USE OF COPPER-BASED COATINGS FOR CROPS UNDER GLASS COVERS, ANTIPHYTOPATHOGENIC COATING GLASS AND THE METHOD OF OBTAINING ANTIPHYTOPATHOGENIC COATINGS

Abstract

A copper-based coatings that contain an additional element selected from titanium, zinc, and tin for cultivation under glass covers. In addition, an antiphytopathogenic coating glass for use as glass covers mainly in greenhouses for crops cultivation, as well as a method for producing coatings on a glass surface.

Claims

1. A copper-based coatings for crops under glass covers comprising: titanium, zinc, or tin, and which are completed by oxygen from the obtained oxides, as antiphytopathogenic coatings the coating is use to eliminate phytopathogens such as: Pseudomonas syringae pv. tomato (IOR2146) and five fungal strains: Alternaria solani (IOR2046), Botrytis cinerea (IOR2235), Aspergillus fumigatus (KKP683), Fusarium oxysporum (IOR2129), Cladosporium fulvum (IOR824) Phytophthora infestans (IOR2276) belonging to the Chromista kingdom, the class Peronosporea.

2. An antiphytopathogenic coating glass having a glass pane with a sputtered coating, the sputtered coating containing: copper in the amount of 10-90% and one of: titanium in the amount of 0.5-15%, zinc in the amount of 3-28%, tin in the amount of 1-20%, wherein the sputtered coating content is completed by an oxygen arising from obtained in process oxides.

3. The antiphytopathogenic coating glass according to claim 2, wherein the sputtered coating is applied to raw glass that is not chemically treated, and to diffused glass that is chemically treated glass.

4. The antiphytopathogenic coating glass according to claim 2, wherein sputtered coating has an antiphytopathogenic effect of 1 to 8 decimal logarithms against phytopathogens in the form of bacteria such as Pseudomonas syringae, fungi like Alternaria solani, Cladosporium fulvum, Botrytis cinerea, Fusarium oxysporum, Chromista like Phytophthora infestans both present on the surface of coated glass and floating in the circulating air.

5. The antiphytopathogenic coating glass according to claim 2, wherein the sputtered coating reduces an average direct light transmittance measured in the Vis range of 400 to 700 nm (according to the NEN 2675:2018 Greenhouse glass) by a maximum of 1.0% compared to the base glass.

6. The antiphytopathogenic coating glass according to claim 2, wherein the sputtered coating reduces an average hemispherical transmittance measured (according to NEN 2675:2018 Greenhouse glass) by a maximum of 1.0% compared to base glass.

7. The antiphytopathogenic coating glass according to claim 2, wherein the sputtered coating has a high durability confirmed by abrasion tests.

8. The antiphytopathogenic coating glass according to claim 2, wherein the sputtered coating is resistant to corrosion in the form of salt mist according to ISO 9227 under the following conditions: 25 C., 36 h in NaCl fog (pH=7).

9. A method for obtaining antiphytopathogenic coatings on a glass pane surfaces, the method comprising the steps of: placing the glass pane surface on rollers of an feeder; transporting the glass pane surface to an initial vacuum chamber, wherein an initial vacuum is generated; transporting the lass pane surface of the orevious step to a process vacuum chamber; wherein the initial vacuum chamber has a preliminary vacuum of 1.0.Math.10.sup.1 Pa; wherein the process vacuum chamber produces a process vacuum of 1.1.Math.10.sup.1 to 7.6.10.sup.2 Pa.; Nextly, the reactive gas of 100-900 cm3/min is dosed and the impulse DC power supply is switched on; Wherein the methotid runs with an electrical current intensity of 30-45 A, an effective power 4.5-8.7 kW, and a circulating power 1.1-4.5 kW in the magnetic field generated in the chamber; wherein a moving speed is set to 1.9-9.2 m/min and the glass pane surface transported through a first magnetron of the process chamber with a glowing plasma using at least a two-component target, wherein the first component is copper; wherein the method produces a transparent coating layer with a thickness of 10-60 nm.

10. The method according to claim 9, wherein the copper is selected from Cu90Zn10, Cu80Ti20, or Cu90Sn10.

11. The method according to claim 9, wherein the coating is made after passing the magnetron once or twice.

12. The method according to claim 9, wherein the coating is obtained at low reactive gas contents between 100 and 300 cm.sup.3.

13. The method according to claim 9, wherein the coating is obtained on glass of various thicknesses between 3 and 18 mm.

14. The method according to claim 9, wherein the coating is obtained on non-tempered and thermally tempered as well as semi-tempered glass.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0008] The essence of this invention is the new use of copper-based coatings for crops under glass covers, which additionally contain one element selected from titanium, zinc or tin, and which are completed by oxygen from the obtained oxides, as antiphytopathogenic coatings used to eliminate phytopathogens such as: Pseudomonas syringae pv. tomato (IOR2146) and five fungal strains: Alternaria solani (IOR2046), Botrytis cinerea (IOR2235), Aspergillus fumigatus (KKP683), Fusarium oxysporum (IOR2129), Cladosporium fulvum (IOR824) Phytophthora infestans (IOR2276) belonging to the Chromista kingdom, the class Peronosporea.

[0009] The further essence of the invention lies in the fact that the antiphytopathogenic coating glass, which is a glass pane with a coating sputtered on it, containing copper and one additional element in accordance with the selected target, characterized in that it contains two elements, the first of which is copper in the amount of 10-90% and one of: [0010] titanium in the amount of 0.5-15% [0011] zinc in the amount of 3-28% [0012] tin in the amount of 1-20%

[0013] The chemical coating content is completed by an oxygen arising from obtained in the process oxides. It is advantageous when the coating can be applied to raw glass, i.e. not chemically treated and diffused glass, i.e. chemically treated glass, and when the coatings have an antiphytopathogenic effect of 1 to 8 decimal logarithms against phytopathogens in the form of bacteria such as Pseudomonas syringae, fungi like Alternaria solani, Cladosporium fulvum, Botrytis cinerea, Fusarium oxysporum, Phytophthora infestans. It is also advantageous when the average direct light transmittance measured in the Vis range of 400 to 700 nm (according to the NEN 2675:2018 Greenhouse glassDetermination of optical properties of greenhouse covering materials and screens) is reduced by a maximum of 1.0% compared to the base glass, and the average hemispheric transmittance measured (according to NEN 2675:2018 Greenhouse glassDetermination of optical properties of greenhouse covering materials and screens) is reduced by a maximum of 1.0% compared to base glass and when the sputtered coatings show high durability confirmed by abrasion tests on the Taber Surface Analyzer (model 5155) device, and the coatings are resistant to corrosion in the form of salt mist according to ISO 9227 under the following conditions 25 C., 36 h in NaCl fog (pH=7).

[0014] In turn, the essence of the method of obtaining antiphytopathogenic coatings is this, that during a process in the initial vacuum chamber a preliminary vacuum of 1.0.Math.10.sup.1 Pa is created, and in the process vacuum chamber a process vacuum reaches values of 1.1.Math.10.sup.1 to 7.6.Math.10.sup.2 Pa. Nextly, the reactive gas of 100-900 cm.sup.3/min is dosed and the impulse DC power supply is switched on. The process runs with the electric current intensity of 30-45 A, effective power 4.5-8.7 kW and circulating power 1.1-4.5 kW in the magnetic field generated in the chamber. The moving speed is set from 1.9 to 5.0 m/min and the glass sheet is transported through the first magnetron of the process chamber with the glowing plasma using at least a two-component target, one of which is copper. As a result a transparent coating layer with a thickness of 10.sup.60 nm is produced. It is preferred that the copper target is one of: Cu90Zn10, Cu80Ti20, Cu90Sn10, and the coating is made after passing the magnetron once or twice and when the coating is obtained at low reactive gas contents between 100 and 300 cm.sup.3. It is also advantageous when the coating is obtained on glass of various thicknesses between 3 and 18 mm, and also when the coating is obtained on non-tempered and thermally tempered as well as semi-tempered glass.

Example 1

[0015] The glass pane of 4 mm thickness was placed on the rollers of the initial feeder, afterward it was transported to the initial vacuum chamber, wherein the initial vacuum of 10.sup.1 Pa was generated. Thereafter it was transported to the process (working) chamber and a process vacuum of 1.5.Math.10.sup.1-7.6.Math.10.sup.2 Pa was created. Nextly, the reactive gasoxygen of 100 cm.sup.3/min was dosed and the impulse DC power supply was switched on. The process ran with the electric current intensity of 30 A, effective power 8.1 kW and circulating power 1.25 kW in the magnetic field generated in the chamber. The moving speed was set to 1.9 m/min and the glass sheet was transported through the first magnetron of the process chamber with the glowing plasma using Cu80Ti20 target. As a result a transparent coating layer with a thickness of 10 nm consisting of 0.5% titanium and 10% copper was obtained.

Example 2

[0016] The glass pane of 4 mm thickness was placed on the rollers of the initial feeder, afterward it was transported to the initial vacuum chamber, wherein the initial vacuum of 10.sup.1 Pa was generated. Thereafter, it was transported to the process (working) chamber and a process vacuum of 2.5-3.5.Math.10.sup.2 Pa was created. Nextly, the reactive gasoxygen of 300 cm.sup.3/min was dosed and the impulse DC power supply was switched on. The process ran with the electric current intensity of 30 A, effective power 7.3 kW and circulating power 3.8 kW in the magnetic field generated in the chamber. The moving speed was set to 1.9 m/min and the glass sheet was transported through the first magnetron of the process chamber with the glowing plasma using Cu80Ti20 target. As a result a transparent coating layer with a thickness of 13 nm consisting of 12% titanium and 55% copper was obtained.

Example 3

[0017] The glass pane of 4 mm thickness was placed on the rollers of the initial feeder, afterward it was transported to the initial vacuum chamber, wherein the initial vacuum of 10.sup.1 Pa was generated. Thereafter it was transported to the process (working) chamber and a process vacuum of 3.0-6.9.Math.10.sup.2 Pa was created. Nextly, the reactive gasoxygen of 700 cm.sup.3/min was dosed and the impulse DC power supply was switched on. The process ran with the electric current intensity of 30 A, effective power 4.5 kW and circulating power 3.1 kW in the magnetic field generated in the chamber. The moving speed was set to 1.9 m/min and the glass sheet was transported through the first magnetron of the process chamber with the glowing plasma using Cu80Ti20 target. As a result a transparent coating layer with a thickness of 17 nm consisting of 15% titanium and 78% copper was obtained.

Example 4

[0018] The glass pane of 4 mm thickness was placed on the rollers of the initial feeder, afterward it was transported to the initial vacuum chamber, wherein the initial vacuum of 10.sup.1 Pa was generated. Thereafter it was transported to the process (working) chamber and a process vacuum of 1.2.Math.10.sup.1-7.2.Math.10.sup.2 Pa Pa was created. Nextly, the reactive gasoxygen of 100 cm.sup.3/min was dosed and the impulse DC power supply was switched on. The process ran with the electric current intensity of 30 A, effective power 4.5 kW and circulating power 3.1 kW in the magnetic field generated in the chamber. The moving speed was set to 5 m/min and the glass sheet was transported through the first magnetron of the process chamber with the glowing plasma using Cu90Zn10 target. As a result a transparent coating layer with a thickness of 12 nm consisting of 3% zinc and 50% copper was obtained.

Example 5

[0019] The glass pane of 4 mm thickness was placed on the rollers of the initial feeder, afterward it was transported to the initial vacuum chamber, wherein the initial vacuum of 10.sup.1 Pa was generated. Thereafter it was transported to the process (working) chamber and a process vacuum of 2.3-3.3.Math.10.sup.2 Pa was created. Nextly, the reactive gasoxygen of 300 cm.sup.3/min was dosed and the impulse DC power supply was switched on. The process ran with the electric current intensity of 30 A, effective power 7.5 kW and circulating power 4.0 kW in the magnetic field generated in the chamber. The moving speed was set to 5 m/min and the glass sheet was transported through the first magnetron of the process chamber with the glowing plasma using Cu90Zn10 target. As a result a transparent coating layer with a thickness of 15 nm consisting of 17% zinc and 60% copper was obtained.

Example 6

[0020] The glass pane of 4 mm thickness was placed on the rollers of the initial feeder, afterward it was transported to the initial vacuum chamber, wherein the initial vacuum of 10.sup.1 Pa was generated. Thereafter it was transported to the process (working) chamber and a process vacuum of 2.7-6.6.Math.10.sup.2 Pa was created. Nextly, the reactive gasoxygen of 900 cm.sup.3/min was dosed and the impulse DC power supply was switched on. The process ran with the electric current intensity of 30 A, effective power 4.7 kW and circulating power 3.4 kW in the magnetic field generated in the chamber. The moving speed was set to 5 m/min and the glass sheet was transported through the first magnetron of the process chamber with the glowing plasma using Cu90Zn10 target. As a result a transparent coating layer with a thickness of 20 nm consisting of 20% zinc and 62% copper was obtained.

Example 7

[0021] The glass pane of 4 mm thickness was placed on the rollers of the initial feeder, afterward it was transported to the initial vacuum chamber, wherein the initial vacuum of 10.sup.1 Pa was generated. Thereafter it was transported to the process (working) chamber and a process vacuum of 2.7-6.6.Math.10.sup.2 Pa was created. Nextly, the reactive gasoxygen of 900 cm.sup.3/min was dosed and the impulse DC power supply was switched on. The process ran with the electric current intensity of 45 A, effective power 8.3 kW and circulating power 4.5 kW in the magnetic field generated in the chamber. The moving speed was set to 5 m/min and the glass sheet was transported through the first magnetron of the process chamber with the glowing plasma using Cu90Zn10 target. As a result a transparent coating layer with a thickness of 60 nm consisting of 23% zinc and 70% copper was obtained.

Example 8

[0022] The glass pane of 4 mm thickness was placed on the rollers of the initial feeder, afterward it was transported to the initial vacuum chamber, wherein the initial vacuum of 10.sup.1 Pa was generated. Thereafter it was transported to the process (working) chamber and a process vacuum of 1.1.Math.10.sup.1-7.1.Math.10.sup.2 Pa was created. Nextly, the reactive gasoxygen of 100 cm.sup.3/min was dosed and the impulse DC power supply was switched on. The process ran with the electric current intensity of 30 A, effective power 8.7 kW and circulating power 1.1 kW in the magnetic field generated in the chamber. The moving speed was set to 4 m/min and the glass sheet was transported through the first magnetron of the process chamber with the glowing plasma using Cu90Sn10 target. As a result a transparent coating layer with a thickness of 15 nm consisting of 20% tin and 70% copper was obtained.

Example 9

[0023] The glass pane of 4 mm thickness was placed on the rollers of the initial feeder, afterward it was transported to the initial vacuum chamber, wherein the initial vacuum of 10.sup.1 Pa was generated. Thereafter it was transported to the process (working) chamber and a process vacuum of 2.2-3.1.Math.10.sup.2 Pa was created. Nextly, the reactive gasoxygen of 300 cm.sup.3/min was dosed and the impulse DC power supply was switched on. The process ran with the electric current intensity of 30 A, effective power 7.7 kW and circulating power 4.2 kW in the magnetic field generated in the chamber. The moving speed was set to 4 m/min and the glass sheet was transported through the first magnetron of the process chamber with the glowing plasma using Cu90Sn10 target. As a result a transparent coating layer with a thickness of 25 nm consisting of 12% tin and 80% copper was obtained.

Example 10

[0024] The glass pane of 4 mm thickness was placed on the rollers of the initial feeder, afterward it was transported to the initial vacuum chamber, wherein the initial vacuum of 10.sup.1 Pa was generated. Thereafter it was transported to the process (working) chamber and a process vacuum of 2.6-6.4.Math.10.sup.2 Pa was created. Nextly, the reactive gasoxygen of 900 cm.sup.3/min was dosed and the impulse DC power supply was switched on. The process ran with the electric current intensity of 30 A, effective power 4.9 kW and circulating power 3.6 kW in the magnetic field generated in the chamber. The moving speed was set to 4 m/min and the glass sheet was transported through the first magnetron of the process chamber with the glowing plasma using Cu90Sn10 target. As a result a transparent coating layer with a thickness of 55 nm consisting of 1% tin and 90% copper was obtained.

TABLE-US-00001 TABLE 1 the list of process parameters described in the examples 1-10 Number of passes Amount of Coating Working Moving through reactive Effective Circulating Process thickness current speed process gas [cm.sup.3 power power vacum Number Target [nm] [A] [m/min] chamber min.sup.1] [kW] [kW] [Pa] 1 Cu80Ti20 10 30 1.9 2 100 8.1 1.25 1.5 .Math. 10 1-7.6 .Math. 10 2 2 Cu80Ti20 13 30 1.9 2 300 7.3 3.8 2.5-3.5 .Math. 10 2 3 Cu80Ti20 17 30 1.9 2 700 4.5 3.1 3.0-6.9 .Math. 10 2 4 Cu90Zn10 12 30 5 1 100 8.5 1.2 1.2 .Math. 10 1-7.2 .Math. 10 2 5 Cu90Zn10 15 30 5 1 300 7.5 4.0 2.3-3.3 .Math. 10 2 6 Cu90Zn10 20 30 5 1 900 4.7 3.4 2.7-6.6 .Math. 10 2 7 Cu90Zn10 60 45 5 1 900 8.3 4.5 2.7-6.6 .Math. 10 2 8 Cu90Sn10 15 30 4 1 100 8.7 1.1 1.1 .Math. 10 1-7.1 .Math. 10 2 9 Cu90Sn10 25 30 4 1 300 7.7 4.2 2.2-3.1 .Math. 10 2 10 Cu90Sn10 55 30 4 1 900 4.9 3.6 2.6-6.4 .Math. 10 2

[0025] After the coatings were sputtered using the method according to the invention, they composed of chemical elements in accordance with the used target, however the quantity of chemical elements was described below in examples 11 to 13.

Example 11

[0026] The magnetron coating obtained according to the Examples 1-3 for the Cu80Ti2O target composed of 10.sup.78% copper and 0.5-15% titanium. Due to the fact that metals are present in the coating in the form of oxides, the remaining elemental percentage (up to 100%) is oxygen.

Example 12

[0027] The magnetron coating obtained according to the Examples 4-7 for the Cu90Zn10 target composed of 50-70% copper and 3-28% zinc. Due to the fact that metals are present in the coating in the form of oxides, the remaining elemental percentage (up to 100%) is oxygen.

Example 13

[0028] The magnetron coating obtained according to the Examples 8-10 for the Cu90Sn10 target composed of 70-90% copper and 1-20% tin. Due to the fact that metals are present in the coating in the form of oxides, the remaining elemental percentage (up to 100%) is oxygen.

TABLE-US-00002 TABLE 2 The share of individual chemical components in the coating depending on the type of used target. Metal percentage in the coating Type of target Cu/% X1/% Cu80Ti20 Cu 10-78 Ti 0.5-15 Cu90Zn10 Cu 50-70 Zn 3-28 Cu90Sn10 Cu 70-90 Sn 1-20

[0029] The coatings described in examples 11-13 were sputtered onto the internal surfaces of experimental cubes (0.50.50.5 m) using the method described in examples 1.Math.10, and then the survival of microorganisms (Pseudomonas syringae pv. tomato) and five fungal strains: Aspergillus fumigatus, Alternaria solani, Botrytis cinerea, Fusarium oxysporum, Cladosporium fulvum syn. Passalora fulva) and one representative of ChromistaPhytophtora infestans) introduced into the cubic experimental object made of coated glass on the inner surfaces of the glass and floating in the circulating air, was investigated.

[0030] An inactivation of microorganisms on the surface of the sputtered glass and in the circulating air was observed at the level between 3 and 8 decimal logarithms, however, for the coating obtained in example 6, the highest level of microorganism reduction was obtained at the level >6.0 and >8.0 for the imprint (using imprint plates) and swab method, respectively. The results for the fungal strains Phytophtora infestans and Cladosporium fulvum turned out to be decisive. On the wall surfaces made of glass with a coating obtained from the Cu90Zn10 cathode, a complete reduction of the above strains was obtained in the analysis performed by swabs. A similar result was obtained by the imprint method. The experimental cube used in the studies had an H13 filter blocking the access of microorganisms from the outside.

[0031] After finishing the investigations in the experimental cubes, further tests were carried out as part of the greenhouse study. The biocidal activity against following phytopathogens Pseudomonas syringae pv. tomato and four fungi strains (Alternaria solani, Botrytis cinerea, Fusarium oxysporum, Cladosporium fulvum syn. Passalora fulva) and one representative of ChromistaPhytophtora infestans at the level between 1 and 3 decimal logarithms both on internal surfaces and in the circulating inside the experimental greenhouse air was observed.