KR102677893B1 - pulverizer inspection lamp for thermal power plant - Google Patents

Abstract

In order to achieve the above object, the differentiator inspection light for a thermal power plant of the present invention is an internal investigation inspection light that is coupled to the upper part of a differentiator tank for a power plant equipped with an inspection window for internal observation, and is coupled to the upper center of the differentiator tank to A guide protrusion pipe that communicates with the inside of the pipe but secures a safety space upward, an upper and lower coupler that blocks the upper part of the safety space by combining tempered glass at the top of the guide protrusion pipe, and a guide protrusion pipe that is coupled to the top of the upper and lower coupler. Since it is composed of a lighting housing that protects the inspection light of the differentiator as much as possible, it not only allows it to function sufficiently even under adverse conditions, but also allows for quick and safe replacement in the event of an abnormality, and at the same time allows replacement work to be performed without stopping the differentiator. It is done.

Description

pulverizer inspection lamp for thermal power plant}

The present invention relates to a differentiator inspection light for a thermal power plant, and more specifically, to a differentiator inspection light for a thermal power plant that prevents damage to the differentiator inspection light, extends its life, and allows safe and easy repair and replacement when an abnormality occurs.

Thermal power plants that use coal as the main raw material supply finely powdered coal (hereinafter referred to as pulverized coal) along with air, combust it in the boiler, and vaporize the water in the water pipe piped into the boiler to rotate the turbine to generate power. A coal pulverizer, which usually grinds coal into fine-sized pulverized coal and supplies it through a fuel supply pipe, has a plurality of grinding rollers rotating in a pressurized state on the upper surface of the grinding table that rotates within the housing, and is fed into the center of the grinding table through the coal supply pipe. It is designed to finely crush coal.

In addition, the coal pulverizer is pushed in the circumferential direction of the grinding table by the rotation of the grinding table, and air is blown upward from the bottom of the grinding table through the journal portion of the grinding roller to send the pulverized coal pulverized by the grinding roller to the outlet provided at the top. Most coal-fired power plants in Korea use the method of supplying pulverized coal to a particle size of less than 200 mesh, along with air, through a piping line to the boiler for combustion.

This combustion method through coal pulverization has the disadvantage of increasing facility and maintenance costs, but good combustion is possible even if the quality of coal is low, rapid operation of ignition and extinguishment is possible, and combustion of a large amount of coal is possible in a short period of time. It is being adopted and operated due to its advantages such as high calorific value.

The pulverizer is the main coal pulverization equipment in a coal-fired power plant that uses the pulverized coal combustion method. The coal supplied by the feeder falls through a pipe that passes through the center of the pulverizer and falls on a disk-shaped pulverizing table, which is then combined with the coal piled on top of it. It is constructed to rotate, and at this time, three coal crushing rollers placed above the rotating crushing table use both their own weight and hydraulic pressure to crush and pulverize the coal into powder.

This finely divided coal powder is pushed out of the grinding table by the centrifugal force of the grinding table and the coal supplied to the center, and flies around the grinding table to the upper part of the grinding table through high-pressure air supplied through the lower part of the grinding machine, where it strongly impacts the grinding roller journal. This causes damage to the journal, and in severe cases, the differentiator may stop working.

Meanwhile, for drying and transport of pulverized coal, high temperature air is supplied to raise the temperature of pulverized coal and moisture, and then the temperature of the air is lowered to maintain a constant temperature along with pulverized coal and water vapor. In this way, air and pulverized coal are maintained at a constant temperature. The constant temperature maintained when the water mixture exits the pulverizer is called the pulverizer outlet temperature. If the pulverizer outlet temperature is low, the pulverized coal pipe may be clogged due to re-condensation of evaporated moisture, so the above-mentioned The outlet temperature of a differentiator is maintained above 56℃, which is the minimum temperature that can prevent re-condensation of moisture. In order to make the outlet temperature above 56℃, the inlet temperature of the differentiator must be at least 200℃ or higher. In the case of unburned coal with a high moisture content, a higher pulverizer inlet temperature is required to dry the moisture, which has a higher specific heat than coal.

Therefore, the inside of the differentiator is visually inspected through the inspection window from time to time, but not only is the internal light frequently damaged due to adverse conditions inside the differentiator q, but there is a problem in that the operation of the differentiator has to be stopped due to replacement of the internal light.

Prior technologies include Patent Registration No. 10-1493169 and Patent Registration No. 10-1568388.

Therefore, the main purpose of the present invention is to provide a differentiator inspection light for a thermal power plant that protects the differentiator inspection light as much as possible so that it can sufficiently perform its function even under adverse conditions.

Another object of the present invention is to provide a differentiator inspection light for a thermal power plant that allows quick and safe replacement when an abnormality occurs in the differentiator inspection light and at the same time allows replacement work to be performed without stopping the differentiator.

In order to achieve the above object, the differentiator inspection light for a thermal power plant of the present invention is an internal investigation inspection light that is coupled to the upper part of a differentiator tank for a power plant equipped with an inspection window for internal observation, and is coupled to the upper center of the differentiator tank to A guide protrusion pipe that communicates with the inside of the pipe but secures a safety space upward, an upper and lower coupler that blocks the upper part of the safety space by combining tempered glass at the top of the guide protrusion pipe, and a guide protrusion pipe that is coupled to the top of the upper and lower coupler. The basic feature of its technical composition is that it is composed of a lighting housing.

Therefore, the differential inspection light for thermal power plants of the present invention allows observation of abnormalities through an inspection window, but the lighting housing can be safely protected by the safety space of the guide protrusion pipe and tempered glass even in high temperature conditions or when burning occurs during the coal grinding process. At the same time, when replacing the lighting housing, the lighting housing can be easily replaced by separating it from the upper joint that supports the tempered glass. It is also replaced while maintaining the operating condition of the pulverizer tank, so it is safe and smooth without interruption in the supply of coal. This has the effect of allowing the lighting housing to be separated and replaced.

Figure 1 is a front view showing a differentiator installed with a differentiator inspection light for a thermal power plant according to the present invention.
Figure 2 is an exploded perspective view showing the differentiator inspection light for a thermal power plant in isolation according to the present invention.
Figure 3 is a front view showing a guide protrusion pipe for a differential inspection light for a thermal power plant according to the present invention.
Figure 4 is a front view showing a combined differential inspection light for a thermal power plant according to the present invention.
Figure 5 is a cross-sectional view showing a combined differential inspection light for a thermal power plant according to the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the attached drawings.

As shown in Figures 1 to 5, the differentiator inspection light for a thermal power plant of the present invention is an internal inspection inspection light (100) coupled to the upper part of the differentiator tank (1) for a power plant equipped with an inspection window (10) for internal observation. ), a guide protruding pipe 110 that is coupled to the upper center of the differentiator tank 1 and communicates with the inside of the differentiator tank 1 while securing a safety space 113 upward, and the guide protruding pipe 110 Upper and lower couplings (120a, 120b) that block the upper part of the safety space (113) by combining tempered glass (123) at the top, and a lighting housing ( 130).

The guide protrusion pipe 110 forms an upper flange 112 and a lower flange 111, and the lower flange 111 is erected and connected to the upper center of the differentiator tank 1 so as to communicate with the interior, and the upper flange 112 It is desirable to secure a sufficient safety space 113 upward between the and the lower flange 111 to suppress damage due to damage caused by the operation of the pulverizer, such as coal crushing.

Here, a fastening hole 114 is formed in the upper flange 112 and the lower flange 111 to fasten them with a bolt ring, etc., but the lower flange 111 can also be fixed by welding to the differentiator tank 1.

Meanwhile, a blocking network (not shown), etc. may be selectively formed between the upper flange 112 and the lower flange 111 as needed.

The upper and lower couplers (120a, 120b) are formed in a ring shape, with locking protrusions (121a, 121b) formed on the inside of the surfaces facing each other to face each other, and the opposing locking protrusions (121a, 121b) have a disc shape. It is formed by sandwiching the tempered glass 123.

At this time, ring-shaped gaskets 124 are inserted on the upper and lower sides of the tempered glass 123 to seal the gap and at the same time stably support the tempered glass.

In addition, it is desirable to drill fastening holes (122a, 122b) in the upper and lower coupling holes (120a, 120b) opposite to the fastening holes (114) of the guide protruding pipe (110) so that they can be fastened together with a bolt ring or the like.

Here, a fastening screw hole 125 is formed in the upper coupler 121a to efficiently fasten the lighting housing 130, which will be described later.

The lighting housing 130 has an outer peripheral flange 132, a coupling piece 131 with threaded holes drilled into the flange 132, and a plurality of fastening holes 133 drilled into the flange 132. form

In addition, it is provided with a ring-shaped coupler 134 corresponding to the lighting housing 130, and a fastening piece 135 is formed on the coupler 134 to correspond to the coupler 131, so that a coupling member such as a screw ( 139).

Furthermore, a fastening hole 136 and a fastening screw hole 137 are drilled in the coupler 134 so that the fastener hole 136 corresponds to the fastener screw hole 125 of the upper coupler 120a to enable coupling of screws, etc. At the same time as fastening with the member 139, the fastening screw hole 137 is made to correspond to the fastening hole 133 to fasten with a coupling member 139 such as a screw.

Meanwhile, the fastening holes 122a and 122b of the upper and lower couplings 120a and 120b and the fastening holes 114 of the upper flange 112 of the guide protrusion pipe 110 are aligned to form fastening members 138 such as bolt rings. Combine with

Light is irradiated to the inside of the pulverizer tank (1) used in coal-fired power plants to observe the progress of coal grinding, etc. through the inspection window (10). However, during the coal grinding process, burns, etc. occur or even in high temperature conditions. The lighting housing 130 is safely protected by the safety space 113 of the guide protrusion pipe 110 and the tempered glass 123 to minimize the risk of damage.

Moreover, if the lighting housing 130 is to be replaced due to damage, etc., the lighting housing 130 can be easily replaced by separating it from the upper coupler 120a supporting the tempered glass 123, as well as the differentiator tank 1. Since it is replaced while maintaining its operating status, the lighting housing 130 can be separated and replaced safely and smoothly without interruption of the supply of coal.

The above description is an illustrative description of the present invention, and the embodiments posted in the specification are not intended to limit the technical idea of the present invention, but are for illustrative purposes, so those skilled in the art will understand the present invention. Various modifications, transformations, or substitution of steps will be possible without departing from the technical idea of . Therefore, the scope of protection of the present invention should be interpreted based on the matters stated in the claims, and technical matters within the equivalent scope thereof should also be interpreted as being included in the scope of rights of the present invention.

1: Differentiator tank 10: Inspection window
100: Inspection light 110: Guide protrusion pipe
111: lower flange 112: upper flange
113: safe space 114: fastening hole
120a: upper coupler 120b: lower coupler
121a, 121b: Locking jaw 122a, 122b: Fastening hole
123: Tempered glass 124: Gasket
125: fastening screw hole 130: lighting housing
131: coupling piece 132: flange
133: fastening hole 134: coupling hole
135: fastening piece 136: fastening hole
137: fastening screw hole 138: fastening member
139: Coupling member

Claims (3)

In the inspection light (100) for internal investigation coupled to the upper part of the differentiator tank (1) for a power plant equipped with an inspection window (10) for internal observation,
A guide protruding pipe 110 that is coupled to the upper center of the differentiator tank 1 to communicate with the inside of the differentiator tank 1 and secures a safety space 113 upward, and tempered glass at the top of the guide protruding pipe 110. It consists of upper and lower couplings (120a, 120b) that combine (123) to block the upper part of the safety space (113), and a lighting housing (130) coupled to the top of the upper and lower couplings (120a, 120b). However,
The upper and lower couplers (120a, 120b) are formed in a ring shape, with locking protrusions (121a, 121b) formed on the inside of the surfaces facing each other to face each other, and the opposing locking protrusions (121a, 121b) have a disc shape. It is formed by sandwiching tempered glass 123, and the lighting housing 130 forms an outer peripheral flange 132 and a coupling piece 131 with a screw hole drilled inside the flange 132, and the lighting housing 130 ) A differentiator inspection light for a thermal power plant, characterized in that it is provided with a ring-shaped coupler 134 corresponding to the coupler 134 and is configured to be fastened to the coupler 131 by forming a fastening piece 135 on the coupler 134.
According to claim 1,
The guide protrusion pipe 110 forms an upper flange 112 and a lower flange 111, and the lower flange 111 is erected and connected to the upper center of the differentiator tank 1 so as to communicate with the interior, thereby forming the upper flange 112 and the lower flange 111. A differentiator inspection light for a thermal power plant, characterized in that it secures a safety space (113) between the lower flanges (111) and is constructed by combining a blocking net between the upper flange (112) and the lower flange (111).
delete

Images