CN105476308A - Wear-resisting cabinet table-board and manufacturing technology thereof - Google Patents
Wear-resisting cabinet table-board and manufacturing technology thereof Download PDFInfo
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- CN105476308A CN105476308A CN201510937908.XA CN201510937908A CN105476308A CN 105476308 A CN105476308 A CN 105476308A CN 201510937908 A CN201510937908 A CN 201510937908A CN 105476308 A CN105476308 A CN 105476308A
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- A—HUMAN NECESSITIES
- A47—FURNITURE; DOMESTIC ARTICLES OR APPLIANCES; COFFEE MILLS; SPICE MILLS; SUCTION CLEANERS IN GENERAL
- A47B—TABLES; DESKS; OFFICE FURNITURE; CABINETS; DRAWERS; GENERAL DETAILS OF FURNITURE
- A47B96/00—Details of cabinets, racks or shelf units not covered by a single one of groups A47B43/00 - A47B95/00; General details of furniture
- A47B96/18—Tops specially designed for working on
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Abstract
The invention belongs to the technical field of furniture, and in particular discloses a wear-resisting cabinet table-board and a manufacturing technology of the wear-resisting cabinet table-board. The wear-resisting cabinet table-board comprises a wooden substrate, wherein a stainless-steel layer is fixedly connected outside the wooden substrate through a stainless-steel bonding layer; a diamond alkene layer is plated outside the stainless-steel layer; stainless-steel water baffle bars are arranged on the side surfaces of the diamond alkene layer; water baffle bar diamond alkene layers are plated outside the stainless-steel water baffle bars; water baffle bar bonding layers are arranged between the water baffle bar diamond alkene layers and the diamond alkene layer, and can be made of synthetic resin; a decoration layer is arranged on the top end surface of the stainless-steel layer; and both the diamond alkene layer and the water baffle bar diamond alkene layers are made of nanometer diamond alkene in a lamellar single-crystal structure. The wear-resisting cabinet table-board is good in wear resistance, long in service life and convenient to clean.
Description
Technical field
The invention belongs to technical field of furniture, relate to a kind of cabinet table surface, particularly the wear-resisting cabinet table surface of one and production technology.
Background technology
In nowadays daily life household, integral cabinet is a very universal household articles, occupation rate of market reaches more than 90%, the table top of integral cabinet is divided into a variety of, mainly contain the various materials such as marble, artificial stone, quartz, stainless steel, length and width variable thickness, but the cabinet table surface of these materials is in concrete use procedure or there is certain problem: 1, non-refractory, high temperature can cause great damage to table top, is heated for a long time and table top crack damage can be caused cannot to use even; 2, hardness is low, and surface is easily scratched, and is easy on table top, be left cut by sharppointed article such as cutting knifes in routine use process; 3, greasy dirt, water stainly easily penetrate into table top inside, greasy dirt, water stain penetrate into table top inside after, it cannot be cleaned up from table top, table top entirety jaundice variable color, have impact on the overall aesthetics of table top; 4, cleaning process trouble, the table top being directed to unlike material need with different cleaning agents, soft rag should be used in cleaning process, acid stronger cleaning agent can not be used to clean table top, otherwise the glaze paint on table top top layer can be caused to damage, the natural stone inside making it tarnish even to damage, table top is caused to use, steel wire lump can not be used to clean the spot, greasy dirt etc. on table top in cleaning table top process simultaneously, easily cause the top layer of table top to be scratched, make its tarnishing property; 5, table top is expensive, and price general charged in hundreds of unit to several thousand yuan every meter not etc., needs table top integral replacing, the cost of adding users after table top Damage.
Summary of the invention
The object of this invention is to provide that a kind of wearability is good, long service life and the wear-resisting cabinet table surface of easy to clean and production technology.
For achieving the above object, the present invention by the following technical solutions: wear-resisting cabinet table surface, comprises wooden substrate, is connected with stainless steel layer outside wooden substrate by stainless steel tack coat; Outside stainless steel layer, plating has diamond alkene layer; The side of diamond alkene layer is provided with stainless steel water bar; Outside stainless steel water bar, plating has water bar diamond alkene layer; Be provided with water bar tack coat between water bar diamond alkene layer and diamond alkene layer, water bar tack coat can adopt synthetic resin; The top end face of stainless steel layer is provided with decorative layer; Diamond alkene layer and water bar diamond alkene layer form by the nanometer diamond alkene of lamellar mono-crystalline structures; Being that sp3 orbital hybridization carbon bond connects between the carbon atom of the same lamella of nanometer diamond alkene of lamellar mono-crystalline structures, is that sp2 hydridization carbon bond connects between carbon atom between layers; The spacing of lattice of nanometer diamond alkene is 0.21nm; The average grain diameter of nanometer diamond alkene is R, 20≤R≤500nm.
Stainless steel water bar top is inclined-plane, and the angle of inclined-plane and horizontal direction is α, 30 °≤α≤60 °.
The beveled top end of stainless steel water bar and the vertical range of diamond alkene layer are S, 1mm≤S≤10mm.
The thickness of diamond alkene layer is t, 100 μm≤t≤200 μm; The thickness of water bar diamond alkene layer is t
1, 50 μm≤t1≤100 μm.
The thickness of stainless steel layer is T, 0.1mm≤T≤5mm; The thickness of stainless steel water bar is T
1, 0.1mm≤T
1≤ 3mm.
Wear-resisting cabinet table surface production technology, comprises the following steps: 1) be bonded on wooden substrate by stainless steel layer; 2) stainless steel layer is cleaned; 3) to stainless steel layer electroplating processes; 4) obtained to step 3) product is washed and dries; 5) according to step 2) stainless steel water bar is processed to step 4); 6) product step 4) and step 5) obtained is bonding by water bar tack coat, obtains finished product.
In step 3), plating solution is made up of the component of following concentration: Ni (SO3NH2) 2400-600g/L, NiCl212-18g/L, H3BO330-40g/L, lauryl sodium sulfate 0.1-0.2g/L, asccharin 8-12g/KAh, 1,4-butynediols 20-30g/KAh, nanometer diamond alkene 3-5g/L.
In step 3) electroplating technology, current density is 1-3A/dm2, and electroplating time is 3-5h.
The preparation technology of nanometer diamond alkene, comprises the following steps:
Pickling is purified: fine powder diamond raw meal being broken into more than 8000 orders, adopts the concentrated sulfuric acid and red fuming nitric acid (RFNA) mixed liquor, watery hydrochloric acid, hydrofluoric acid to this fine powder pickling successively, then use washed with de-ionized water to cleaning fluid pH close to 7; Sorting: the material after cleaning is carried out centrifugation, gets supernatant liquid and carries out the sorting of 1-5 days precipitations, remove supernatant liquor, by the nanometer diamond alkene that gets product after the drying of lower sediment thing.
Carry out ball milling shaping and airflow crash before acid pickling step, first the fines of more than 800 orders is sieved out in the ball milling shaping of diamond raw material; Again this fines is delivered in airflow crash machine and pulverizes and sieve out the fine powder of more than 8000 orders.
At ball milling shaping step, diamond sifts out the particle of more than 70 orders through the screen cloth of ball milling shaping barrel, and the broken time is 1-5h; This particle sieves out the fines of more than 800 orders through multistage vibrating sieving machine, and the sieve time of shaking is 30min-2h; At ball milling shaping step, fineves more than 800 orders sieved out repeats to sieve once; At ball milling shaping step, the coarse fodder below 70 orders returns ball milling shaping barrel and carries out again broken; Residue on sieve Returning flow disintegrating machine carries out again broken; In sorting step, centrifugation time is 30min-2h, and rotating speed is 8000rpm-15000rpm; The concentrated sulfuric acid and red fuming nitric acid (RFNA) mixed liquor are that 5:1 mixes by mass fraction to be 98% concentrated sulfuric acid and mass fraction be 10% red fuming nitric acid (RFNA) according to mass ratio; Adopting nanometer diamond alkene prepared by said method, is lamellar mono-crystalline structures, is that sp3 orbital hybridization carbon bond connects between the carbon atom of same lamella, is that sp2 hydridization carbon bond connects between carbon atom between layers; Granularity is 20-500nm, and C content is 99 ~ 100%, and spacing of lattice is 0.21nm.
Compared with prior art, beneficial effect of the present invention is as follows: wear-resisting cabinet table surface, comprises wooden substrate, is connected with stainless steel layer outside wooden substrate by stainless steel tack coat; Outside stainless steel layer, plating has diamond alkene layer, and the existence of diamond alkene layer can improve hardness and the anti-wear performance of table top, and long-time use also can not cause wearing and tearing; Nanometer diamond alkene for plating is lamellar mono-crystalline structures, be that sp3 orbital hybridization carbon bond connects between the carbon atom of same lamella, the diamond alkene layer water proofing property, the good heat resistance that are formed, nanometer diamond alkene good stability, can use for a long time, even if use Acidity of Aikalinity cleaning agent to clean, also the phenomenon of table top damage and variable color can not be caused, and the phosphorus content of nanometer diamond alkene is 99 ~ 100%, crystallinity is very strong, to human non-toxic's side effect; The side of diamond alkene layer is provided with stainless steel water bar, and outside stainless steel water bar, plating has water bar diamond alkene layer, arranges water bar and the water on table top can be avoided to flow out, and arrange diamond alkene layer outside water bar, avoid water bar to wear and tear after a long time use; Be provided with water bar tack coat between water bar diamond alkene layer and diamond alkene layer, reduce the setting of fixture, reduce the difficulty of processing of table top on the one hand, on the other hand because water bar thickness is less, if station is installed in processing can cause the problems such as water bar frangibility; The top end face of stainless steel layer is provided with decorative layer, improves the aesthetic property of table top, and decorative layer, by being formed the etching of stainless steel layer upper surface, also can directly be bonded on the top end face of stainless steel layer; The average grain diameter of nanometer diamond alkene is 20≤R≤500nm, and particle diameter concentration degree is high, particle size range narrowly distributing, and particle size is controlled, and the glaze bed roughness of formation is little, smooth surface and not easy to wear; Water bar top is inclined-plane, and the angle of inclined-plane and horizontal direction is α, 30 °≤α≤60 °, and water bar top is inclined-plane, conveniently cleans table top, reduces clean dead angle; The beveled top end of water bar and the vertical range of diamond alkene layer are S, 1mm≤S≤10mm, and water bar excessive height easily causes ponding and cleaning inconvenience, and water bar is too low, can lose water retaining function; The thickness of diamond alkene glaze layer is t, 100 μm≤t≤200 μm, forms the coating that thickness is moderate, ensures wear-resisting, waterproof, the resistance to elevated temperatures of coating, reduces production cost simultaneously; The thickness of water bar diamond alkene layer is t
1, 50 μm≤t
1≤ 100 μm, improve the anti-wear performance of water bar; The thickness of stainless steel layer is T, 0.1mm≤T≤5mm, and the thickness of stainless steel water bar is T
1, 0.1mm≤T
1≤ 3mm, suitable thickness chosen by stainless steel, both ensured hardness and the flatness of table top, cost-saving again.
Wear-resisting cabinet table surface production technology, comprises the following steps: 1) be bonded on wooden substrate by stainless steel layer, 2) stainless steel layer is cleaned, 3) to stainless steel layer electroplating processes, 4) obtained to step 3) product is washed and dries, 5) according to step 2) stainless steel water bar is processed to step 4), 6) product step 4) and step 5) obtained is bonding by water bar tack coat, obtains finished product, in step 3), plating solution is made up of the component of following concentration: Ni (SO3NH2) 2400-600g/L, NiCl212-18g/L, H3BO330-40g/L, lauryl sodium sulfate 0.1-0.2g/L, asccharin 8-12g/KAh, 1, 4-butynediols 20-30g/KAh, nanometer diamond alkene 3-5g/L, in step 3) electroplating technology, current density is 1-3A/dm2, electroplating time is 3-5h, nanometer diamond alkene is attached to stainless steel surfaces along with electroplating process, under the effect of suitable current density and electroplating time, make nanometer diamond alkene be plated on stainless steel surfaces tightly, not easily drop, make simultaneously coating and stainless steel surfaces adhesion good, there will not be coating skin effect phenomenon.
Accompanying drawing explanation
Fig. 1 is the structural representation of the embodiment of the present invention one;
Fig. 2 is the XRD spectra of nanometer diamond alkene;
Fig. 3 is the tem analysis figure of nanometer diamond alkene;
Fig. 4 is the MAS-NMR spectrogram of nanometer diamond alkene;
Fig. 5 is the atomic orbital schematic diagram of nanometer diamond alkene;
Fig. 6 is the Raman spectrum of nanometer diamond alkene.
Detailed description of the invention
embodiment one
Wear-resisting cabinet table surface, comprises wooden substrate 5, is connected with stainless steel layer 4 outside wooden substrate 5 by stainless steel tack coat 7; Outside stainless steel layer 4, plating has diamond alkene layer 6; The side of diamond alkene layer 6 is provided with stainless steel water bar; Outside stainless steel water bar 1, plating has water bar diamond alkene layer 3; Water bar tack coat 2 is provided with between water bar diamond alkene layer 3 and diamond alkene layer 6; The top end face of stainless steel layer 4 is provided with decorative layer 8; Diamond alkene layer 6 and water bar diamond alkene layer 3 form by the nanometer diamond alkene of lamellar mono-crystalline structures; Being that sp3 orbital hybridization carbon bond connects between the carbon atom of the same lamella of nanometer diamond alkene of lamellar mono-crystalline structures, is that sp2 hydridization carbon bond connects between carbon atom between layers; The spacing of lattice of nanometer diamond alkene is 0.21nm; The average grain diameter of nanometer diamond alkene is 500nm.Stainless steel water bar 1 top is inclined-plane, and the angle of inclined-plane and horizontal direction is 60 °.The beveled top end of stainless steel water bar 1 and the vertical range of diamond alkene layer 6 are 10mm.The thickness of diamond alkene layer 6 is 200 μm; The thickness of water bar diamond alkene layer 3 is 100 μm.The thickness of stainless steel layer 4 is 5mm; The thickness of stainless steel water bar 1 is 3mm.
Wear-resisting cabinet table surface production technology, comprises the following steps: 1) be bonded on wooden substrate 5 by stainless steel layer 4; 2) stainless steel layer 4 is cleaned; 3) to stainless steel layer 4 electroplating processes; 4) obtained to step 3) product is washed and dries; 5) according to step 2) stainless steel water bar 1 is processed to step 4); 6) product step 4) and step 5) obtained is bonding by water bar tack coat 2, obtains finished product.In step 3), plating solution is made up of the component of following concentration: Ni (SO3NH2) 2400-600g/L, NiCl212-18g/L, H3BO330-40g/L, lauryl sodium sulfate 0.1-0.2g/L, asccharin 8-12g/KAh, 1,4-butynediols 20-30g/KAh, nanometer diamond alkene 3-5g/L.In step 3) electroplating technology, current density is 1-3A/dm2, and electroplating time is 3-5h.
embodiment two
The average grain diameter of nanometer diamond alkene is 300nm.Stainless steel water bar top is inclined-plane, and the angle of inclined-plane and horizontal direction is 60 °.The beveled top end of stainless steel water bar and the vertical range of diamond alkene layer are 8mm.The thickness of diamond alkene layer is 180 μm; The thickness of water bar diamond alkene layer is 90 μm.The thickness of stainless steel layer is 3mm; The thickness of stainless steel water bar is 2mm.
embodiment three
The average grain diameter of nanometer diamond alkene is 200nm.Stainless steel water bar top is inclined-plane, and the angle of inclined-plane and horizontal direction is 45 °.The beveled top end of stainless steel water bar and the vertical range of diamond alkene layer are 6mm.The thickness of diamond alkene layer is 160 μm; The thickness of water bar diamond alkene layer is 80 μm.The thickness of stainless steel layer is 2mm; The thickness of stainless steel water bar is 1mm.
embodiment four
The average grain diameter of nanometer diamond alkene is 100nm.Stainless steel water bar top is inclined-plane, and the angle of inclined-plane and horizontal direction is 45 °.The beveled top end of stainless steel water bar and the vertical range of diamond alkene layer are 4mm.The thickness of diamond alkene layer is 140 μm; The thickness of water bar diamond alkene layer is 70 μm.The thickness of stainless steel layer is 1mm; The thickness of stainless steel water bar is 0.5mm.
embodiment five
The average grain diameter of nanometer diamond alkene is 80nm.Stainless steel water bar top is inclined-plane, and the angle of inclined-plane and horizontal direction is 45 °.The beveled top end of stainless steel water bar and the vertical range of diamond alkene layer are 3mm.The thickness of diamond alkene layer is 120 μm; The thickness of water bar diamond alkene layer is 60 μm.The thickness of stainless steel layer is 0.5mm; The thickness of stainless steel water bar is 0.3mm.
embodiment six
The average grain diameter of nanometer diamond alkene is 50nm.Stainless steel water bar top is inclined-plane, and the angle of inclined-plane and horizontal direction is 30 °.The beveled top end of stainless steel water bar and the vertical range of diamond alkene layer are 2mm.The thickness of diamond alkene layer is 100 μm; The thickness of water bar diamond alkene layer is 50 μm.The thickness of stainless steel layer is 0.2mm; The thickness of stainless steel water bar is 0.2mm.
embodiment seven
The average grain diameter of nanometer diamond alkene is 20nm.Stainless steel water bar top is inclined-plane, and the angle of inclined-plane and horizontal direction is 30 °.The beveled top end of stainless steel water bar and the vertical range of diamond alkene layer are 1mm.The thickness of diamond alkene layer is 100 μm; The thickness of water bar diamond alkene layer is 50 μm.The thickness of stainless steel layer is 0.1mm; The thickness of stainless steel water bar is 0.1mm.
the performance test of nanometer diamond alkene is as follows:
(1) XRD analysis
Fig. 2 is a: explosion method Nano diamond; B: nanometer diamond alkene in the present invention; C: graphite; D: the XRD spectra of Graphene.
From the XRD spectra of Fig. 2, by x-ray powder diffraction instrument (CuK alpha ray, tube voltage 40Kv, tube current 40mA, λ=1.54056) test show, nanometer diamond alkene of the present invention in the angle of diffraction 2 θ=43.93 ° and 75.3 ° can see clearly diffraction maximum, with typical diamond phase diffraction maximum (111), (220) corresponding, can prove that novel nano diamond alkene of the present invention is the carbon nanosheet with diamond phase structure, the Nano diamond that the diffracted intensity of the diffracted primary peak (111) of novel nano diamond alkene of the present invention synthesizes much larger than explosion method can be found out from XRD spectra simultaneously, illustrate that the Nano diamond that diamond alkene crystallinity of the present invention is synthesized more than explosion method is strong.Can find out that Graphene and graphite can see diffraction maximum significantly in the angle of diffraction 2 θ=26.3 ° simultaneously, corresponding with typical Graphene and graphite diffraction maximum (002), to go out peak position different from novel nano diamond alkene of the present invention, this illustrates that novel nano diamond alkene of the present invention is formed mutually from the thing of graphite, Graphene is different, the peak position that goes out of the main diffraction maximum of CNT is set to 26.4 °, corresponding crystal face is (002), and this is also different from diamond alkene of the present invention.According to Scherrer formula D=, K is constant, β is halfwidth, diamond alkene grain size of the present invention is about 5 times of the Nano diamond of explosion method synthesis, this means that diamond alkene of the present invention distorts on atomic structure of carbon very little, crystallinity is good, because crystal grain is more little more easily produce distortion of lattice, this is for expanding the range of application of Nano diamond advantageously.
(2) tem analysis
Fig. 3 is a: explosion method Nano diamond; B: novel nano diamond alkene of the present invention; C: graphite; D: the tem analysis figure of Graphene.Corresponding 1 is partial enlarged drawing, and 2 is corresponding HRTEM figure, and 1 figure upper left corner illustration is corresponding SAED figure.
Can find out that the pattern of nanometer diamond alkene of the present invention is different from other material with carbon element significantly by Fig. 3, and be a kind of multilayer chip structure, us are schemed as can be seen from the SAED in the 1 figure upper left corner, diamond alkene of the present invention is a kind of mono-crystalline structures, and Nano diamond prepared by explosion method is the particle composition of reuniting, and be polycrystalline structure, graphite and Graphene are laminated structure, this laminated structure is different from diamond alkene of the present invention, the length of a film of diamond alkene of the present invention is between 200-500nm, the length of a film of graphite and Graphene is more than 10 μm, and thickness is also than graphite, Graphene is thick.Us are schemed also as can be seen from SAED, although all present monocrystalline electronic diffraction, but the SAED figure of graphite and Graphene is the SAED figure of typical hexaplanar, and be different from diamond alkene prepared by the present invention, this illustrates that diamond alkene of the present invention has different crystal structures from graphite, Graphene.
Can find out that spacing of lattice is 0.21nm from HRTEM figure, close with diamond phase (111) face spacing of lattice 0.206nm, this illustrates that the product of this laminated structure is all along (111) face, from figure, we it can also be seen that the Nano diamond that nanometer diamond alkene dispersiveness is prepared more than explosion method will be got well, and specific area is large, be more prone to adsorb other functional group from the teeth outwards, thus realize the functionalization to diamond surface, expand its range of application.
(3) MASNMR analyzes
Fig. 4 is a: nanometer diamond alkene of the present invention, b: the MASNMR of explosion method Nano diamond analyzes.
Nanometer diamond alkene of the present invention is layer structure as seen from Figure 4, the Nano diamond of explosion method synthesis is made up of two kinds of different carbon C1 and C2, wherein C1 carbon to go out peak position different from diamond alkene of the present invention, this illustrates that the carbon atom arrangement inside these two kinds of Nano diamonds also exists certain difference.Nanometer diamond alkene of the present invention has the sp3 orbital hybridization carbon carbon structure different with two kinds, sp2 orbital hybridization carbon, be that sp3 orbital hybridization carbon bond connects between the carbon atom of same lamella, be that sp2 hydridization carbon bond connects between carbon atom between layers, make there are many electron vacancys between layers, electron vacancy facilitates electronics freely to come in and go out, wherein, as shown in Figure 5, sp3 orbital hybridization carbon is the hydridization carbon of stereochemical structure, sp2 orbital hybridization carbon be planar structure hydridization carbon this be different from the carbon structure of the Nano diamond that explosion method is synthesized.And Graphene has a kind of two dimensional crystal structure, the hexagon that its lattice is made up of six carbon atom, combination between carbon atom is sp2 orbital hybridization, graphite is the hexagon of the six carbon atom composition of same layer, with layer carbon atom between combination be sp2 orbital hybridization formed chemical bond, and be connect by Van der Waals force between layers, carbon atom in nanotube is based on sp2 orbital hybridization, also there is certain bending simultaneously, certain sp3 hybrid bond can be formed, namely the chemical bond formed in same flexure plane has sp2 and sp3 mixed hybridization state simultaneously, the carbon atom arrangement of these material with carbon elements is all different from nanometer diamond alkene of the present invention.
(4) Raman spectrum analysis
Fig. 6 is the Raman spectrogram of nanometer diamond alkene, (a) particle diameter 250nm; (b) particle diameter 200nm; (c) particle diameter 100nm; (d) particle diameter 50nm.
As can be seen from Figure 6, the diamond alkene of layer structure of the different-grain diameter of synthesis has the similar Raman spectrogram of the Nano diamond of explosion method synthesis, but with its unlike, along with the change of sample particle diameter, also there is regular change in Raman spectrogram, the intensity at two main peak D peak and G peak is weakening gradually, this is mainly because the structure of sample itself there occurs change, sp2 carbon and sp3 carbon two kinds of carbon atoms constitute a kind of special dimeric structure, along with the change of sample particle diameter, this special dimeric structure content increases gradually and causes two main diffraction peak intensities to weaken gradually.
Claims (8)
1. wear-resisting cabinet table surface, is characterized in that: comprise wooden substrate, is connected with stainless steel layer outside wooden substrate by stainless steel tack coat; Outside stainless steel layer, plating has diamond alkene layer; The side of diamond alkene layer is provided with stainless steel water bar; Outside stainless steel water bar, plating has water bar diamond alkene layer; Water bar tack coat is provided with between water bar diamond alkene layer and diamond alkene layer; The top end face of stainless steel layer is provided with decorative layer; Diamond alkene layer and water bar diamond alkene layer form by the nanometer diamond alkene of lamellar mono-crystalline structures; Being that sp3 orbital hybridization carbon bond connects between the carbon atom of the same lamella of nanometer diamond alkene of described lamellar mono-crystalline structures, is that sp2 hydridization carbon bond connects between carbon atom between layers; The spacing of lattice of nanometer diamond alkene is 0.21nm; The average grain diameter of nanometer diamond alkene is R, 20≤R≤500nm.
2. wear-resisting cabinet table surface as claimed in claim 1, is characterized in that: described stainless steel water bar top is inclined-plane, and the angle of inclined-plane and horizontal direction is α, 30 °≤α≤60 °.
3. wear-resisting cabinet table surface as claimed in claim 2, is characterized in that: the beveled top end of described stainless steel water bar and the vertical range of diamond alkene layer are S, 1mm≤S≤10mm.
4. wear-resisting cabinet table surface as claimed in claim 3, is characterized in that: the thickness of described diamond alkene layer is t, 100 μm≤t≤200 μm; The thickness of described water bar diamond alkene layer is t
1, 50 μm≤t
1≤ 100 μm.
5. wear-resisting cabinet table surface as claimed in claim 4, is characterized in that: the thickness of described stainless steel layer is T, 0.1mm≤T≤5mm; The thickness of described stainless steel water bar is T
1, 0.1mm≤T
1≤ 3mm.
6. the wear-resisting cabinet table surface production technology as described in as arbitrary in claim 1-5, is characterized in that: comprise the following steps: 1) be bonded on wooden substrate by stainless steel layer; 2) stainless steel layer is cleaned; 3) to stainless steel layer electroplating processes; 4) obtained to step 3) product is washed and dries; 5) according to step 2) stainless steel water bar is processed to step 4); 6) product step 4) and step 5) obtained is bonding by water bar tack coat, obtains finished product.
7. wear-resisting cabinet table surface production technology as claimed in claim 6, is characterized in that: in step 3), plating solution is made up of the component of following concentration: Ni (SO
3nH
2)
2400-600g/L, NiCl
212-18g/L, H
3bO
330-40g/L, lauryl sodium sulfate 0.1-0.2g/L, asccharin 8-12g/KAh, Isosorbide-5-Nitrae-butynediols 20-30g/KAh, nanometer diamond alkene 3-5g/L.
8. wear-resisting cabinet table surface production technology as claimed in claim 7, is characterized in that: in step 3) electroplating technology, current density is 1-3A/dm
2, electroplating time is 3-5h.
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