EA012710B1 - Coke oven operating unit for catching residual coke and the residues cleaned from said oven - Google Patents

Abstract

The invention relates to a coke oven operating unit (1) of a coke pushing machine and/or a coke transfer machine of a coke oven comprising a large number of neighbouring coking chambers (3), said unit being designed to catch residual coke and remove it from the area of the primary duct (2) of the coke oven. The unit comprises a scoop unit (4) with at least one coke scoop (5), the latter (5) adopting a catching position below an oven door of the coking chamber (3) in the vicinity of the base of the primary duct (2), in order to catch the residual coke and the residues that are cleaned from the oven. According to the invention, at least one suction unit (12) is situated on and/or in the coke scoop (5) to siphon off the emissions that are released in the vicinity of the coke scoop (5).

Description

The present invention relates to an aggregate interacting with a coke pusher and / or machine for moving coke formed in numerous and adjacent coking chambers, the task of which is to collect and remove coke accumulating in the gallery under the service platform, with a device for attaching shovels, while the coke shovel is in the position for trapping coke and waste generated during cleaning of the furnace frame, under the coking chamber furnace door at the gallery level under service platform. It follows that the invention relates to coke ovens equipped with units of the indicated type.

Coke ovens consist of several disk-shaped coking chambers, which are arranged one after another in a row. At the end of coal coking, coke is removed from the furnace using a coke ejector. The necessary opening and closing of the oven doors from the coke ejector side is carried out automatically by the coke ejector itself. The coke pushed out of the furnace by the coke pusher is guided by the guide integrated into the car for moving coke into the car. The necessary opening and closing of oven doors from the side of the machine for moving coke is done automatically by the machine for moving coke.

During the opening of the oven doors to perform the coke ejection procedure both from the coke ejector side and from the coke transfer machine side, a large amount of coke accumulates, which must be removed from the area of this gallery under the service area.

For trapping coke residues, aggregates of the type indicated at the beginning of the text are provided for trapping and removing accumulated coke; the coke collecting shovel is in the position for trapping coke under the coking chamber furnace door at the gallery level under the service platform and is able to move from the trapping position to the coke removal position. When moving from the capture position to the coke removal position, the coke collecting spade rises above the gallery area under the service area and occupies the corresponding position for the subsequent removal of coke residues.

A drawback of units for removing coke residues of the type described above from the coke oven is that the coke collected by the shovel releases side and harmful substances in the area of action of the coke shovel, which are usually not captured by the suction devices of the coke ejector and / or coke transfer machine. Such emissions, along with dust, include in particular emissions in the form of steam, gas or smoke. To extinguish the collected coke, the shovel is filled with not less than half water, which turns into steam when combined with the hot residues of coke. Quenching of coke residues is carried out mainly with or without water. Together with steam, along with solid particles, gaseous harmful substances are also released from the inside of the shovel to collect coke into the environment.

The purpose of this invention was defined as the elimination of the above disadvantages.

When operating units of the described type for removing coke residues from a coke oven, this problem was solved due to the fact that at least one suction device is provided on and / or in the coke pick-up shovel, which ensures suction of discharge in the shovel's area of operation. The main idea of the invention is to capture, directly in the area of action of the shovel, a collection of coke, before they can leave the area of action of the shovel and enter the environment. One of the advantages is that the emissions are captured completely and this prevents them from entering the environment.

A preferred installation location for the suction device is the longitudinal side, and especially both longitudinal sides of the coke pick shovel. As a result of this, it becomes possible to easily and completely capture the discharge in the area of action of the shovel for collecting coke and, thereby, prevent the release of emissions into the environment. In addition, the process of unloading the collected excess coal and coke residues is not interrupted by the operation of the exhaust device. However, there is no need for the suction device to run along the entire length of the longitudinal side of the coke collecting shovel. It will be sufficient if the suction device will pass only over part of the longitudinal side, preferably over the front part of the longitudinal side. A good and possible solution is also that the suction device can be installed on the front side of the coke shovel, or that the suction device can also pass over both longitudinal sides and the front side of the shovel.

In order that the precipitates formed in the coke collecting spade can be completely captured, regardless of the degree of filling of the spade, the suction device or its suction opening, having an optimal shape in accordance with the concept of the invention, is located in the region of the upper edge of the spade or in the region of the upper edge of the side wall a shovel attached to an aspiration device. Moreover, to further improve the operation of the suction device, the side of the spade for collecting coke may have an angled or rounded edge, which makes it easier to catch the secretions formed inside the spade. As a result, the aspiration of accumulations accumulated inside the shovel for collecting coke is ensured, as well as control that the proportion of air flow drawn in from the environment will be kept low.

The most preferred constructive solution in the manufacture of this invention is pre

- 1 012710 includes at least one suction port of the suction device, extending along the entire length of the suction device connected to the side wall. In this case, it becomes possible to simultaneously capture the discharge along the entire longitudinal side of the side wall. The suction opening of the suction device can be located in the inner region of the coke collecting shovel, which also helps to catch the secretions formed inside the coke collecting shovel.

The aspiration device can be made in the form of a collector, which ensures the most uniform collection of secretions along the entire length of the shovel and greater suction performance with smaller overall dimensions of the suction. When choosing collector sizes, determine the volume to be captured using the airflow balance method.

If the suction device is designed in the form of an exhaust device-collector, then located inside the guide surface of the suction device is formed due to the inclined side wall of the shovel for collecting coke. The guide surface is designed to guide the release of the coke that is released inside the shovel in the direction of the suction opening of the exhaust device. This is also facilitated by the manufacture of the side wall of the shovel for collecting coke and the collector in the form of an integral part, with the upper edge of the side wall being bent inward in accordance with the shape of the collector. If the guide surface and the collector are part of the side wall of the shovel for collecting coke, this contributes to a simple structural assembly of the invented unit for removing coke residues from the coke oven. The invention, if necessary, allows you to connect the suction device to the side wall or the front wall of the coke shovel, for example by bolting or welding, which makes it possible to further equip the coke shovel for the unit to remove the remaining coke from the coke oven with an exhaust device.

Depending on the design solution in the manufacture, the cross section of the collector can be semi-cylindrical or multifaceted, and in both cases the final section of the collector can be narrowed towards the middle axis of the collector to achieve the desired narrowing of the flow before it enters the area of the suction port.

If a collector is provided as an aspiration device, it must have at least two suction openings. For example, you can provide a minimum of two outlet pipes passing through the collector sheathing and entering the collector, as well as connected to the suction system and representing a streamlined double drain, and the discharge pipes should be spaced from each other so that a vortex flow passes between adjacent pipes .

This is how a particularly high suction performance is achieved with little energy consumption by the suction system. The volume that must be captured using an aspiration device consists of a stream of emissions, as a rule, it is a mixture of harmful substances with air, and air flows drawn from the environment. The present invention is designed to ensure that the volumetric flow rate of the mixture sucked by the suction device is greater than the discharge stream at the level of the suction device. In any case, due to this, the contaminated air flows released inside the coke shovel are almost completely trapped, the volumetric flow rate of the suction mixture depends on the shape of the trapping element of the suction device. Based on the volume of the discharge stream located at the level of the suction device or at the level of the suction port, the volume of the stream to be captured is calculated according to the equation below:

V1 (b) = V0 (th) xa, where V | (11) is the volumetric flow rate of the suction mixture,

Y _o (11) is the volumetric flow rate of the discharge stream at the level of the suction device, σ is the safety factor for taking into account the air flows coming from the environment when calculating the flow rate of the suction mixture.

During tests conducted in connection with this invention, it was found that the most suitable value of the safety factor σ, which can vary from 1.1 to 3.0, is approximately 1.5. The ratio of the volumetric flow rate of the suction mixture to the volumetric flow rate of the discharge stream at the level of the suction device may be 1.1-3.0, but the most acceptable value is about 1.5.

The invented unit for removing coke residues from a coke oven can be used in conjunction with a coke ejector and / or coke transfer machine. The volumetric flow rate of the suction mixture should vary from 3000 to 5000 m ³ / h, if the unit for removing from the coke oven the remaining coke is used together with the coke ejector. On a machine for moving coke in a coke oven, the volumetric flow rate of the suction mixture can be from 2000 to 4000 m ³ / h, because the volumetric flow rate of the discharge from the machine for moving coke is usually less than from the coke-ejector side of the coke oven. The most preferred design solution for

According to the invention, the consumption of the suction mixture from the side of the coke ejector is about 4200 m ³ / h, and from the side of the machine for moving coke about 3000 m ³ / h.

There are many possibilities for equipping and improving the invented unit for removing coke residues from a coke oven, indicated, on the one hand, in the claims and, on the other, in the following detailed description of the most preferred design solution in the manufacture of this invention with reference to the drawings.

Brief Description of the Drawings

FIG. 1 is a cross-sectional view of a proposed unit for collecting and removing loose coke or the like with a coke shovel, which is set in a catching position.

FIG. 2 - shown in FIG. 1 unit for removing the remaining coke from the coke oven, the coke collecting spade is installed in the unloading position.

FIG. 3 is a side view of a shovel for collecting coke of FIG. 1 unit for removing coke residues from the coke oven.

FIG. 4 is a plan view of FIG. 3 shovel for collecting coke.

FIG. 5 is a front view of FIG. 3 shovel for collecting coke.

In FIG. 1 schematically shows the proposed unit, designed to capture and remove loose coke to or from the service area 2 of one of the coke pushers of the coke oven, consisting of several coking chambers located one after another. On the unit for removing coke residues 1 from the coke oven, there is a device for attaching shovels 4 with at least one shovel for collecting coke 5; in FIG. 1 a shovel for collecting coke 5 in the catching position of loose coke is located under the door of the coking chamber 3 at the level of the service platform 2. On the side next to the door of the coking chamber 3 is an anchor holder 6. In the transition area between the inside of the coking chamber 3 and the service platform 2 there is a drain the groove 7, through which the loose coke from the coking chamber 3 enters the coke shovel 5, located on the device for attaching the shovels 4, during the ejection process.

On the unit for removing coke residues 1 from the coke oven, there is a device for transporting coke 8, by means of which loose coke trapped by the shovel for collecting coke 5 is transported to the collector 9. The contents of the coke collecting shovel 5 can also be transferred to the drive or to the coke cake guide a device located on the side of the machine for moving coke. On the device for moving coke 8 there is an inclined wide drain chute 10, which can be moved between the collector 9 and the device for attaching the shovels 4.

In FIG. 2 shows a device for attaching shovels 4 with a shovel for collecting coke 5 in the unloading position or in the initial position. Unloading is carried out by means of a discharge chute 10. To move the coke pickup shovel 5 from the loading position to the unloading position, it is necessary to lift the coke pickup shovel 5 above the service platform 2, and to rotate the rotary axis 11. To extinguish coke residues, with or without water .

In FIG. 3-5, a device for attaching shovels 4 of an invented unit for removing coke residues from a coke oven is shown. On the device for attaching the shovels 4 there is one shovel for collecting coke 5 with two suction devices 12, which are located on two sides of the shovel for collecting coke 5. The shovel for collecting coke 5 at this stage of the development of technology has the already known design. The same applies to the device for attaching the shovels 4. In the presented design solution, it is provided that the suction devices 12 are located mainly along the entire length of the side walls 13 of the shovel for collecting coke 5 near horizontal or inclined upper edges and are connected to the side walls 13. Near the side walls 13, an arrangement of additional side walls 14 is provided, which are connected to the side walls 13 and taper at an inclination at the top. The present invention contemplates the possibility of installing an additional suction device on the front wall 15 of the shovel for collecting coke 5 or placing suction devices 12 over the entire side wall of the shovel for collecting coke 5, i.e. along the entire length of the side walls 13, 14 near the corresponding upper edges of the shovel.

The loose coke generated during the ejection process moves along the back wall 16 of the shovel to collect coke 5 during the unloading of the shovel 5 through the drain chute into the collector 9. Aspiration devices 12 are designed to trap the emissions that are released from the loose coke during the ejection process in the area of the shovel for collecting coke during capture and / or unloading.

To ensure the most uniform collection of the discharge, the suction devices 12 can be made in the form of a collector. Each exhaust device 12 has at least one collector 17. At least two outlet pipes 18 are provided on the collectors 17, which are included in the collector 17 and connected to the traction drive and representing a streamlined double drain. Moreover, the discharge pipes 18 should be located from each other at such a distance that between the adjacent pipelines 18 during suction a vortex flow passes. This increases the suction capacity with little energy consumption by the traction stimulator.

In FIG. 5 clearly shows how the emissions released from the coking products 19 inside

- 3 012710 depicted in FIG. 5, the coke collecting shovels 5 move along the guide surfaces 20 to the suction openings 21 located in the manifolds 17. The suction openings 21 are located mainly along the entire length of the side walls 13. This ensures almost complete capture of the secretions that are released inside the collecting shovel coke 5. The guide surface 20 is formed by the upper region of the side side 13 of the coke collecting spade 5, and the collector 17 of the suction device 12 and the side wall 13 of the coke collecting spade 5 can be made us as one.

The suction holes 21 are directed to the inner region of the coke collecting shovel 5. The emissions, for example dust and / or gas, steam or smoke, move along the guide surface 20 in the direction of the suction holes 21 and are almost completely trapped by the suction device 12. In this case, the suction the device 12 captures and sucks a part of the ambient air, since the air flows surrounding the coke shovel 5 also enter the suction holes 21. This makes it possible to maintain the surrounding lobe In order to collect coke 5, the area is relatively clean of harmful and impurity substances.

The lateral side 13 in the presented design solution in the region of the upper edge of the shovel is circularly bent inward and forms the collector 17 of the suction device 12. Moreover, the lateral side 13 in the region of the suction hole 21 can be bent inward in the direction of the middle axis of the collector 17. This helps to ensure that the vortex flow arising between the discharge pipes 18, before entering the region of the suction hole 21 inside the manifold 17 is compacted and accelerated, while the dynamic pressure increases, and the static The second pressure, which is responsible for the confluent discharge flows, the air from the inner region of the coke pickup shovel 5 and the surrounding air, decreases compared to the constant total pressure.

If necessary, instead of the suction device 12 in the form of a collector, it is also possible to use other known suction devices for collecting and suctioning the discharge on and / or in a shovel for collecting coke 5. It is worth noting that the claims and / or the features or described features can be combined with each other, even if it is not described separately. The invention is not limited to the constructive solution given and described here in the manufacture. The above parameter values and the given intervals cover all, without exception, parameters, i.e. not only the lower bounds (for intervals, the boundaries of the intervals).

Claims (14)

CLAIM 1. A unit for removing coke residue (1) from a coke oven, mounted on a coke pusher and / or a machine for transporting coke formed in numerous coking chambers (3) of the furnace, located next to each other, designed to capture and remove loose coke that accumulates in the gallery under the service platform (2) containing a device for attaching shovels (4) with at least one shovel for collecting coke (5), while the shovel for collecting coke is in position to catch loose coke and waste, when cleaning the furnace frame, under the door of the oven of the coking chamber (3) at the level of the service platform (2), characterized in that at the side wall (13) of the shovel for collecting coke (5) there is at least one aspiration device (12) for suction of excretions released in the area of a shovel for collecting coke (5); the suction opening (21) of the suction device (12) is located on the side of the coke collection shovel (5), and the suction opening (21) is located in the inner area of the coke collection shovel (5), and the suction opening (21) extends at least partially along the side wall (13). 2. The unit according to claim 1, characterized in that on both sides of the shovel for collecting coke (5) is provided on the suction inlet (21). 3. Unit according to claim 1 or 2, characterized in that the aspiration device (12) is located near the upper edge of the side wall (13) of the shovel for collecting coke (5). 4. Unit in one of the preceding paragraphs, characterized in that the upper edge of the side wall (13) of the shovel for collecting coke (5) is bent or rounded down. 5. Unit according to one of the preceding paragraphs, characterized in that the suction inlet (21) extends along the entire length of the side wall (13). 6. The unit according to one of the preceding paragraphs, characterized in that at least one collector (17) is installed on the suction device (12). 7. Unit according to one of the preceding paragraphs, characterized in that the side wall (13) of the coke collection shovel (5) forms the inner guide surface of the aspiration device (12). 8. Unit according to one of the preceding paragraphs, characterized in that the side wall (13) of the shovel for collecting coke (5) and the collector (17) are manufactured as one piece. 9. Unit according to one of the preceding paragraphs, characterized in that in the manifold (17) there are at least two suction ports. 10. Unit in one of the preceding paragraphs, characterized in that the volumetric flow rate of the mixture sucked by the suction device (12) is greater than the volumetric flow rate of the discharge on - 4 012710 level of the aspiration device (12). 11. The unit according to one of the preceding paragraphs, characterized in that the ratio of the volume flow rate of the aspirated mixture to the volume of the discharge flow at the level of the aspiration device (12) may be 1.1-3.0, but preferably about 1.5. 12. Unit in one of the preceding paragraphs, characterized in that the volumetric flow rate of the suction mixture varies from 3000 to 5000 m ³ / h, if the unit for removing coke residues from the coke oven (1) is used in conjunction with a coke pusher. 13. An assembly according to one of the preceding claims, characterized in that the volume flow rate of the suction mixture in the machine for moving coke in a coke oven is from 2,000 to 4,000 m ³ / h. 14. Machine for servicing coke ovens with units for removing coke residue (1) from a coke oven according to one of the preceding paragraphs.