KR102415730B1 - Thermoelectric generation apparatus - Google Patents

Abstract

A thermoelectric generator positioned between first high-temperature slabs and second high-temperature slabs stacked adjacent to each other in the yard includes a first heat collecting plate facing the first high-temperature slabs, and facing the second high-temperature slabs a second heat collecting plate, a cooling plate positioned between the first heat collecting plate and the second heat collecting plate and through which cooling water passes, a first thermoelectric element positioned between the first heat collecting plate and the cooling plate, and the second heat collecting plate and the and a second thermoelectric element positioned between the cooling plates.

Description

Thermoelectric generator {THERMOELECTRIC GENERATION APPARATUS}

The present disclosure relates to a thermoelectric power generation device.

In general, a thermoelectric power generation device is a device that generates power through a thermoelectric element using the Seebeck effect.

In the steel production process, high-temperature (for example, 700°C to 900°C) slabs produced through the casting process are naturally cooled in a state in which 10 or more are stacked in a yard such as a refinery before being transferred to the rolling process. do.

There is a problem in that the natural cooling time required for the high-temperature slabs stacked in the yard (eg, 48 hours) is long, resulting in loss of opportunity for logistical stability and productivity improvement.

In addition, it is necessary to recover the sensible heat generated from the high-temperature slabs stacked in the yard.

One embodiment is to provide a thermoelectric power generation device that reduces the cooling time of the high-temperature slabs stacked in the yard while at the same time recovering the sensible heat generated from the high-temperature slabs stacked in the yard to generate electricity.

One side is a thermoelectric generator positioned between first high-temperature slabs and second high-temperature slabs stacked adjacent to each other in a yard, wherein a first heat collecting plate facing the first high-temperature slabs, the second a second heat collecting plate facing the high-temperature slabs, a cooling plate positioned between the first heat collecting plate and the second heat collecting plate and through which cooling water passes, a first thermoelectric element positioned between the first heat collecting plate and the cooling plate, and Provided is a thermoelectric generator including a second thermoelectric element positioned between the second heat collecting plate and the cooling plate.

A first thermal block in contact with the first thermoelectric element and the cooling plate between the first thermoelectric element and the cooling plate and having a higher thermal conductivity than the first thermoelectric element, and between the second thermoelectric element and the cooling plate A second thermal block in contact with the second thermoelectric element and the cooling plate and having a higher thermal conductivity than the first thermoelectric element may be further included.

The first thermoelectric element is in contact with the first heat collecting plate and the first thermal block between the first heat collecting plate and the first thermal block, and the second thermoelectric element is disposed between the second heat collecting plate and the second thermal block. It may contact the second heat collecting plate and the second heat block.

The cooling plate may include a plate body positioned between the first thermoelectric element and the second thermoelectric element, overlapping the first thermoelectric element and the second thermoelectric element a plurality of times within the plate body, and through which the cooling water passes It may include a roof channel, a cooling water supply port located at one end of the roof channel, and a cooling water outlet located at the other end of the roof channel.

A cooling water supply pipe buried in the ground of the yard and extending in a vertical direction from the ground, a first cooling water branch pipe extending in a horizontal direction from the cooling water supply pipe and supplying the cooling water to the cooling water supply port of the cooling plate, the cooling water supply pipe a cooling water discharge pipe that is spaced apart from and buried in the ground of the yard and extends in a vertical direction from the ground, and a second cooling water branch pipe extending in a horizontal direction from the cooling water discharge pipe and discharging the cooling water from the cooling water outlet of the cooling plate may further include.

It supports at least one of the cooling plate, the first heat collecting plate, and the second heat collecting plate, and may further include a support supported in the ground of the yard.

According to one embodiment, there is provided a thermoelectric power generation device that recovers sensible heat generated from the high-temperature slabs stacked in the yard to generate electricity while reducing the cooling time of the high-temperature slabs stacked in the yard.

1 is a view showing a thermoelectric generator according to an embodiment positioned between high-temperature slabs stacked in a yard.
FIG. 2 is a view showing a side surface of the thermoelectric generator according to the embodiment shown in FIG. 1 .
FIG. 3 is a diagram specifically illustrating a thermoelectric power generation device according to the exemplary embodiment shown in FIG. 2 .
4 is a front view of a thermoelectric generator according to another exemplary embodiment.

Hereinafter, with reference to the accompanying drawings, embodiments of the present invention will be described in detail so that those of ordinary skill in the art to which the present invention pertains can easily implement them. The present invention may be embodied in several different forms and is not limited to the embodiments described herein.

In order to clearly explain the present invention, parts irrelevant to the description are omitted, and the same reference numerals are assigned to the same or similar components throughout the specification.

In addition, throughout the specification, when a part "includes" a certain component, this means that other components may be further included, rather than excluding other components, unless otherwise stated.

Hereinafter, a thermoelectric power generation device according to an exemplary embodiment will be described with reference to FIGS. 1 to 3 .

1 is a view showing a thermoelectric power generation device according to an embodiment positioned between high-temperature slabs stacked in a yard. Figure 1 (A) is a plan view showing a plurality of thermoelectric power generation devices located between the stacked high-temperature slabs in the yard. FIG. 1B is a perspective view illustrating a thermoelectric generator positioned between adjacent high-temperature slabs.

Referring to FIG. 1A , each of a plurality of thermoelectric power generation devices 1000 according to an embodiment is located between a plurality of high temperature slabs 10 and 20 stacked in a yard. . The plurality of thermoelectric power generation devices 1000 recover sensible heat generated from the high-temperature slabs 10 and 20 to generate power and cool the plurality of high-temperature slabs 10 and 20 . Here, the plurality of high-temperature slabs 10 and 20 may be in a state of being stacked in a yard such as a refinery factory before being produced through a casting process and transferred to a rolling process, but is not limited thereto.

Referring to FIG. 1B , the thermoelectric power generation device 1000 according to an embodiment is located between the first high-temperature slabs 10 and the second high-temperature slabs 20 stacked adjacent to each other in the yard. The sensible heat generated from the first high-temperature slabs 10 and the second high-temperature slabs 20 is recovered to generate electricity, and the cooling of the first high-temperature slabs 10 and the second high-temperature slabs 20 is performed.

FIG. 2 is a view showing a side surface of the thermoelectric generator according to the embodiment shown in FIG. 1 . FIG. 3 is a diagram specifically illustrating the thermoelectric power generation device according to the exemplary embodiment shown in FIG. 2 .

2 and 3 , the thermoelectric generator 1000 according to an embodiment positioned between the first high-temperature slabs 10 and the second high-temperature slabs 20 includes a first heat collecting plate 100, a first 2 includes a heat collecting plate 200 , a cooling plate 300 , a first thermoelectric element 400 , a second thermoelectric element 500 , a first thermal block 600 , a second thermal block 700 , and a supporter 800 . do.

The first heat collecting plate 100 faces the first high temperature slabs 10 stacked in the vertical direction. The first heat collecting plate 100 recovers sensible heat (HE) including radiant heat and convective heat generated from the first high-temperature slabs 10 and simultaneously cools the first high-temperature slabs 10 . For example, the first heat collecting plate 100 may include a heat absorbing coating layer coated on the surface. The heat absorbing coating layer can easily absorb radiant heat and convective heat generated from the first high temperature slabs 10 because the infrared absorption rate is higher than that of the first heat collecting plate 100 . As another example, the first heat collecting plate 100 may further include a plurality of heat dissipation fins. The length of some of the heat dissipation fins among the plurality of heat dissipation fins is longer than the length of the other heat dissipation fins, so the convective heat generated from the first high temperature slabs 10 stays between the long heat dissipation fins for a certain time and is absorbed by the plurality of heat dissipation fins. 1 The convective heat absorption generated from the high-temperature slabs 10 is maximized so that the power generation output by the thermoelectric power generation device 1000 is maximized, and at the same time, the cooling of the first high temperature slabs 10 by the thermoelectric power generation device 1000 is maximized. can The first heat collecting plate 100 contacts the front surface of the first thermoelectric element 400 to form a high temperature region of the first thermoelectric element 400 . A plurality of first heat collecting plates 100 may be arranged in a matrix form, but the present invention is not limited thereto.

The second heat collecting plate 200 faces the second high temperature slabs 20 stacked in the vertical direction. The second heat collecting plate 200 recovers sensible heat (HE) including radiant heat and convective heat generated from the second high-temperature slabs 20 and simultaneously cools the second high-temperature slabs 20 . For example, the second heat collecting plate 200 may include a heat absorbing coating layer coated on the surface. The heat absorbing coating layer can easily absorb radiant heat and convective heat generated from the second high temperature slabs 20 because the infrared absorption rate is higher than that of the second heat collecting plate 200 . As another example, the second heat collecting plate 200 may further include a plurality of heat dissipation fins. The length of some of the heat dissipation fins among the plurality of heat dissipation fins is longer than the length of the other heat dissipation fins, so the convective heat generated from the second high temperature slabs 20 stays between the long heat dissipation fins for a certain time and is absorbed by the plurality of heat dissipation fins. 2 The convective heat absorption generated from the high-temperature slabs 20 is maximized so that the power generation output by the thermoelectric power generation device 1000 is maximized, and at the same time, the cooling of the second high temperature slabs 20 by the thermoelectric power generation device 1000 is maximized. can The second heat collecting plate 200 contacts the front surface of the second thermoelectric element 500 to form a high temperature region of the second thermoelectric element 500 . A plurality of second heat collecting plates 200 may be arranged in a matrix form, but the present invention is not limited thereto.

The cooling plate 300 is positioned between the first heat collecting plate 100 and the second heat collecting plate 200 and between the first thermoelectric element 400 and the second thermoelectric element 500 . Cooling water passes through the inside of the cooling plate 300 . The cooling water passing through the inside of the cooling plate 300 may be cooling water for a process used in a refinery factory, but is not limited thereto. The cooling plate 300 is adjacent to the rear surface of the first thermoelectric element 400 and the rear surface of the second thermoelectric element 500 to form a low-temperature region of the first thermoelectric element 400 and a low-temperature region of the second thermoelectric element 500 . to form The cooling plate 300 includes a plate body 310 , a roof channel 320 , a cooling water supply port 330 , and a cooling water discharge port 340 .

The plate body 310 is positioned between the first thermoelectric element 400 and the second thermoelectric element 500 . A roof channel 320 is formed inside the plate body 310 .

The loop channel 320 overlaps the first thermoelectric element 400 and the second thermoelectric element 500 in the inside of the plate body 310 a plurality of times. The loop channel 320 may have a planarly curved loop shape a plurality of times, but is not limited thereto. Cooling water passes through the inside of the roof channel 320 .

The cooling water supply port 330 is located at one end of the roof channel 320 , and external cooling water is supplied to the roof channel 320 through the cooling water supply port 330 .

The cooling water outlet 340 is located at the other end of the roof channel 320 , and the cooling water inside the roof channel 320 is discharged from the roof channel 320 through the cooling water outlet 340 .

A plurality of cooling plates 300 may be arranged in a matrix form, but is not limited thereto.

The first thermoelectric element 400 is positioned between the first heat collecting plate 100 and the cooling plate 300 . The first thermoelectric element 400 is in contact with the first heat collecting plate 100 and the first thermal block 600 . The first thermoelectric element 400 is in contact with the first heat collecting plate 100 and the first thermal block 600 between the first heat collecting plate 100 and the first thermal block 600 . The front surface of the first thermoelectric element 400 is in contact with the first heat collecting plate 100 to form a high temperature portion, and the rear surface of the first thermoelectric element 400 is in contact with the first thermal block 600 to form a cooling plate 300 and to form an adjacent low-temperature section. The first thermoelectric element 400 is a cooling plate 300 through which cooling water passes through the high temperature portion of the front surface of the first thermoelectric element 400 in contact with the first heat collecting plate 100 absorbing the sensible heat of the first high temperature slabs 10 . ), electricity is generated by using the temperature difference between the first thermal block 600 and the low-temperature portion, which is the rear surface of the first thermoelectric element 400 in contact. The first thermoelectric element 400 includes various types of known thermoelectric elements capable of generating electricity using the Seebeck effect. A plurality of first thermoelectric elements 400 may be arranged in a matrix form, but the present invention is not limited thereto. The plurality of first thermoelectric elements 400 generate electricity using sensible heat (HE) generated from the first high-temperature slabs 10 between the plurality of first heat collecting plates 100 and the plurality of cooling plates 300 . do.

The second thermoelectric element 500 is positioned between the second heat collecting plate 200 and the cooling plate 300 . The second thermoelectric element 500 is in contact with the second heat collecting plate 200 and the second thermal block 700 . The second thermoelectric element 500 is in contact with the second heat collecting plate 200 and the second thermal block 700 between the second heat collecting plate 200 and the second thermal block 700 . The front surface of the second thermoelectric element 500 is in contact with the second heat collecting plate 200 to form a high temperature portion, and the rear surface of the second thermoelectric element 500 is in contact with the second thermal block 700 to form a cooling plate 300 and to form an adjacent low-temperature section. The second thermoelectric element 500 is a cooling plate 300 through which cooling water passes through the high temperature portion of the front surface of the second thermoelectric element 500 in contact with the second heat collecting plate 200 absorbing the sensible heat of the second high temperature slabs 10 . ), electricity is generated by using a temperature difference between the second thermal block 700 in contact with the low-temperature portion, which is the rear surface of the second thermoelectric element 500 in contact with the second thermal block 700 . The second thermoelectric element 500 includes various types of known thermoelectric elements capable of generating electricity using the Seebeck effect. A plurality of second thermoelectric elements 500 may be arranged in a matrix form, but the present invention is not limited thereto. The plurality of second thermoelectric elements 500 generate electricity using sensible heat (HE) generated from the second high-temperature slabs 10 between the plurality of second heat collecting plates 200 and the plurality of cooling plates 300 . do.

The first thermal block 600 is in contact with the first thermoelectric element 400 and the cooling plate 300 between the first thermoelectric element 400 and the cooling plate 300 . The first thermal block 600 may have higher thermal conductivity than the first thermoelectric element 400 and the cooling plate 300 , but is not limited thereto. The first thermal block 600 may include a variety of known materials. Since the first thermal block 600 in contact with the first thermoelectric element 400 and the cooling plate 300 has higher thermal conductivity than the first thermoelectric element 400 and the cooling plate 300 , the first thermoelectric element 400 . ) and the cooling plate 300 are stably secured, so the power generation output by the thermoelectric power generation device 1000 is maximized and the cooling of the first high temperature slabs 10 by the thermoelectric power generation device 1000 at the same time This is maximized.

The second thermal block 700 is in contact with the second thermoelectric element 500 and the cooling plate 300 between the second thermoelectric element 500 and the cooling plate 300 . The second thermal block 700 may have higher thermal conductivity than the second thermoelectric element 500 and the cooling plate 300 , but is not limited thereto. The second thermal block 700 may include a variety of known materials. Since the second thermal block 700 in contact with the second thermoelectric element 500 and the cooling plate 300 has higher thermal conductivity than the second thermoelectric element 500 and the cooling plate 300 , the second thermoelectric element 500 . ) and the cooling plate 300 is stably secured, so that the power generation output by the thermoelectric power generation device 1000 is maximized and the second high temperature slabs 20 are cooled by the thermoelectric power generation device 1000 at the same time. This is maximized.

The support 800 supports at least one of the cooling plate 300 , the first heat collecting plate 100 , the second heat collecting plate 200 , the first thermoelectric element 400 , and the second thermoelectric element 500 . A plurality of cooling plates 300 , a plurality of first heat collecting plates 100 , a plurality of second heat collecting plates 200 , a plurality of first thermoelectric elements 400 , and a plurality of second thermoelectric elements 500 . They are supported by the support 800 and disposed between the adjacent first high-temperature slabs 10 and the second high-temperature slabs 20 .

As described above, the thermoelectric power generation device 1000 according to an embodiment is located between the first high-temperature slabs 10 and the second high-temperature slabs 20 stacked adjacent to each other in the yard, the first heat collecting plate 100 and By using the second heat collecting plate 200 to absorb sensible heat (HE) from the first high-temperature slabs 10 and the second high-temperature slabs 20 , While performing cooling, the first thermoelectric element 400 is positioned between the cooling plate 300 and the first heat collecting plate 100 and the second thermoelectric element is positioned between the cooling plate 300 and the second heat collecting plate 200 . 500 performs power generation using sensible heat (HE) generated from the first high-temperature slabs 10 and the second high-temperature slabs 20 .

That is, there is provided a thermoelectric power generation device 1000 that recovers the sensible heat generated from the high-temperature slabs stacked in the yard to generate electricity and at the same time shortens the cooling time of the high-temperature slabs stacked in the yard.

Hereinafter, a thermoelectric generator according to another exemplary embodiment will be described with reference to FIG. 4 . Hereinafter, parts different from the thermoelectric power generation device according to the above-described exemplary embodiment will be described.

4 is a front view of a thermoelectric generator according to another exemplary embodiment. 4 is a view illustrating a direction of a first heat collecting plate of a thermoelectric generator according to another exemplary embodiment.

Referring to FIG. 4 , a thermoelectric generator 1002 according to another exemplary embodiment includes a first heat collecting plate 100 , a second heat collecting plate, a cooling plate, a first thermoelectric element, a second thermoelectric element, a first thermal block, and a second column. It includes a block, a support 800 , a coolant supply pipe 910 , a first coolant branch pipe 920 , a coolant discharge pipe 950 , and a second coolant branch pipe 960 .

Support 800 is buried in the ground (UG) of the yard is supported in the ground (UG). The support 800 is supported in the underground UG to support the thermoelectric generator 1002 .

The cooling water supply pipe 910 is buried in the underground (UG) of the yard and extends in the vertical direction from the underground (UG). The external cooling water WT is supplied through the cooling water supply pipe 910 .

The first cooling water branch pipe 920 extends in a horizontal direction from the cooling water supply pipe 910 . The first cooling water branch pipe 920 supplies the cooling water WT to the cooling water supply port 330 of the cooling plate. There are a plurality of first coolant branch pipes 920 , and the plurality of first coolant branch pipes 920 are vertically spaced apart to connect the coolant supply pipe 910 and the coolant supply port 330 of the cooling plate. The cooling water WT passing through the first cooling water branch pipe 920 from the cooling water supply pipe 910 moves into the cooling plate through the cooling water supply port 330 of the cooling plate.

The cooling water discharge pipe 950 is spaced apart from the cooling water supply pipe 910 and is buried in the ground (UG) of the yard. The cooling water discharge pipe 950 extends in a vertical direction from the underground UG. The cooling water WT that has passed through the inside of the cooling plate is discharged to the outside through the cooling water discharge pipe 950 .

The second cooling water branch pipe 960 extends from the cooling water discharge pipe 950 in the horizontal direction. The second cooling water branch pipe 960 discharges the cooling water WT discharged from the cooling water outlet 340 of the cooling plate to the cooling water discharge pipe 950 . There are a plurality of second coolant branch pipes 960 , and the plurality of second coolant branch pipes 960 are vertically spaced apart to connect the coolant outlet pipe 950 and the coolant outlet 340 of the cooling plate. The cooling water WT passing through the second cooling water branch pipe 960 from the cooling water outlet 340 of the cooling plate is discharged to the outside through the cooling water discharge pipe 950 .

As described above, in the thermoelectric generator 1002 according to another embodiment, the cooling water supply line configured by the cooling water supply pipe 910 , the first cooling water branch pipe 920 , the cooling water discharge pipe 950 , and the second cooling water branch pipe 960 . Since the cooling water WT filled in the thermoelectric generator 1002 moves from the lower part to the upper part, heat transfer resistance that may be generated due to air filling the cooling water supply line is minimized.

That is, there is provided a thermoelectric power generation device 1002 that minimizes heat transfer resistance using sensible heat generated from the high-temperature slabs stacked in the yard to minimize the decrease in power generation output and simultaneously cools the high-temperature slabs.

Although the embodiments of the present invention have been described in detail above, the scope of the present invention is not limited thereto, and various modifications and improvements by those skilled in the art using the basic concept of the present invention as defined in the following claims are also presented. It belongs to the scope of the invention.

The first heat collecting plate 100 , the second heat collecting plate 200 , the cooling plate 300 , the first thermoelectric element 400 , the second thermoelectric element 500 , the first thermal block 600 , the second thermal block 700 . )

Claims (6)

A thermoelectric power generation device positioned between first and second high-temperature slabs stacked adjacent to each other in a yard, the thermoelectric power generation device comprising:
a first heat collecting plate facing the first high temperature slabs;
a second heat collecting plate facing the second high temperature slabs;
a cooling plate positioned between the first heat collecting plate and the second heat collecting plate, and through which cooling water passes;
a first thermoelectric element positioned between the first heat collecting plate and the cooling plate; and
a second thermoelectric element positioned between the second heat collecting plate and the cooling plate
includes,
The cooling plate is
a plate body positioned between the first thermoelectric element and the second thermoelectric element;
a loop channel overlapping the first thermoelectric element and the second thermoelectric element a plurality of times in the plate body and through which the cooling water passes;
a cooling water supply port located at one end of the loop channel; and
Cooling water outlet located at the other end of the roof channel
includes,
a cooling water supply pipe buried in the ground of the yard and extending in a vertical direction from the ground;
a first cooling water branch pipe extending in a horizontal direction from the cooling water supply pipe and supplying the cooling water to the cooling water supply port of the cooling plate;
a cooling water discharge pipe that is spaced apart from the cooling water supply pipe and is buried in the ground of the yard and extends in a vertical direction from the ground; and
a second cooling water branch pipe extending in a horizontal direction from the cooling water discharge pipe and discharging the cooling water from the cooling water discharge port of the cooling plate
Thermoelectric power generation device further comprising a. In claim 1,
a first thermal block between the first thermoelectric element and the cooling plate, in contact with the first thermoelectric element and the cooling plate, and having a higher thermal conductivity than the first thermoelectric element; and
A second thermal block between the second thermoelectric element and the cooling plate, in contact with the second thermoelectric element and the cooling plate, and having a higher thermal conductivity than the first thermoelectric element
Thermoelectric power generation device further comprising a. In claim 2,
the first thermoelectric element is in contact with the first heat collecting plate and the first thermal block between the first heat collecting plate and the first thermal block;
The second thermoelectric element is in contact with the second heat collecting plate and the second thermal block between the second heat collecting plate and the second thermal block. delete delete In claim 1,
The thermoelectric power generation device further comprising a support supporting at least one of the cooling plate, the first heat collecting plate, and the second heat collecting plate, and supported in the ground of the yard.

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