Capacitive Electrode, Membrane Stack Comprising Electrode and Method for Manufacturing Such Electrode

Abstract

The invention relates to a capacitive electrode comprising: an electrode housing comprising: ˜a number of housing walls that enclose a housing space; and ˜an opening that is operatively connected to the housing space, and wherein the opening is configured to be positioned adjacent an end membrane of a membrane stack; —a capacitive layer that is positioned in the housing space; —a current feeder that is positioned in the housing space and that is in electrical contact with the capacitive layer; —a gel layer that is positioned in contact with the capacitive layer; wherein the gel layer is provided in or adjacent to the opening such that the gel layer seals the opening, or wherein the gel layer is positioned near a bottom housing wall of the housing and the current feeder is positioned in or near the opening.

Claims

1. Capacitive electrode for a membrane based device, the electrode comprising: an electrode housing comprising: a number of housing walls that enclose a housing space; and an opening that is operatively connected to the housing space, and wherein the opening is configured to be positioned adjacent an end membrane of a membrane stack; a capacitive layer that is positioned in the housing space; a current feeder that is positioned in the housing space and that is in electrical contact with the capacitive layer; a gel layer that is positioned in contact with the capacitive layer; wherein the gel layer is provided in or adjacent to the opening such that the gel layer seals the opening of the electrode housing, or wherein the gel layer is positioned near a bottom housing wall of the housing and the current feeder is positioned in or near the opening.

2. Capacitive electrode according to claim 1, comprising a separator layer, preferably a filter paper layer, that is positioned between the gel layer and the capacitive layer.

3. Capacitive electrode according to claim 1, wherein the gel layer is an ion-conducting layer and/or wherein the gel is chosen from a group of a hydrogel, preferably an aqua-based hydrogel, gelatin, a PVA based gel, a PMMA based gel or agar-agar.

4. Capacitive electrode according to claim 1, wherein the housing is end-plate of a membrane-based device, such as an electrodialysis device, a reverse electrodialysis device or a fuel cell.

5. Capacitive electrode according to claim 1, wherein the capacitive layer is an activated carbon layer.

6. Capacitive electrode according to claim 1, wherein the current feeder is chosen from a (perforated) carbon foil, a (perforated) carbon plate, a (perforated) graphite foil, a (perforated) graphite plate, a platinum coated titanium mesh, or a platinum coated titanium (perforated).

7. Capacitive electrode according to claim 1, wherein the gel layer comprises a reinforcement layer, wherein the reinforcement layer preferably comprises a netting or a non-woven.

8. Capacitive electrode according to claim 1, wherein the housing comprises a lining or rim that extends around the opening and that is in electrical contact with the current feeder, wherein the lining or rim preferably is copper or graphite.

9. Capacitive electrode according to claim 1, wherein the electrode additionally comprises a second capacitive layer and a second gel layer, such that, when viewed from the opening towards the housing space, the electrode comprises the gel layer, the capacitive layer, the current feeder, the second capacitive layer and the second gel layer.

10. Capacitive electrode according to claim 1, wherein the electrode comprises a second gel layer, wherein, when viewed from the opening towards the housing space and the bottom housing wall, the electrode comprises the gel layer, the capacitive layer, the current feeder and the second gel layer.

11. Capacitive electrode according to claim 1, wherein the housing comprises at least one side wall, and wherein a gel layer is provided in the housing space adjacent the at least one side wall.

12. Capacitive electrode according to claim 1, wherein the current feeder is integrated in the capacitive layer, wherein the current feeder preferably extends in direction substantially parallel to the opening in the capacitive layer.

13. Capacitive electrode according to claim 1, wherein the gel comprises a salt composition, such as NaCl, wherein the composition is preferably a solution in the range of 0.1 M<salt<6 M.

14. Membrane-based device for performing a membrane-based process, such as electrodialysis and/or reverse electrodialysis, the device comprising: at least one electrode according to claim 1; a number membranes that are stacked to form a stack of membranes, wherein the at least one electrode is positioned adjacent to an end membrane of the membrane stack such that the opening and/or gel layer of the electrode are in contact with the end membrane.

15. Method for manufacturing a capacitive electrode for a membrane-based process, the method comprising the steps of: providing an electrode housing comprising: a number of housing walls that enclose a housing space; and an opening that is operatively connected to the housing space, and wherein the opening is configured to be positioned adjacent an end membrane of a membrane stack; providing a current feeder to the electrode housing, wherein the current feeder comprises a connector that extends at least partially outside the electrode housing; providing a capacitive layer to the electrode housing; applying a gel layer, such that the gel layer is in contact with the capacitive layer, wherein the gel layer is applied near or in the opening and seals the opening of the electrode housing, or wherein the gel layer is applied near a bottom end of the housing which is opposite the opening.

16. Method according to claim 15, wherein the step of providing a capacitive layer to the electrode housing comprises: providing a slurry of water and activated carbon; applying the slurry on the current feeder such that the slurry and the current feeder are in electrical contact with each other; drying the slurry to form a flexible, moist capacitive layer.

17. Method according to claim 15, wherein the step of applying the gel layer comprises applying a liquid gel on top of the capacitive layer, and wherein the step of applying the gel layer optionally also comprises applying a filter paper layer between the gel and the capacitive layer.

Description

[0103] Further advantages, features and details of the invention are elucidated on the basis of preferred embodiments thereof, wherein reference is made to the accompanying drawings, in which:

[0104] FIGS. 1A, 1B show a cross sectional view of a first example of a capacitive electrode according to the invention;

[0105] FIGS. 2A, 2B show a cross sectional view of a second example of a capacitive electrode according to the invention;

[0106] FIGS. 3A, 3B show a cross sectional view of a third example of a capacitive electrode according to the invention;

[0107] FIGS. 4A, 4B show a cross sectional view of a fourth example of a capacitive electrode according to the invention;

[0108] FIGS. 5A, 5B show a cross sectional view of a fifth example of a capacitive electrode according to the invention;

[0109] FIGS. 6 and 7 show graphical data concerning experiments with a capacitive electrode according to the invention; and

[0110] FIG. 8 shows an example of a method according to the invention.

[0111] In a first example, capacitive electrode 2 comprises housing 4 with housing walls 6, 8 and opening 10 that together delineate housing space 12. In this example, housing 4 is a housing in which housing wall 6 is side wall 6 and housing wall 8 forms bottom wall 8. Housing walls 6, 8 together enclose housing space 12, while opening 10 provides access to housing space 12.

[0112] Furthermore, opening 10 is delineated by end section 14 of end wall 6, which end section is configured to be adjacent to end membrane 16 of a membrane stack. In this example, end membrane 16 is a CEM-membrane. Naturally, it may also be a different type of membrane, depending on the configuration of the membrane stack to which the capacitive electrode is connected. Moreover, it may even be a flow compartment of the membrane stack.

[0113] Housing space 12, when viewed in first direction x that is parallel to central axis A, subsequently comprises gel layer 18, capacitive layer 20, which in this example is manufactured from (powdered) activated carbon, and current feeder 22 with connector 24. Gel layer 18 extends in second direction y, which is perpendicular to first direction x, over the entire surface area of housing space 12. As such, gel layer 18 forms a seal between end membrane 16 and capacitive layer 20 in housing space 12 (see FIGS. 1A, 1B). Capacitive layer 20 extends directly adjacent to gel layer 18 in second direction y over the entire surface of housing space 18 (see FIG. 1A) or a central part of housing space 18 (see FIG. 1B). In an example (see FIG. 1B) in which capacitive layer 20 extends over at least a central part of housing space 12, a gel layer 32 is provided between the circumference of capacitive layer 20 and the internal side 6a of housing wall 6. In this case, capacitive layer 20 is encapsulated by gel layer 18, current feeder 22 and the gel layer 32 positioned next to capacitive layer 20. Current feeder 22 is in this example positioned adjacent with and directly in electrical contact with capacitive layer 20 and, on an opposite side, with bottom wall 8 of housing 4. Bottom wall 8 in this example is provided with an opening through which connector 24 extends. Connector 24 is connected to, or integrally formed with, current feeder 22 and forms a connection to connect an external power source or power load/sink to current feeder 22. As such, a direct electrical connection exists between connector 24 and current feeder 22, as well as between current feeder 22, via capacitive layer 20 and gel layer 18. In this example (FIG. 1B), gel layer 18 is further provided with reinforcement layer 26 that enhances stability and rigidity of gel layer 18. Furthermore, in this example porous separator layer 28, which in this example is filter paper layer 28, is provided between gel layer 18 and capacitive layer 20. It is noted that reinforcement layer 26 and/or separator layer 28 may be obviated, since they are not essential for capacitive electrode 2.

[0114] In a second example, capacitive electrode 102 comprises housing 104 with housing walls 106, 108 and opening 110 that together delineate housing space 112. In this example, housing 104 is a housing in which housing wall 106 is side wall 106 and housing wall 108 forms bottom wall 108.

[0115] Housing walls 106, 108 together enclose housing space 112, while opening 110 provides access to housing space 112.

[0116] Furthermore, opening 110 is delineated by end section 114 of end wall 106, which end section is configured to be adjacent to end membrane 116 of a membrane stack. In this example, end membrane 116 is a CEM-membrane. Naturally, it may also be a different type of membrane, depending on the configuration of the membrane stack to which the capacitive electrode is connected. Moreover, it may even be a flow compartment of the membrane stack.

[0117] Housing space 112 when viewed in first direction x that is parallel to central axis A, subsequently comprises gel layer 118, capacitive layer 120, which in this example is manufactured from (powdered) activated carbon, current feeder 122 with connector 124 and gel layer 130. Gel layer 118 extends in second direction y, which is perpendicular to first direction x, over the entire surface area of housing space 112. As such, gel layer 118 forms a seal between end membrane 116 and capacitive layer 120 in housing space 112 (see FIG. 2A). Capacitive layer 120 extends directly adjacent to and in contact with gel layer 118 in second direction y over the entire surface of housing space 118 (see FIG. 2A) or a central part of housing space 118 (see FIG. 2B). In the example of FIG. 2B, in which capacitive layer 120 extends over at least a central part of housing space 112, a gel layer 132 is provided between the circumference of capacitive layer 120 and the internal side of housing wall 106. In this case, capacitive layer 120 is encapsulated by gel layer 118, current feeder 122 and the gel positioned next to capacitive layer 120. Current feeder 122 is in this example positioned adjacent with and directly in contact with capacitive layer 120 and, on an opposite side, with second gel layer 130. As such, current feeder 122 and capacitive layer 120 are completely encapsulated in a gel layer comprising gel layers 118, 130 as well as the layer 132 next to side wall 106. Second gel layer 130 is further in contact with bottom wall 108 of housing 104.

[0118] Bottom wall 108 in this example is provided with an opening through which connector 124 extends. Connector 124 extends through gel layer 130 and is connected to, or integrally formed with, current feeder 122 and forms a connection to connect an external power source or power sink to current feeder 122. As such, a direct electrical connection exists between connector 124 and current feeder 122, as well as between current feeder 122, capacitive layer 120 and gel layer 118.

[0119] In a third example, capacitive electrode 202 comprises housing 204 with housing walls 206, 208 and opening 210 that together delineate housing space 212. In this example (see FIGS. 3A, 3B), housing 204 is a housing in which housing wall 206 is side wall 206 and housing wall 208 forms bottom wall 208. It is noted that housing 204 may have different shapes, including cylindrical, hexagonal, rectangular or square. Housing walls 206, 208 together enclose housing space 212, while opening 210 provides access to housing space 212.

[0120] Furthermore, opening 210 is delineated by end section 214 of end wall 206, which end section is configured to be adjacent to end membrane 216 of a membrane stack. In this example, end membrane 216 is a CEM-membrane. Naturally, it may also be a different type of membrane, depending on the configuration of the membrane stack to which the capacitive electrode is connected. Moreover, it may even be a flow compartment of the membrane stack.

[0121] Housing space 212, when viewed in first direction x that is parallel to central axis A, subsequently comprises gel layer 218, capacitive layer 220, which in this example is manufactured from (powdered) activated carbon and gel layer 230. Gel layer 218 extends in second direction y, which is perpendicular to first direction x, over the entire surface area of housing space 212. As such, gel layer 218 forms a seal between end membrane 216 and capacitive layer 220 in housing space 212 (see FIG. 3A). Capacitive layer 220 extends directly adjacent to and in contact with gel layer 218 in second direction y over the entire surface of housing space 218 (see FIG. 3A) or a central part of housing space 218 (see FIG. 3B). In the example of FIG. 3B, in which capacitive layer 220 extends over at least a central part of housing space 212, gel layer 232 is provided between the circumference of capacitive layer 220 and the internal side of housing wall 206. In this case, capacitive layer 220 is encapsulated by gel layers 218, 232 and 230. Current feeder 222 in this example is positioned inside capacitive layer 220 and is provided with two connectors 224 which extend from capacitive layer 220 through gel layer 218 towards and over end section 214 to outside housing 204. As such, connectors 224 in this example extends between end section 214 and the membrane stack that is positioned against it (not shown) to outside housing 204. It is noted that in this example, connectors 224 are integral part of current feeder 222.

[0122] Second gel layer 230 is further in contact with bottom wall 208 of housing 204. Bottom wall 208 in this example is a completely closed bottom 208.

[0123] In a fourth example (see FIGS. 4A, 4B), capacitive electrode 302 comprises housing 304 with housing walls 306, 308 and opening 310 that together delineate housing space 312. In this example (see FIGS. 4A, 4B), housing 304 is a housing in which housing wall 306 is side wall 306 and housing wall 308 forms bottom wall 308. It is noted that housing 304 may have different shapes, including cylindrical, rectangular or square. Housing walls 306, 308 together enclose housing space 312, while opening 310 provides access to housing space 312.

[0124] Furthermore, opening 310 is delineated by end section 314 of end wall 306, which end section is configured to be adjacent to end membrane 316 of a membrane stack. In this example, end membrane 316 is a CEM-membrane. Naturally, it may also be a different type of membrane, depending on the configuration of the membrane stack to which the capacitive electrode is connected. Moreover, it may even be a flow compartment of the membrane stack.

[0125] Housing space 312, when viewed in first direction x that is parallel to central axis A, subsequently comprises gel layer 318, capacitive layer 320, which in this example is manufactured from (powdered) activated carbon and gel layer 330. Gel layer 318 extends in second direction y, which is perpendicular to first direction x, over the entire surface area of housing space 312. As such, gel layer 318 forms a seal between end membrane 316 and capacitive layer 320 in housing space 312 (see FIG. 4A). Capacitive layer 320 extends directly adjacent to and in contact with gel layer 318 in second direction y over the entire surface of housing space 318 (see FIG. 4A) or a central part of housing space 318 (see FIG. 4B). In the example of FIG. 4B, in which capacitive layer 320 extends over at least a central part of housing space 312, gel layer 332 is provided between the circumference of capacitive layer 320 and the internal side 306a of housing wall 306. In this case, capacitive layer 320 is encapsulated by gel layers 318, 332 and 330. Current feeder 322 in this example is positioned inside capacitive layer 320 and is provided with two connectors 324 which extend from capacitive layer 320 through side wall 306 and adjacent gel layer 332 to outside housing 304. Second gel layer 330 is further in contact with bottom wall 308 of housing 304.

[0126] Bottom wall 308 in this example is a completely closed bottom 308.

[0127] Furthermore, the example shown in FIG. 4B also shows drainage channel 334, which comprises first part 336 that extends partially or completely along the circumference of housing 304 in or near end section 314 and second part 338, which forms channel 338 that extends from first part 336 through side wall 306 towards and through bottom wall 308 to outside housing 304 to remove excess water from housing 304. Channel 338 may also be positioned on an outer wall of side wall 306 rather than in side wall 306. It is noted that drainage channel 334 may also be provided in any of the other examples in a similar manner.

[0128] In a fifth example (see FIGS. 5A, 5B), capacitive electrode 402 comprises housing 404 with housing walls 406, 408 and opening 410 that together delineate housing space 412. In this example (see FIGS. 5A, 5B), housing 404 is a housing in which housing wall 406 is side wall 406 and housing wall 408 forms bottom wall 408. It is noted that housing 404 may have different shapes, including cylindrical, rectangular or square. Housing walls 406, 408 together enclose housing space 412, while opening 410 provides access to housing space 412.

[0129] Furthermore, opening 410 is delineated by end section 414 of end wall 406, which end section is configured to be adjacent to end membrane 416 of a membrane stack. In this example, end membrane 416 is a CEM-membrane. Naturally, it may also be a different type of membrane, depending on the configuration of the membrane stack to which the capacitive electrode is connected. Moreover, it may even be a flow compartment of the membrane stack.

[0130] Housing space 412, when viewed in first direction x that is parallel to central axis A, subsequently comprises current feeder 422, capacitive layer 420, which in this example is manufactured from (powdered) activated carbon, and gel layer 430. Current feeder 422 extends in second direction y, which is perpendicular to first direction x, over the entire surface area of housing space 412 or over a part thereof. Current feeder 422 in this example extends parallel to end membrane 416 and over end section 414 to outside housing 402. In this example, end section 414 is provided with conductor 440 which extends over at least a part of the circumference of housing 402. In this example, conductor 440 is copper ring 440 that extends in groove 442 in end section 414 along the entire circumference of housing 402. Part of copper ring 440 extends above the surface of end section 414 and is in direct electrical contact with current feeder 422. Capacitive layer 420 extends in second direction y directly adjacent to and in contact with current feeder 422 and, on an opposite side, with gel layer 430. In the example of FIG. 5B, in which capacitive layer 420 extends over at least a central part of housing space 412, gel layer 432 is provided between the circumference of capacitive layer 420 and the internal side 406a of housing wall 406. In this case, capacitive layer 420 is encapsulated by gel layers 430 and 432 as well as by current feeder 422.

[0131] In an example the method 1000 for manufacturing a capacitive electrode according to the invention comprises the steps of providing 1002 providing an electrode housing having a number of housing walls that enclose a housing space and an opening that is operatively connected to the housing space. In a subsequent step, the method comprises the step of providing 1004 a current feeder to the electrode housing, wherein the current feeder comprises a connector that extends at least partially outside the electrode housing and providing 1006 a capacitive layer to the electrode housing and applying 1008 a gel layer near or in the opening, such that the gel layer is in contact with the capacitive layer and seals the opening.

Experimental Results

[0132] An embodiment of the capacitive electrode according to the invention was tested in a lab-test using an in-house designed 10×10 cm.sup.2 lab cross-flow membrane assembly operated in capacitive reverse electrodialysis (CRED) mode with 30 cells (=cell pairs; N=30).

[0133] The membrane assembly comprised ion exchange membranes (cation exchange membranes and anion exchange membranes) stacked in a membrane stack, which was provided with side-plates and two end-plates, which were positioned at opposite ends of the membrane stack. The end plates were formed by the capacitive electrodes according to the invention. The electrode compartment comprised an activated carbon layer, a gel layer and a current feeder/collector. A platinum coated titanium mesh electrode was used as current feeder. It should be noted that for economic reasons the preferred current feeder may be constructed from mainly carbon/graphite based materials.

[0134] The low concentration feed solution had a salinity of 1.0 gram/liter NaCL (conductivity of ˜2.0 mS/cm at a temperature of approximately 23° C.) and the high concentration feed solution had a salinity of 32.6 gram/liter (conductivity of ˜49.6 mS/cm at a temperature of approximately 26° C.).

[0135] The measurements were conducted at an average temperature of approximately 25 degrees ° C. using a potentiostat. The feed solutions were made using NaCl and tap water.

[0136] The gel layer was made of using an agar-agar gel powder and an 3 M NaCl solution. The activated carbon layer was made by performing the steps of: [0137] making a paste/slurry using activated carbon powder (Norit) and demi-water; [0138] mixing the components, and leaving the mixture to settle for a period of 15 minutes before further processing; [0139] depositing the paste/slurry on top of the current feeder in the electrode compartment; [0140] casting the mixture to the required layer thickness; [0141] drying the paste/slurry (using an electric blow dryer) until the activated carbon layer contained a low amount of moisture (i.e. slightly moist).

[0142] In order to prepare the slurry, activated carbon powder and water were mixed with a predetermined content ratio, which preferably is a content ratio between activated carbon powder and demi-water of 1:2 (w/w). For the first experiment, 50 grams of demi-water was added to 25 grams of activated carbon powder (see also FIG. 6). For the second experiment a content ratio of 1:2 (w/w) (see also FIG. 7), with 50 grams of AC-powder and 100 grams of water was used. The drying was performed to the amount that the top layer was dry or at most moist in order to prevent mixing with the subsequently applied gel layer. It is noted that no binder was added during any of the steps in the experiment.

[0143] The gel layer was prepared using agar-agar powder (Boom B.V.), demi-water and NaCl (ESCO food grade, 99.8% purity). The ratio between agar-agar and demi-water is 1:50 (w/w). Thus, 2 grams of agar-agar power is boiled in 100 ml of a 3 M NaCl solution for 5-8 minutes during continuous stirring at 500 rpm. After removing air bubbles from the solution, the prepared gel was poured on top of the activated carbon layer and subsequently left to cool down.

[0144] The results from the experiments were captured in a CRED performance graph showing two power producing cycles with 25 g activated carbon (FIG. 6) and double the amount, thus 50 g of activated carbon (FIG. 7). The figures (see FIGS. 6, 7) show a substantially linear trend between the thickness of the capacitive layer and the voltage drop, which is an indication of the electrode capacity. The experiments were performed with a 300 ml/minute flow rate, a current density of 20 A/m.sup.2 and respectively a 32.6 gram/liter versus 1.0 gram/liter NaCl solution at about 25° C. The present invention is by no means limited to the above described preferred embodiments thereof.

[0145] The rights sought are defined by the following claims, within the scope of which many modifications can be envisaged.