KR102098955B1 - ladle preheater - Google Patents

Abstract

The present invention comprises a vertical frame, a lifting plate, a closing cover, and a heating heater. In particular, the closing cover is made to prevent the heat inside the ladle from leaking to the outside, and the heating heater is an inner wall surface of the ladle. It provides a ladle preheating device characterized in that it is configured to be able to be safely protected from the effects of residual hot water remaining on the outside while preventing heat leakage to the outside.

Description

Ladle preheater

The present invention relates to an apparatus for preheating an aluminum ladle, and more specifically, a ladle according to a new form that enables the ladle to be preheated to a certain temperature before storing the molten metal in a ladle for storing an aluminum melt. It relates to a preheating device.

Generally, a ladle is a container provided to move molten metal (metal) from the furnace to the place of use of the metal.

Such a ladle is formed of a container with an open top surface, and is made to receive and store molten metal inside the ladle through the open top surface.

In particular, before the molten metal is stored in the ladle, the ladle is preheated to a predetermined temperature to be provided to improve the heat retention effect by the ladle.

The preheating of such a ladle is usually performed using a gas burner. In this regard, there are registered patents No. 10-0561064, registered patents 10-1135304, registered patents 10-1597590, and registered patents 10-1763861 , As registered in Patent No. 10-1839205.

However, in the case of the above-described gas burner-type preheating device, an exhaust gas treatment system for treating exhaust gas generated during combustion of the gas must be additionally provided, and it also takes a long time for heating, so there is a disadvantage of low heating efficiency. .

Accordingly, in recent years, various technologies have been provided for preheating with an electric heater instead of a gas burner, and in this regard, it is as proposed in the public utility model No. 20-2017-0001017.

However, the electric heater type preheating device according to the above-mentioned prior art has no structure for preventing the occurrence of damage to the electric heater due to the residual water remaining in the ladle, and in particular, the residual water generated in the process of heating the inside of the ladle is an electric heater There is a problem in that frequent replacement of the electric heater is required because there is no structure for preventing defects or damage of the electric heater caused by the furnace.

In addition, the electric heater-type preheating device according to the above-mentioned prior art had low heating efficiency due to external leakage of heating heat due to heat conduction to the cover to which the electric heater is coupled when heating the inside of the ladle using the electric heater. There are disadvantages.

Registered Patent No. 10-0561064 Registered Patent No. 10-1135304 Registered Patent No. 10-1597590 Registered Patent No. 10-1763861 Registered Patent No. 10-1839205 Public Utility Model No. 20-2017-0001017

The present invention has been devised to solve various problems according to the prior art described above, and the object of the present invention is to provide a new form to minimize heat loss while preventing the heating element from being damaged during preheating of the ladle. It is to provide a ladle preheating device.

According to the ladle preheating device of the present invention for achieving the above object is a vertical frame installed to be vertically up and down; An elevating plate that is elevated under the guidance of the vertical frame by the operation of the elevating driving unit; A closing cover installed on the lifting plate and configured to close the open upper surface of the ladle while lifting and lowering together with the lifting plate; It characterized in that it is configured to include; a plurality of heating heaters consisting of a non-heating portion installed to penetrate the closed cover and a heating portion extending from the non-heating portion to the inside of the ladle to generate heat.

Here, the closed cover is provided with a casing that is fixed to the lifting plate while forming an exterior, a heat-resistant board that blocks heat from inside the ladle provided in the casing, and the bottom surface of the heat-resistant board. It characterized in that it comprises a sealing member made of a compressible ceramic wool to prevent leakage of heat as well as sealing the open upper surface of the ladle.

In addition, the heating portion of the heating heater is configured to include a plurality of heating elements that are generated by a power supply while being formed in a zigzag structure, and a plurality of insulators provided in a plurality along the longitudinal direction of the heating element to connect each of the heating elements to each other. The non-heating portion of the heating heater is configured to include a plurality of leads that are delivered to each of the heating elements by receiving external power, and the gap between the heating portion and the non-heating portion is further provided with a gap portion spaced apart from each other.

In addition, each of the heating heaters is characterized in that each of the non-heating portion and the heating tube is provided with a protective tube made of a non-metallic material that is installed to collectively cover each.

Along with this, a heat dissipation member made of ceramic wool is provided on the side where the non-heating part is located in the inside of the protection tube of the heating heater.

As described above, the ladle preheating device of the present invention is configured to perform electric heater-type preheating using electricity rather than gas burner-type preheating using gas, but improves airtightness when contacting the ladle through structural improvement of the closed cover. This has the effect of reducing the heat loss.

In particular, in the ladle preheating device of the present invention, each heating heater is provided with a protective tube, and the heating elements and the non-heating portions are collectively wrapped, thereby preventing the heating elements from being exposed to the external environment. In addition to being able to be protected, it is possible to minimize heat conduction due to the heat dissipation member in the protection tube, so that high-temperature heat generated in the heating element is conducted to the closed cover through the lid, thereby reducing heat loss.

In addition, the ladle preheating device of the present invention improves the coupling structure between the closed cover and the heating heater, thereby preventing damage to the heat-resistant board and the sealing member due to the heating heater, thereby extending the service life of the heat-resistant board and the sealing member. It has an effect.

1 is a side view showing to explain a ladle preheating device according to an embodiment of the present invention
Figure 2 is a front view showing to explain the ladle preheating device according to an embodiment of the present invention
3 is a plan view illustrating a ladle preheating device according to an embodiment of the present invention
Figure 4 is a state diagram for explaining the heating heater of the ladle preheating device according to an embodiment of the present invention
Figure 5 is a state diagram for explaining the initial state of the ladle preheating device according to an embodiment of the present invention

Hereinafter, a preferred embodiment of the ladle preheating device of the present invention will be described with reference to FIGS. 1 to 5.

1 is a side view showing for explaining a ladle preheating device according to an embodiment of the present invention, Figure 2 is a front view showing for explaining a ladle preheating device according to an embodiment of the present invention, Figure 3 is the present invention It is a plan view showing to explain a ladle preheating device according to an embodiment.

As shown in these drawings, the ladle preheating device according to an embodiment of the present invention is largely composed of a vertical frame 100, a lifting plate 200, a closing cover 300, and a heating heater 400, In particular, the closing cover 300 is made to prevent the heat inside the ladle 10 from leaking to the outside, and the heating heater 400 is to be safely protected from the influence of residual water remaining on the inner wall surface of the ladle 10 It is characterized by being configured to be able to prevent heat leakage to the outside while being able to.

This will be described in detail for each configuration.

First, the vertical frame 100 is a frame that is installed vertically up and down.

The vertical frame 100 serves to guide the lifting movement of the lifting plate 200 to be described later.

The upper and lower rotating shafts 120 and the lower rotating shaft 120 are provided at the upper and lower portions of the vertical frame 100, and main sprockets 111 and 121 are provided at both sides of the rotating shafts 110 and 120, respectively. The two main sprockets 111 and 121 are disposed so that the main chains 140 pass through each.

Along with this, the lower rotation shaft 120 is made to be forced to rotate by the lift driving unit 130. The lifting driving unit 130 is provided with an auxiliary sprocket 131 installed on the lower rotating shaft 120 and driving power of the driving motor 133 and the driving motor 133 provided on the lower side of the vertical frame 100. It is composed of an auxiliary chain 132 that is delivered to the auxiliary sprocket 131.

Next, the lifting plate 200 is a portion provided to move up and down by driving of the lifting driving unit 130.

The lifting plate 200 is made of a flat plate structure and is installed to receive the support of the vertical frame 100.

At this time, the lifting plate 200 is connected to the main chain 140 and is made to be elevated by driving of the lifting driving unit 130.

Next, the closing cover 300 is a portion provided to close the developed upper surface of the ladle 10.

The closing cover 300 is installed on the elevating plate 200 and is made to close the open upper surface of the ladle 10 as it is elevating and operating together with the elevating plate 200.

Particularly, in the embodiment of the present invention, it is suggested that the closing cover 300 includes a casing 310, a heat-resistant board 320, and a sealing member 330.

Here, the casing 310 is a portion that is fixed to the lifting plate 200 while forming an exterior, and the inside is formed of an empty cylinder.

In addition, the heat-resistant board 320 is a portion made of a heat-resistant material so as to be provided in the casing 310 to prevent the heat inside the ladle 10 from being conducted to the casing 310, and the heat-resistant board 320 By this, the heat inside the ladle 10 is conducted to the casing 310 to prevent the disadvantage of dropping the temperature.

In addition, the sealing member 330 is provided on the bottom surface of the heat-resistant board 320, and is a part made of a compressible ceramic wool to seal the open top surface of the ladle 10 and prevent leakage of heat. That is, heat leakage to the inside of the ladle 10 may be minimized due to the step due to the snout portion of the ladle 10 due to the sealing member 330 described above.

At the same time, the sealing member 330 is formed in an empty ring shape. That is, when considering that the upper surface is made of an open cylinder, the ladle 10 is formed in a ring shape so that it can be closely adhered to the upper surface of the ladle 10 while heating the heater through the inner portion. By preventing direct contact with the 400, damage to the sealing member 330 or damage to the heating heater 400 can be prevented.

Next, the heating heater 400 is an electric heater provided to heat the inside of the ladle 10.

The heating heater 400 is provided in plural (in the embodiment of the present invention, it is provided as three examples to achieve three phases) while being installed to penetrate the closed cover 300 and the non-heating part 410 and It consists of a heating unit 420 that generates heat while extending from the non-heating unit 410 to the inside of the ladle 10.

That is, the portion passing through the closed cover 300 can be a non-heated portion 410 of the heating heater 400 so that the heat conduction to the closed cover 300 can be minimized while the heating element 421 will be described later. This is to prevent damage.

Here, the heating unit 420 of the heating heater 400 is made of a zigzag structure, and while connecting the plurality of heating elements 421 and each of the heating elements 421 generated by power supply, each heating element is fixed to each other. It comprises a plurality of insulators 422 provided along the longitudinal direction of the heating element provided to maintain the gap, the non-heating portion 410 of the heating heater 400 is supplied with external power to each of the heating elements 421 Coupling flange 412 for coupling the plurality of leads 411 and the heating heater 400 to the closed cover 300 and a center rod coupling between the coupling flange 412 and the heating unit 420 ( 413). At this time, the heating element 421 is formed of an advanced powder metallurgy (APM) made of iron-chromium-aluminum alloy (FeCrAl alloy) or an advanced powder metallurgy high temperature (APMT) made of iron-chromium-aluminum-molybdenum alloy. .

In particular, a gap portion 430 spaced apart from each other is further provided between the heating portion 420 and the non-heating portion 410. That is, the heating unit 420 and the non-heating unit 410 can be distinguished through the additional provision of the gap unit 430 described above. At this time, the heat generating unit 420 is to be located on the outside of the heat-resistant board 320 of the closed cover 300, and the non-heating unit 410 is positioned inside the heat-resistant board 320 so that the heat-resistant board 320 ) To prevent damage due to high temperature heat.

In addition, each of the heating heaters 400 is further provided with a non-metallic protective tube 440 that is installed to collectively cover the non-heating portion 410 and the heating portion 420, respectively. The protection tube 440 prevents the residual water from directly contacting the heating element 421 when the residual water is present inside the ladle 10, and the residual water existing in a fixed state on the inner wall surface of the ladle 10 is prevented. It is a configuration provided to prevent the problem of hitting the heating element 421 while falling down.

The protection tube 440 is formed of a tube body surrounding both the heating part 420 and the non-heating part 410, and the upper end of the protection tube 440 is coupled to the end of the non-heating part 410 The flange 412 is formed to be fixedly installed on the upper surface of the heat-resistant board 320 in the casing 310. In this case, the protection tube 440 is formed of an advanced powder metallurgy (APM) made of iron-chromium-aluminum alloy (FeCrAl alloy) or an advanced powder metallurgy high temperature (APMT) made of iron-chromium-aluminum-molybdenum alloy. By doing so, it is possible to provide high thermal conductivity and excellent stiffness.

Along with this, a heat dissipation member 441 made of ceramic wool is provided on the side where the non-heating part 410 is located in the inside of the protection tube 440 of the heating heater 400. The heat dissipation member 441 prevents high-temperature heat generated as the heating element 421 of the heating unit 420 from being leaked to the outside through the protection tube 440 to prevent the heating efficiency from being deteriorated. It is made to be able to.

In particular, a deformation preventing end 442 for preventing contact with the heating element 421 due to deformation of the protection tube 440 is further provided at an end side portion in the protection tube 440.

The deformation preventing end 442 is formed of a block body having a diameter in consideration of the entire width of each heating element 421, and the lower insulator of each insulator 422 is connected to the connection end 443 to be in its position. It is configured to be fixed.

That is, even though the lower end of the protection tube 440 is deformed due to the high temperature heat through the additional provision of the deformation preventing end 442, the heating element 421 while preventing contact with the heating element 421 due to the deformation ) To be protected.

On the other hand, the bottom portion of the heating heater 400 is provided with a mounting portion 500 on which the ladle 10 is placed.

Such a mounting portion 500 is made of a conveyor provided to carry the carry-in and carry-out the ladle 10 to a certain distance.

In the following, the preheating process of the ladle 10 using the ladle preheating device according to the embodiment of the present invention described above will be described in more detail.

First, through the operation control of the lifting driving unit 130, the lifting plate 200 can be moved upward.

That is, the heating heater 400 is maintained in an upward movement state by the upward movement of the elevation plate 200 by the driving of the elevation driving unit 130, and in this state, the ladle to the working portion of the placing unit 500 (10) Bring in. This is as shown in Figure 5 attached.

Then, when the ladle 10 is brought in by the above-described process, the elevating plate 200 is moved downward through the operation control of the elevating driving unit 130.

That is, the heating heater 400 is also moved downward by the downward movement of the elevation plate 200 by the driving of the elevation driving unit 130 while being accommodated inside the ladle 10, and the closed cover installed on the elevation plate 200 300 is to close the open upper surface of the ladle 10.

In particular, the sealing member 330 constituting the closed cover 300 is in contact with the upper surface of the ladle 10 and is compressed by the weight of the closed cover 300 while airtighting the open upper surface of the ladle 10. Will be closed.

In addition, when the above-described closed cover 300 is completely closed, power is supplied to each heating heater 400, and the heating element 421 constituting each heating heater 400 is heated, whereby the inside of the ladle 10 is Preheat.

At this time, while the inside of the ladle 10 is preheated, the residual water remaining on the inner wall surface of the ladle 10 may be momentarily collapsed due to the heat of the heating heater 400, but the heating element 421 of each heating heater 400 ) Is formed by the protection tube 440, so the heating element 421 is protected from the residual water.

In addition, the heat generated due to heating inside the ladle 10 may leak out of the ladle 10 or be conducted to the closed cover 300, but the ladle 10 may be caused by the sealing member 330 made of ceramic wool. In addition to being prevented from leaking to the outside, heat conduction to the casing 310 of the closed cover 300 is prevented by the heat-resistant board 320.

And, when the preheating inside the ladle 10 by the above-described process is completed, the power supply to the heating heater 400 is cut off, and the elevation plate 200 is moved upward by the driving of the elevation driving unit 130, respectively. The heating heater 400 is detached from the ladle 10, and the preheating operation for the ladle 10 is completed by an operation of carrying out the ladle 10.

After all, the ladle preheating apparatus of the present invention is configured to perform electric heater-type preheating using electricity, not gas burner-type preheating using gas, but airtightness upon close contact with the ladle 10 through structural improvement of the closed cover 300. To improve the heat loss can be reduced.

In particular, in the ladle preheating device of the present invention, while the protection tube 440 is additionally provided on each heating heater 400, the heating element is transferred to the external environment while collectively surrounding the heating portion 420 and the non-heating portion 410. Each heating element 421 can be protected from residual water inside the ladle 10 as it is prevented from being exposed, and high-temperature heat generated from the heating element 421 is caused by the heat dissipation member 441 in the protection tube 440. Conduction through the lid 411 to the closed cover 300 can be minimized, thereby reducing heat loss.

In addition, the ladle preheating device of the present invention improves the coupling structure between the closed cover 300 and the heating heater 400 to prevent damage to the heat-resistant board 320 and the sealing member 330 due to the heating heater 400. It is possible to extend the service life of the heat-resistant board 320 and the sealing member 330.

10. Ladle 100. Vertical frame
110. Upper rotating shaft 120. Lower rotating shaft
111,121. Main Sprocket 130. Elevator Drive
131. Auxiliary sprocket 132. Auxiliary chain
133. Drive motor 140. Main chain
200. Lifting plate 300. Closed cover
310. Casing 320. Heat-resistant board
330. Sealing member 400. Heating heater
410. Non-heating part 411. Lead
412. Combined Flange 413. Center Road
420. Heating element 421. Heating element
422. Insulator 430. Gap
440. Protective tube 441. Heat dissipation member
442. Deformation prevention stage 443. Connection stage
500. Placement

Claims (5)

A vertical frame installed vertically vertically; An elevating plate that is elevated under the guidance of the vertical frame by the operation of the elevating driving unit; A closing cover installed on the lifting plate and configured to close the open upper surface of the ladle while lifting and lowering together with the lifting plate; It includes; a plurality of heating heaters made of a non-heating portion installed to penetrate the closed cover and a heating portion extending from the non-heating portion to the inside of the ladle to generate heat.
The closed cover includes a casing fixed to the elevating plate while forming an exterior, a heat-resistant board provided in the casing and blocking heat from inside the ladle, and provided on the bottom surface of the heat-resistant board. In addition to sealing the open upper surface of the ladle, and includes a sealing member to prevent leakage of heat,
The sealing member is formed of an empty ring shape inside and is made of compressible ceramic wool, so that direct contact with the heating heater penetrating the inner portion does not occur and at the same time, even if a step is present in the spout portion of the ladle, the ladle Close to the top, minimizes heat leakage,
The heating part of the heating heater includes a plurality of heating elements that are generated by a power supply while being formed in a zigzag structure, and a plurality of insulators provided in a plurality along the longitudinal direction of the heating elements to connect each of the heating elements to each other,
The non-heating portion of the heating heater is configured to include a plurality of leads that receive external power and transfer it to each heating element.
A gap portion is provided between the heating portion and the non-heating portion to separate them from each other, and while the heating portion is located outside the heat-resistant board, the non-heating portion is located in the heat-resistant board,
Each of the heating heaters is provided with a protective tube made of a non-metal material, which is installed to collectively cover the non-heating portion and the heating portion,
The end portion of the protective tube is formed of a block body and is fixed by a connection terminal connected to an insulator located at the lowermost side, and is provided with a deformation preventing end preventing contact with the heating element due to deformation of the protective tube. Ladle preheating device. According to claim 1,
Ladle preheating device, characterized in that the heat-resistant member made of a ceramic wool is provided on the side where the non-heating portion is located inside the protective tube of the heating heater. delete delete delete

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