KR101394238B1 - A wind turbine nacelle fire detection and extinguishing system - Google Patents

Abstract

The present invention relates to a fire detecting and extinguishing system which is able to detect and extinguish fire in the nacelle of a wind generator and, more specifically, to a wind generator nacelle fire detecting and extinguishing system which is able to: fundamentally extinguish fire while minimizing damage of various electronic devices or mechanical devices in the nacelle by extinguishing the fire in a suffocation extinguishing method which removes oxygen by discharging air from a space where the fire is detected among multiple divided spaces after dividing the inside of the wind generator nacelle where fire often arises into the multiple spaces in consideration of the distinct characteristics of the wind generator which is separated tens of meters from the ground and is usually operated in an unmanned way; perform an exhaust or an intake about a specific space where fire is detected among the multiple spaces which are divided by partition walls through a vacuum pump and a ventilation means which are formed in the outer surface of the nacelle by separating the outside of the nacelle from the inside of the nacelle with a certain space especially through a double separation wall, forming the vacuum pump and the ventilation means in the outer surface of the nacelle, and making the multiple spaces which are divided by the partition wall connected or blocked from the space which is formed between the outside and inside of the nacelle by the double separation wall through a separate opening and closing means.

Description

FIELD OF THE INVENTION [0001] The present invention relates to a wind turbine Nacelle fire detection and extinguishing system,

FIELD OF THE INVENTION The present invention relates to a fire detection and fire extinguishing system capable of detecting and suppressing fire in a nacelle of a wind turbine generator. More particularly, the present invention relates to a fire detection and fire extinguishing system capable of detecting a fire in a nacelle of a wind turbine generator, In view of this, the wind generator is divided into a plurality of spaces, in which a fire is mainly generated, and then the air is exhausted to a space where a fire is detected, It is possible to suppress the fire fundamentally while minimizing the damage to the various electronic devices and mechanical devices in the nacelle. In particular, it is possible to isolate the nacelle from the inside and the inside of the nacelle to a certain space through the double wall, And the plurality of spaces partitioned by the partition walls are connected to the double-divided wall through separate opening / And the air is exhausted to a specific space where a fire is detected among a plurality of spaces partitioned by the partition wall through one vacuum pump and ventilation means formed on the outer surface of the nacelle To a wind power generator nucelle fire detection and fire extinguishing system.

The nacelle of the wind turbine is located at a distance of several tens of meters from the ground, and various mechanical and electronic devices such as a generator for inserting a shaft portion such as a main shaft of the rotor blade and generating electric power are embedded therein.

Therefore, even in wind turbines, especially in the nacelle, fire is likely to occur in the inside. However, since it is located at several tens of meters above the ground and operated unmanned, it is difficult to suppress the fire in the early stage. nacelle, as well as the risk that the whole wind turbine will burn out.

In consideration of the specificity of such a wind turbine generator, the following patent document relates to a wind turbine generator condition monitoring system for detecting the occurrence of a fire as well as a status monitoring for a main device of a wind turbine generator.

(Patent Literature)

Registered patent publication No. 10-095409 (issued on Mar. 23, 2010) "Wind turbine condition monitoring system"

However, the conventional surveillance system for the wind power generation facility is focused on making it possible to detect various kinds of abnormalities of the wind power generation facility in advance, and in the actual nacelle, a fire extinguishing system There is a method in which a fire tube is broken and a fire extinguishing liquid is blown out of the fire tube or a method in which water is injected into fine particles through a nozzle to be quenched or in which an inert gas is injected to suppress fire The conventional fire suppression methods cause damages to various electronic equipment and mechanical equipments in nacelle by the injected digestive juice and water and also cause damage to the nacelle Since the entire space is extinguished in a batch, it causes an inefficient problem in the initial fire suppression .

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems,

The object of the present invention is to provide a wind turbine nacelle which is divided into a plurality of spaces by dividing the inside of a wind turbine nacelle into which fire is mainly generated in consideration of the specificity of a wind turbine, By suppressing the fire with the fire extinguishing method that removes oxygen by exhausting the air to the fire-detected space, it is possible to minimize the damage to various electronic devices and machinery in the nacelle, And a fire extinguishing system.

Another object of the present invention is to provide a nacelle fire detection and fire extinguishing system that enables normal management operations to be performed early after a fire is extinguished through a ventilation means for supplying air again into the space after the fire is extinguished by the stratified fire extinguishing I would like to.

It is a further object of the present invention to provide a vacuum cleaner in which the space between the outside of the nacelle and the inside of the nacelle is separated into a certain space through the double dividing wall and the vacuum pump and the ventilation means are formed on the outside surface of the nacelle, A plurality of spaces partitioned by the partition wall through one vacuum pump formed on the outer surface of the nacelle and the ventilation means are formed in a space defined between the outside of the nacelle and the inside thereof by the double partition wall, And to provide a nucelle fire detection and fire extinguishing system capable of exhausting or inhaling space.

Yet another object of the present invention is to provide a fire extinguishing system and a fire extinguishing system capable of promptly operating an inert fire extinguishing unit in a situation where oxygen saturation does not fall in a short period of time by operation of a vibro- And to provide a nucelle fire detection and fire extinguishing system capable of complete digestion.

The wind power generator nucelle fire detection and fire extinguishing system for achieving the object of the present invention includes the following configuration.

According to an aspect of the present invention, there is provided a wind turbine nacelle fire detection and fire extinguishing system comprising: a partition wall partitioning a nacelle of a wind turbine generator into a plurality of spaces; A fire detection sensor installed in each space partitioned by the partition to sense heat and smoke; And a sucking and extinguishing unit for exhausting air in a specific space among a plurality of spaces partitioned by the partition to remove oxygen.

According to another embodiment of the present invention, in the wind power generator nacelle fire detection and fire extinguishing system according to the present invention, the vagrant extinguishing unit includes a vacuum pump for exhausting the air inside to outside, And ventilation means for supplying air again.

According to another embodiment of the present invention, in the wind power generator nacelle fire detection and fire extinguishing system according to the present invention, the nacelle of the wind power generator further includes a double partition wall isolating the outside of the nacelle from the inside thereof into a predetermined space, And a space formed between the outside of the nugle and the inside by the double separation wall is formed adjacent to a plurality of spaces partitioned by the partition wall.

According to another embodiment of the present invention, in the wind power generator nacelle fire detection and fire extinguishing system according to the present invention, the vacuum pump and the ventilation means are formed on the outer surface of the nacelle, The plurality of spaces partitioned by the partition walls are communicated with or blocked from the space formed between the outside of the nucelle and the inside by the double separation wall through separate opening and closing means And a plurality of spaces partitioned by the partition wall through one vacuum pump formed on the outer surface of the nucelle and the ventilation means can be exhausted or sucked into a specific space in which a fire is sensed.

According to another embodiment of the present invention, the wind power generator nucelle fire detection and fire extinguishing system according to the present invention further comprises an inert fire extinguishing unit for supplying an inert gas to each space partitioned by the partition wall do.

According to another embodiment of the present invention, in the nucelle fire detection and fire extinguishing system according to the present invention, the inert gas extinguishing unit includes a nitrogen tank for storing nitrogen, a transfer line for transferring nitrogen into the nacelle from the nitrogen tank, And a jetting unit for jetting nitrogen transferred at the end of the transfer line to extinguish the fire.

According to another embodiment of the present invention, in the wind power generator nucelle fire detection and fire extinguishing system according to the present invention, the transfer line of the inert fire extinguishing unit is provided with a branch line for each space partitioned by the partition wall, The control valve and the oxygen sensor are provided for each of the branched lines so that the oxygen saturation is not lowered in a short period of time by the operation of the vibro-fire extinguishing unit for a specific space in which a fire is detected among a plurality of spaces partitioned by the partition, And the inert fire extinguishing part is operated together.

The present invention can obtain the following effects by the above-described embodiment, the constitution described below, the combination, and the use relationship.

In consideration of the specificity of a wind turbine, which is isolated from the ground by a few tens of meters, and is operated by an unmanned wind turbine, a plurality of spaces are divided into a plurality of spaces in a wind turbine nacelle, By suppressing the fire by the exhausting method in which oxygen is removed by exhausting the air against the sensed space, it is possible to suppress the fire fundamentally while minimizing damage to various electronic devices and machinery in the nacelle.

The present invention has the effect of allowing normal management operation to be performed early after the fire is extinguished through the ventilation means for supplying air again into the space after the fire is suppressed by the stratified fire extinguishing.

According to the present invention, the space between the outside of the nugget and the inside of the nugget is separated into a certain space through the double separation wall, the vacuum pump and the ventilation means are formed on the outside surface of the nugget, and the plurality of spaces partitioned by the partition are separated A plurality of spaces partitioned by the partition walls through one vacuum pump formed on the outer surface of the nucelle and the ventilation means to be communicated with or blocked from the space formed between the outside and the inside of the nucelle by the wall, And the air intake can be performed.

In the present invention, when the oxygen saturation does not drop in a short period of time due to the operation of the vibro-fire extinguishing unit for a specific space in which a fire is detected from among a plurality of spaces partitioned by the partition wall, the inert fire extinguishing unit is instantaneously operated together, .

1 is a state diagram showing a general wind turbine generator
2 is a structural diagram of a fire detection and fire extinguishing system in a nacelle according to an embodiment of the present invention.
Fig. 3 is a view showing an operation example of the vacuum pump and the ventilation means in Fig. 2
Fig. 4 is a schematic view showing a state in which the inert fire extinguishing unit is further installed in Fig.
5 is a structural diagram of a fire detection and fire extinguishing system in a nacelle according to another embodiment of the present invention
Fig. 6 is a view showing an example of the operation of the vacuum pump and the ventilation means in Fig. 5
Fig. 7 is a schematic view showing a state in which the inert fire extinguishing unit is further installed in Fig. 5

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of a wind power generator nacelle fire detection and fire extinguishing system according to the present invention will be described in detail with reference to the accompanying drawings. DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear. Throughout the specification, when an element is referred to as "comprising ", it means that it can include other elements, rather than excluding other elements, unless specifically stated otherwise.

1 to 7, a wind power generator nacelle fire detection and extinguishing system according to an embodiment of the present invention includes a partition 20 partitioning the inside of a nacelle 1 of a wind power generator into a plurality of spaces; A fire detection sensor 30 installed in each space partitioned by the partition 20 to sense heat and smoke; A sucking and extinguishing unit (40) for exhausting air in a specific space (in which a fire is detected) out of a plurality of spaces partitioned by the partition (20) to remove oxygen; And an inactive fire extinguishing part 60 for supplying an inert gas to each space partitioned by the partition 20.

The partition 20 separates the inside of the nacelle 1 of the wind turbine generator into a plurality of spaces. Generally, inside the nacelle 1 of the wind turbine generator, various electronic and mechanical devices such as a main shaft of a rotor blade, In order to exhaust the air in the entire inner space all at once by using the nitrogen extinguishing unit 40, which will be described later, the space inside the nacelle 1 having such a large volume is unreasonable in terms of efficiency As shown in FIG. 2, according to the present invention, the space inside the nacelle 1 of the wind turbine generator can be partitioned into a plurality of spaces by utilizing the partition 20. It is possible to allow the administrator to carry out the maintenance work through the entrance and exit facility where the plurality of spaces partitioned by the partition 20 can be separately opened and closed. In the nacelle 1, there may be a plurality of piping facilities that pass through the partition 20 that divides a plurality of spaces. In the portion where the piping facility penetrates the partition 20, However, in the present invention, the gas-fired extinguishing unit 40, which will be described later, removes oxygen instantaneously through instantaneous air exhaustion in a specific space in which a fire is detected (100% (Meaning that it is removed to the degree of oxygen saturation in the inactive state) to suppress the fire, it is not necessarily 100% sealed.

The fire detection sensor 30 is installed in each space partitioned by the partition 20 and senses heat and smoke. The temperature of the fire detection sensor 30 rises to a certain range or exceeds a predetermined standard, The sensed signal is transmitted to the management system or a later-described mass-extinguishing unit 40 or an inactive fire-extinguishing unit 60 so that the mass-extinguishing unit 40 or the inert-fire extinguishing unit 60 can operate. Particularly, in the present invention, unlike other facilities installed on the ground, the fire detection sensor 30 has a special environment called a nucelle 1 of a wind turbine, which is always subject to rapid changes in temperature and humidity due to vibration and weather change at altitudes of several tens of meters or more. It is possible to periodically update the reference value setting according to the temperature change of the outside in detecting the temperature rise over a certain range so that accurate fire detection and judgment can be performed.

The vortex extinguishing unit 40 is configured to remove oxygen by exhausting air in a specific space (in which a fire is detected) among a plurality of spaces partitioned by the partition 20, For example, a vacuum pump 410 for exhausting the air to the outside as shown in FIG. 2, and an air supply unit for supplying air back into the space after the fire is extinguished by the vacuum pump 410 (Not shown).

As in the example of the present invention, the partition wall 20 divides the inside of the nacelle 1 of the wind turbine generator into a plurality of spaces, and then the vacuum pump 410, And ventilation means 420 for supplying air again to the space after the fire is extinguished by the vaginal digestion by the vacuum pump 410. The operation of the ventilation means 420 will be described in detail. When a fire is detected in the specific space by the fire detection sensor 30 which detects heat or smoke and detects the presence or absence of a fire, And the vacuum pump 410 disposed in the space is started to operate as shown in FIG. 3 (1), and the air in the space is instantaneously discharged By removing oxygen, the fire generated in the space is sucked out. In addition, when the oxygen saturation in the space is not instantaneously lowered by the operation of the vacuum pump 410 to an extent sufficient to digest the fire, the inert fire extinguishing unit 60, which will be described later, . After the digestion of the space in which the fire has been detected by the operation of the vacuum pump 410 is completed, the ventilation means 420 is operated again as shown in (2) of FIG. 3, Air and oxygen can be supplied so that normal management operations can be done early after the fire is extinguished.

5, a dual separation wall 50 separating the space structure inside the nacelle 1 of the wind power generator from the outside of the nacelle 1 into a predetermined space, as shown in FIG. 5, And a space formed between the outside of the nacelle 1 and the inside of the nacelle 1 by the double dividing wall 50 may be formed adjacent to a plurality of spaces defined by the partition 20. [

The inside of the nacelle 1 is separated from the inside and outside of the nacelle 1 by the double dividing wall 50 and is separated by the double dividing wall 50 from the outside to the inside of the nacelle 1, The vacuum pump 410 and the ventilation means 420 are formed on the outer surface of the nacelle 1 so that the vacuum pump 410 and the ventilation means 420 are formed on the outer surface of the nacelle 1 in a state in which the space formed in the nacelle 1 is formed adjacent to a plurality of spaces defined by the partition 20, The partition wall 20 is provided with a partition wall 20 for discharging air in a space formed between the outside and the inside of the nacelle 1 by the separation wall 50 or supplying air to the space. A single vacuum pump 410 formed on the outer surface of the nacelle 1 may be connected to the space formed between the outside and the inside of the nacelle 1 by the double dividing wall 50 through the opening and closing means 210, And the ventilation means 420 to the partition 20 It is possible to perform exhausting or intake of a specific space in which a fire is detected among a plurality of spaces partitioned by the filter, thereby enabling the operation of the smokable fire extinguisher 40 more efficiently and economically.

That is, when the vacuum pump 410 and the ventilation means 420 are installed for each of the plurality of spaces partitioned by the partition 20, the high-cost and low-efficiency structure It is possible to separate the plurality of spaces partitioned by the partition 20 from each other so as to enable a more effective and economical operation of the vibro-fire extinguisher 40 while structurally solving such a problem. The vacuum pump 410 and the ventilation means 420 of the vat fire extinguishing unit 40 are both formed by the double separation wall 50 in the nacelle 1, A space formed between the outside and the inside of the nacelle 1 and formed on the outer surface of the nacelle 1 as well as a plurality of spaces partitioned by the partition wall 20 are respectively connected to the double split wall 50 through separate opening / Formed between the outside and the inside of the nacelle (1) (1) of FIG. 6, when a fire is detected by the fire detection sensor 30 in a specific one of a plurality of spaces, for example, The opening and closing means 210 installed in the partition 20 of the specific space in which the fire is detected is opened and the double wall 50 is opened by the double partition wall 50, The opening and closing means 210 provided on the partition wall 20 of the other spaces are closed to form a space formed between the outside and the inside of the nacelle 1 by the double partition wall 50, By the operation of the vacuum pump 410, only the space formed between the outside of the nacelle 1 and the inside of the nacelle 1 by the double dividing wall 50 and the air in the specific space in which the fire is detected are quickly exhausted The oxygen in the specific area where the fire was detected The fire is extinguished through the digestion by removing. 6 (2), the ventilation means 420 is operated, and a space and fire formed between the outside and the inside of the nacelle 1 by the double separation wall 50 Air and oxygen as usual are supplied in the detected specific space so that normal management operation can be performed early after the fire suppression.

The inertial fire extinguishing unit 60 is configured to suppress the fire by supplying an inert gas to each of the spaces partitioned by the partition 20. As described above, when the fire pump 410 is operated, In addition, when the detected oxygen saturation in the space does not drop instantaneously to a sufficient degree to suffocate the fire, the inert fire extinguishing unit 60 works together to completely extinguish the fire. 4 and 7, the inert gas fire extinguishing unit 60 includes a nitrogen tank 610 for storing nitrogen, a transfer unit for transferring nitrogen from the nitrogen tank 610 into the nacelle 1, Line 620 and a jetting unit 630 for jetting nitrogen transferred at the end of the transfer line 620 to suppress the fire.

Nitrogen generated from the nitrogen generator is stored and managed in the nitrogen tank 610 and transported through the transfer line 620 if necessary.

The transfer line 620 for transferring nitrogen from the nitrogen tank 610 to the inside of the nacelle 1 has a line 620 branched for each space partitioned by the partition wall 20, And may include a control valve 640 and an oxygen sensor 650 for each branch line 620. That is, in a state in which each of the transfer lines 620 branched from one nitrogen tank 610 is formed so that nitrogen gas can be supplied to each space partitioned by the partition 20, the fire detection sensor 30 If a situation occurs in which the oxygen saturation does not fall in a short period of time as a result of the measurement of the oxygen sensor 650 despite the operation of the nitrification and fire extinguishing unit 40 in a specific space where the fire is detected by the oxygen sensor 650, The control valve 640 of the transfer line 620 is opened so that the nitrogen gas in the nitrogen tank 610 can be injected instantaneously through the jetting part 630 of the transfer line 620 disposed in the space The inert fire extinguishing part 60 can be operated together to additionally suppress the fire completely.

While the present invention has been described in connection with what is presently considered to be practical exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, Should be interpreted as belonging to the scope.

1: Nussel
20: partition wall 210: opening / closing means
30: fire detection sensor 40:
410: Vacuum pump 420: Ventilation means
50: double separation wall 60: inert fire extinguisher
610: Nitrogen tank 620: Transfer line
630: dispenser 640: control valve
650: oxygen sensor

Claims (7)

A partition wall partitioning the inside of the nacelle of the wind turbine generator into a plurality of spaces;
A fire detection sensor installed in each space partitioned by the partition to sense heat and smoke;
A sucking and extinguishing unit for exhausting air in a specific space out of a plurality of spaces partitioned by the partition to remove oxygen;
A double separating wall separating the outside of the nacelle and the inside of the nacelle into a predetermined space; And
And a space formed between the outside of the nucelle and the inside by the double dividing wall is formed adjacent to a plurality of spaces partitioned by the partition wall. The method according to claim 1,
And a ventilation means for allowing the air to be supplied again into the space after the fire is extinguished by the vaginal digestion. The fire extinguishing system according to claim 1, wherein the fire extinguishing unit comprises: . delete 3. The method of claim 2,
The vacuum pump and the ventilation means are formed on the outer surface of the nacelle to exhaust air in a space formed between the outside of the nacelle and the inside of the nacelle or to supply air to the space,
The plurality of spaces partitioned by the partition walls are communicated with or blocked by a space formed between the outside and the inside of the nucelle by the double separation wall through separate opening and closing means so that one vacuum pump and ventilation means Wherein a plurality of spaces partitioned by the partition walls are capable of exhausting or sucking in a specific space in which a fire is detected, and a wind power generator nacelle fire detection and fire extinguishing system. The fire detection and fire extinguishing system according to any one of claims 1 to 2 and 4, further comprising an inert fire extinguishing unit for supplying an inert gas to each space defined by the partition wall Wind power generator nucelle fire detection and fire extinguishing system. 6. The method of claim 5,
Wherein the inert gas extinguishing unit includes a nitrogen tank for storing nitrogen, a transfer line for transferring nitrogen from the nitrogen tank into the nacelle, and a jet unit for injecting nitrogen transferred at the transfer line end to extinguish the fire Wind power generator nucelle fire detection and fire extinguishing system. The method according to claim 6,
Wherein the transfer line of the inert fire extinguishing unit has a branch line for each space partitioned by the partition wall and includes a control valve and an oxygen sensor for each branch line,
Wherein the inertial fire extinguishing unit is operable immediately in a situation where oxygen saturation does not fall in a short period of time due to the operation of the vibro-fire extinguishing unit for a specific space in which a fire is detected among a plurality of spaces partitioned by the partition wall. Nussel fire detection and fire extinguishing system.

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