLVED: To simplify a gas turbine power generation plant by eliminating ducts and separations. SOLUTION: An gas turbine 1 and a power generator 2 are accommodated in an enclosure 3. Inside of the enclosure 3 is a single space with no separation or duct. This space continues from an air inlet port 5 through an air discharge port 6 directly. At the air inlet port 5, a guide plate 7 is provided, while at the air discharge port 6, a ventilation fan 8 with a large static pressure is provided. Cooling air for the power generator 2 is sucked from the air inlet port 5 into the enclosure 3 by the ventilation fan 8 at the air discharge port 6. The power generator 2 is thus made to suck air from the enclosure 3. In regard with the air flow in the enclosure 3, which is generated by the ventilation fan 8, a suction port 2a of the power generator 2 is assigned to be the upstream and a discharge port 2b thereof to be the downstream. Accordingly, air used for cooling the power generator 2 is discharged outside without being circulated. Since there are no duct or separation, assembling and disassembling is easy.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a gas turbine power generator for driving a generator by a gas turbine, and more particularly to a gas turbine power generator of a type in which a gas turbine and a generator linked together are housed in a box-shaped enclosure. It concerns the device.

[0002]

2. Description of the Related Art A gas turbine power generator of a type in which a gas turbine and a generator linked together are housed in a box-shaped enclosure, air is taken into the enclosure to cool the generator, and after cooling, the air is removed. It has a structure for discharging to

FIG. 2 is a sectional view of a conventional gas turbine power generator having a duct type structure. The gas turbine 1 and the generator 2 linked together are connected to a box-shaped enclosure 20.
It is stored in. An intake silencer 21 is provided at one end of the enclosure 20, and an air intake 22 is formed. The generator 2 has a cooling intake device. The intake port 2 a is on the side remote from the gas turbine 1, and the exhaust port 2 b is on the side close to the gas turbine 1. The air inlet 22 of the enclosure 20 and the air inlet 2 a of the generator 2 are directly connected and communicated by a duct 23. That is, the air inlet 22 of the enclosure 20 is not directly opened in the enclosure 20, and all the air entering from the air inlet 22 of the enclosure 20 enters the generator 2 through the air inlet 2 a of the generator 2. Have been. An air outlet 24 is formed on the gas turbine 1 side of the enclosure 20. A ventilation fan 25 is provided at the air outlet 24. The air discharged into the enclosure 20 from the exhaust port 2b of the generator 2 is discharged outside the enclosure 20 by the ventilation fan 25. 26 is a lubricating oil cooler.

According to the gas turbine power generator shown in FIG. 2, the air inlet 22 of the enclosure 20 is directly connected to the air inlet 2 a of the generator 2. That is, in this device, air is sucked from outside the enclosure 20 by the suction device of the generator itself, and is taken into the generator 2.

[0005] The air that has cooled the generator 2 is exhausted from the exhaust port 2 b into the enclosure 20, and the air is exhausted outside the enclosure 20 by the ventilation fan 24.

FIG. 3 is a sectional view of a conventional gas turbine power generator having a partition type structure. The gas turbine 1 and the generator 2 linked together are housed in a box-shaped enclosure 30. An intake silencer 31 is provided at one end of the enclosure 30, and an air intake 32 is formed. The inside of the enclosure 30 is divided into two spaces by a partition wall 33. The generator 2 penetrates the partition wall 33 in a substantially airtight state, and is installed over two spaces. The generator 2 has a cooling air intake device, and its air intake port 2a is on the side remote from the gas turbine 1 and opens to the first space, and its exhaust port 2b
Is on the side close to the gas turbine 1 and opens to the second space. On the gas turbine 1 side of the enclosure 30,
An air outlet 34 is formed. Here, a ventilation fan 35 is provided. The ventilation fan 35 is connected to the generator 2
And for discharging the air discharged from the lubricating oil cooler 35 to the outside.

According to the gas turbine power generator shown in FIG. 3, the air inlet 32 of the enclosure 30 is located in the first space partitioned by the partition wall 33, and the air can be sucked here by the generator 2 itself. Only the intake device. That is, in this device, the enclosure 3 is operated by the suction device of the generator 2 itself.
Air is sucked from outside and taken into the generator 2.

Then, the air that has cooled the generator 2 is discharged from the exhaust port 2b into the second space, and this air is discharged out of the enclosure 30 by the ventilation fan 35.

[0009]

The reason why the conventional gas turbine power generator has the duct 23 and the partition wall 33 as described with reference to FIGS. 2 and 3 is as follows. That is, in these conventional devices, since the air is sucked in from the outside by the static pressure of the fan incorporated in the generator 2, unless the intake and the exhaust of the generator 2 are separated, the generator 2 This is because it is in a state where the own exhaust gas is sucked again. That is, if there is no duct 23 or partition wall 33, air circulates in the generator 2 and the cooling efficiency is reduced.

Therefore, conventionally, the intake muffler 21 is provided so that the air exhausted from the generator 2 does not go to the intake side of the generator 2.
The structure is either such that the duct and the generator 2 are connected with each other by a duct 23, or the intake side and the exhaust side of the generator 2 are separated by a partition wall 33.

As described above, the structure having the duct and the partition wall has a problem that it is not easy to assemble or disassemble the apparatus. That is, the ducts and bulkheads are parts that directly interact with the generator, but since the shape of this generator is all different depending on the manufacturer and model, each time the generator changes, the duct or bulkhead must be designed each time. There are inconveniences. Also, at the time of assembling, complicated work such as aligning the intake muffler and the intake duct, the intake duct and the generator intake port (or the generator and the partition, or the partition and the enclosure) with each other and tightening bolts is required. .

According to the present invention, in a gas turbine power generator of a type in which a gas turbine and a generator connected in an interlocking manner are housed in a box-shaped enclosure, the structure is simplified by eliminating ducts and partitions, and assembly and disassembly are facilitated. It is intended to be.

[0013]

According to a first aspect of the present invention, there is provided a gas turbine power generator (10) having an air inlet (5) formed at one end and an air outlet (6) formed at the other end. An enclosure (3), a generator (2) installed on the side of the air inlet inside the enclosure and having an air intake device, and a generator installed on the side of the air outlet inside the enclosure. A gas turbine power generator having a driven gas turbine (1), wherein the inside of the enclosure (3) from the air inlet (5) to the air outlet (6) is constituted by a continuous single chamber; A ventilation fan (8) having a static pressure for taking in external air from an air inlet (5) and discharging the air to the outside from the air outlet (6) is provided at the air outlet (6); Intake system of the air inlet the enclosure (5) (3) the air taken into the generator (2) is aspirated by the static pressure of § down,
The air exhausted by the intake device of the generator is discharged from the air outlet (6) to the outside of the enclosure (3) by the static pressure of the ventilation fan (8).

According to a second aspect of the present invention, in the gas turbine power generator according to the first aspect, an intake device of the generator (2) is configured such that an intake device is provided on a side remote from the gas turbine. An inlet (2a), an exhaust port (2b) on the side close to the gas turbine, and an air inlet (5) connected to the inlet (2a) of the generator (2). An opening is provided between the exhaust ports (2b), and air sucked by the static pressure of the ventilation fan (8) is supplied to the air intake port (5) of the generator (2). A guide plate (7) for leading to 2a) is provided.

According to this configuration, air for cooling the generator (2) is taken into the enclosure (3) from the air inlet (5) by the ventilation fan (8). The generator (2) only needs to suction air inside the enclosure (3). In the flow of air generated in the enclosure (3) by the ventilation fan (8), if the intake port (2a) of the generator (2) is on the upstream side and the exhaust port (2b) is on the downstream side, the generator (2) The air used for cooling is discharged outside the generator (outside the enclosure) without circulation.

[0016]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS A gas turbine power generator 10 according to an embodiment of the present invention will be described with reference to FIG.
The gas turbine 1 and the generator 2 linked together are housed in a box-shaped enclosure 3. An intake silencer 4 is provided at one end of the enclosure 3, and an air intake 5 is formed. The other end of the enclosure 3 has an air outlet 6
Are formed. There is no partition wall or duct inside the enclosure 3 as in the related art, and it is a single space.
This space is directly continuous from the air inlet 5 to the air outlet 6, and is not connected through any member or structure on the way. Air can flow directly from the air inlet 5 to the air outlet 6.

The gas turbine 1 and the generator 2 are installed in the only space in the enclosure 3. This generator 2
Is provided with an intake device for cooling itself, has an intake port 2a on the side remote from the gas turbine 1,
The exhaust port 2b is provided on the side closer to. Enclosure 3
The air intake 5 of the generator 2 has an intake port 2a and an exhaust port 2b of the generator 2.
Open between. A guide plate 7 is provided in the air intake 5.
Is provided. Since the guide plate 7 opens toward the intake port 2 a of the generator 2, the air that has entered the enclosure 3 from the air intake 5 is once directed to the direction of the intake port 2 a of the generator 2.

An air outlet 6 of the enclosure 3 is provided with a ventilation fan 8 having a higher static pressure than the conventional one.
The static pressure of the ventilation fan 8 is such that external air can be taken into the enclosure 3 from the air inlet 5 and discharged to the outside from the air outlet 6. That is, the ventilation fan 8 allows the air flow from the air inlet 5 to the air outlet 6 to always exist in the enclosure 3.

According to the present apparatus 10, the air taken into the enclosure 3 from the air inlet 5 by the static pressure of the ventilation fan 8 is sucked by the intake device of the generator 2, and
Is discharged from the enclosure 3 through the air discharge port 6 by the static pressure of the ventilation fan 8.

Air for cooling the generator 2 is taken into the enclosure 3 from the air inlet 5 by a ventilation fan 8 provided at an air outlet 6 of the enclosure 3. The generator 2 only needs to take air inside the enclosure 3. In the flow of air generated in the enclosure 3 by the ventilation fan 8, the intake port 2a of the generator 2 is located on the upstream side and the exhaust port 2b is located on the downstream side.
The air used for cooling the generator 10 is circulated without circulation.
It is discharged outside (outside the enclosure 3).

As described above, in the present embodiment, unlike the conventional case, the interior of the enclosure 3 is made into one room directly communicating from the entrance to the exit by removing the intake duct and the partition wall, and the static pressure of the ventilation fan 8 is increased. In the conventional structure, the ventilation fan 8 is for exhausting the air discharged from the generator 2 and the lubricating oil cooler 9 to the outside. In this embodiment, in addition to this function, the ventilation fan 8 takes in the air into the power generator. I also had the role of intake. That is why the ventilation fan 8 of this example has a higher static pressure than the conventional one. That is, instead of the generator 2 directly sucking air from the outside of the power generator 10, air is taken into the power generator 10 by the ventilation fan 8,
The intake air is sucked by the generator 2.
Since the air in the power generation device 10 is constantly pulled toward the outlet by the ventilation fan 8, the generator 2 does not draw in its own exhaust again without the duct or the partition wall.

[0022]

According to the present invention, since the inside of the enclosure is communicated directly from the inlet to the outlet, and the flow of air is caused inside by the power of the ventilation fan at the outlet, the generator enters the enclosure. The cooling may be performed by sucking the air, and no undesired circulation of the air occurs in the generator even without the partition wall or the like.

Therefore, according to the present invention, in a gas turbine power generator of a type in which a gas turbine and a generator interlockingly connected are housed in a box-shaped enclosure, the structure is simplified by eliminating ducts and partition walls, and assembly and The effect that decomposition can be facilitated is obtained.

[Brief description of the drawings]

FIG. 1 is a cross-sectional view of a gas turbine power generation device as an example of an embodiment of the present invention.

FIG. 2 is a cross-sectional view of a conventional duct type gas turbine power generator.

FIG. 3 is a cross-sectional view of a conventional partition type gas turbine power generator.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Gas turbine 2 Generator 2a Inlet 2b Exhaust 3 Enclosure 5 Air inlet 6 Air outlet 7 Guide plate 8 Ventilation fan 10 Gas turbine generator

──────────────────────────────────────────────────続 き Continued on the front page (51) Int.Cl. ⁶ Identification code FI H02K 9/04 H02K 9/04 A

Claims (2)

[Claims] 1. An enclosure having an air inlet formed at one end and an air outlet formed at the other end, a generator installed inside the enclosure at a side of the air inlet and having an air intake device, A gas turbine installed on the side of the air discharge port inside the enclosure and driving the generator, wherein a gas turbine is connected to the inside of the enclosure from the air intake to the air discharge port. A ventilation fan having a static pressure for taking in external air from the air intake and discharging the air to the outside from the air exhaust port, wherein the air exhaust port is provided by the static pressure of the ventilation fan. The air taken into the enclosure from the intake was sucked by the suction device of the generator and discharged by the suction device of the generator. Gas turbine power generating apparatus according to claim care by the static pressure of the ventilation fan that is configured to discharge to the outside of the enclosure from the air outlet. 2. The air intake device of the power generator has an air intake port on a side remote from the gas turbine and an exhaust port on a side close to the gas turbine. A guide plate that guides air sucked by the static pressure of the ventilation fan to the intake port of the generator, wherein the guide plate is open between the intake port and the exhaust port of the machine. The gas turbine power generator according to claim 1, wherein: