ELECTROCHEMICAL PUMP UNIT OF MESH COMBINED ELECTRODE

Abstract

The electrochemical pump unit of mesh combined electrode of the present invention is connected to a drug injection container for operation, when it is connected to the power supply, the cathode (or anode) enters into electrochemical reaction with the electrolyte of the superabsorbent material layer through the mesh electrode to release a first gas, the first gas flows through the screen meshes of mesh electrode immediately without obstruction loss; the anode (or cathode) enters into electrochemical reaction with the electrolyte on the opposite side of superabsorbent material layer through the plane electrode to release a second gas, the second gas flows through the inter fibrous small space/channels of superabsorbent material layer and the screen meshes of mesh electrode; as the first gas and the second gas increase, the piston is pushed, and the medicament is pushed.

Claims

1. A electrochemical pump unit of mesh combined electrode is connected to a power supply, said device includes: a mesh electrode, connected to a first polarity of the power supply, the electrochemical reaction generates a gas which is a first gas, said first gas can flow through the screen meshes of said mesh electrode without obstruction loss; a second electrode, connected to a second polarity of the power supply, the gas generated by electrochemical reaction is a second gas, said second gas flows through the inter fibrous small space/channels of said superabsorbent material layer and said screen meshes of the mesh electrode; a superabsorbent material layer, located between said mesh electrode and said second electrode, said superabsorbent material layer stores an electrolyte; and an outer casing, wrapping said mesh electrode, said second electrode and said superabsorbent material layer, said outer casing includes a gas outlet, the first gas and the second gas are discharged from said gas outlet.

2. The electrochemical pump unit of mesh combined electrode defined in claim 1, wherein said second electrode includes a plane electrode composed of a substrate layer and an electrode layer, said substrate layer includes a flexible substrate.

3. The electrochemical pump unit of mesh combined electrode defined in claim 1, wherein there are upper and lower outer layers of said second electrode, connected to said superabsorbent material layer and said mesh electrode inwards respectively, there is one layer of said mesh electrode, the rest has two layers vertically corresponding to each other.

4. The electrochemical pump unit of mesh combined electrode defined in claim 2, wherein said substrate layer of said second electrode is a porous substrate.

5. The electrochemical pump unit of mesh combined electrode defined in claim 2, wherein said substrate layer is connected to said electrode layer, said superabsorbent material layer and said mesh electrode respectively towards the upper and lower faces, there is one substrate layer, the rest has two layers vertically corresponding to each other.

6. The electrochemical pump unit of mesh combined electrode defined in claim 1, wherein said outer casing is connected to a drug injection container for operation, said first gas and said second gas are discharged from said gas outlet to push the piston of the drug injection container, the medicament is pushed indirectly.

7. The electrochemical pump unit of mesh combined electrode defined in claim 1, wherein said second polarity includes: rectangular electrode (one electrode), interdigital electrode (two electrodes), cathode-anode-reference electrode (three electrodes).

8. A electrochemical pump unit of mesh combined electrode is connected to a power supply, said device includes: a mesh electrode, connected to a first polarity of said power supply, the electrochemical reaction generates a gas which is a first gas; a second electrode, connected to a second polarity of said power supply which is reelable porous material, the gas generated by electrochemical reaction is a second gas; a superabsorbent material layer, located between said mesh electrode and said second electrode, said superabsorbent material layer stores an electrolyte; the outer layer is said mesh electrode, the middle layer is said superabsorbent material layer and the inner layer is said second electrode, the three layers are rolled up to form a winding cylindrical pump; and an outer casing, wrapping the winding cylindrical pump, said outer casing includes a gas outlet, said first gas and said second gas are discharged from said gas outlet.

9. The electrochemical pump unit of mesh combined electrode defined in claim 8, wherein said outer casing is connected to a drug injection container for operation, said first gas and said second gas are discharged from said gas outlet to push the piston of said drug injection container, the medicament is pushed indirectly.

10. The electrochemical pump unit of mesh combined electrode defined in claim 8, wherein said second electrode comprises a plurality of screen meshes formed by multiple cross and interconnected mesh lines.

11. The electrochemical pump unit of mesh combined electrode defined in claim 8, wherein said second polarity includes: rectangular electrode (one electrode), interdigital electrode (two electrodes), cathode-anode-reference electrode (three electrodes).

12. A electrochemical pump unit of mesh combined electrode is connected to a power supply, said device includes: a mesh electrode, connected to a first polarity of said power supply, the electrochemical reaction generates a gas which is a first gas; a second electrode, connected to a second polarity of said power supply which is reelable material, the gas generated by electrochemical reaction is a second gas; a superabsorbent material layer, located between said mesh electrode and said second electrode, said superabsorbent material layer stores an electrolyte; the outer layer is said second electrode, the middle layer is said superabsorbent material layer and the inner layer is said mesh electrode, the three layers are rolled up to form a hollow cylindrical pump; and an outer casing, wrapping the hollow cylindrical pump, said outer casing includes a gas outlet, said first gas and said second gas are discharged from the center of said hollow cylindrical pump through said gas outlet.

13. The electrochemical pump unit of mesh combined electrode defined in claim 12, wherein said outer casing is connected to a drug injection container for operation, said first gas and said second gas are discharged from said gas outlet to push the piston of said drug injection container, the medicament is pushed indirectly.

14. The electrochemical pump unit of mesh combined electrode defined in claim 12, wherein a porous gas pipe is installed in the center of said hollow cylindrical pump, said gas is led to said gas outlet through a plurality of gas holes in said porous gas pipe wall.

15. The electrochemical pump unit of mesh combined electrode defined in claim 13, wherein said outer casing can be designed as separate type, it is inserted in the drug injection container before use and sealed with an airtight spacer.

16. The electrochemical pump unit of mesh combined electrode defined in claim 12, wherein said second polarity includes: rectangular electrode (one electrode), interdigital electrode (two electrodes), cathode-anode-reference electrode (three electrodes).

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0021] [FIG. 1] Schematic diagram of electrochemical pump of mesh combined electrode.

[0022] [FIG. 2] Flow diagram of electrochemical pump unit of mesh combined electrode.

[0023] [FIG. 3] Schematic diagram of electrochemical pump connected to drug injection container.

[0024] [FIG. 4] Schematic diagram of three embodiments of plane electrode.

[0025] [FIG. 5] Schematic diagram of electrochemical pumps of different combinations.

[0026] [FIG. 6] Schematic diagram of Roll-up electrochemical pump of mesh combined electrode.

[0027] [FIG. 7] Schematic diagram of winding electrochemical pump connected to drug injection container.

[0028] [FIG. 8] Schematic diagram of circular electrochemical pump unit of mesh combined electrode.

[0029] [FIG. 9] Electrode performance test—current diagram,

[0030] [FIG. 10] Electrode performance test—volume diagram.

DETAILED DESCRIPTION OF THE INVENTION

[0031] An embodiment of the present invention, an electrochemical pump of mesh combined electrode 100 is connected to a power supply 1, the electrochemical pump 100 is shown in [FIG. 1] and [FIG. 5], including:

[0032] A mesh electrode 2, connected to a first polarity of the power supply 1, the electrochemical reaction generates a gas 6 which is a first gas (e.g. H2), the first gas can flow through the screen meshes of the mesh electrode 2 without obstruction loss;

[0033] A second electrode 3, connected to a second polarity of the power supply 1, the second electrode 3 in this embodiment is a plane electrode 30 composed of a substrate layer 31 and an electrode layer 32, the electrochemical reaction generates the gas 6 which is a second gas (e.g. O.sub.2), the second gas flows through the inter fibrous small space/channels of the superabsorbent material layer 4 and the screen meshes of the mesh electrode 2;

[0034] A superabsorbent material layer 4, located between the mesh electrode 2 and the second electrode 3, the superabsorbent material layer 4 stores an electrolyte (DI water with salts, e.g. NaCl, CaCl.sub.2, KCl . . . ); and

[0035] The superabsorbent material layer 4 is sandwiched in between the mesh electrode 2 and the second electrode 3, the first gas and the second gas are discharged from the mesh electrode 2.

[0036] The electrochemical pump of mesh combined electrode 100 of the present invention can provide a gas discharge rate several times higher than the bi electrode structure of the present technology, so as to reduce the voltage and power consumption of electrochemical system,

[0037] In the said embodiment, if the first polarity is positive pole (anode), the second polarity is negative pole (cathode); if the first polarity is negative pole (cathode), the second polarity is positive pole (anode).

[0038] Preferably, the electrolyte materials include hydroxide electrolyte, aqueous solution of water and salt, acid or alkali, and non aqueous ion solution, ethanol.

[0039] Preferably, the mesh electrode 2 comprises a plurality of screen meshes formed by multiple cross and interconnected mesh lines.

[0040] Preferably, the power supply I includes mercury cell, lithium battery, carbon-zinc battery and power supply which can provide a voltage.

[0041] Preferably, the mesh electrode materials include Pt, Ti, Au, IrO2, Ag, C and Pd and any electrode materials.

[0042] An embodiment of the preset the second electrode 3 includes the substrate layer 31 and the electrode layer 32, the substrate layer 31 can be a hard substrate, a flexible substrate or a porous substrate,

[0043] Preferably, the substrate layer 31 is the hard substrate material, including hard glass substrate, sapphire substrate, transparent ceramic substrate or other appropriate substrates; the substrate layer is the flexible substrate material, including thin glass substrate or polymer flexible substrate.

[0044] Preferably, the materials of the electrode layer 32 include Pt, Ti, Au, IrO2, Ag, C and Pd and any electrode materials.

[0045] Preferably, the material of the superabsorbent material layer 4 can be any absorbent material, e.g. solid phase of gel, cotton, superabsorbent polymer, sponge material or an arbitrary combination (e.g. gel absorbed in sponge); its function is to maintain the uniform distribution of electrolyte in the entire superabsorbent material layer 4, and to maintain contact with the electrode.

[0046] An embodiment of the present invention, the second electrode 3 can be the mesh electrode 2 or the second electrode 3 composed of screen mesh shape and sire different from the mesh electrode 2.

[0047] Preferably, the gas 6 generated by the first polarity and the second polarity under electrochemical action includes the combination of hydrogen, oxygen and/or CO2; for example, the electrolysis of water generates oxygen and hydrogen, the electrolysis of ethanol generates CO2 and hydrogen; the power consumption of electrolytic pump can be reduced by using ethanol, the battery lifetime is extended.

[0048] An embodiment of the present invention, as shown in [FIG. 4], the second electrode 3 includes the plane electrode 30, e.g. rectangular electrode (one electrode), interdigital electrode (two electrodes), cathode-anode-reference electrode (three electrodes), but the present invention is not limited to them.

[0049] Preferably, the screen meshes formed by multiple mesh lines of the mesh electrode 2 include interdigital, square, rectangular, quadrangular, honeycomb and polygonal meshes.

[0050] An embodiment of the present invention, an electrochemical pump of mesh combined electrode 200 is connected to a power supply shown in the middle part of [FIG. 5]:

[0051] A mesh electrode 2, connected to a first polarity of the power supply 1, the electrochemical reaction generates a gas 6 which is a first gas;

[0052] A second electrode 3. the second electrode 3 in this embodiment has two layers, it is a plane electrode 30 composed of a substrate layer 31 and an electrode layer 32, two layers of the plane electrode 30 are connected to a second polarity of the power supply 1 respectively, the electrochemical reaction generates the gas 6 which is a second gas;

[0053] A superabsorbent material layer 4, the superabsorbent material layer 4 has two layers, storing an electrolyte; and upper and lower outer layers are the substrate layer 31 of the second electrode 3, connected to the electrode layer 32, the superabsorbent material layer 4 and the mesh electrode 2 inwards respectively, the mesh electrode 2 has one layer, the rest has two layers vertically corresponding to each other; the first gas and the second gas are discharged from the side edge through the inter fibrous small space/channels of the superabsorbent material layer 4.

[0054] In the said embodiment, the substrate layer 31 of two layers of the plane electrode 30 is a porous substrate, the first gas and the second gas can be discharged through the holes in the substrate layer 31.

[0055] An embodiment of the present invention, electrochemical pump of mesh combined electrode 300 is connected to a power supply 1, as shown in the lower part of [FIG. 5]:

[0056] A mesh electrode 2, there are two layers of the mesh electrode 2 in this embodiment, connected to a first polarity of the power supply respectively, the electrochemical reaction generates a gas 6 which is a first gas, the first gas can flow through the screen meshes of the upper and lower mesh electrodes 2 without obstruction loss;

[0057] A second electrode 3, the second electrode 3 in this embodiment is a double sided plane electrode 30 composed of a substrate layer 31 and upper and lower electrode layers 32, connected to a second polarity of the power supply 1, the electrochemical reaction generates the gas 6 which is a second gas, the second gas flows through the inter fibrous small space/channels of the upper and lower superabsorbent material layers 4 and through the screen meshes of the upper and lower mesh electrodes 2;

[0058] A superabsorbent material layer 4, the superabsorbent material layer 4 has two layers, storing an electrolyte; and upper and lower outer layers are connected to the superabsorbent material layer 4, the electrode layer 32 and the substrate layer 31 inwards respectively for the mesh electrode 2, there is one of the substrate layer 31, the rest has two layers vertically corresponding to each other; the first gas and the second gas are discharged from the upper and lower mesh electrodes 2 and periphery.

[0059] In the said embodiment, the operation process is described below: [0060] B1. The mesh electrode 2 is connected to a first polarity of a power supply 1, two layers of the electrode layer 32 are connected to a second polarity anode of the power supply 1; [0061] B2. The cathode enters into electrochemical reaction with the electrolyte on one side of the upper superabsorbent material layer 4 through the upper mesh electrode 2 to release a first gas; when the first gas is released from the end of the upper superabsorbent material layer 4 near the upper mesh electrode 2, it will be released upwards through the screen meshes of the upper mesh electrode 2 immediately without obstruction loss; [0062] B3. The cathode enters into electrochemical reaction with the electrolyte on one side of the lower superabsorbent material layer 4 through the lower mesh electrode 2 to release a first gas; when the first gas is released from the end of the lower superabsorbent material layer 4 near the lower mesh electrode 2, it will be released down wards through the screen meshes of the lower mesh electrode 2 immediately without obstruction loss; [0063] B4. The anode enters into electrochemical reaction with the electrolyte on one side of the upper superabsorbent material layer 4 through the upper electrode layer 32 to release a second gas; when the second gas is released from the end of the upper superabsorbent material layer 4 near the upper electrode layer 32, it is released from the side edge or/and through the inter fibrous small space/channels of the upper superabsorbent material layer 4 and released upwards through the screen meshes of the upper mesh electrode 2; [0064] B5. The anode enters into electrochemical reaction with the electrolyte can one side of the lower superabsorbent material layer 4 through the lower electrode layer 32 to release the second gas; when the second gas is released from the end of the lower superabsorbent material layer 4 near the lower electrode layer 32, it is released from the side edge or/and through the inter fibrous small space/channels of the lower superabsorbent material layer 4 and released downwards through the screen meshes of the lower mesh electrode 2; and [0065] B6. The electrochemical pump of mesh combined electrode 300 releases the gas 6 from periphery.

[0066] An embodiment of the present invention, an electrochemical pump of mesh combined electrode is connected to a power supply 1, as shown in [FIG. 6]:

[0067] A mesh electrode 2, connected to a first polarity of the power supply 1, the electrochemical reaction generates a gas 6 which is a first gas;

[0068] A second electrode 3, connected to a second polarity of the power supply 1, the second electrode 3 in this embodiment is a plane electrode 30 composed of a substrate layer 31 of reelable porous substrate material and an Roll-up electrode layer 32, the gas 6 generated by electrochemical reaction is a second gas;

[0069] A superabsorbent material layer 4, located between the mesh electrode 2 and the second electrode 3, the superabsorbent material layer 4 stores an electrolyte; and

[0070] The outer layer is the mesh electrode 2, the middle layer is the superabsorbent material layer 4 and the inner layer is the second electrode 3, the three layers are rolled up to form a winding cylindrical pump 400, the first gas and the second gas in the inner layer flow through the inter fibrous small space/channels of the superabsorbent material layer 4 and the holes in the substrate layer 31, and then they are discharged from the outer mesh electrode 2.

[0071] In the said embodiment, the second electrode 3 of the winding cylindrical pump 400 can be composed of screen mesh shape and size different from or identical to the mesh electrode 2; this structure can reduce the obstruction loss when the first gas and the second gas are discharged from the inner layer.

[0072] In the said embodiment, as shown in [FIG. 7], an electrochemical pump unit of mesh combined electrode 400A includes the winding cylindrical pump 400 and an outer casing 5; the electrochemical pump of mesh combined electrode 400A is used with a drug injection container 9, the gas 6 generated by electrochemical action flows through a gas outlet 51 of the outer casing 5 into a gas cell 91 of the drug injection container 9, the gas cell 91 expands as the gas 6 increases and pushes a piston 92, indirectly pushing a medicament 93.

[0073] As shown in [FIG. 7], the electrochemical pump unit of mesh combined electrode 400A is connected to the drug injection container 9 by an airtight spacer 8, the airtightness of the gas cell 911 is enhanced.

[0074] An embodiment of the present invention, an electrochemical pump of mesh combined electrode is connected to a power supply 1, as shown in [FIG. 8]:

[0075] A mesh electrode 2, connected to a first polarity of the power supply 11, the electrochemical reaction generates a gas 6 which is a first gas;

[0076] A second electrode 3, connected to a second polarity of the power supply 1, the second electrode 3 in this embodiment is a plane electrode 30 composed of a substrate layer 31 of reelable substrate material and an Roll-up electrode layer 32, the gas 6 generated by electrochemical reaction is a second gas;

[0077] A superabsorbent material layer 4, located between the mesh electrode 2 and the second electrode 3, the superabsorbent material layer 4 stores an electrolyte; and

[0078] The outer layer is the second electrode 3, the middle layer is the superabsorbent material layer 4 and the inner layer is the mesh electrode 2, the three layers are rolled up to form a hollow cylindrical pump 500, the first gas can flow through the screen meshes of the mesh electrode 2 to the center without obstruction loss, and the second gas flows through the inter fibrous small space/channels of the superabsorbent material layer 4 and the screen meshes of the mesh electrode 2 to the center.

[0079] In the said embodiment, as shown in [FIG. 7], an electrochemical pump unit of mesh combined electrode 500A includes the hollow cylindrical pump 500 and an outer casing 5; the electrochemical pump of mesh combined electrode 500A is used with a drug injection container 9, the gas 6 generated by electrochemical action flows into a gas cell 91 of the drug injection container 9 through a gas outlet 51 of the outer casing 5 from the center of the hollow cylindrical pump 500, the gas cell 91 expands as the gas 6 increases and pushes a piston 92, indirectly pushing a medicament 93.

[0080] In the said embodiment, a porous gas pipe 7 is installed in the middle of the hollow cylindrical pump 500, the gas 6 is led to the gas outlet 51 through a plurality of gas holes 71 in the wall of the porous gas pipe 7.

[0081] In the said embodiment, the porous gas pipe 7 can protrude from the outer casing 5. it can be inserted in the drug injection container 9 and sealed with an airtight spacer 8,

[0082] Preferably, the electrochemical pump of mesh combined electrode 500A can be designed as separate type, it is inserted in the drug injection container 9 before use.