KR101764151B1 - Replacement type thermocouple unit for fire monitoring and suppression of silo - Google Patents

Abstract

An objective of the present invention is to provide a thermocouple replacement type silo fire monitoring and extinguishing unit, capable of monitoring a fire, and spraying a fire extinguishing solution to extinguish a fire likely to occur inside a silo in an early stage. According to the present invention, the unit comprises: a plurality of thermocouples (100) having a distance different from each other; a housing tube (200) having one or more spray holes (210) penetrated one an outer circumference; a wire rope (300) to prevent position change of a measurement point, and to prevent separation, breakage, and damage of the housing tube (200); a slot tube (400) wherein the thermocouple (100) is inserted and coupled to facilitate attachment/detachment; one or more fire extinguishing units (500) formed along the outer circumference of the wire rope (300) to receive the fire extinguishing solution from the outside and spray the same through a spray hole (210); and a fixated tube (600) installed to simultaneously fixate the slot tube (400) and the fire extinguishing unit (500) to the wire rope (300).

Description

[0001] The present invention relates to a thermocouple replacement type fire suppression and suppression unit,

The present invention relates to a thermocouple interchange type fire monitoring and suppression unit, and more particularly, to a thermocouple interchange type fire interception monitoring and suppression unit. More particularly, To monitor the fire along with the fire and to prevent the fire from occurring inside the space due to unexpected ignition to be able to quickly suppress the initial pressure and to repair or replace the whole in order to correct the measurement error due to partial failure or malfunction of the thermocouple The present invention relates to a thermocouple interchangeable fire monitoring and suppression unit that can quickly solve troublesome problems through partial replacement and thereby reduce maintenance costs.

Generally, since coal is used as a raw material for producing electricity in a thermal power plant and a considerable amount of coal is consumed during the operation, continuity of operation for electric production requires a continuous supply of raw materials through storage Fossil fuels, such as coal, are stored in yards, in mulch sheds or in separate silos.

Generally, coal is stored in a final stage for supplying fuel in the operation for thermal power generation. It is formed as a cylindrical storage part and a hopper type discharge part so as to rapidly discharge the coal required for operation as needed. do. In addition to the part for storing the coal of the thermal power generation, such a storage type is used for storing grain and various powders, and in particular, it is possible to store a large amount of coal for thermal power generation Because it has the function, it is being produced in a considerable size.

However, coal is a combustible material, and when the constituent molecules of coal adsorb the oxygen in the air, a part of the coal stored locally undergoes an exothermic oxidation reaction. If the heat generated during the exothermic oxidation reaction is not sufficiently released to the outside, It is more likely to be exposed to the risk of fire due to the spontaneous ignition inside the furnace as the exothermic oxidation reaction is accelerated gradually when oxygen is continuously supplied with the increase of the internal temperature of the coal stored in the furnace.

The cause and effect factors of spontaneous ignition are very complicated, so it is not easy to prevent in advance. Since it occurs mostly from inside the coal when it occurs, it is very difficult to suppress the fire until the stored coal is completely burned. Can lead to loss of equipment and, above all, the continuity of operation for thermal power generation.

In addition, since coal is a porous material, the amount of oxygen adsorbed per unit weight is favorable for the oxidation reaction, while the thermal conductivity is low. Therefore, when heat is generated once, it is difficult to discharge to the outside. If not released, it may cause a gas explosion. In other words, the spontaneous ignition in the cistern where the coal is stored may induce the dust explosion, so that the internal fire monitoring is the most important part because of the spontaneous ignition.

Spontaneous ignition temperature (SIT) is the most widely used characteristic value for estimating the possibility of spontaneous ignition in order to prevent spontaneous ignition through fire monitoring, which is the lowest temperature that can cause spontaneous ignition.

Here, the spontaneous ignition temperature is not a material coefficient and can be determined by experiments and is influenced by various factors. In detail, the spontaneous ignition temperature depends on the shape and size of the storage pile (surface area, height, squeeze degree, etc.), the type and quality of coal (carbon content, volatiles, carbonization duration, etc.), the physical and chemical properties (Temperature, humidity, temperature, etc.), storage period, and so on. For example, the amount of airborne pulverized coal that is suspended in the air Is ignited at a high temperature of about 600, but if it is piled up, it spontaneously ignites at a low temperature of about 200 ° C.

Further, even in the case of sediment dust, the ignition temperature sharply decreases as the sediment layer of the dust becomes thicker. That is, the spontaneous ignition temperature changes according to the amount (height) of the coal stored in the inside of the coal, and the spontaneous ignition is likely to occur due to the inter-coal friction pressure stored in the space.

Among these coal, anthracite is not likely to spontaneously ignite. Bituminous is likely to spontaneously ignite during long-term storage, and lignite is most likely to spontaneously ignite. Therefore, the loading height of coal is not limited for low volatile coal, and for volatile coal (15 ~ 40%), the maximum loading height is 8m. When the temperature of the coal is increased by 10, the oxidation reactivity is doubled and the reaction rate is increased by more than 50%.

The spontaneous combustion as described above occurs mostly in a closed storage room, which is stored in a yard or a coal pile rather than in a syringe, but it should be noted that it is not generated in the inside of the room. That is, the coal stored in the silo may spontaneously ignite under the above conditions, but the risk of spontaneous ignition due to the temperature rise due to the friction in the process of discharging through the lower hopper, And the risk of spontaneous ignition due to a rise in the temperature of the exhaust gas. Therefore, in order to prevent spontaneous ignition between coal, it is not possible to observe through additional devices such as a yard or a storage room, such as an infrared camera, but it is necessary to continuously monitor the temperature inside the coal.

As a result of this measure, a temperature measuring device in which a plurality of thermocouples (thermocouples, thermocouples) are connected is installed in the inside of the space according to the height of the space, and the temperature inside the thermocouple is detected So as to prevent the occurrence of fire due to spontaneous ignition.

However, since the thermocouples for the temperature measurement are installed in a space and many units are coupled to one unit depending on the depth or height for measuring the temperature, the thermocouple measuring one of the temperatures in the whole unit If there is a measurement error due to damage or malfunction, there is a troublesome problem that it is necessary to replace the entire unit or to repair the entire unit after it has been lifted from the inside for some maintenance. In this process, Exposed vulnerabilities and maintenance or replacement processes take a considerable amount of time to work, and the need and cost of skilled personnel are present, making maintenance difficult.

Furthermore, since the conventional thermocouple for measuring the temperature of the inside of the cylinder is merely measuring the temperature only, there is no other way to suppress this after the ignition has already proceeded In case of a fire, it is necessary to rapidly discharge the coal inside to suppress the fire, so that the loss of the raw material occurs and the damage of the apparatus in the space can be brought about. Therefore, additional fire extinguishing equipment or fire extinguishing equipment must be provided for fire suppression, which causes additional installation cost.

In addition, although it has been mentioned for a while, when there is a fire, the fire inside the stored coal is generated due to the characteristics of the space, and it is difficult to suppress the fire because of the difficulty in suppressing the fire. It is required to construct a structure capable of simultaneously suppressing fire.

Korean Utility Model Publication No. 20-2009-0008771, published on September 01, 2009.

SUMMARY OF THE INVENTION Accordingly, the present invention has been made in an effort to solve the above-mentioned problems, and it is an object of the present invention to provide a method and apparatus for simultaneously detecting temperatures of a plurality of points in a space, The thermocouple can be combined with the depth or height corresponding to the point so that fire monitoring can be performed and the fire extinguishing part can be formed together to inject fire extinguishing liquid inside the space, And to provide a fire monitoring and suppression unit between the fire detection unit and the fire detection unit.

In addition, the present invention can prevent the thermocouple unit installed inside the gap from being partially malfunctioned and partially replaceable due to damage, so that it is not necessary to replace the entire thermocouple unit installed inside the gap, Another object of the present invention is to provide a thermocouple interchangeable fire monitoring and suppression unit which can easily replace or repair a couple and re-install it, thereby simplifying maintenance and reducing maintenance costs.

In order to achieve the above object, the thermocouple interchange type fire alarm monitoring and suppressing unit according to the present invention includes a plurality of thermocouples 100 having different lengths from each other to measure the temperature from the upper part to the lower part of the room; At least one spray hole (210) is formed through the outer periphery of the cylindrical tube, and the housing tube (200) is insulated; The housing tube 200 is pulled downward by the lower tensile force generated when the contents stored in the space are discharged downward to prevent the displacement of the measuring point or the separation, breakage or damage of the housing tube 200 A wire rope 300 coupled from the upper center to the lower center inside the housing tube 200; The thermocouple 100 is formed to correspond to the number of the thermocouples 100 installed along the circumference of the outer circumference of the wire rope 300 according to the number of intervals to be measured, A slot tube (400) interfitting with the slot tube (400); The fire extinguishing liquid is injected through the injection holes 210 of the housing tube 200 so that the fire extinguishing liquid is supplied from the outside and the initial pressure can be exerted when a fire occurs and at least one or more of the fire extinguishing liquid is formed along the periphery of the outer periphery of the wire rope 300 A digestion unit 500; A fixing tube 600 fixed to the wire rope 300 and formed to correspond to a length of the inside of the housing tube 200; .

The housing tube 200 and the slot tube 400 are preferably formed of Teflon having excellent insulation and heat resistance and the wire rope 300 has a fixing ring 302 of a thimble type And the lower end is fixed so that the housing tube 200 is prevented from being separated downward.

The digestion unit 500 includes at least one digestive fluid tube 510 connected to the injection hole 210 on the length from the upper end to the lower end of the housing tube 200 by being supplied with extinguishing liquid from the outside, And is connected to an end of the digestive liquid tube 510 and is coupled to the inside of the housing tube 200 corresponding to the injection hole 210 of the housing tube 200. The digestive liquid supplied from the outside through the digestive liquid tube 510 flows into the injection hole 210, And an injection nozzle (520) arranged to inject ink through the nozzle (210).

A thermocouple unit having a fire extinguishing unit is constructed so that a thermocouple is detachably coupled to measure a temperature inside a room to monitor the occurrence of fire, It is possible to rapidly improve the vulnerability of fire monitoring due to malfunction or damage of the thermocouple. If a single thermocouple malfunctions or is damaged like a conventional multi-thermocouple, It is possible to replace and replace the parts separately without the hassle of reinstallation, thus it is easy to maintain, and the maintenance cost such as labor costs can be reduced, and the fire caused by the spontaneous ignition that may occur in the inside of the room can be prevented by the fire extinguisher So that it can be suppressed at an early stage.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is an overall perspective view of a thermocouple type inter-space fire monitoring and suppression unit according to the present invention; FIG.
2 is a side cross-sectional view of a thermocouple type inter-space fire monitoring and suppression unit according to the present invention.
3 is a cross-sectional view taken along line AA of Fig. 2 according to the present invention.
4 is a sectional view taken along line BB of Fig. 2 according to the present invention.
Fig. 5 is a schematic view of a system for installing a thermocouple interchangeable inter-bay fire monitoring and suppression unit according to the present invention.

BRIEF DESCRIPTION OF THE DRAWINGS The advantages and features of the present invention, and how to accomplish them, will become apparent by reference to the embodiments described in detail below with reference to the accompanying drawings. However, the present invention is not limited to the embodiments described below, but may be embodied in many different forms.

In the present specification, the present embodiment is provided to complete the disclosure of the present invention and to fully disclose the scope of the invention to a person having ordinary skill in the art to which the present invention belongs. And the present invention is only defined by the scope of the claims. Accordingly, in some embodiments, well known components, well known operations, and well-known techniques are not specifically described to avoid an undesirable interpretation of the present invention.

Like reference numerals refer to like elements throughout the specification. And, the terms used (hereafter) used herein are intended to illustrate the embodiments and are not intended to limit the invention in any way. In the present specification, the singular form includes plural forms unless otherwise specified in the specification. Also, components and acts referred to as " comprising (or comprising) " do not exclude the presence or addition of one or more other components and operations.

Unless defined otherwise, all terms (including technical and scientific terms) used herein may be used in a sense commonly understood by one of ordinary skill in the art to which this invention belongs. Also, commonly used predefined terms are not ideally or excessively interpreted unless they are defined.

Hereinafter, technical features according to embodiments of a thermocouple interstitial fire monitoring and suppression unit according to the present invention will be described in detail with reference to the accompanying drawings.

2 is a side sectional view of a thermocouple interchangeable type fire alarm monitoring and suppressing unit according to the present invention, and FIG. 3 is a cross-sectional view of a thermocouple interchangeable type fire alarm monitoring and suppressing unit according to the present invention. FIG. 4 is a sectional view taken along line BB of FIG. 2 according to the present invention, and FIG. 5 is a schematic view of a system for installing a thermocouple interstitial fire monitoring and suppression unit according to the present invention .

The thermocouple interchangeable type fire alarm monitoring and suppression unit according to the present invention is only responsible for the fire monitoring through the conventional multi-type thermocouple. When malfunction or damage occurs, the whole unit is replaced or the whole is salvaged, A plurality of thermocouples are fitted in a slot shape, and abnormalities are generated in the thermocouple, and the thermocouple is formed to solve the problem of exposing the vulnerability of fire monitoring through the difficulty of a series of processes to be reinstalled, , It is possible to replace only the thermocouple that has occurred without replacing the entire installed thermocouple unit, so that the vulnerability of quick replacement and fire monitoring is minimized, reinstallation or full replacement is not necessary, and the cost of replacement is significantly reduced As well as the initial suppression of the fire can be more stable from fire As shown in FIGS. 1 and 2, the thermocouple 100, the housing tube 200, the wire rope 300, the slot tube 400, the fire extinguishing part 500, the fixing tube 600, .

The thermocouple 100 is provided to measure the internal temperature of stored contents such as coal or grains contained in the space to detect the occurrence of fire due to spontaneous ignition. To measure the temperature of the section from the upper part to the lower part of the space, And a plurality of thermocouples 100 having mutually different lengths. That is, since the sensing part for measuring the temperature of the thermocouple is formed at the end side of the thermocouple 100, the temperature of the part where the sensing part of the thermocouple is located is the inside temperature of the contents accommodated in the space, It is easy to detect the point where the fire occurs due to spontaneous ignition and to take measures by measuring the temperature by dividing the stored contents such as the upper part, the center, and the lower part.

The minimum number of the thermocouples 100 may include at least two thermocouples so that the thermocouples 100 can be divided into upper and lower portions of the internal temperature of the contents stored therein. It is preferable that the number of the thermocouples 100 is eight to nine.

In the conventional thermocouple 100, 8 to 9 units are fixedly coupled as one unit. If any one of the thermocouples 100 is malfunctioned or damaged, some of the thermocouples 100 can not be replaced. Instead, the thermocouple 100 needs to be replaced entirely, If a part that can replace the fire monitoring during the reinstallation time is not provided separately because it has to repair and re-install part of the damaged part, it shows the vulnerability of the fire, and the labor cost and maintenance cost .

Accordingly, the present invention solves the above-mentioned problems. The present invention is not limited to the configuration in which the 8 to 9 thermocouples 100 are fixed to one unit, but the thermocouples 100 are individually inserted into slot- If a malfunction or a malfunctioning thermocouple 100 is found, only the thermocouple 100 of the slot tube to which the malfunctioning or damaged thermocouple 100 is inserted is replaced, or repaired, Therefore, there is no waste of installation time or cost due to the entire installation, and the vulnerability of fire monitoring can be minimized.

The housing tube 200 includes a wire rope 300, a slot tube 400, a fire extinguisher 400, and a fixing tube 500, which are formed to protect the housing 200, In the measurement of the thermocouple 100, measurement errors due to external electrical factors due to static electricity or the like are minimized. The housing tube 200 is long in the longitudinal direction and has a hollow shape. At least one or more spray holes 210 are formed through the outer periphery of the housing tube 200, and the housing tube 200 is formed of an insulating Teflon.

The housing tube 200 is formed of Teflon. The housing tube 200 is excellent in heat resistance due to the nature of Teflon and is excellent in electrical insulation. Therefore, when the contents contained in the housing tube 200 are in contact with the housing tube 200, It is necessary to minimize the measurement error of the thermocouple 100 installed in the housing tube 200 due to external factors such as static electricity caused by the friction generated in the discharging process and to prevent the measurement error of the thermocouple 100 caused by the heat generated inside the housing tube 200, In order to prevent deformation.

The wire rope 300 is for fixing the housing tube 200 described above and coupling the housing tube 200 to the housing tube 200 without interfering with each other based on the center of the slot tube and the fire extinguishing unit described later. 4, when the housing tube 200 is pulled downward due to a lower tensile force generated when the contents stored in the space are discharged downward, the change of the measurement point position inside the space by the thermocouple installed inside, The housing tube 200 is coupled from the upper center to the lower center of the housing tube 200 to fix the housing tube 200 to prevent the housing tube 200 from being separated, damaged or damaged.

1 and 2, the wire rope 300 is fixed to the upper end of the wire rope 300 so that the upper end of the wire rope 300 is positioned at a predetermined position so that the housing tube 200 is always positioned, And the lower end of the housing tube 200 is fixed to prevent the downward departure of the housing tube 200. That is, as shown in FIG. 5, it is the first to prevent the fluctuation of the measurement position of the thermocouple due to the downward tensile force that may be generated when the contents accommodated in the space, such as coal or grain, And the fire extinguishing unit serves as a center reference so that the fire extinguishing unit can not be fixed to one without discrimination. The third function is to prevent the escape or breakage of the flow due to the downward tensile force and to facilitate the replacement or lifting of the housing tube. This is the fourth role.

The slot tube 400 is formed so that the thermocouple 100 described above is fitted to fit separately. As shown in FIGS. 3 and 4, the slot tube 400 measures the temperature along the circumference of the outer periphery of the wire rope 300 The thermocouple 100 is formed to correspond to the number of the thermocouples 100 installed according to the number of sections to be thermocouple, and the thermocouple 100 is formed of a cylindrical Teflon so that the thermocouple 100 can be easily inserted and removed. Here, since the slot tube 400 is formed of Teflon in the same manner as the housing tube 200, it is excellent in heat resistance and insulation so that measurement errors of the thermocouple can be minimized.

The fire extinguishing unit 500 is capable of only monitoring the fire according to the spontaneous ignition only by the conventional temperature measurement. Therefore, when the fire occurs, it is impossible to take the initial action against the fire suppression and fire. It is possible to prevent the fire from occurring in the whole of the space because the initial fire suppression is possible, and it is possible to suppress the fire without discharging the entire contents, thereby simplifying post-treatment by fire. As shown in FIG. 5, the fire extinguishing unit 500 is provided to inject a fire extinguishing liquid through the fire extinguishing holes 210 of the housing tube 200 so that the fire extinguishing liquid is supplied from the outside and can be suppressed at the time of fire occurrence And at least one or more of the outer circumferences of the wire rope 300 are formed.

3 and 4, the fire extinguishing unit 500 includes a fire extinguishing liquid tube 510 and an injection nozzle 520. The fire extinguishing liquid tube 510 receives the extinguishing liquid from the outside, At least one of which is formed communicating with the spray hole 210 on the length from the upper end to the lower end of the inside of the housing tube 200. Here, the digestive liquid tube 510 is also disposed around the wire rope.

The injection nozzle 520 is connected to the end of the digestive liquid tube 510 and is coupled to the inside of the housing tube 200 corresponding to the injection hole 210 of the housing tube 200, And the supplied digestive liquid is injected through the injection hole 210. Here, the injection nozzle 520 is formed to correspond to the number of the digestive liquid tubes 510.

The fixing tube 600 is provided to fix the slot tube 400 and the fire extinguishing part 500 around the wire rope 300 and is formed to correspond to the length of the inside of the housing tube 200 . 3 and 4, the fixation tube 600 is constructed to have elasticity, and the slot tube 400 and the digestive tube 500 of the fire extinguisher 500 (refer to FIG. 3 and FIG. 4) 510 are fixed so that measurement at a constant position is always possible without interference between the respective components and without changing the measuring point of the thermocouple 100 fitted on the slot tube 400, 510 to restrict the flow of the digestive juice in the course of the flow of the digestive juices, thereby providing a more stable supply of the digestive juices.

As shown in FIG. 5, the thermocouple interchangeable inter-space fire monitoring and suppression unit according to the present invention is installed between the houses where coal is accommodated. It is desirable to set up a point over the upper, middle, and lower sides of the space between the coals, and measure the temperature for each point.

Next, if the operation error or damage of the thermocouple 100 at a specific position occurs in the course of continuously measuring the temperature of the inside of the coal accommodated in the space, the operator may cause the malfunctioning thermocouple 100 to contact the corresponding slot tube 400 So that the thermocouple 100 can be easily replaced at the corresponding position by inserting the thermocouple 100 into the slot tube 400 again.

On the other hand, in the process of continuously measuring the temperature by the thermocouple 100, when the fire occurs in the inside of the coal accommodated in the space due to spontaneous ignition, the temperature due to the fire rapidly increases and the temperature of the thermocouple 100 located nearest The control unit supplies the extinguishing liquid to the digestive liquid tube 510 of the extinguishing unit 500 and then sends the excreted liquid through the injection nozzle 520 connected to the end of the excretory liquid tube 510, (210) so that an initial fire suppression is performed.

Therefore, the early suppression can be performed quickly when a fire inside the coal is easily accommodated, thereby preventing loss of raw materials and loss of equipment due to fire.

That is, according to the present invention, since the thermocouple 100 can be quickly replaced by configuring the unit for monitoring and suppressing fire between the thermocouple replacement type, it is possible to continuously measure the inside temperature without interruption, And the maintenance cost can be reduced. In addition, since the initial fire suppression can be performed quickly, safety against fire can be ensured and the efficiency of operation can be increased.

While the present invention has been described in detail with reference to the embodiments thereof, it will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the scope and spirit of the invention. And embodiments of the present invention.

100: thermocouple 200: housing tube
210: Sprue 300: Wire rope
302: Retaining ring 400: Slot tube
500: Digestion part 510: Digestion tube
520: injection nozzle 600: fixed tube

Claims (4)

A plurality of thermocouples 100 having mutually different lengths for measuring the temperature of the section from the upper part to the lower part;
At least one spray hole (210) is formed through the outer periphery of the cylindrical tube, and the housing tube (200) is insulated;
The housing tube 200 is pulled downward by the lower tensile force generated when the contents stored in the space are discharged downward to prevent the displacement of the measuring point or the separation, breakage or damage of the housing tube 200 A wire rope 300 coupled from the upper center to the lower center inside the housing tube 200;
The thermocouple 100 is formed to correspond to the number of the thermocouples 100 installed along the circumference of the outer circumference of the wire rope 300 according to the number of intervals to be measured, A slot tube (400) interfitting with the slot tube (400);
The fire extinguishing liquid is injected through the injection holes 210 of the housing tube 200 so that the fire extinguishing liquid is supplied from the outside and the initial pressure can be exerted when a fire occurs and at least one or more of the fire extinguishing liquid is formed along the periphery of the outer periphery of the wire rope 300 A digestion unit 500;
A fixing tube 600 fixed to the wire rope 300 and formed to correspond to a length of the inside of the housing tube 200; And a thermocouple interchangeable interspace fire monitoring and suppression unit.
The method according to claim 1,
Wherein the housing tube (200) and the slot tube (400) are formed of Teflon having excellent insulation and heat resistance.
The method according to claim 1,
Wherein the wire rope (300) has a fixing ring (302) in the form of a thimble and the lower end is fixed to prevent the housing tube (200) from falling downward. Monitoring and suppression units.
The method according to claim 1,
The fire extinguishing unit 500 includes at least one fire extinguishing liquid tube 510 which is supplied with extinguishing liquid from the outside and communicates with the spraying hole 210 on the length from the upper end to the lower end of the housing tube 200;
And is connected to an end of the digestive liquid tube 510 and is coupled to the inside of the housing tube 200 corresponding to the injection hole 210 of the housing tube 200. The digestive liquid supplied from the outside through the digestive liquid tube 510 flows into the injection hole 210, And a spray nozzle (520) arranged to spray air through the spray nozzle (210).

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