KR101975455B1 - Performance Assessment Apparatus for Flexible Thermoelectric Device and Method of the Same - Google Patents

Abstract

The present invention relates to a thermoelectric element which generates an electromotive force by the temperature difference between one side and the other side, more specifically, to a cooling thermoelectric device which can evaluate a cooling performance or a power generation performance in consideration of a resistance change depending on a curvature of a flexible thermoelectric device, The present invention relates to an apparatus and method for evaluating performance of a flexible thermoelectric element.

Description

TECHNICAL FIELD The present invention relates to a flexible thermoelectric device and a method for evaluating performance of the flexible thermoelectric device,

The present invention relates to a thermoelectric element which generates an electromotive force by the temperature difference between one side and the other side, more specifically, to a cooling thermoelectric device which can evaluate a cooling performance or a power generation performance in consideration of a resistance change depending on a curvature of a flexible thermoelectric device, The present invention relates to an apparatus and method for evaluating performance of a flexible thermoelectric element.

Thermoelectric materials can be directly converted between thermal energy and electric energy by the Seebeck effect and the Peltier effect, and they have been widely applied to electronic cooling and thermoelectric power generation. In the electronic cooling module and the thermoelectric module using the thermoelectric material, the n-type thermoelectric legs and the p-type thermoelectric legs are electrically connected in series and thermally connected in parallel. When the thermoelectric module is used for electronic cooling, a DC current is applied to the module, and heat is pumped from the cooling substrate to the heating substrate by the movement of holes and electrons in the n-type and p-type thermoelectric elements, . On the other hand, in the case of thermoelectric power generation, due to the temperature difference between the high temperature end and the low temperature end of the module, when heat moves from the high temperature end to the low temperature end, the holes and electrons move from the high temperature end to the low temperature end in the p- The electromotive force is generated by the Seebeck effect.

1 is a schematic cross-sectional view of a conventional vertical thermoelectric transducer 10. As shown in the figure, the thermoelectric element 10 includes a first substrate 1, a second substrate 2, a first thermoelectric leg 3, a second thermoelectric leg 4 and an electrode 5. The first substrate 1 is attached to a heat source (not shown) in a plate shape, and the second substrate 2 is disposed in a plate shape at a predetermined distance above the first substrate 1. Between the first substrate 1 and the second substrate 2, a P-type thermoelectric leg 3 and an N-type thermoelectric leg 4 are formed along the vertical direction, and a plurality of the P-type thermoelectric legs 3 and the N- The P-type and N-type thermoelectric legs 3 and 4 generate electricity according to the temperature difference between the first substrate 1 and the second substrate 2, 2 and the p-type semiconductor and the n-type semiconductor are alternately arranged. The electrode 5 electrically connects the P-type and N-type thermoelectric legs 3 and 4 so that the P-type and N-type thermoelectric legs 3 and 4 are alternately connected in series.

When the thermoelectric element 10 is attached to a heat source having a temperature higher than that of the atmosphere according to the above-described configuration, the temperature of the first substrate 1 contacting the heat source and the temperature of the second substrate 2 exposed to the atmosphere, And the N-type thermoelectric legs 3 and 4 generate electric power and transmit the generated electricity through the electrodes 5. [

In the conventional thermoelectric element as described above, a current is applied to the thermoelectric element to evaluate the cooling performance, and the temperature difference between one side and the other side is measured. When the power generation performance is evaluated, the heat is applied to one side of the thermoelectric element and the other side is cooled .

On the other hand, in the case of a flexible thermoelectric device, since the thickness is thin and bending is possible, it is possible to attach to a narrow space or a bent portion, and thus the application is actively performed in various fields. In the case of a flexible thermoelectric element, the resistance is increased as the curvature is larger, and therefore the performance also deteriorates. Therefore, it is required to evaluate the performance according to the curvature of a flexible thermoelectric element such as a wick.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a flexible thermoelectric transducer with a bending load and a curvature radius of the flexible thermoelectric transducer, And to provide a device and a method for evaluating the performance of a flexible thermoelectric device.

An apparatus for evaluating performance of a flexible thermoelectric transducer according to an embodiment of the present invention includes: a flexible thermoelectric transducer; An actuator for changing the curvature of the flexible thermoelectric element by applying a bending load to the flexible thermoelectric element; A heater provided on one surface of the flexible thermoelectric element to heat the flexible thermoelectric element; And cooling means provided on the other surface of the flexible thermoelectric element to cool the flexible thermoelectric element; Laser measuring means arranged to be spaced apart from the flexible thermoelectric element to measure a curvature of the flexible thermoelectric element; .

Further, the heater is a convection type heater attached to one surface of the flexible thermoelectric element, and the cooling means is a heat sink attached to the other surface of the flexible thermoelectric element, and the heater and the cooling means are made of a flexible material.

In another embodiment, the heater is a radiative heater disposed on one side of the flexible thermoelectric element, and the cooling means is an air cooling type cooler disposed on the other side of the flexible thermoelectric element.

The actuator may further include: fixing means coupled to one longitudinal side of the flexible thermoelectric element; And pressurizing means coupled to the other longitudinal side of the flexible thermoelectric transducer for pressing the flexible thermoelectric transducer to one longitudinal side of the flexible thermoelectric transducer; .

The actuator may further include: a first link having one side hinged to the fixing means and the other side coupled to the flexible thermoelectric element; And a second link, the other side of which is hinged to the pressing means and whose one end is coupled to the flexible thermoelectric element; .

In another embodiment, the actuator includes a film having one side fixed to the fixing means and the other side coupled to the pressing means; And the flexible thermoelectric element is attached to one surface of the film.

A method of evaluating performance of a flexible thermoelectric device according to an embodiment of the present invention includes: a temperature difference generation step of applying current to a flexible thermoelectric element to cool one surface of the thermoelectric element and to heat the other surface; A heater heating step of heating one surface of the flexible thermoelectric element through a heater so that a temperature difference between one surface and the other surface of the thermoelectric element becomes zero; Measuring a heat absorption amount of the flexible thermoelectric element by measuring a power of the heater when the temperature difference becomes zero; And a current varying step of varying the intensity of a current applied to the flexible thermoelectric element to measure each heat absorbing amount; .

Here, the evaluation method may include: a curvature variable step of varying the curvature of the flexible thermoelectric element to measure the respective heat absorption amounts; .

According to another aspect of the present invention, there is provided a method of evaluating the performance of a flexible thermoelectric device, including heating a flexible thermoelectric element through a heater to generate a temperature difference between one surface and the other surface of the thermoelectric element; A power generation amount measuring step of measuring a power generation amount of the thermoelectric element by measuring an amount of current generated in the flexible thermoelectric element; A heating variable step of varying the heating intensity of the heater to measure the generation amount of each thermoelectric element; And a variable curvature step of varying a curvature of the flexible thermoelectric element to measure a power generation amount thereof; .

The apparatus and method for evaluating the performance of a flexible thermoelectric device according to the present invention as described above can evaluate the performance according to the curvature of the flexible thermoelectric device, It is expected that the selection and application of a suitable thermoelectric element will be possible.

1 is a schematic cross-sectional view showing a conventional thermoelectric element
2 is a cross-sectional view of the performance evaluating device of the flexible thermoelectric element of the first embodiment of the present invention (before applying a bending load)
3 is a cross-sectional view (after a bending load is applied) of the performance evaluation device of the flexible thermoelectric element of the first embodiment of the present invention,
4 is a sectional view (after a bending load is applied) of the performance evaluating device of the flexible thermoelectric device according to the second embodiment of the present invention,
5 is a cross-sectional view of the actuator of the first embodiment of the present invention
6 is a cross-sectional view of the actuator according to the second embodiment of the present invention
7 is a flow chart of a performance evaluation method of a flexible thermoelectric element according to an embodiment of the present invention (at the time of cooling performance evaluation)
FIG. 8 is a flowchart of a method of evaluating performance of a flexible thermoelectric element according to an embodiment of the present invention (at the time of power generation performance evaluation)
9 is a graph showing the resistance change according to the curvature of the flexible thermoelectric element
10 is a graph showing a heat absorbing amount (cooling performance) versus a temperature difference measured by using an evaluation apparatus according to an embodiment of the present invention
11 is a graph showing a power generation amount (power generation performance) versus a heating amount measured using an evaluation apparatus according to an embodiment of the present invention

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

Evaluation device Example 1 (contact type)

2 and 3 are schematic sectional views of an apparatus 100 for evaluating the performance of a flexible thermoelectric transducer according to the first embodiment of the present invention (hereinafter referred to as " performance evaluation apparatus ").

As shown in the figure, the performance evaluation apparatus 100 includes a flexible thermoelectric element 110, an actuator 120 fixed to both ends of the flexible thermoelectric element 110 and applying a bending load to the flexible thermoelectric element 110, A heater 130 attached to one surface of the flexible thermoelectric element 110 to heat the flexible thermoelectric element 110, a heat sink 140 attached to the other surface of the flexible thermoelectric element 110 to cool the flexible thermoelectric element, And a laser measuring means 150 for measuring the curvature of the flexible thermoelectric element 110 at a predetermined distance from the element 110.

The actuator 120 is configured to apply a load to the flexible thermoelectric element 110 to change the curvature of the flexible thermoelectric element 110. The actuator 120 is coupled to one longitudinal side of the flexible thermoelectric element 110, A fixing means 121 for fixing one side of the flexible thermoelectric element 110 and a pressing means 122 for applying a load to one longitudinal side of the flexible thermoelectric element 110 in the longitudinal direction of the flexible thermoelectric element 110 .

A heater 130 for heating one surface of the flexible thermoelectric element 110 to a specific temperature is attached to one surface of the flexible thermoelectric element 110. The heater 130 may be configured to heat the flexible thermoelectric element 110 to a predetermined temperature. For example, an electric heater that conveys heat through the flexible thermoelectric element 110 may be applied . However, a flexible material heater may be applied to the flexible thermoelectric element 110 so that a bending load is transmitted.

A heat sink 140 for cooling the other surface of the flexible thermoelectric element 110 is attached to the other surface of the flexible thermoelectric element 110. The heat sink 140 may have any configuration as long as it can cool the flexible thermoelectric element 110 to a predetermined temperature. For example, the heat sink may include a plurality of heat dissipating fins have. However, a flexible material or a bendable heat sink may be applied to the flexible thermoelectric element 110 so that a bending load is transmitted.

A laser measuring unit 150 may be provided on one side of the flexible thermoelectric element 110 at a predetermined distance. The laser measuring means 150 is configured to measure the curvature of the flexible thermoelectric element 110 by irradiating the flexible thermoelectric element 110 with a line laser.

It is possible to evaluate the cooling performance and the power generation performance of the flexible thermoelectric element 110 while sequentially changing the curvature of the flexible thermoelectric element 110 through the performance evaluation apparatus 100 having the above-described configuration. Concrete cooling performance and power generation performance evaluation methods will be described later with reference to the drawings.

-Evaluation Apparatus Example 2 (Non-contact type)

4 is a schematic cross-sectional view of an apparatus 200 for evaluating flexibility and performance of a flexible thermoelectric device 200 (hereinafter referred to as a "performance evaluation apparatus") according to a second embodiment of the present invention.

The performance evaluation apparatus 200 according to the second embodiment of the present invention is advantageous in that the heater and the heat sink can be constructed without a flexible thermoelectric element and the heater and the heat sink can be applied without being made of a flexible material.

As shown in the figure, the performance evaluation apparatus 200 includes a flexible thermoelectric transducer 210, an actuator 220 fixed to both ends of the flexible thermoelectric transducer 210 and applying a bending load to the flexible thermoelectric transducer 210, A heater 230 spaced apart from one side of the flexible thermoelectric element 210 to heat the flexible thermoelectric element 210, a cooler 240 spaced apart from the other side of the flexible thermoelectric element 210 to cool the flexible thermoelectric element, And a laser measuring means 250 for measuring the curvature of the flexible thermoelectric element 210 at a predetermined distance from the thermoelectric element 210.

The actuator 220 has a structure for changing the curvature of the flexible thermoelectric element 210 by applying a load to the flexible thermoelectric element 210. The actuator 220 is coupled to one longitudinal side of the flexible thermoelectric element 210, And fixing means 221 for fixing one side of the flexible thermoelectric element 210 and pressing means 222 for applying a load to one longitudinal side of the flexible thermoelectric element 210 coupled to the other side of the flexible thermoelectric element 210 in the longitudinal direction .

A heater 230 for heating one surface of the flexible thermoelectric element 210 to a specific temperature is disposed on one side of the flexible thermoelectric element 210. The heater 230 may have any structure as long as it is configured to heat the flexible thermoelectric element 210 to a predetermined temperature by radiation. For example, an optical heater or the like may be applied.

A cooler 240 for cooling the other surface of the flexible thermoelectric element 210 is disposed on the other side of the flexible thermoelectric element 210. The cooler 240 may have any structure as long as it can cool the flexible thermoelectric element 210 to a predetermined temperature. For example, an air-cooled fan may be used.

A laser measuring unit 250 may be provided on one side of the flexible thermoelectric element 210 at a predetermined distance. The laser measuring means 250 is configured to measure the curvature of the flexible thermoelectric element 210 by irradiating the flexible thermoelectric element 210 with a line laser.

The cooling performance and the power generation performance of the flexible thermoelectric element 210 can be evaluated while changing the curvature of the flexible thermoelectric element 210 sequentially through the performance evaluation device 200 having the above-described configuration. Concrete cooling performance and power generation performance evaluation methods will be described later with reference to the drawings.

FIG. 5 is a sectional view showing the actuator 120, 220 of the first embodiment of the present invention, and FIG. 6 is a sectional view showing the actuator 220 of the second embodiment of the present invention.

The evaluation apparatuses 100 and 200 of the present invention have the following configuration so as to minimize damage to the flexible thermoelectric elements 110 and 210 when the flexural thermoelectric elements 110 and 210 are varied in curvature through the actuators 120 and 220 .

5, the first links 123 and 223 are provided on the other side of the fixing means 121 and 221 and the second links 124 and 224 are provided on one side of the pressing means 122 and 222 . One side of the first links 123 and 223 is hinged to the fixing means 121 and 221 and the other side is coupled to one side of the flexible thermoelectric elements 110 and 210. The other ends of the second links 124 and 224 are hinged to the pressing means 122 and 222 and one side of the second links 124 and 224 is coupled to the other side of the flexible thermoelectric elements 110 and 210. It is possible to prevent both sides of the flexible thermoelectric elements 110 and 210 from being hinge-deformed through the structure of the first and second links.

The evaluation apparatus 200 of the present invention has the following configuration so as to minimize the change in curvature from one side to the other side of the flexible thermoelectric element 210 when the flexible thermoelectric element 210 is varied in curvature through the actuator 220. This embodiment can be applied only to the evaluation apparatus 200 of the second embodiment.

As shown in FIG. 6, the actuator 220 further includes a film 225, one side of which is coupled to the fixing means 221 and the other side of which is coupled to the pressing means 222. The upper film 225 is made of a material less flexible than the flexible thermoelectric element 210 so that the curvature of the upper film 225 is constantly maintained from one side to the other side through the pressing means 222.

That is, when the flexible thermoelectric element 210 is attached to one surface of the upper film 225, only the curvature of a specific portion increases as the flexible thermoelectric element 210 is made of a flexible material through the pressing means 222 .

- Evaluation method Example 1 (cooling performance)

FIG. 7 is a flow chart of a method of evaluating the flexibility and performance of a flexible thermoelectric device according to the first embodiment of the present invention.

The cooling performance of the flexible thermoelectric element 110 is determined by evaluating the heat absorbing amount Qc of the flexible thermoelectric element 110 to apply a current to the flexible thermoelectric element 110 and to provide a temperature difference DELTA T ), And then the heat absorbed amount Qc of the surface to be cooled of the thermoelectric element is measured. Particularly, the present invention is characterized in that the heater 130 measures the heat absorbed Qc. Specifically,

First, a temperature difference generation step (S11) is performed in which a current is applied to the flexible thermoelectric element (110), one side of the thermoelectric element is cooled, and the other side is heated.

Next, a heater heating step (S12) is performed to heat one surface of the flexible thermoelectric element (110) through the heater (130) so that the temperature difference becomes zero.

Next, when the temperature difference becomes 0, the power of the heater 130 is measured to calculate a heat absorbing amount of the thermoelectric element (S13). When the temperature difference between the one surface and the other surface of the flexible thermoelectric element becomes zero, the power of the heater 130 becomes equal to the heat absorbed by the thermoelectric element, so that the heat of the thermoelectric element is calculated by measuring the power of the heater 130.

Next, a current varying step S14 is performed to vary the current intensity of the flexible thermoelectric element 110 and measure the respective heat absorbed amounts.

Next, a curvature variable step S15 is performed to vary the curvature of the flexible thermoelectric element 110 and measure the respective heat absorption amounts.

- Evaluation method Example 2 (power generation performance)

FIG. 8 is a flow chart of a method of evaluating flexibility and performance of a flexible thermoelectric device according to a second embodiment of the present invention.

The power generation performance of the flexible thermoelectric element 110 is evaluated by evaluating the power generation amount (power) of the flexible thermoelectric element 110 to generate a temperature difference between one surface and the other surface of the flexible thermoelectric element 110, . Specifically,

A heater heating step S21 for heating one surface of the flexible thermoelectric element 110 through the heater 130 to generate a temperature difference between one surface and the other surface of the thermoelectric element is performed.

Next, a power generation amount measuring step (S22) for measuring the amount of current, i.e., the power, generated in the flexible thermoelectric element 110 and calculating the power generation amount of the thermoelectric element is performed.

Next, a heating variable step (S23) is performed to vary the heating intensity of the heater 130 and measure the amount of generation of each thermoelectric element.

Next, a curvature variable step S24 is performed for varying the curvature of the flexible thermoelectric element 110 and measuring the respective amounts of generated electricity.

- result

FIG. 9 is a graph showing a change in resistance according to the curvature of the flexible thermoelectric element, and FIG. 10 is a graph showing a change in the amount of heat absorbed (cooling performance) relative to the temperature difference measured using the evaluation apparatuses 100 and 200 according to an embodiment of the present invention. FIG. 11 is a graph showing a power generation amount (power generation performance) versus a heating amount measured using the evaluation apparatuses 100 and 200 according to an embodiment of the present invention.

As shown in FIG. 9, as the radius of curvature of the flexible thermoelectric element 110 increases, the resistance increases, and accordingly, the necessity of evaluating each of the performance indexes according to the curvature variation of the flexible thermoelectric element 110 .

As shown in FIG. 10, when the current applied to the flexible thermoelectric element 110 is increased to increase the temperature difference, the heat absorbed amount decreases in proportion to the increase of the temperature difference. When the curvature of the flexible thermoelectric element 110 decreases , It can be seen that the endothermic amount decreases at the same temperature difference.

As shown in FIG. 11, when the amount of heating applied to the flexible thermoelectric element 110 is increased and the temperature difference is increased, the amount of generated electricity increases to a certain temperature difference, It can be seen that as the curvature decreases, the power generation amount decreases at the same temperature difference.

The technical idea should not be construed as being limited to the above-described embodiment of the present invention. 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 appended claims. Accordingly, such modifications and changes are within the scope of protection of the present invention as long as it is obvious to those skilled in the art.

100, 200: Flexibility and performance evaluation device of flexible thermoelectric device
110, 210: Flexible thermoelectric element
120 and 220: actuators 121 and 221: fixing means
122, 222: pressing means
130, 230: heater
140: heat sink 240: cooler
150, 250: laser measuring means

Claims (9)

Flexible thermoelectric devices;
An actuator for changing the curvature of the flexible thermoelectric element by applying a bending load to the flexible thermoelectric element;
A heater provided on one surface of the flexible thermoelectric element to heat the flexible thermoelectric element;
Cooling means provided on the other surface of the flexible thermoelectric element to cool the flexible thermoelectric element; And
And a curvature measuring unit spaced apart from the flexible thermoelectric element to measure a curvature of the flexible thermoelectric element,
The heater
A flexible thermoelectric element attached to one surface of the flexible thermoelectric element,
Wherein the cooling means comprises:
Wherein the flexible thermoelectric element is attached to the other surface of the flexible thermoelectric element,
Wherein the heater and the cooling means are made of a flexible material.
The method according to claim 1,
The heater
A convection type heater attached to one surface of the flexible thermoelectric element,
Wherein the cooling means comprises:
Wherein the flexible thermoelectric element is a heat sink attached to the other surface of the flexible thermoelectric element.
delete Flexible thermoelectric devices;
An actuator for changing the curvature of the flexible thermoelectric element by applying a bending load to the flexible thermoelectric element;
A heater provided on one surface of the flexible thermoelectric element to heat the flexible thermoelectric element;
Cooling means provided on the other surface of the flexible thermoelectric element to cool the flexible thermoelectric element; And
And a curvature measuring unit spaced apart from the flexible thermoelectric element to measure a curvature of the flexible thermoelectric element,
Wherein the actuator comprises:
Fixing means coupled to one longitudinal side of the flexible thermoelectric element; And
A pressing means coupled to the other longitudinal side of the flexible thermoelectric transducer for pressing the flexible thermoelectric transducer to one side of the longitudinal direction of the flexible thermoelectric transducer;
And a temperature sensor for measuring the temperature of the flexible thermoelectric element.
5. The method of claim 4,
Wherein the actuator comprises:
A first link in which one side is hinged to the fixing means and the other side is coupled to the flexible thermoelectric element; And
A second link, the other side of which is hinged to the pressing means, and the other end of which is coupled to the flexible thermoelectric element;
Further comprising a temperature sensor for measuring the temperature of the flexible thermoelectric element.
5. The method of claim 4,
Wherein the actuator comprises:
A film having one side fixed to the fixing means and the other side coupled to the pressing means; Further comprising:
Wherein the flexible thermoelectric element is attached to one surface of the film.
A method for evaluating performance of a flexible thermoelectric device using the apparatus for evaluating performance of a flexible thermoelectric device according to claim 1 or 4,
A temperature difference generation step of applying current to the flexible thermoelectric element to cool one surface of the thermoelectric element and to heat the other surface;
A heater heating step of heating one surface of the flexible thermoelectric element through a heater so that a temperature difference between one surface and the other surface of the thermoelectric element becomes zero;
Measuring a heat absorption amount of the flexible thermoelectric element by measuring a power of the heater when the temperature difference becomes zero; And
A current varying step of varying the intensity of a current applied to the flexible thermoelectric element to measure each heat absorbing amount;
And a second thermoelectric conversion element.
8. The method of claim 7,
The method for evaluating the performance of the flexible thermoelectric device includes:
A curvature variable step of varying the curvature of the flexible thermoelectric element to measure the respective heat absorption amounts;
Further comprising the steps of:
A method for evaluating performance of a flexible thermoelectric device using the apparatus for evaluating performance of a flexible thermoelectric device according to claim 1 or 4,
A heater heating step of heating one surface of the flexible thermoelectric element through a heater to generate a temperature difference between one surface and the other surface of the thermoelectric element;
A power generation amount measuring step of measuring a power generation amount of the thermoelectric element by measuring an amount of current generated in the flexible thermoelectric element; And
A heating variable step of varying the heating intensity of the heater to measure the generation amount of each thermoelectric element; And
A curvature variable step of varying the curvature of the flexible thermoelectric element to measure the respective power generation amounts;
And a second thermoelectric conversion element.

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