KR101447776B1 - Dye-adsorption equipment for dye sensitized solar cell - Google Patents

Abstract

The dye-adsorbing apparatus for a dye-sensitized solar cell of the present invention comprises a substrate supporter for supporting a photo-electrode substrate of a dye-sensitized solar cell, a dye-liquid spraying nozzle provided on the substrate supporter for spraying a dye- And a dye solution reservoir for storing a dye solution not adsorbed to the dye of the substrate among the dye solution injected from the injection nozzle, wherein a dye solution discharging portion is provided in the dye solution storing portion, and the dye solution discharged from the dye solution discharging portion Is circulated to the dye liquid jetting nozzle.

Description

TECHNICAL FIELD The present invention relates to a dye-adsorbing dye for dye-sensitized solar cells,

The present invention relates to a dye-adsorbing apparatus for a dye-sensitized solar cell, and more particularly, to a dye-adsorbing apparatus for adsorbing dye to a semiconductor oxide layer of a dye-sensitized solar cell.

Dye-Sensitized Solar Cell (DSSC) is a solar cell developed by Michael Gratzel of the Swiss Federal Institute of Technology. It has lower manufacturing cost compared to conventional silicon solar cells, It is possible to manufacture a cell which is high in transparency and bendability and thus can be used in various applications.

The dye-sensitized solar cell includes a photoelectrode including a dye molecule that generates an electron-hole pair and a semiconductor oxide layer that transfers generated electrons, an electrolyte that replenishes electrons as a dye molecule, and a catalyst for a redox reaction of the electrolyte solution And a counter electrode coated with a platinum layer. When the light is incident on the dye-sensitized solar cell, the dye absorbing the light enters an excited state and sends electrons to the conduction band of the semiconductor oxide layer. The conducted electrons flow to the external circuit along the electrode to transfer the electric energy , The energy state becomes as low as the electric energy is transmitted to the counter electrode. The dye receives electrons from the electrolyte solution as much as the number of electrons transferred to the semiconductor oxide layer, and returns to the original state. At this time, the electrolyte used in the dye transfers electrons from the counter electrode to the dye by oxidation-reduction reaction. The photoelectrode serving as a negative electrode of the battery includes a semiconductor semiconductor layer such as titanium dioxide (TiO ₂ ), and a dye which absorbs light in the visible light region and generates electron-hole pairs is adsorbed on the surface. The electrolyte that supplies electrons to the dye is composed of redox species such as I ^- / I ₃ ^- , LiI, NaI, alkaline ammonium iodide, and imidazolium iodide are used as the source of I ^- ion, and I ₃ ^- ions are generated by dissolving I ₂ in a solvent. The counter electrode is made of platinum or the like and acts as a catalyst for the ion oxidation-reduction reaction, and serves to provide electrons to the ions in the electrolyte through redox reaction on the surface.

Conventional methods of adsorbing dyes to a semiconductor oxide layer of a dye-sensitized solar cell can be roughly divided into an immersion type and a circulation type. The immersion type is a method in which a substrate containing a semiconductor oxide layer is immersed in a container in which a dye solution is stored to adsorb the dye. Such a method is the method of adsorbing the dye to the semiconductor oxide layer most certainly, but the opposite side of the substrate is dyed with dye, so that the dye is consumed excessively and can be applied to a small substrate, but it is difficult to apply to a large substrate have. The circulation type is a method of circulating the dye in a space between the substrates by using a pump after attaching the photosensitive plate and the counter substrate. However, as the area of the substrate is increased, the circulation type dye adsorption method can not meet the tendency of the dye-sensitized solar cell to be large-sized and the automation trend of the process because the dye migration speed in the space between the substrates becomes slower. A prior art document on dye adsorption apparatus for dye-sensitized solar cells is Korean Patent Publication No. 2010-0079379. The prior art document includes a stage for fixing a dye-sensitized solar cell or a sub-module, a dye tank for storing a dye for preparing a dye-sensitized solar cell, A dye supply pump for supplying the dye from the dye tank to the outside, a needle portion for receiving the dye from the dye supply pump and accommodating the dye in the cylinder and guiding the dye to the injection port extending to the lower end, A piston portion for injecting a dye into the solar cell or submodule by pressurizing the dye in the cylinder and discharging the dye to the injection port; and a recycling portion for recycling the dye discharged from the dye- sensitized solar cell or the submodule to the dye tank And a controller for controlling the dye supply to the cylinder of the dye supply pump and the upward and downward movement of the piston. However, since the dye adsorption apparatus disclosed in the above-mentioned literature adopts the method of injecting the dye liquid in the state where the photomask and the counter substrate are bonded together, the dye adsorption time is long and it is difficult to apply to the large area dye-sensitized solar cell .

Accordingly, the dye can be applied to a large area, and the adsorption of the dye can be made uniform, and there is a great need to develop a new dye-adsorbing apparatus and method for a dye-sensitized solar cell suitable for automation of the process.

SUMMARY OF THE INVENTION Accordingly, it is an object of the present invention to provide a dye adsorption apparatus for a dye-sensitized solar cell capable of uniformly adsorbing a dye to a semiconductor oxide layer, being applicable to a large area dye-sensitized solar cell, will be.

According to an aspect of the present invention, there is provided a dye-sensitized solar cell comprising a substrate supporter for supporting a photo-electrode substrate of a dye-sensitized solar cell, a dye-liquid spraying nozzle provided above the substrate supporter for spraying a dye- And a dye solution reservoir for storing a dye solution not adsorbed to the dye of the substrate among the dye solution injected from the injection nozzle, wherein a dye solution discharging portion is provided in the dye solution storing portion, and the dye solution discharged from the dye solution discharging portion Wherein the dye-sensitized solar cell is recycled to the dye-liquid jetting nozzle.

According to an embodiment of the present invention, the direction of ejection of the dye liquid jetting nozzle relative to the substrate may be adjusted.

According to another embodiment of the present invention, a heater may be installed in a line connecting the dye liquid discharging portion and the dye liquid jetting nozzle.

According to another embodiment of the present invention, a supporter heater may be installed in the substrate supporter.

According to another embodiment of the present invention, the substrate supporter can be inclined so that the non-adsorbed dye liquid can flow down.

According to another embodiment of the present invention, the dye adsorption apparatus for a dye-sensitized solar cell may further include a nitrogen injection unit for maintaining a space in which the dye liquid is injected in a nitrogen atmosphere.

According to another embodiment of the present invention, a dye concentration measuring unit for measuring the concentration of the dye solution may be installed in a line connected to the dye solution discharging unit.

The dye adsorption apparatus of the dye-sensitized solar cell of the present invention has the following effects.

1. Since the dye is adsorbed by the method of spraying the dye liquid in one direction of the substrate, the dye is not brought into contact with the substrate on the opposite side where the semiconductor oxide layer is formed, so consumption of the dye liquid can be minimized.

2. Since the dye liquid is injected only onto the photo-electrode substrate before the photo-electrode substrate and the counter electrode substrate are bonded together, the time required for adsorption of the dye can be shortened.

3. Dye liquid which is injected and not adsorbed on the semiconductor oxide layer is recycled to the nozzle in the dye liquid storage part, so that consumption of unnecessary dye can be prevented.

4. Since the heater is installed on the substrate supporter on which the substrate is loaded, the adsorption temperature of the dye can be controlled.

5. Dye liquid It is possible to control the temperature of the dye liquid injected into the nozzle by installing a heater in the transfer line of the dye liquid supplied to the nozzle or the dye liquid reservoir.

6. Dye liquid can be uniformly sprayed on a large substrate because the nozzle connection can be rotated or the injection direction can be switched.

7. Since a light measuring part is formed on a line connected to the dye liquid spray nozzle from the dye solution storage part, the dye concentration in the dye solution can be easily measured, so that the replenishment timing of the dye can be easily grasped.

8. Since the inclination of the substrate supporter can be adjusted, it is possible to quickly recover the unadsorbed dye liquid, thereby shortening the processing time.

1 shows a dye adsorption apparatus for a dye-sensitized solar cell according to an embodiment of the present invention.
FIG. 2 illustrates the structure of a dye adsorption apparatus for a dye-sensitized solar cell according to an embodiment of the present invention.
3 is a view for explaining a dye concentration measuring unit applied to a dye adsorbing apparatus for a dye-sensitized solar cell according to the present invention.
4 is a view for explaining a substrate tilt adjusting unit applied to a dye adsorbing apparatus for a dye-sensitized solar cell according to the present invention.
FIG. 5 illustrates a substrate fixing unit applied to a dye adsorbing apparatus for a dye-sensitized solar cell according to the present invention.
6 is a view for explaining a spray angle adjusting method of a dye liquid spray nozzle applied to a dye adsorbing apparatus for a dye-sensitized solar cell according to the present invention.
7 is a view for explaining a dye liquid spray nozzle rotating method applied to a dye adsorbing apparatus for a dye-sensitized solar cell according to the present invention.
FIG. 8 illustrates a continuous dye adsorption apparatus according to an embodiment of the present invention.

Hereinafter, the present invention will be described in detail.

The dye-adsorbing apparatus for a dye-sensitized solar cell of the present invention comprises a substrate supporter for supporting a photo-electrode substrate of a dye-sensitized solar cell, a dye-liquid spraying nozzle provided on the substrate supporter for spraying a dye- And a dye solution reservoir for storing a dye solution not adsorbed to the dye of the substrate among the dye solution injected from the injection nozzle, wherein a dye solution discharging portion is provided in the dye solution storing portion, and the dye solution discharged from the dye solution discharging portion Is circulated to the dye liquid jetting nozzle.

The construction and function of the dye adsorbing apparatus for a dye-sensitized solar cell according to an embodiment of the present invention will be described with reference to FIG.

1 shows a dye adsorption apparatus for a dye-sensitized solar cell according to an embodiment of the present invention. 1, a dye adsorption apparatus 100 includes a substrate supporter 101, a dye liquid storage unit 107, a chamber panel 108, a dye liquid discharge unit 109, a pump 113, a nozzle connection unit 117 And a dye liquid jetting nozzle 108. As shown in Fig. The substrate supporter 101 is a part where the photoelectrode substrate of the dye-sensitized solar cell is loaded, and the height of the substrate loaded by the substrate height adjusting unit 103 provided at the lower part can be adjusted. The dye solution reservoir 107 stores the dye before the start of the process and temporarily stores the dye solution not adsorbed in the semiconductor oxide layer in the dye solution injected onto the substrate and is separately installed in the lower part of the dye adsorption device And may be installed in a configuration extending from the chamber panel 108 to have a closed bottom surface. The chamber panel 108 prevents the dye liquid sprayed from the dye liquid spray nozzle 108 from leaking to the outside and the dye liquid can be transferred to the dye liquid storage unit 107 on the inner surface of the chamber panel 108 . The dye solution discharging portion 109 may be provided on the side or the lower side of the dye solution storing portion 107 so that the dye solution temporarily stored in the dye solution storing portion 107 is returned to the dye solution jetting nozzle 108 And the dye solution discharge line 110 is connected. The pump 113 becomes a power for re-transferring the dye liquid discharged to the dye liquid discharging portion 109 to the dye liquid jetting nozzle 108 again. The nozzle connection portion 117 may include a transfer passage for re-supplying the dye liquid discharged from the dye liquid discharge portion 109 as means for installing one or a plurality of dye liquid spray nozzles 108 thereon . The dye liquid jetting nozzle 108 functions to jet the dye liquid onto the substrate on which the semiconductor oxide layer is formed, and it is possible to control the jet angle of the dye liquid and the particles of the dye liquid to be jetted.

The dye adsorbing apparatus for a dye-sensitized solar cell according to an embodiment of the present invention may include the following additional structures. The substrate fixing part 101a is provided on the upper part of the substrate supporter 101. The substrate fixing part 101a functions to fix the position of the substrate in the jetting process of the dye liquid and can vary the forming position and the number in consideration of the size of the substrate have. The substrate height adjuster 103 may be selectively applied to the substrate supporter 101. The substrate height adjuster 103 may adjust the distance to the dye liquid jetting nozzle depending on the size of the substrate loaded on the substrate supporter 101. [ The substrate height adjuster 103 may be controlled by using air pressure or hydraulic pressure, or may be controlled by using a rack gear and a pinion gear. When the air pressure is used, the pressurizing unit 105 and the pressure adjusting unit 106 may be driven, . ≪ / RTI > The partition wall 104 functions to prevent the dye liquid from contacting the lower part of the substrate height adjusting part 103. The partition wall 104 may be formed in the form of a partition wall 104 considering the height of the dye liquid stored in the dye liquid storage part 107. [ The height can be varied. The transparent line 111 may be formed in the middle of the dye-solution discharge line 110 connected to the dye-solution discharging unit 109. The transparent dye-concentration measuring unit 112 may be formed of a transparent material In the drawing, the dye liquid discharging portion 109 is shown as being formed adjacent to the dye liquid discharging portion 109, but the forming position may be variously modified. The dye solution discharging line 110 may be provided with a heater 114, a valve 115 and a dye solution pressure regulating part 116. The heater 114 may supply the dye solution passing through the dye solution discharging line 110 And controls the temperature of the dye liquid sprayed to the dye liquid jetting nozzle 118. The valve 115 functions to start or stop the jetting of the dye liquid when the process is started or completed The dye pressurizing unit 116 regulates the amount of the dye liquid to be supplied to the dye liquid jetting nozzle 118 and controls the injection amount of the dye liquid. The nitrogen injection port 120 functions to prevent oxidation of the dye by adsorbing the dye in a nitrogen atmosphere by filling the inside of the chamber with nitrogen, and the nitrogen storage portion 122 and the nitrogen discharge portion 123 are additionally installed And may include a valve 121 for controlling the injection of nitrogen. Although the nitrogen injection port 120 and the nitrogen discharge port 123 are illustrated as being installed on the upper portion of the drawing, the installation position of the nitrogen injection port 120 and the nitrogen discharge portion 123 may be variously selected.

Referring to FIG. 2, the operation of injecting a dye in a dye adsorbing apparatus for a dye-sensitized solar cell according to an embodiment of the present invention will be described.

FIG. 2 illustrates the structure of a dye adsorption apparatus for a dye-sensitized solar cell according to an embodiment of the present invention. Referring to FIG. 2, a dye liquid reservoir 107 formed in a lower portion of the chamber panel 108 is filled with a predetermined amount of dye liquid, and the photoelectrode substrate of the dye-sensitized solar cell is loaded in the substrate supporter 102. At this time, the height of the substrate 102 may be adjusted to a predetermined height by the substrate height adjusting unit 103 in consideration of the size of the substrate 102. The filled dye solution 200 is conveyed to the dye liquid jetting nozzle 118 through the dye liquid discharging portion 109 and the dye liquid discharging line 110 by the pump 103. In this process, the amount of dye is transferred through the pump 103, the valve 115, and the dye-liquid pressurizing unit 116, and a temperature measuring unit may be installed on the transfer path of the dye liquid And if the temperature of the transferred dye liquid is lower than the reference value, the heater 114 may operate to heat the dye liquid. The transferred dye liquid is jetted downward through a dye liquid jetting nozzle 118 provided in a nozzle connecting portion 117. The jetted dye liquid contacts the semiconductor oxide layer formed on the substrate 102 and the dye is adsorbed. The amount of the dye solution not adsorbed to the semiconductor oxide layer flows into the dye solution reservoir 107 along the upper surface of the substrate or the inner surface of the chamber panel 108, And is recirculated in the direction of the dye liquid jetting nozzle 118. During this process, nitrogen may be injected into the nitrogen inlet 120 to fill the space where the dye adsorption occurs with nitrogen, and the nitrogen may be discharged to the nitrogen outlet 123. Further, the supporter heater 101a is operated to maintain the substrate 102 at a constant temperature. Although the supporter heater 101a is illustrated as being installed below the substrate supporter 101 in the figure, the supporter heater 101a may be installed inside or above the substrate supporter 101 and may include means for measuring and controlling the temperature . When the dye is adsorbed during the process, the dye concentration in the dye liquid becomes low. The dye concentration measuring unit 112 can measure the concentration of the dye in-situ, Dye solution or dye can be supplemented. The dye concentration measuring unit may be configured in various ways. For example, the dye liquid may be configured in such a manner that a transparent window is formed on the conveyance path to measure the absorbance of light, and a valve for extracting a part of the dye liquid is provided And the concentration of the dye may be measured from the extracted dye solution. Although not shown in the drawing, a heater may be additionally provided in the dye-solution storage unit 107.

An example in which the dye concentration measuring section is constructed using Fig. 3 will be described.

3 is a view for explaining a dye concentration measuring unit applied to a dye adsorbing apparatus for a dye-sensitized solar cell according to the present invention. 3, a light source 112a and a light measuring unit 112b are provided in both directions of a transparent line 111 formed on a path through which the dye liquid is conveyed, so that the light generated from the light source passes through the transparent line 111 It is possible to measure the concentration of the dye liquid by measuring the degree of weakening of the light intensity as it passes. The transparent line 111 may be formed of a transparent material, or may be formed of a metal material having windows formed on both sides thereof. The dye concentration measurement method described in the drawings is only an example, and various other known means may be used.

The tilt adjustment of the substrate supporter 101 will be described with reference to Fig.

4 is a view for explaining a substrate tilt adjusting unit applied to a dye adsorbing apparatus for a dye-sensitized solar cell according to the present invention. Referring to FIG. 4 (a), a substrate height adjusting unit using a cylinder may be installed below the substrate supporter 101. The substrate height adjusting unit may include a first cylinder 103a, a second cylinder 103a ', a first piston 103b and a second piston 103b', and further the third cylinder 103c and the rollers 103d ). The first cylinder 103a and the second cylinder 103a 'are connected to the pressure means so that the first piston 103b and the second piston 103b' can move. A separate pressurizing means may not be connected to the third cylinder 103c, and a roller 103d may be provided in the middle of the third cylinder 103c so that the inclination of the substrate can be changed. Referring to FIG. 4 (b), when the first piston 103b and the second piston 103b 'are provided with latching protrusions, the pistons can be protruded to different heights. Referring to FIG. 4 (c), when the first piston 103b and the second piston 103b 'are blown at different heights, the inclination of the substrate 101 can be adjusted by rotating the roller 103d. The inclination of the substrate 101 can be adjusted by adjusting the positions of the latching jaws provided on the first piston 103b and the second piston 103b '. The configuration of the substrate height adjusting unit described in the drawings is merely an example, and various known methods can be used to adjust the tilt of the substrate. At this time, in order to prevent the substrate from slipping in the inclined substrate supporter 101, the substrate securing portion 101a may be provided on the substrate supporter 101 as shown in Fig. The position and number of the substrate fixing portions 101a can be changed depending on the size and shape of the substrate.

A configuration for adjusting the jet direction of the dye liquid jetting nozzle will be described with reference to FIGS. 6 and 7. FIG.

6 is a view for explaining a spraying angle adjusting method of a nozzle applied to a dye adsorbing apparatus for a dye-sensitized solar cell according to the present invention. 6A, a rotating portion 117a is provided at an upper portion of the nozzle connecting portion 117 so that the nozzle connecting portion 117 can change the spraying angle of the dye liquid spraying nozzle in the lateral direction. The rotation part 117a functions to operate the nozzle connection part 117 in the left and right direction. The rotation part 117a may be constructed by installing a motor, a rotary shaft, gears, etc., and various other known means may be used. Referring to FIG. 6 (B), while the nozzle connecting part 117 is in the correct position, the dye liquid jetting nozzle 118 is positioned vertically and the dye liquid is sprayed to a predetermined area indicated by an arrow. (A) on the right shows the area where the dye liquid is sprayed. Referring to FIG. 6 (C), when the nozzle connecting portion 117 moves leftward and rightward, the spraying direction is changed in the left-right direction of the dye liquid spraying nozzle, and the dye liquid is sprayed to the area indicated by the arrow. (B) in the figure to the right shows the area where the dye liquid injection nozzle is additionally spraying the dye liquid while changing the direction. When the direction of spraying the dye liquid is adjusted as described above, the dye liquid can be uniformly sprayed over a wider area.

7 is a view for explaining a nozzle rotation method applied to a dye adsorbing apparatus for a dye-sensitized solar cell according to the present invention. Referring to FIG. 7 (a), a rotating portion 117a is provided at an upper portion of the nozzle connecting portion 117 so that the nozzle connecting portion 117 can rotate in a plane. The rotating portion 117a may be composed of a motor and a speed reducer. When the nozzle connection part 117 is rotated as described above, the injection of the dye liquid can be uniformly performed over a wider area. 7A and 7B, the dye liquid is sprayed only on the area (a) when the nozzle connecting part 117 is fixed, but when the nozzle connecting part 117 rotates at right angles, The dye liquid can be injected, and when the nozzle connecting portion 117 is continuously rotated, (c) the dye liquid can be uniformly sprayed over the entire region. Although not shown in the drawing, the nozzle diameter of the dye liquid jetting nozzle, the jetting pressure and the like can be controlled, and the jetting angle of the dye liquid based on one nozzle can also be adjusted.

The construction of a dye adsorption apparatus to which a substrate is fed in a continuous manner will be described with reference to Fig.

FIG. 8 illustrates a continuous dye adsorption apparatus according to an embodiment of the present invention. Referring to FIG. 8, a dye-liquid spraying nozzle 318 is provided on the upper part of the continuous dye adsorption apparatus 300, and a dye-solution storage unit in which a dye solution is stored is installed in the lower part. Since the structure in which the dye liquid is recycled from the dye liquid reservoir to the dye liquid spray nozzle is the same as described above, the structure except for the dye liquid discharging unit 304 and the pump 305 is omitted. The substrate 302 is continuously supplied along the moving rollers 303 provided in the space between the dye liquid jetting nozzles 318 and the dye liquid storing portion and the substrate is allowed to adsorb the dye to the semiconductor oxide layer while passing through the dye liquid jetting region This happens. At this time, the blocking wall 306 is installed in a certain region, and the extra dye solution not causing adsorption of the dye is guided to the dye solution storage portion along the blocking wall 306.

While the present invention has been described in connection with what is presently considered to be the most practical and preferred embodiment, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the invention. Therefore, the embodiments described in the present invention are not intended to limit the scope of the present invention but to limit the scope of the present invention. The scope of protection of the present invention should be construed according to the claims, and all technical ideas within the scope of equivalents should be construed as falling within the scope of the present invention.

100: dye absorption apparatus 101: substrate supporter
101a: Substrate fixing section 101a: Supporter heater
102: substrate 103: substrate height adjuster
103a: first cylinder 103b: first piston
103a ': Second cylinder 103b': Second piston
103c: third cylinder 103d: roller
104: partition wall 105:
106: Pressure regulator 107: Dye liquid reservoir
108: Chamber panel 109: Dye liquid discharge part
110: Dye liquid discharge line 111: Transparent line
112: dye concentration measuring unit 112a: light source
112b: light measuring unit 113: pump
114: heater 115: valve
116: Dye liquid pressure regulating part 117: Nozzle connection part
117a: rotating part 118: dye liquid jetting nozzle
120: nitrogen inlet 121: valve
122: nitrogen storage part 123: nitrogen discharge part
200: Dye liquid 300: Continuous dye absorption apparatus
302: substrate 303: moving roller
304: Dye liquid discharging portion 305: Pump
306: blocking wall 318: dye liquid spray nozzle

Claims (7)

A substrate supporter for supporting the photoelectrode substrate of the dye-sensitized solar cell;
A dye liquid spray nozzle installed on the substrate supporter and spraying a dye liquid toward the substrate; And
And a dye solution storage part for storing a dye solution not adsorbed to the dye of the substrate in the dye solution injected from the dye solution injection nozzle,
A dye liquid discharging portion is provided in the dye liquid storing portion, the dye liquid discharged from the dye liquid discharging portion is circulated to the dye liquid jetting nozzle,
Wherein the dye liquid jetting nozzle is provided with a heater on a line connecting the dye liquid discharging portion and the dye liquid jetting nozzle, a supporter heater is provided on the substrate supporter, The tilt is adjusted so that the non-existent dye liquid flows down,
Wherein the tilt adjustment of the substrate supporter is performed by a plurality of cylinders and pistons formed at different positions. delete delete delete delete The method according to claim 1,
And a nitrogen injection unit for maintaining the space in which the dye liquid is injected in a nitrogen atmosphere. The method according to claim 1,
And a dye concentration measuring unit for measuring the concentration of the dye solution is installed in a line connected to the dye solution discharging unit.

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