JP2003172606A - Tip position-instructing apparatus and method for coke push-out ram - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a tip position-instructing apparatus for a coke push-out ram for measuring the shape of the oven wall of a plurality of kilns efficiently and continuously without preventing the operation of a coke oven. <P>SOLUTION: As a guide pipe 2 in a ram beam 1 of the coke push bench, a stainless pipe is laid. A stainless box 3 is provided at the tip section of the ram beam 1 for connecting to the guide pipe 2. Further, a guide pipe 4 is additionally joined toward the upper section of the ram beam 1 for going out of the ram beam. Then, a tip section 4a of the guide pipe 4 is fixed so that it is directed toward the direction (direction of the outside of the oven) of the push bench. Light from a light source 5 is guided to the tip section of the ram beam 1 by an optical fiber 6 in the guide pipe, and is discharged toward the direction (direction toward the outside of the oven) of the push bench from the tip of the optical fiber 6. <P>COPYRIGHT: (C)2003,JPO

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a coke extruder for a coke oven, in which a sensor portion of a distance measuring means is mounted on the tip end of the extrusion ram, and the profile of the oven wall is profiled when the extrusion ram is inserted into the coke oven carbonization chamber. Sequentially measuring coke oven coke chamber In measuring the shape of the furnace wall, the coke provided to refer to the position of the distance measuring means sensor unit installed at the extruding ram tip end part with the insertion of the extruding ram in the width direction of the kiln chamber Extrusion ram tip position indicator,
And a method for measuring the tip position of a coke extrusion ram using the same.

[0002]

2. Description of the Related Art In order to know the change in the shape of the furnace wall of the coke oven in the coke oven, the distance from the range finder to the furnace wall is sequentially measured at the tip of the extrusion ram provided in the extruder, and this measurement data is used. The method of sequentially measuring the profile of the furnace wall is used. In this coke oven carbonization chamber furnace wall shape measurement, the tip of the extrusion ram fluctuates in the carbonization chamber kiln width direction as the extrusion ram is inserted, and the position of the distance measuring means sensor unit also changes in the carbonization chamber kiln width direction. Since it fluctuates due to fluctuations, if the measured value measured by the distance measuring means is taken as the profile of the furnace wall as it is, an error occurs.

As a method of correcting this error, a sensor position reference point provided at a position near the sensor installed at the tip of the ram, together with a furnace body reference point provided near the charring chamber kiln, is provided outside the furnace. A method has been developed in which the variation of the sensor position is calculated from the relative positional relationship between the sensor position reference point and the furnace body reference point, which are photographed, and correction is performed.
As a sensor position reference point used for such a purpose, Japanese Patent Application Laid-Open No. 2001-21527 discloses a method in which an LD is installed to emit light.

[0004]

However, when continuously measuring the furnace wall shape of different kilns, the LD is destroyed by the effect of radiant heat. Therefore, it is impossible to continuously measure the furnace wall shape for multiple kilns. Further, if the measurement is performed while replacing the damaged LD, the coke oven operation is hindered and the measurement efficiency is poor. Also, multiple L's
Preparing D is costly.

The present invention has been made in view of the above circumstances, and a coke extruding ram that enables the furnace wall shape measurement of a plurality of kilns to be efficiently and continuously performed without hindering the operation of the coke oven. An object is to provide a tip position indicating device and a method for detecting the tip position of a coke pushing ram using the same.

[0006]

A first means for solving the above-mentioned problems is a device for indicating a tip position of an extrusion ram provided in a coke extruder of a coke oven, which comprises a light source and an extrusion ram. And an optical fiber provided along the extrusion ram toward the tip of the extrusion ram, and a holding portion for holding the tip of the optical fiber toward the outside of the furnace of the extrusion ram, at the tip of the extrusion ram. It is a tip position indicating device for a coke extrusion ram (claim 1).

In the present means, the light from the light source provided at the rear end of the extrusion ram is transmitted to the tip of the extrusion ram through the optical fiber, and the tip is directed toward the outside of the extrusion ram by the holding portion. Light is emitted toward the outside of the coke oven from the tip of the optical fiber held toward the outside. The tip of the optical fiber, which is the light emission point, can be used as a sensor position reference point. Since the optical fiber has heat resistance, its tip has a long life, and therefore, it becomes possible to efficiently and continuously measure the furnace wall shape of a plurality of kilns without hindering the operation of the coke oven. As the optical fiber to be used, one having high heat resistance and mechanical strength is preferable.

A second means for solving the above problems is
In the first means, a guide tube made of a flame-retardant material is laid inside the beam of the extruding ram, and the extruding ram tip side of the guide tube is pulled out to the outside of the extruding ram so that the end of the guide tube is A guide tube is fixed so as to face the beam rear end direction of the extrusion ram, and an optical fiber is laid inside the guide tube (claim 2).

In this means, since the optical fiber is passed through the guide tube inside the beam of the extrusion ram, mechanical damage to the optical fiber can be avoided. Moreover, since the guide tube is made of a flame-retardant material, it is possible to prevent the guide tube itself from being damaged or deformed by heat. Then, the extruding ram tip side of the guide tube is pulled out to the outside of the extruding ram, and the guide tube is fixed so that the end of the guide tube faces the beam rear end direction of the extruding ram. The front end portion of the beam also faces the beam rear end direction of the extrusion ram.

A third means for solving the above problems is
In the second means, a box made of a flame-retardant material is installed in the middle of the guide tube, the box and the guide tube are connected to each other, and the expansion and contraction of the optical fiber can be adjusted inside the box. (Claim 3).

As the extrusion ram is moved in and out of the coking chamber of the coke oven, the temperature experienced by the optical fiber rises and falls dramatically. Therefore, the tip of the optical fiber may be pulled into the guide tube or broken.
In this means, a box made of a flame-retardant material is installed in the middle of the guide tube, and the expansion and contraction of the optical fiber can be adjusted by means such as slackening the optical fiber in the box. Therefore, the expansion and contraction of the optical fiber can be absorbed by this portion.

A fourth means for solving the above problems is
The second means or the third means is characterized in that cooling air is blown into the guide pipe (claim 4).

According to this means, it is possible to prevent the temperature of the optical fiber from becoming high due to the cooling air, and it is possible to reduce the amount of expansion and contraction of the optical fiber.

The fifth means for solving the above-mentioned problems is as follows.
Any of the first to fourth means, characterized in that a polyimide-coated optical fiber is used (claim 5).

The polyimide coating sublimes in a high temperature atmosphere of 600 ° C. or higher, and no coating carbide or the like remains on the optical fiber strand. Therefore, it is possible to prevent the occurrence of an accident in which the property of the coating is changed by such a residue and the optical fiber is cut.

A sixth means for solving the above-mentioned problems is as follows.
In any one of the second means to the fifth means, FIMT (Fiber in Metal Tube) is used as an optical fiber, and the metal forming the sheath is removed at the tip of the optical fiber. What does (claim 6).

Since FIMT is used in this means, the mechanical strength can be increased. Since the metal forming the sheath is removed at the tip, the optical fiber body is drawn into the guide tube due to the difference in the thermal expansion coefficient between the optical fiber body and the metal sheath, and the light is emitted to the outside. It is possible to prevent the optical fiber from being broken or the optical fiber being damaged.

The seventh means for solving the above-mentioned problems is as follows.
The position of the light emitted from the tip of the light transmitting means of the tip position indicating device of the coke extrusion ram, which is any of the first to sixth means, with respect to the coke oven furnace body installed on the extruder is known. The method for detecting the tip position of the coke pushing ram is characterized in that the tip position of the coke pushing ram is detected from the photographing position.

In this means, the light emitted from the tip of the optical transmission means of the tip position indicating device of the coke extrusion ram, which is any of the first to sixth means, is picked up by the image pickup means. Since the tip position of the coke pushing ram is detected from the photographing position, it is possible to efficiently and continuously measure the furnace wall shape of a plurality of kilns without hindering the operation of the coke furnace.

[0020]

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, an example of an embodiment of the present invention will be described with reference to the drawings. FIG. 1 is a schematic diagram showing a tip position indicating device for a coke extrusion ram, which is an example of an embodiment of the present invention. A stainless steel pipe is laid as a guide pipe 2 in a ram beam 1 of the coke extruder. A stainless steel box 3 is provided at the tip of the ram beam 1 and is connected to the guide tube 2. Further, a guide tube 4 is extended toward the upper part of the ram beam 1 so that the ram beam 1 goes out of the ram beam. Is fixed so as to face the direction of the extruder (outside the furnace).

On the other hand, a light source 5 is provided at the rear end of the ram beam 1, and the light from the light source 5 is guided to the tip 4a of the guide tube through the optical fiber 6 passing through the guide tube 4,
The tip is directed toward the extruder (outside the furnace). The light from the light source 5 is guided to the tip of the ram beam 1 by the optical fiber 6, and emitted from the tip of the optical fiber 6 toward the extruder (outside the furnace).

An enlarged schematic view of the extruding ram tip is shown in FIG.
Shown in. In the following drawings, the same components as those shown in the previous drawings are designated by the same reference numerals and the description thereof will be omitted. The guide tube 4 is bent at the tip of the ram beam 1 to the outside of the ram beam and is directed toward the extruder, and the tip 4 a is fixed to the holding table 7. An optical fiber tip fixing jig 8 is provided at the tip 4a of the guide tube 4, and the optical fiber 6 coming out of the guide tube 4 is fixed thereto. In addition, the tip of the optical fiber is opened so as to project light efficiently with a certain degree of directivity.

As the optical fiber, an ordinary optical fiber may be used, but in the present embodiment, an optical fiber coated with a polyimide that sublimes at high temperature or a FIMT (Fiber in Metal Tub) considering heat resistance and mechanical strength is used.
e) is inserted in the guide tube 4.

FIG. 3 is an enlarged schematic view of the vicinity of the box 3. At high temperatures, the coefficient of thermal expansion of the metal-clad tubes used for the FIMT and the guide tube is larger than that of the optical fiber, so that the optical fiber is pulled into the guide tube 4 or cut due to the increase in ambient temperature. However, it may not be possible to refer to the tip position of the extrusion ram from outside the furnace.

Therefore, in the present embodiment, the extruded ram tip side is cut into the stainless steel tube of the FIMT just before entering into the stainless box 3 installed at the tip of the ram beam 1, and the polyimide coated tube is cut. Only certain optical fiber strands are used. The fiber strands are wound in multiple layers and housed inside a stainless steel box 3.
The expansion / contraction of the optical fiber can be adjusted by raising and lowering the temperature of the inside of the box 3, and the optical fiber is prevented from being drawn into the guide tube 4 due to the rise of the ambient temperature.

FIG. 4 is an enlarged schematic view of the rear end portion of the ram beam 1. As the light source 5 to be incident on the optical fiber 6, a green laser beam is used so that the extrusion ram tip position reference point can be distinguished from the in-furnace radiant light in the carbonization chamber. When the light quantity is insufficient in the furnace, a plurality of optical fibers (FIMT) may be used.

When the optical fiber expands and contracts greatly due to temperature changes, the guide tube 2 is introduced from the rear end of the ram beam 1.
Cooling air is blown therein as shown in the figure. For blowing the cooling air, a compressor attached to the extruder may be used. The polyimide coating of the optical fiber sublimes in a hot atmosphere of 600 ° C. or higher, which lowers the mechanical strength of the optical fiber. Since the sublimation of the polyimide coating is prevented by blowing cooling air, the optical fiber 6 can be used for a longer period of time.

In a normal optical fiber, the coating may be carbonized in a high temperature atmosphere, and the properties of the coating may change to cause cutting of the fiber. However, in a polyimide-coated optical fiber, the coating sublimes, and therefore the coating properties change. It is possible to suppress the occurrence of fiber breakage due to changes.

The light emitted from the tip of the optical fiber 6 fixed at a known position on the extruding ram tip is photographed by using a camera whose position is known with respect to the furnace body installed on the extruder, The position of the tip of the extrusion ram in the kiln width direction of the coke oven carbonization chamber can be obtained.

The extrusion ram is about 25 m long,
The depth of the carbonization chamber of the coke oven is about 15 m. Therefore, the installation position of the light source is 5 from the rear end of the extrusion ram.
If it is within m, it is convenient because the thermal effect from the carbonization chamber is small. The rear end position of the extrusion ram has the least thermal influence and is desirable as the light source installation position.

It is also possible to provide the light source in an extruder body other than the ram. However, when comparing the case where it is provided on the ram with other cases, it is preferable to provide it on the ram. That is, when it is provided on the ram, the light source and the optical fiber are arranged on the same member, and the measurement error and the like due to the vibration at the time of inserting the ram can be eliminated. Furthermore, when the ram is arranged on the ram, it is possible to eliminate problems such as the extension of the optical fiber due to the relative position change between the ram and the extruder main body, and the cutting due to the catch.

[0032]

As described above, according to the present invention,
Coke extrusion ram tip position indicating device capable of efficiently and continuously measuring the furnace wall shape of a plurality of kilns without disturbing the operation of the coke oven, and a method for detecting the tip position of a coke extrusion ram using the same Can be provided.

[Brief description of drawings]

FIG. 1 is a schematic diagram showing a tip position indicating device for a coke extrusion ram, which is an example of an embodiment of the present invention.

FIG. 2 is an enlarged schematic view of a tip portion of an extrusion ram.

FIG. 3 is an enlarged schematic view of the vicinity of a box 3.

FIG. 4 is an enlarged schematic view of a rear end portion of the ram beam 1.

[Explanation of symbols]

1 ... Lamb Beam 2 ... Guide tube 3 ... box 4 ... Guide tube 4a ... Tip of guide tube 5 ... Light source 6 ... Optical fiber 7 ... Holding table 8 ... Fixing jig for optical fiber tip

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Claims (7)

[Claims] 1. A device for indicating a tip position of an extrusion ram provided in a coke extruder of a coke oven, comprising a light source and an optical fiber provided along the extrusion ram toward the tip of the extrusion ram. A tip position indicating device for a coke extrusion ram, comprising: a holding portion that holds the tip of the optical fiber toward the outside of the furnace of the extrusion ram, at the tip of the extrusion ram. 2. The tip position indicating device for a coke extruding ram according to claim 1, wherein a guide tube made of a flame-retardant material is laid inside the beam of the extruding ram, and the extruding ram tip side of the guide tube. Is pulled out of the extrusion ram, the guide tube is fixed so that the end of the guide tube faces the direction of the beam rear end of the extrusion ram, and an optical fiber is laid inside the guide tube. Pointing device. 3. The coke extrusion ram tip position indicating device according to claim 2, wherein a box made of a flame-retardant material is installed in the middle of the guide tube, and the box and the guide tube are connected to each other. The tip position indicator of the coke extrusion ram is characterized in that the expansion and contraction of the optical fiber can be adjusted inside the box. 4. The coke extruding ram tip position indicating device according to claim 2 or 3, wherein cooling air is blown into the guide tube. apparatus. 5. Any one of claims 1 to 4
The coke extruding ram tip position indicating device according to item 1, wherein a polyimide coating is used as an optical fiber. 6. Any one of claims 2 to 5
The tip position indicating device for a coke extrusion ram according to the above item, wherein the optical fiber is a fiber in metal tube (FIMT).
A device for indicating the position of the tip of a coke extruding ram, characterized in that the metal forming the sheath is removed at the tip of the optical fiber by using e). 7. Any one of claims 1 to 6
The light emitted from the tip of the optical transmission means of the tip position indicating device of the coke extrusion ram according to the paragraph, is photographed by the image photographing means whose position with respect to the coke oven furnace body installed on the extruder, and the photographing position thereof. The method for detecting the tip position of the coke pushing ram is characterized by detecting the tip position of the coke pushing ram from the.