JP2001346318A - Structure for introducing electric wire into explosion- proof facilities - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a structure for introducing electric wire into explosion- proof facilities, capable of setting the introduction path of an electric wire according to the fixing timing of the introduction path of the electric wire without implementing the work related to the introduction of the electric wire at the stage of foundation work. SOLUTION: This structure for introducing electric wire into explosion-proof facilities comprises an explosion-proof building (4) covering an operating apparatus (3), a rack (5) which is disposed outside the explosion-proof building (4) and makes a junction for an internal electric wire (75) introduced into the inside of the explosion-proof building (4), and a junction terminal box (7) for connecting an external electric wire (61) wired to the outside of the rack (5) with the internal electric wire (75).

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a structure for introducing electric wires into an explosion-proof facility for introducing electric wires into an indoor explosion-proof facility where a gas turbine or the like is installed.

[0002]

2. Description of the Related Art In a facility such as a thermal power plant, a gas turbine is an example of an operating device. The gas turbine is installed inside an explosion-proof facility that is isolated from the outside world, that is, inside an explosion-proof building. The explosion-proof building is constructed from a structure that can be easily disassembled so that the gas turbine can be easily exposed to the outside in consideration of maintenance work of the gas turbine.

[0003] Electric wires are introduced from the outside of the explosion-proof building to the inside thereof through buried conduits provided on the floor of the explosion-proof building so as not to hinder the disassembly of the explosion-proof building.

FIG. 8 is a conceptual diagram showing the installation state of a conventional gas turbine. In the figure, the base 1b, the floor 2,
An explosion-proof facility including a gas turbine 3, an intake section 3a, an explosion-proof building 4, a first rack 5, a generator 51, and a steam turbine 52 is shown.

[0005] The gas turbine 3 is installed inside the explosion-proof building 4 and is isolated from the outside. The electric wire introduced from the outside of the explosion-proof facility 4 to the inside is introduced through a buried pipe provided on the floor 2.

FIG. 9 is a conceptual diagram showing the arrangement of a conventional buried pipe. The figure shows the structure of the intervening part of the explosion-proof building 4. In the figure, a floor 2, an explosion-proof building 4, a first rack 5
Is shown. An electric wire trench 2 a is provided on the side surface of the floor 2. A buried pipe 73 is buried in the floor 2.

[0007] A terminal box 70 is arranged in the electric wire trench 2a. An external electric wire 70a is introduced into the terminal box 70. The terminal box 70 is provided with an electric wire tray 71.
The electric wire tray 71 is installed inside the electric wire trench 2a. External wires (heat-resistant wires) 72 are arranged on the wire tray 71. External wires (heat-resistant wires) on the wire tray 71
72 is introduced into the first rack 5 (explosion-proof building 4) via the buried pipe 73.

An external electric wire (heat-resistant electric wire) 72 introduced into the first rack 5 is connected to an internal electric wire 75 via a buried pipe 73 and a relay terminal box 74. The internal electric wire 75 is a heat-resistant electric wire made of, for example, a Teflon (registered trademark) electric wire.

FIG. 10 is a conceptual diagram showing the internal structure of a conventional explosion-proof building. The explosion-proof structure 200 shown in the figure includes a substructure 1a constructed on a substructure 1b. The substructure 1a forms a subspace 1c. The floor 2 is constructed in the basic space 1c. The floor 2 is an electric wire trench 2a
Is provided. On the floor 2, a gas turbine 3, an explosion-proof building 4, a first rack 5, and a second rack 6 are installed. An explosion-proof relay terminal box 74 is installed inside the explosion-proof building 4.

The substructure 1a includes, for example, an explosion-proof building 4
A crane and the like used for disassembly are installed. An electric wire tray 71 is installed in the electric wire trench 2a. The floor 2 has a buried pipe 73 connecting the electric wire trench 2a and the explosion-proof space 4a.
Is buried. The external electric wires 72 on the electric wire tray 71 are introduced into the explosion-proof space 1c via the buried pipe 73 (embedded portion 72a) (introduction portion 72b). The external electric wire 72 introduced into the explosion-proof building 4 is introduced into the junction terminal box 74.
The outer wire 72 is connected to the inner wire 7 in the relay terminal box 74.
5 The internal electric wire 75 is wired inside the explosion-proof building 4. The wire trench 2a has, for example, a depth and a width that allow a person who performs maintenance of the wire to walk.

In order to shield the inside of the explosion-proof building 4 from the outside, the gap is filled with a sealing agent such as a silicone resin after the introduction of the external electric wire 72.

Incidentally, assuming maintenance of the gas turbine 3,
The explosion-proof building 4 and the first and second racks 6 have a structure that can be disassembled. After the maintenance of the gas turbine 3 is completed, the explosion-proof building 4, and the first and second racks 5, 6 are reassembled. In the explosion-proof structure 200 in which such disassembly and reassembly are expected, there is no construction concept of introducing an electric wire into the explosion-proof building 4 via a wall surface. Therefore,
A structure in which the buried pipe 73 is buried and the electric wire is introduced has been adopted.

[0013]

In the conventional electric wire introduction structure and the electric wire introduction method to the explosion-proof facility, at the stage of the foundation work for constructing the base part 1b and the floor part 2, the burial location of the buried pipe 73 is determined. I had to. It is difficult to accurately determine the burial location at the stage of foundation work. For this reason, conventionally, buried pipes have been buried in all places where introduction of electric wires is expected, and predetermined buried pipes have been selected to introduce electric wires in accordance with the progress of gas turbine installation. For this reason, many buried pipes that are not actually used have been generated. Also, providing unused buried pipes has increased construction costs. Furthermore, with the increase in the number of burial points where buried pipes are buried, there were many situations where they interfered with concrete backs and reinforcing bars, and construction costs for preventing interference increased.

The present invention provides a structure for introducing an electric wire into an explosion-proof facility in which an electric wire introduction route can be set in accordance with the timing for determining an electric wire introduction route without performing work related to the introduction of the electric wire at the stage of foundation work. The purpose is to provide.

[0015]

Means for solving the problem are described as follows. The technical items appearing in the expression are appended with numbers, symbols, etc. in parentheses (). The numbers, symbols, etc. are technical items that constitute at least one embodiment or a plurality of examples of the embodiments or examples of the present invention, in particular, the embodiments or the examples. Corresponds to the reference numerals, reference symbols, and the like assigned to the technical matters expressed in the drawings corresponding to the above. Such reference numbers and reference symbols clarify the correspondence and bridging between the technical matters described in the claims and the technical matters of the embodiments or examples. Such correspondence / bridge does not mean that the technical matters described in the claims are interpreted as being limited to the technical matters of the embodiments or the examples.

An electric wire introduction structure for an explosion-proof facility according to the present invention is an explosion-proof building (4) that covers an operating device (3) and an explosion-proof building (4) that is disposed outside the explosion-proof building (4). A rack (5) for relaying an internal electric wire (75) introduced into the inside of the rack, and an external electric wire (6) installed on the rack (5) and wired outside the internal electric wire (75) and the rack (5).
1) A relay terminal box (7) for connecting the terminal box is provided.

In the structure for introducing electric wires into a further explosion-proof facility according to the present invention, the wiring route of the internal wires (75) of the rack (5) and the relay terminal box (7) is formed between the inside of the rack (5) and the relay terminal box ( And 7) a sealing portion (13) for shutting off the inside.

According to a further structure for introducing electric wires to an explosion-proof facility according to the present invention, the explosion-proof facility (4) has a structure that can be disassembled and reassembled, and a rack (5) when the explosion-proof facility (4) is disassembled. Maintains the installed configuration, and the internal wires (75) maintain the configuration introduced from the rack (5).

According to a further structure for introducing an electric wire into an explosion-proof facility according to the present invention, the wiring route of the internal electric wire (75) is a rack (5).
The first introduction part (8) introduced into the inside of the rack (5) from the relay terminal box (7) through the wall surface of the above and the wall surface forming the boundary between the explosion-proof building (4) and the rack (5). A second introduction portion (4b) introduced into the interior of the explosion-proof building (4) from the rack (5) through the second introduction portion (4b).

In the structure for introducing electric wires into a further explosion-proof facility according to the present invention, the operating device (3) is a gas turbine.

According to the method of introducing electric wires into an explosion-proof facility according to the present invention, a relay terminal box (7) is installed in a rack (5) installed adjacent to an explosion-proof building (4) covering an operating device (3). An internal electric wire (75) introduced into the explosion-proof building (4) and an external electric wire (61) wired outside the rack (5) are connected via a box (7), and the internal electric wire (75) is connected. Explosion-proof building (4) from the junction terminal box (7) via a rack
How to introduce electric wires to explosion-proof facilities introduced inside

[0022]

FIG. 1 is a conceptual diagram showing an installation state of a gas turbine according to the present invention. In the figure, the base part 1b,
Floor 2, gas turbine 3, intake section 3a, explosion-proof building 4, first rack 5 (explosion-proof facility), and generator 51
And the steam turbine 52 (above, a non-explosion-proof facility).
In the first rack 5, a relay terminal box 7 is provided.

The gas turbine 4 is installed inside the explosion-proof building 4 and is isolated from the outside. The electric wire introduced from the outside of the explosion-proof facility 4 to the inside is introduced via the relay terminal box 7.

FIG. 2 is a conceptual diagram showing the internal structure of an explosion-proof building according to the present invention. The explosion-proof structure 100 shown in the figure
It comprises a substructure 1a constructed on a base 1b. The substructure 1a forms a subspace 1c. Basic space 1
The floor 2 is constructed at c. The floor 2 is provided with an electric wire trench 2a. On the floor 2, a gas turbine 3
An explosion-proof building 4, a first rack 5, and a second rack 6 are installed. The wall formed by the explosion-proof building 4 and the first rack 5 has a sleeve 4b. The sleeve 4 b is formed by an open pipe that connects the inside of the explosion-proof building 4 and the inside of the first rack 5. The sleeve 4b is filled with a sealing agent as necessary, so that the inside of the explosion-proof building 4 and the inside of the first rack 5 are shut off.

In the explosion-proof structure 100 according to the present invention, the explosion-proof building 4 has a structure that can be disassembled and reassembled. On the other hand, the first and second racks 5 and 6 have a structure that is difficult to disassemble. That is, even if the explosion-proof building 4 is disassembled, the construction state of the first and second racks 5 and 6 is maintained.

The first rack 5 is provided with a wire tray 60 and a relay terminal box 7. The terminal box 7 includes a sleeve 8 extending inside the first rack 5. The first rack 5 includes an introduction pipe 5b extending to the explosion-proof space 4a of the explosion-proof building 4. External wires 61 are arranged on the wire tray 60. The external electric wires 61 are introduced into the relay terminal box 7.

In the wire trench 2a, for example, a terminal box 7 is provided.
0 (FIG. 9). The external electric wires 61 wired from the terminal box 70 are arranged on the electric wire tray 60.

The first rack 5 is used as a repeater for electric wires wired inside the explosion-proof building 4. Second rack 6
Is used as a relay for the fuel supplied into the interior of the explosion-proof building 4.

Inside the junction terminal box 7, an external electric wire 61 and an internal electric wire 75 (Teflon electric wire) are connected. The internal electric wire 75 is introduced into the inside of the first rack 5 via the sleeve 8. In the first rack 5, the internal electric wire 75 is introduced into the explosion-proof space 4a via the introduction pipe 4b.

The inside of the sleeve 8 is the first rack 5
After the introduction of the internal electric wire 75, the gap is filled with a sealing agent in order to shield the inside from the outside. Similarly, the inside of the introduction tube 4b is filled with the sealing agent.

When the explosion-proof building 4 is disassembled with the maintenance of the gas turbine 4, the first rack 5 and the second rack 6
Is left on the floor 2. The introduction pipe 4b is an explosion-proof building 4
When forming a part of the first rack 5, the introduction pipe 4b is also left.

FIG. 3 is a conceptual diagram showing an installation state of the relay terminal box according to the present invention. As shown in the figure, the upper opening 7a of the relay terminal box 7 provided in the first rack 5 has:
The external electric wire 61 is introduced. The external electric wire 61 is connected to the internal electric wire 75 inside the relay terminal box 7. The internal electric wire 75 is introduced into the inside of the first rack 5 via the sleeve 8.

FIG. 4 is a front view of the junction terminal box according to the present invention. The relay terminal box 7 shown in the figure is installed on the first rack 5. The relay terminal box 7 includes first to fourth sleeves 8a to
8d is provided. First to fourth sleeves 8
a to 8d enter the inside of the first rack 5 via the introduction portion 5a provided in the first rack 5.

FIG. 5 is a side view of the junction terminal box according to the present invention. The relay terminal box 7 shown in the figure has an upper opening 7a.
And an upper fixing part 7b and a lower fixing part 7c. The relay terminal box 7 is installed on the first rack 5 via the upper fixing part 7b and the lower fixing part 7c.

The sleeve 8 includes a first union 11 and a first union 11.
Nipple 12, sealing part 13, second nipple 1
4, elbow 15, conduit 16, second union 17
Is provided. The sealing section 13 has a filling port 13a into which a sealing agent is filled.

After the introduction of the internal electric wire is completed, the sealing portion 13 is filled with a sealing agent. The sealing agent shields the inside of the first rack 5 from the outside.

FIG. 6 is a front view of another relay terminal box according to the present invention. The relay terminal box 7 'shown in the figure is different from the relay terminal box 7 shown in FIGS. 4 and 5 in the position of the sleeve and the position for receiving the external electric wire. In the relay terminal box 7 ', the sleeve 9 including the first to fourth sleeves 9a to 9d is provided on the upper surface of the relay terminal box 7'. The first to fourth sleeves 9a to 9d enter the inside of the first rack 5 through the introduction portion 5a provided in the first rack 5.

The first rack 5 shown in the figure is provided with introduction portions 5b and 5c. These introduction portions are used, for example, as wiring routes for electric wires that are introduced into the first rack 5 but are not introduced into the explosion-proof building 4.

FIG. 7 is a side view of another relay terminal box according to the present invention. The relay terminal box 7 'shown in the figure includes a lower opening 7a', an upper fixing part 7b ', and a lower fixing part 7c'. The relay terminal box 7 'is installed on the first rack 5 via the upper fixing part 7b' and the lower fixing part 7c '.

The sleeve 8 includes a first union 21 and a first union 21.
Nipple 22, sealing part 23, second nipple 2
4, elbow 25, conduit 26, second union 27
Is provided. The sealing part 23 has a filling port 23a into which a sealing agent is filled.

After the introduction of the internal electric wire is completed, the sealing portion 23 is filled with a sealing agent. The sealing agent shields the inside of the first rack 5 from the outside.

In the explosion-proof structure 100 in which the relay terminal boxes 7, 7 'having the above-described configuration are installed, the external electric wires 61 wired via the electric wire tray 60 are wired to the relay terminal boxes 7, 7'. External electric wires 61 wired to the junction terminal boxes 7, 7 '
Are connected to the internal electric wires 75 inside the relay terminal boxes 7, 7 '. The internal electric wire 75 is introduced into the inside of the first rack 5 via the sleeves 8 and 9. Sleeves 8, 9
Sealing portions 13 and 23 block the inside of the first rack 5 and the inside of the relay terminal boxes 7 and 7 ′.

Since the relay terminal boxes 7, 7 'according to the present invention are arranged outside the explosion-proof building 4, they need not be, for example, explosion-proof relay terminal boxes.

The electric wires introduced into the interior of the explosion-proof building 4 from the junction terminal boxes 7, 7 'according to the present invention are connected to the junction terminal boxes 7, 7'.
´ can be used as the boundary for the internal electric wires. For this reason, the situation where electric wires other than the internal electric wires are introduced into the explosion-proof building 4 can be avoided.

Further, according to the present invention, since the work for burying the buried conduit is not required, the labor and cost for the work can be reduced.

[0046]

According to the structure for introducing an electric wire into an explosion-proof facility according to the present invention, since a buried pipe is not used for introducing the electric wire, there is no need to carry out the idea and work related to the introduction of the electric wire at the stage of foundation work. Further, since a situation in which a large number of buried pipes are installed does not occur, a situation in which the buried pipes interfere with the back and reinforcement of the concrete does not occur.

Further, the construction of the electric wire introduction route can be executed in accordance with the construction of the explosion-proof building. For this reason, it is not necessary to consider the introduction route of the electric wire at the initial timing of the work in which the foundation work and the like are executed.

[Brief description of the drawings]

FIG. 1 is a conceptual diagram showing an installation state of a gas turbine of the present invention.

FIG. 2 is a conceptual diagram showing an internal structure of an explosion-proof building according to the present invention.

FIG. 3 is a conceptual diagram showing an installation state of a relay terminal box according to the present invention.

FIG. 4 is a front view of a relay terminal box according to the present invention.

FIG. 5 is a side view of the relay terminal box according to the present invention.

FIG. 6 is a front view of another relay terminal box according to the present invention.

FIG. 7 is a side view of another relay terminal box according to the present invention.

FIG. 8 is a conceptual diagram showing an installation state of a conventional gas turbine.

FIG. 9 is a conceptual diagram showing the arrangement of a conventional buried pipe.

FIG. 10 is a conceptual diagram showing the internal structure of a conventional explosion-proof building.

[Explanation of symbols]

 1a: Foundation structure 1b: Foundation part 1c: Foundation space 2: Floor 2a: Electric wire trench 3: Gas turbine 3a: Inlet part 4: Explosion-proof building 4a: Explosion-proof space 5: First rack 6: Second rack 7: Relay terminal box 8, 9: Sleeve 60: Electric wire tray 61: External electric wire 75: Internal electric wire

──────────────────────────────────────────────────続 き Continued on the front page (51) Int.Cl. ⁷ Identification symbol FI Theme coat ゛ (Reference) H02G 3/06 H02G 3/08 N 3/08 H02B 1/12 N 3/38 H02G 3/28 GF term (Reference) 5G357 BA04 BB02 BC05 DA10 DB01 DC11 DD02 DD05 DD16 DE10 5G361 AA07 AB12 AC05 AC11 AE02 5G363 AA20 BA07 CA06 CA12 CB01 DC10

Claims (6)

[Claims] An explosion-proof building that covers operating equipment; a rack that is disposed outside the explosion-proof building and relays internal wires introduced into the explosion-proof building; and a rack that is installed on the rack; In addition, a wire introduction structure to an explosion-proof facility including a relay terminal box for connecting the internal wire and an external wire wired outside the rack. 2. The wire introduction structure to an explosion-proof facility according to claim 1, wherein a wiring route of the internal wires of the rack and the relay terminal box cuts off the inside of the rack and the inside of the relay terminal box. Structure for introducing electric wires into explosion-proof facilities equipped with a sealing part. 3. The structure for introducing electric wires into an explosion-proof facility according to claim 1 or 2, wherein the explosion-proof facility has a structure that can be disassembled and reassembled. An electric wire introduction structure to an explosion-proof facility that maintains an installed configuration and maintains the internal electric wire introduced from the rack. 4. The structure for introducing electric wires into an explosion-proof facility according to claim 1, wherein a wiring route of the internal electric wires extends from the relay terminal box to the rack via a wall surface of the rack. The first introduced inside
And an electric wire introduction structure to an explosion-proof facility including a second introduction part introduced from the rack into the interior of the explosion-proof building via a wall surface forming a boundary between the explosion-proof building and the rack. 5. The electric wire introduction structure to an explosion-proof facility according to claim 1, wherein the operating device is a gas turbine. 6. A relay terminal box is installed on a rack installed adjacent to an explosion-proof building covering operating equipment, and said internal electric wire and said rack are inserted into said explosion-proof building via said relay terminal box. A method for introducing an electric wire to an explosion-proof facility, wherein an external electric wire to be wired outside is connected, and the internal electric wire is introduced from the relay terminal box through the rack to the inside of the explosion-proof building.