KR101256353B1 - Kiln surveillance cameras - Google Patents

Abstract

A kiln furnace surveillance camera module without the need for a coolant circulation system is introduced. The kiln furnace monitoring camera module according to the present invention is provided with a first air injection port 12 on one side, the outer housing 10 is provided with an insertion hole 14 on the other side; An inner housing 20 inserted into the insertion hole 14 and having a second air injection hole 22 communicating with the first air injection hole 12 at one side thereof and a first air inlet 24 formed at the other side thereof; And a pinhole camera 30 mounted inside the inner housing 20 so as to monitor the inside of the kiln, and a stopper at the other side of the inner housing to prevent the other side of the inner housing from being completely inserted into the insertion hole. Characterized in that formed.

Description

Kiln furnace surveillance camera module {KILN SURVEILLANCE CAMERAS}

The present invention relates to a surveillance camera module, and more particularly, to a kiln song surveillance camera module mounted in the vicinity of a kiln, a preliminary reduction furnace for ferronickel production, for monitoring the furnace.

Nickel is one of the most important metals as an alloying element of steel. With the development of the machinery industry, the demand for non-ferrous alloys, stainless steel, plating, corrosion resistance, heat-resistant materials, magnetic materials, etc. is increasing day by day, the demand for nickel or its demand is increasing.

The alloy of nickel and iron is ferronickel. These ferronickels are also increasing in demand as the international demand for alloy steel materials increases.

As shown in Fig. 1, generally, ferronickel is produced through a raw material treatment process, a preliminary reduction process, an electric furnace process, a refining process and a casting process.

In the raw material processing process, the ore is unloaded by using the unloader, and the ore is transferred to the raw material yard using a Celt conveyor and an impeller (Stacker). Then, a reclaimer ), The various kinds of ores are mixed in an appropriate ratio. At this time, the nickel ore passes through a dryer to remove a large amount of moisture contained therein.

In the preliminary reduction process, the coal supplied in the reduction furnace is used to remove moisture in the ore and to remove a certain amount of oxygen contained in the nickel and iron elements present in the form of oxides.

The ore that has undergone the preliminary reduction process is supplied to the closed electric furnace and is melted and reduced. As a result, a slag containing about 20% nickel is produced, and the slag produced in this process is subjected to a separate treatment process, , Magnesium oxide, iron, aluminum oxide, calcium oxide, and the like are processed into earthwork materials.

Finally, the sludge produced in the electric furnace at about 1500 ° C is produced as a ferronickel product in the casting process after impurities are removed in the refining process.

On the other hand, as shown in Figure 2, in the preliminary reduction process was installed in the furnace monitoring camera system in the preliminary reduction path (Rotary Kiln), it was common to monitor the situation in the furnace. This conventional in-vehicle surveillance camera system inserted a rod-shaped pinhole lens 1 into the lens housing 3 to monitor the interior of the preliminary reduction path, which was mainly for monitoring the furnace calcine.

However, when applying the conventional in-house surveillance camera system, various problems as described below have occurred.

First, in order to prevent the pinhole lens 1 from being burned out by the heat generated in the preliminary reduction path, the burnt water is prevented by using the coolant 5, and when the coolant is heated and evaporated by the heat, the vapor In addition to the pinhole lens 1, water vapor condenses on the pinhole lens 1 due to the temperature difference between the coolant 5 and the lens housing 3, making it difficult to monitor the furnace. 3) There was a problem that corrosion occurs on the back.

Second, to design a separate piping line and circulation system for the input of the coolant (5), this has a problem that not only increases the cost, but also lowers the work efficiency.

Third, in the case of monitoring the state of the furnace by providing such a pipeline and circulation system, since the weight is about 15 ~ 20kg, the freedom of operation is reduced, so that two or more people are required to move the furnace surveillance camera system freely. There was a problem that it was necessary.

Fourth, the conventional in-vehicle surveillance camera system had a problem that its mounting space was limited due to problems such as a piping line, so it had to be located above one side of the preliminary reduction path, and the field of view that can be monitored by the pinhole lens 1 was observed. There was a problem that is limited. That is, it is not possible to stare at the preliminary reduction path from the front, it is not possible to monitor the flame state of the burner, there was a problem that directly hit the field of view when dust or the like is generated.

Fifth, since the conventional in-house surveillance camera system uses an expensive pinhole lens 1, the cost increases, and when it is burned, a repair period takes a long time and expensive repair costs are required. There was this.

It should be understood that the foregoing description of the background art is merely for the purpose of promoting an understanding of the background of the present invention and is not to be construed as adhering to the prior art already known to those skilled in the art.

In order to solve the conventional problems, the present invention not only uses air that is not coolant as a cooling medium but also improves cooling efficiency by injecting such air in a direction in which a heat source is located, thereby preventing visual disturbance and camera corrosion caused by condensation of coolant. The aim is to provide a kiln song surveillance camera module that is prevented.

The kiln furnace monitoring camera module according to the present invention for achieving the above object is provided with a first air injection port on one side, the outer housing provided with an insertion port on the other side; An inner housing inserted into the insertion hole, and having a second air injection hole formed on one side thereof to communicate with the first air injection hole; and a first air inlet hole formed on the other side thereof; It includes a pinhole camera mounted inside the inner housing to monitor the inside of the kiln, characterized in that the stopper is formed on the other side of the inner housing to prevent the other side of the inner housing is completely inserted into the insertion port. .
A perspective part is provided at one side of the inner housing, and the second air injection port is formed in a shape surrounding the perspective part, and the pinhole camera is configured to monitor the kiln through the sight hole.

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The inner circumferential surface of the outer housing and the outer circumferential surface of the inner housing are spaced apart by a predetermined interval, and an air flow path is formed, and a second air inlet is formed on the other upper end of the outer housing to communicate with the air flow path.

A mounting plate is coupled to the other side lower end of the outer housing, and side plates facing each other are coupled to both sides of the mounting plate.

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The present invention can achieve the following effects due to the above technical configuration.

First, because the camera is cooled by the air injection method, not the cooling water circulation structure, there is an advantage that can prevent the view obstruction and corrosion by water vapor.

Second, since there is no need to design a separate piping line and circulation system for the cooling water input, it is possible to prevent cost increase and work efficiency deterioration.

Third, since the use of cooling water is not required, the operation of the in-vehicle surveillance camera system can be used while moving freely, thereby improving work efficiency.

Fourth, it is possible to stare at the preliminary reduction path from the front, there is an advantage that can monitor the flame state of the burner.

Fifth, the use of a pinhole camera, the cost is reduced, even if it is burned there is an advantage that can reduce the repair period and repair costs.

1 is a view generally showing a ferronickel manufacturing process,
2 is a view showing a conventional kiln furnace surveillance camera system,
3 is a view showing a combined state of the kiln furnace monitoring camera module of the present invention,
4 is a view showing the outer housing of the kiln furnace monitoring camera module of the present invention,
5 is a view showing the inner housing of the kiln furnace monitoring camera module of the present invention.
6 is a view showing a pinhole camera used in the present invention.

Hereinafter, a kiln furnace surveillance camera module according to an embodiment of the present invention will be described with reference to the accompanying drawings.

3 is a view showing a combined state of the kiln furnace monitoring camera module of the present invention. Figure 4 is a view showing the outer housing of the kiln furnace monitoring camera module of the present invention, Figure 5 is a view showing the inner housing of the kiln furnace monitoring camera module of the present invention, Figure 6 shows a pinhole camera used in the present invention Drawing.

As shown in FIGS. 3 and 4, the kiln furnace surveillance camera module of the present invention includes an outer housing 10.

The first air injection port 12 is provided on one side of the outer housing 10, the insertion hole 14 is provided on the other side, the outer housing 10 is preferably manufactured in the shape of a pipe through the center. . The other end of the outer housing 10, the mounting plate 50 is coupled, it is preferable that both sides of the mounting plate 50 are coupled to the side plate 60 facing each other. The mounting plate 50 and the side plate 60 may function effectively when the kiln furnace monitoring camera module is fixed to a frame or the like.

As shown in Figure 3 and 5, the inner housing 20 is inserted into the outer housing 10 of the pipe shape through the center through the insertion hole (14).

One side of the inner housing 20 is provided with a see-through portion 26, the second air injection port 22 is formed around the see-through portion 26 surrounding the bar, the second air injection port 22 is provided The first air injection port 12 of the outer housing 10 is communicated with. In addition, a first air inlet 24 is formed at the other side of the inner housing 20.

Therefore, the cooling air introduced through the first air inlet 24 is injected from the second air injection port 22 and is injected to the outside through the first air injection port 12.

3 and 6, the pinhole camera 30 is mounted inside the inner housing 20. The pinhole camera 30 functions to monitor the kiln through the sight hole, and the pinhole camera 30 photographs the kiln furnace situation and transmits the information to a monitoring monitor (not shown) installed outside.

Referring to Figure 3, the coupling state of the kiln song monitoring camera module of the present invention will be described in more detail.

The inner circumferential surface of the outer housing 10 and the outer circumferential surface of the inner housing 20 are maintained at a predetermined interval. That is, the outer housing 10 and the inner housing 20 are both formed in a pipe shape, and the inner diameter of the outer housing 10 is larger than the outer diameter of the inner housing 20 to maintain a predetermined distance from each other. As such, the gap formed between the inner circumferential surface of the outer housing 10 and the outer circumferential surface of the outer housing 10 is referred to as an air flow passage 40. In addition, it is preferable that a second air inlet 16 communicating with the air flow passage 40 is formed at the upper end of the other side of the outer housing 10.

The stopper 28 is preferably formed at the other side of the inner housing 20 to prevent the other side of the inner housing 20 from being completely inserted into the insertion hole 14. The stopper 28 of the inner housing 20 is formed to be caught by the insertion opening 14 formed on the other side of the outer housing 10. The operator can use the various assembling means while the sputter is hanging on the insertion opening 14. By using the inner housing 20 can be fixed to the outer housing 10 fixed.

On the other hand, the air supply hose is fitted into the first air inlet 24 and the second air inlet 16, respectively, and the power line C of the pinhole camera 30 mounted inside the inner housing 20 is a stopper. It is preferable to carry out through 28 and to be carried out outside.

Hereinafter will be described the operation of an embodiment of the kiln furnace monitoring camera module of the present invention.

External cooling air is supplied through the first air inlet 24 and the second air inlet 16. The cooling air supplied through the first air inlet 24 moves to the inside of the inner housing 20 to the outside through the second air injection hole 22 provided around the see-through part 26 on one side of the inner housing 20. Sprayed.

Meanwhile, the cooling air supplied through the second air inlet 16 moves to a space formed between the inner circumferential surface of the outer housing 10 and the outer circumferential surface of the inner housing 20 through the air flow passage 40, and thus, the outer housing. 10 is sprayed to the outside through the first air injection port 12 provided on one side.

As described above, the kiln furnace monitoring camera module of the present invention avoids the cooling system based on the cooling water circulation structure, and therefore, it is possible to prevent the view of the water vapor generated by the use of the cooling water and corrosion of the module. In addition, since there is no need for a separate piping line for cooling water input, cost increase and work efficiency can be prevented, and the monitoring camera system in the furnace can be moved freely. Even if the camera 30 is burned, there is an advantage of reducing the repair cost and shortening the repair period.

While the present invention has been particularly shown and described with reference to specific embodiments thereof, it will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the following claims It will be apparent to those of ordinary skill in the art.

10: outer housing 12: first air injection port
14: insertion hole 16: the second air inlet
20: inner housing 22: second air injection port
24: 1st air inlet 26: see-through section
28: stopper 30: pinhole camera
40: air flow path 50: mounting plate
60: side plate

Claims (5)

An outer housing 10 provided with a first air injection hole 12 on one side and an insertion hole 14 on the other side;
An inner housing 20 inserted into the insertion hole 14 and having a second air injection hole 22 communicating with the first air injection hole 12 at one side thereof and a first air inlet 24 formed at the other side thereof;
Including a pinhole camera 30 mounted inside the inner housing 20 to monitor the inside of the kiln,
The kiln furnace monitoring camera module, characterized in that a stopper (28) is formed on the other side of the inner housing (20) to prevent the other side of the inner housing (20) is completely inserted into the insertion opening (14). According to claim 1, One side of the inner housing 20 is provided with a perspective portion 26, the second air injection port 22 is formed in a form surrounding the transparent portion 26, the pinhole camera ( 30 is the kiln furnace monitoring camera module, characterized in that for monitoring the kiln through the see-through (26). The inner peripheral surface of the outer housing 10 and the outer peripheral surface of the inner housing 20 are spaced apart by a predetermined interval to form an air passage 40, and the other side upper end of the outer housing 10 of the air passage ( The kiln furnace monitoring camera module, characterized in that the second air inlet 16 is formed in communication with the 40. delete The kiln according to claim 3, wherein the other side lower end of the outer housing 10 is coupled to the mounting plate 50, and both sides of the mounting plate 50 are coupled to the side plates 60 facing each other. In-house surveillance camera module.

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