CN204122249U - Be separated the electrode structure of microparticle thing, its battery lead plate formed and electrod-array - Google Patents

Abstract

The utility model proposes a kind of electrode structure being separated microparticle thing, its battery lead plate formed and electrod-array, electrode structure comprises anode and negative electrode, anode has anode first surface, negative electrode has negative electrode first surface and both are oppositely arranged, anode first surface has at least one anode protuberance, the top of anode protuberance protrudes from the non-adjacent protuberance part of coupled anode first surface, anode first surface region between two adjacent anode protuberance tops is not in one plane and section is non-rectangle, negative electrode first surface has at least one negative electrode protuberance, the top of negative electrode protuberance protrudes from the non-adjacent protuberance part of coupled negative electrode first surface, negative electrode first surface region between two neighbouring cathode protuberance tops is not in one plane and section is non-rectangle.The structure of anode of the present utility model and negative electrode, improves the electrophoretic force that particle is subject in the electric field, can carry out effective filtering to the particle that molecule particularly can enter lung.

Description

Be separated the electrode structure of microparticle thing, its battery lead plate formed and electrod-array

Technical field

The utility model belongs to material purification, separation technology field, relate to a kind of can the device of Purge gas, solid or liquid, be specifically related to a kind of electrode structure, its battery lead plate formed and electrod-array of being separated microparticle thing.

Background technology

Along with socioeconomic development, consumption and the pollutant discharge amount thereof of one side fossil energy constantly raise, and on the other hand, in order to more live, people require more and more higher to clean environment degree healthiness.In order to tackle the environmental problem that high pollution brings, the Pollutant emission concentration in national subtend air, water and soil proposes more and more stricter requirement.In order to realize the discharge of lower concentration, enterprise's desirability can better cleaner.At present, for the dust granules in air, cleaner has a variety of, comprise mechanical dust collector, electric cleaner, wet scrubber and filtration dust catcher, but above deduster mainly processes to dust larger in air, for small particle, particularly can enter the particle of lung, existing cleaner dust removing effects is not good, uses such cleaner, for the healthy and safe of the public has buried hidden danger.

Utility model content

In order to overcome the defect existed in above-mentioned prior art, the purpose of this utility model is to provide a kind of electrode structure, its battery lead plate formed and electrod-array of being separated microparticle thing, can be separated particle, in dust removal field, can to particle, the particle that particularly can suck carries out effective filtering.

In order to realize above-mentioned purpose of the present utility model, the utility model provides a kind of electrode structure being separated microparticle thing, it comprises anode and negative electrode, described anode has anode first surface, described negative electrode has negative electrode first surface, described anode first surface and negative electrode first surface are oppositely arranged, described anode first surface has at least one anode protuberance, the top of described anode protuberance protrudes from the non-adjacent protuberance part of coupled described anode first surface, anode first surface region between two adjacent anode protuberance tops is not in one plane and section is non-rectangle, described negative electrode first surface has at least one negative electrode protuberance, the top of described negative electrode protuberance protrudes from the non-adjacent protuberance part of coupled described negative electrode first surface, negative electrode first surface region between two neighbouring cathode protuberance tops is not in one plane and section is non-rectangle.

Upon application of a voltage, anode of the present utility model and cathode construction can strengthen the inhomogeneities of electric field, improve the electrophoretic force that particle is subject in the electric field, improve filtering efficiency.

Preferably, described anode protuberance in anode first surface periodic distribution negative electrode protuberance in negative electrode first surface non-periodic distribution; Or described anode protuberance in anode first surface non-periodic distribution negative electrode protuberance in negative electrode first surface periodic distribution; Or anode protuberance in anode first surface periodic distribution and negative electrode protuberance in negative electrode first surface periodic distribution; Or anode protuberance in anode first surface non-periodic distribution and negative electrode protuberance in negative electrode first surface non-periodic distribution.

Multiplely be shaped to preparation and provide multiple choices.

Preferably, described anode protuberance is identical at the distribution period of negative electrode first surface with negative electrode protuberance at the distribution period of anode first surface.

Thus reduce the complexity of structure, more easily prepare.

Preferably, anode first surface region between described two adjacent anode protuberance tops is cylinder, sphere, ellipsoid, curved section moves the cambered surface of formation or moves the cambered surface formed after being connected by many curved sections, and the mobile cambered surface formed after being connected by straightway and/or curved section.

Preferably, negative electrode first surface region between described two neighbouring cathode protuberance tops is cylinder, sphere, ellipsoid, curved section moves the cambered surface of formation or the cambered surface moving and formed that is connected by many curved sections, and the cambered surface moving and formed that is connected by straightway and/or curved section.

Preferably, the cross section in the anode first surface region between described two adjacent anode protuberance tops is semicircle.

Preferably, the cross section in the negative electrode first surface region between described two neighbouring cathode protuberance tops is semicircle.

Multiplely be shaped to preparation and provide multiple choices.

Preferably, described anode protuberance top is just to the part caved in most in the negative electrode first surface region between its two nearest negative electrode protuberances; Described negative electrode protuberance top is just to the part caved in most in the anode first surface region between its two nearest anode protuberances.

This structure makes the inhomogeneities of electric field violent, improves the electrophoretic force that particle is subject in the electric field, improves filtering efficiency.

Preferably, described anode has anode second surface, described anode second surface and described anode first surface shape identical or different, described anode second surface and described anode first surface are symmetrical or asymmetric.

Preferably, described negative electrode has negative electrode second surface, described negative electrode second surface and described negative electrode first surface shape identical or different, described negative electrode second surface and described negative electrode first surface are symmetrical or asymmetric.

Preferably, the distance of described two adjacent anode protuberances is L1, and the distance of described two neighbouring cathode protuberances is L2, and the distance of described negative electrode and positive electrode is greater than 0 and is less than or equal to 10*L3, and described L1, L2 are positive number, and described L3 is the greater in L1 and L2.Adjust the distance and limit, thus ensure that particle can obtain enough large electrophoretic force, improve separative efficiency.

The utility model additionally provides a kind of battery lead plate, formed by the electrode structure of separation microparticle thing described in the utility model, comprise anode part and the cathode portion of interlaced arrangement, described anode part is distributed by anodic cycle described in the utility model and is formed, described cathode portion is distributed by cathode deposition period described in the utility model and is formed, described anode part and cathode portion are set in turn in the one side of insulation support plate or upper and lower two surfaces, described insulation support plate is tabular, cambered surface or hollow cylinder.Adopting electrode plate structure, increase effective separating area, when needing the amount of separate substance to increase, improve separative efficiency.

Preferably, described anode part and cathode portion is measure-alike.The utility model additionally provides a kind of electrod-array, described electrod-array is formed by M group battery lead plate periodic distribution, described battery lead plate anode part parallel connection access positive source, described battery lead plate cathode portion parallel connection access power cathode, described M be greater than 1 positive integer.

Preferably, each anode part described and cathode portion just to or tiltedly right.

Thus make filter area larger, improve filter efficiency, the expansion scope of application.

The utility model additionally provides a kind of battery lead plate, comprises conductor support plate and at the one side of described conductor support plate or the electrode of two sides periodic distribution, described electrode is anode described in the utility model or negative electrode described in the utility model.The utility model additionally provides a kind of electrod-array, described electrod-array is formed by the battery lead plate periodic distribution described in this paragraph of M block, from side, odd number electrode plate in described electrod-array connects power supply one pole, even numbered blocks battery lead plate in described electrod-array connects another pole of power supply, described M be greater than 1 positive integer.

Adopting electrode plate structure, increase effective separating area, when needing the amount of separate substance to increase, improve separative efficiency.Adopt electrod-array to make filter area larger, improve filter efficiency, the expansion scope of application.Additional aspect of the present utility model and advantage will part provide in the following description, and part will become obvious from the following description, or be recognized by practice of the present utility model.

Accompanying drawing explanation

Above-mentioned and/or additional aspect of the present utility model and advantage will become obvious and easy understand from accompanying drawing below combining to the description of embodiment, wherein:

Fig. 1 is the schematic diagram of the utility model electrode structure.

Detailed description of the invention

Be described below in detail embodiment of the present utility model, the example of described embodiment is shown in the drawings, and wherein same or similar label represents same or similar element or has element that is identical or similar functions from start to finish.Being exemplary below by the embodiment be described with reference to the drawings, only for explaining the utility model, and can not being interpreted as restriction of the present utility model.

The utility model provides a kind of electrode structure being separated microparticle thing, and as shown in Figure 1, it comprises anode 1 and negative electrode 2, wherein, anode 1 has anode first surface 3, and negative electrode 2 has negative electrode first surface 4, and anode first surface 3 and negative electrode first surface 4 are oppositely arranged.Anode first surface 3 has at least one anode protuberance 5, the top of anode protuberance 5 protrudes from the non-adjacent protuberance part of coupled anode first surface 3, in the present embodiment, anode protuberance 3 is arbitrary shape in addition to a rectangle, the shape preferably having two arcs caved in be connected to form as shown in Figure 1, the top of anode protuberance can have any shape, and is specifically as follows but is not limited to plane, cambered surface or spininess, preferably adopting spininess.

As shown in Figure 1, anode first surface region between two adjacent anode protuberance 3 tops is not in one plane and section is arbitrary shape in addition to a rectangle, anode first surface region between two adjacent anode protuberance tops is specifically as follows but is not limited to cylinder, sphere, ellipsoid, curved section moves the cambered surface of formation or moves the cambered surface formed after being connected by many curved sections, or by straightway, curved section, the mobile cambered surface formed after straightway is connected with curved section.In the utility model embodiment be more preferably, the cross section in the anode first surface region between two adjacent anode protuberance tops is semicircle.

Negative electrode first surface 4 has at least one negative electrode protuberance 6, the top of negative electrode protuberance 6 protrudes from the non-adjacent protuberance part of coupled negative electrode first surface 4, in the present embodiment, negative electrode protuberance 4 is arbitrary shape in addition to a rectangle, the shape preferably having two arcs caved in be connected to form as shown in Figure 1, the top of negative electrode protuberance can have any shape, and is specifically as follows but is not limited to plane, cambered surface or spininess, preferably adopting spininess.

As shown in Figure 1, negative electrode first surface region between two neighbouring cathode protuberance tops is not in one plane and section is non-rectangle, i.e. arbitrary shape in addition to a rectangle, negative electrode first surface region between two neighbouring cathode protuberance tops is specifically as follows but is not limited to cylinder, sphere, ellipsoid, curved section moves the cambered surface of formation or moves the cambered surface formed after being connected by many curved sections, or by straightway, curved section, the mobile cambered surface formed after straightway is connected with curved section.In the utility model embodiment be more preferably, the cross section in the anode first surface region between two neighbouring cathode protuberance tops is semicircle.

In the present embodiment, the distance of two adjacent anode protuberances is L1, and the distance of two neighbouring cathode protuberances is L2, the distance of negative electrode and positive electrode is greater than 0 and is less than or equal to 10*L3, L1, L2 are positive number, and L3 is the greater in L1 and L2, L1 and L2 is that micron is to millimeter magnitude.

The utility model Anodic protuberance in anode first surface periodic distribution negative electrode protuberance in negative electrode first surface non-periodic distribution; Or anode protuberance in anode first surface non-periodic distribution negative electrode protuberance in negative electrode first surface periodic distribution; Or anode protuberance in anode first surface periodic distribution and negative electrode protuberance in negative electrode first surface periodic distribution; Or anode protuberance in anode first surface non-periodic distribution and negative electrode protuberance in negative electrode first surface non-periodic distribution.In the preferred embodiment that the utility model is other, anode protuberance 5 is in anode first surface 3 periodic distribution, negative electrode protuberance 6 is in negative electrode first surface 4 periodic distribution, both distribution period can identical also can not be identical, preferably, anode protuberance is identical at the distribution period of negative electrode first surface with negative electrode protuberance at the distribution period of anode first surface.Anode and negative electrode form the relative waveform set up and rise and fall, material can between anode and negative electrode and anode and cathode surface circulate.

In a kind of embodiment be more preferably of the utility model, anode protuberance 5 top is just to the part caved in most in the negative electrode first surface region between its two nearest negative electrode protuberances 6; Negative electrode protuberance 6 top is just to the part caved in most in the anode first surface region between its two nearest anode protuberances 5.

In embodiments, anode has anode second surface, this anode second surface is identical with anode first surface shape or not identical, the structure that preferred employing is identical, anode second surface and anode first surface can symmetry also can be asymmetric, the asymmetric structure of preferred employing, more preferably adopts the differing distribution half period of the anode protuberance on two sides.Negative electrode also has negative electrode second surface, negative electrode second surface is identical with negative electrode first surface shape or not identical, the structure that preferred employing is identical, negative electrode second surface and negative electrode first surface can symmetry also can be asymmetric, the asymmetric structure of preferred employing, more preferably adopts the differing distribution half period of the negative electrode protuberance on two sides.

In a kind of preferred embodiment of the present utility model, the utility model additionally provides a kind of battery lead plate, formed by electrode structure of the present utility model, comprise anode part and the cathode portion of interlaced arrangement, anode part is distributed by anodic cycle of the present utility model and is formed, cathode portion is distributed by cathode deposition period of the present utility model and is formed, anode part and cathode portion are set in turn in a surface of insulation support plate or upper and lower two surfaces, insulation support plate is tabular, cambered surface or hollow cylinder.

It should be noted that, in present embodiment, when a surface of insulation support plate or upper and lower two surfaces refer to that the maximum face of insulation support plate surface area is horizontal, the face faced upward or downward.

Preferably, anode part and cathode portion is measure-alike.

In this embodiment, the utility model additionally provides a kind of electrod-array, and this electrod-array is formed by M group plate electrode plate periodic distribution, the anode part parallel connection access positive source of battery lead plate, battery lead plate cathode portion parallel connection access power cathode, wherein, M be greater than 1 positive integer.When battery lead plate is arranged, each anode part and cathode portion just to or tiltedly right, when anode is identical with distribution period with the size of negative electrode, the form that preferred employing is just right, when oblique pair, the anode of a battery lead plate is preferably adopted to be adjacent two nearest adjacent anode of battery lead plate and the equidistant form of negative electrode.

In another kind of preferred embodiment of the present utility model, the utility model additionally provides another kind of battery lead plate, it comprises conductor support plate and at the one side of conductor support plate or the electrode of two sides periodic distribution, electrode is anode according to claim 1 or negative electrode according to claim 1.The battery lead plate provided according to the present embodiment, the utility model additionally provides a kind of electrod-array, this electrod-array is formed by the battery lead plate periodic distribution described in this section of M block, and from side, the odd number electrode plate in electrod-array connects power supply one pole, even numbered blocks battery lead plate in electrod-array connects another pole of power supply, wherein, M be greater than 1 positive integer, namely an electrode plate is positive pole, another block adjacent electrode plates is negative pole, and positive pole and negative pole are interspersed.

It should be noted that, the voltage magnitude of positive source and power cathode and frequency are not limited in the utility model, the amplitude that prior art dielectric electrophoretic techniques specifically can be adopted usually to adopt and the system of selection of frequency are selected, and do not do too much repeating at this.

Also it should be noted that; although only refer to dedusting in background technology of the present utility model; but those skilled in the art can not be interpreted as that this is to restriction of the present utility model; in other technologies field; such as bio-separation field, the heavy metal isolation technics in liquid, and soil sanitation field; as long as adopt electrode structure that is identical with the utility model or obvious distortion, still within protection domain of the present utility model.

In the description of this description, specific features, structure, material or feature that the description of reference term " embodiment ", " some embodiments ", " example ", " concrete example " or " some examples " etc. means to describe in conjunction with this embodiment or example are contained at least one embodiment of the present utility model or example.In this manual, identical embodiment or example are not necessarily referred to the schematic representation of above-mentioned term.And the specific features of description, structure, material or feature can combine in an appropriate manner in any one or more embodiment or example.

Although illustrate and described embodiment of the present utility model, those having ordinary skill in the art will appreciate that: can carry out multiple change, amendment, replacement and modification to these embodiments when not departing from principle of the present utility model and aim, scope of the present utility model is by claim and equivalents thereof.

Claims (14)

1. one kind is separated the electrode structure of microparticle thing, it is characterized in that, comprise anode and negative electrode, described anode has anode first surface, described negative electrode has negative electrode first surface, described anode first surface and negative electrode first surface are oppositely arranged, described anode first surface has at least one anode protuberance, the top of described anode protuberance protrudes from the non-adjacent protuberance part of coupled described anode first surface, anode first surface region between two adjacent anode protuberance tops is not in one plane and section is non-rectangle, described negative electrode first surface has at least one negative electrode protuberance, the top of described negative electrode protuberance protrudes from the non-adjacent protuberance part of coupled described negative electrode first surface, negative electrode first surface region between two neighbouring cathode protuberance tops is not in one plane and section is non-rectangle.

2. the as claimed in claim 1 electrode structure being separated microparticle thing, is characterized in that, described anode protuberance in anode first surface periodic distribution negative electrode protuberance in negative electrode first surface non-periodic distribution; Or described anode protuberance in anode first surface non-periodic distribution negative electrode protuberance in negative electrode first surface periodic distribution; Or anode protuberance in anode first surface periodic distribution and negative electrode protuberance in negative electrode first surface periodic distribution; Or anode protuberance in anode first surface non-periodic distribution and negative electrode protuberance in negative electrode first surface non-periodic distribution.

3. the electrode structure being separated microparticle thing as claimed in claim 2, it is characterized in that, described anode protuberance is identical at the distribution period of negative electrode first surface with negative electrode protuberance at the distribution period of anode first surface.

4. the electrode structure being separated microparticle thing as claimed in claim 1, it is characterized in that, anode first surface region between described two adjacent anode protuberance tops is cylinder, sphere, ellipsoid, curved section moves the cambered surface of formation or moves the cambered surface formed after being connected by many curved sections, or the mobile cambered surface formed after being connected by straightway and/or curved section;

Negative electrode first surface region between described two neighbouring cathode protuberance tops is cylinder, sphere, ellipsoid, curved section moves the cambered surface of formation or the cambered surface moving and formed that is connected by many curved sections, or the cambered surface moving and formed that is connected by straightway and/or curved section.

5. the electrode structure being separated microparticle thing as claimed in claim 4, is characterized in that, the cross section in the anode first surface region between described two adjacent anode protuberance tops is semicircle.

6. the electrode structure being separated microparticle thing as claimed in claim 4, is characterized in that, the cross section in the negative electrode first surface region between described two neighbouring cathode protuberance tops is semicircle.

7. the electrode structure of the separation microparticle thing as described in claim 5 or 6, is characterized in that, described anode protuberance top is just to the part caved in most in the negative electrode first surface region between its two nearest negative electrode protuberances; Described negative electrode protuberance top is just to the part caved in most in the anode first surface region between its two nearest anode protuberances.

8. the electrode structure of the separation microparticle thing as described in one of the claims, it is characterized in that, described anode has anode second surface, described anode second surface is identical or not identical with described anode first surface shape, and described anode second surface and described anode first surface are symmetrical or asymmetric;

Described negative electrode has negative electrode second surface, and described negative electrode second surface is identical or not identical with described negative electrode first surface shape, and described negative electrode second surface and described negative electrode first surface are symmetrical or asymmetric.

9. the electrode structure being separated microparticle thing as claimed in claim 1, it is characterized in that, the distance of described two adjacent anode protuberances is L1, the distance of described two neighbouring cathode protuberances is L2, the distance of described negative electrode and positive electrode is greater than 0 and is less than or equal to 10*L3, described L1, L2 are positive number, and described L3 is the greater in L1 and L2.

10. a battery lead plate, it is characterized in that, formed by the electrode structure of separation microparticle thing according to claim 1, comprise anode part and the cathode portion of interlaced arrangement, described anode part is distributed by anodic cycle according to claim 1 and is formed, described cathode portion is distributed by cathode deposition period according to claim 1 and is formed, described anode part and cathode portion are alternately disposed at the one side of insulation support plate or upper and lower two surfaces successively, described insulation support plate is tabular, cambered surface or hollow cylinder.

11. 1 kinds of battery lead plates, is characterized in that, comprise conductor support plate and at the one side of described conductor support plate or the electrode of two sides periodic distribution, described electrode is anode according to claim 1 or negative electrode according to claim 1.

12. battery lead plates as described in claim 10 or 11, is characterized in that, described anode part and cathode portion measure-alike.

13. 1 kinds of electrod-arrays, it is characterized in that, described electrod-array is formed by M block battery lead plate periodic distribution according to claim 10, the anode part parallel connection access positive source of described battery lead plate, described battery lead plate cathode portion parallel connection access power cathode, described M be greater than 1 positive integer.

14. 1 kinds of electrod-arrays, it is characterized in that, described electrod-array is formed by M block battery lead plate periodic distribution according to claim 11, from side, odd number electrode plate in described electrod-array connects power supply one pole, even numbered blocks battery lead plate in described electrod-array connects another pole of power supply, described M be greater than 1 positive integer.