The invention concerns a glazing comprising conductors, a method of manufacturing said glazing and use of said glazing.
Glazings comprising heated electrical conductors are known for demisting and defrosting. For example, heated wired glazing is used in motor vehicles for windshields, rear windows, side windows and roof windows.
JP2017212148A (Ogawa) discloses two heaters in a vehicle glazing, each connected to its own busbars. The first heater is in an information acquisition area. The second heater is in an area other than the information acquisition area. The information acquisition area is used for an information acquisition device capable of obtaining information from outside the vehicle by receiving light. An example is a camera using visible light or infra-red light. First and second heaters are prepared on a release film. An adhesive layer is deposited thereon forming a transfer sheet. After transferring to either surface of an outer glass plate or inner glass plate of the glazing, the release layer is peeled off and the adhesive layer dissolved.
EP3486225A1 (Ogawa) discloses two regions for heat generation, each comprising a plurality of heating lines extending in the up-down direction and connected to common busbars. First heating lines pass over a window portion (information acquisition region) in a central region. Second heating lines are arranged in side regions on both sides parallel to the first heating lines. Width of the heating lines is reduced near the window portion for more effective defogging. Width of heating lines is increased in other regions to reduce the amount of heat generation. WO2019107460A1 (Ogawa) discloses a windshield.
WO2018055390A1 (Day) and WO2019131928A1 (Yasuda) disclose a wire-heated window having a wire-free area located inside a conductive member or “busbar ring”.
An object of the present invention is to provide an alternative glazing which achieves faster defogging or defrosting in a required region.
A further object of the present invention is to provide a method of manufacturing such a glazing.
The present invention provides, in a first aspect, a glazing according to claim 1.
The glazing comprises at least one gap on one side of the third busbar opposite a conductor on the other side.
Preferably, the glazing comprises a fourth busbar positioned between the third busbar and the second busbar wherein the second group of conductors extends to the fourth busbar to form the second resistor and a third group of conductors extends from the fourth busbar to the second busbar to form a third resistor.
Preferably, in the glazing, more conductors extend from a side of the fourth busbar facing the second busbar than extend from a side of the fourth busbar facing the third busbar.
In the glazing, an information acquisition area is arranged between the third busbar and the second busbar.
Preferably, the information acquisition area is arranged between the third busbar and the fourth busbar.
In the glazing, fewer conductors extend from a side of the third busbar facing the second busbar than extend from a side of the third busbar facing the first busbar outside the information acquisition area.
Preferably, the at least one gap is positioned outside the information acquisition area.
Preferably, the conductors are heating wires.
Preferably, a group of conductors extends from the first busbar to the second busbar to form a parallel resistor, or a split busbar to form a split busbar parallel resistor and a distance between the first busbar and the split busbar is selected to be different from a distance between the first busbar and the second busbar.
Preferably, a power density in a region of the second resistor is greater than a power density of the first resistor or the parallel resistor or the split busbar parallel resistor, or any combination thereof.
Preferably, the glazing comprises outer and inner plies of glazing material and a ply of interlayer material therebetween to form a laminated glass wherein first and second resistors are between the ply of interlayer material and the inner ply of glazing material. Conductors may be in contact with outer or inner plies of glazing material, or an additional ply of interlayer material.
The glazing may have any suitable shape, for example trapezoidal, rectangular or triangular. Glazing thickness including all glazing material, interlayer material and conductors may be any thickness, for example 2.5 mm to 10.6 mm, preferably 2.6 mm to 3.8 mm, more preferably 2.7 mm to 3.2 mm. Glazing material may be any suitable material, for example soda-lime-silica glass or borosilicate glass.
The outer ply of glazing material may be any thickness, for example, to suit a requirement for durability and impact resistance against flying stones. On the other hand, as thickness increase, weight increases, which is undesirable. The outer ply of glazing material thickness may be 1.6 mm to 2.5 mm, more preferably 1.9 mm to 2.1 mm.
The inner ply of glazing material may be any thickness, for example, to suit a requirement to reduce weight of the glazing. The inner ply of glazing material thickness may be less than the outer ply of glazing material thickness, for example 0.6 mm to 2.1 mm, more preferably 0.8 mm to 1.6 mm, most preferably 0.8 to 1.3 mm.
The glazing may comprise two or more plies of interlayer material. The interlayer material may be polyvinyl butyral (PVB) which is advantageous because it exhibits good adhesion after lamination to glass and allows conductors in the form of wires to be embedded during manufacture. PVB thickness may be any thickness, for example 0.76 mm.
The conductors may be any material, for example wires of copper, tungsten, silver, gold, aluminium and alloys thereof. Conductors may have any resistivity, for example 116 ohm/m. Conductors may have any shape in cross-section, for example circle or rectangle, and any thickness, for example 30 μm or less, or any width, for example 30 μm or less.
Conductors may be of any shape on the glazing, for example linear or a wavy shape, such as a sine wave. Wavy conductors may have any amount of extension of path length, for example 107%. Conductors may be crimped wires. Conductors may have any pitch, i.e. spacing of adjacent wires, for example greater than or equal to 1.25 mm, preferably 1.8 mm to 4.5 mm, more preferably 2 mm to 2.6 mm. Conductors may be parallel or fanned with different spacing at the top and bottom of the window.
The present invention provides, in a second aspect, a method of manufacturing a glazing according to claim 10.
Preferably, the method of manufacturing a glazing further comprises a step of removing at least a part of at least one conductor on one side of the third busbar to form a gap in the second resistor.
Conductors may be removed by any method, for example laser ablation, ultrasonic cutting, ablation by passing electric current, or cutting with a knife.
The plurality of conductors in the form of wires may be embedded in the ply of interlayer material using a wire laying apparatus. The wire laying apparatus may bend the wire to provide crimped wire and embed the wire in the ply of interlayer material using a pressure roller.
The present invention provides, in a third aspect, use of a glazing in a motor vehicle as a windshield, a rear window, side window or roof window, or as a window in an aircraft, in a train or in a building.
The present invention provides a glazing providing faster defogging or defrosting in a required region. The region may be a viewing region of a vehicle windshield for a driver or a device capable of obtaining information from outside the vehicle such as a camera. With the invention, the camera is ready before the driver. An Advanced Driver Assistance System (ADAS) depending on the camera for information is enabled to be ready before the driver.
The present invention provides a method for manufacturing said glazing which is simpler than conventional methods. The present invention does not need a transfer sheet and corresponding method steps for transferring to a glazing.
The following is a description with reference to the drawings, wherein reference numerals have the same meaning throughout.
First busbar 1 and second busbar 2 are provided, shown adjacent upper and lower edges of the glazing 1 for connection to an external electrical supply (not shown). A third busbar 3 is positioned between first and second busbars, shown as parallel to and closer to first busbar 1. Conductors 5 are electrically connected to the first busbar 1.
A first group of conductors extends from the first busbar 1 to the third busbar 3 to form a first resistor R1. A second group of conductors extends from a side of the third busbar 3 facing the second busbar 2 and is electrically connected to the second busbar 2 to form a second resistor R2. First resistor 1 and second resistor 2 are electrically in series forming a series combination so the same current flows through resistor 1 and resistor 2.
Fewer conductors extend from a side of the third busbar 3 facing the second busbar 2 than extend from a side of the third busbar 3 facing the first busbar 1. One of the conductors of the second resistor R2 has been removed to form a gap 6.
A parallel resistor R is arranged to one side of first and second resistors R1, R2 and is electrically in parallel with them so that the same voltage is applied to parallel resistor R and the series combination of first and second resistors R1, R2. Parallel resistor R is connected to first and second busbars 1, 2, in the same way as the series combination of first and second resistors R1, R2.
The following is a description of non-limiting examples of the present invention.
Table 1 shows results of a first simulation of a glazing generally as
Table 1 discloses increased power density for a comparative example having no conductors removed (gaps) and four examples having between two and twelve fewer conductors in the second resistor R2 than in the first resistor R1.
Table 2 shows results of a second simulation of a glazing generally as
Table 2 discloses increased power density for the example having four conductors removed (gaps) in an information acquisition area and having a distance from the second resistor to the first busbar different from a distance from the second resistor to the second busbar.
Table 2 shows that power density above/below the second resistor R2 is 591 W/m2. To achieve the nominal power density across the glazing the split busbar 8 of
Table 3 discloses results of a third simulation of a glazing generally as
764
879
600
753
600
Difference in distance between busbars is 886−879=7 mm. Reducing the distance between busbars in the series combination R1, R2, R3 compared with the distance between busbars in the parallel resistor restores nominal power density to first and third resistors to compensate for the increased resistance of the second resistor due to the fewer conductors therein.
In all simulations the applied voltage is 12.33 volts. Conductor spacing is 2.6 mm. Conductors are simulated as wires of resistivity 116 ohms/m and having increased path length due to crimped shape of 107%.
The present invention may have any number of required regions having fewer conductors extending from the side of an additional busbar facing the second busbar than extend from a side of the additional busbar facing the first busbar. Two or more regions may be spaced across the width of the glazing, for example left and right for stereo cameras. Two or more regions may be spaced along the height of the glazing, for example a series combination of first, second, third, fourth and fifth resistors having third, fourth, fifth and sixth busbars between them. Second and fourth resistors have fewer conductors, providing higher power density in two regions, for example at top and bottom of the glazing.
First and second groups of conductors may be partly formed by a plurality of continuous wires which are partly overlapped by at least first, second and third busbars.
The method of manufacturing may comprise a step of embedding a plurality of conductors in the form of continuous wires in a ply of interlayer material. Preferably, sections of selected continuous wires between the third busbar and the second busbar or the fourth busbar are cut and removed.
First, second and third examples according to the invention and one comparative example were made. The examples were as
In a standard defrost test known in the art, time required for the information acquisition area to reach the temperature 0° was measured for each example relative to the time required for the comparative example. The first example was 30 seconds faster, the second example was 60 seconds faster and the third example was 80 seconds faster.
1, 2, 3, 4: First, second, third, fourth busbar
5: Conductors
6: Gap
7: Information acquisition area
8: Split busbar
10: Glazing
11: Outer ply of glazing material
12: Inner ply of glazing material
13: Ply of interlayer material
R: Parallel resistor
R1, R2, R3: First, second, third resistor
R8: Split busbar parallel resistor
Number | Date | Country | Kind |
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2000442.0 | Jan 2020 | GB | national |
Filing Document | Filing Date | Country | Kind |
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PCT/GB2021/050062 | 1/12/2021 | WO |