Ruggedized switchable glazing, and/or method of making the same

What is claimed is: 1. A window comprising: an inner glass substrate and an outer glass substrate, the inner and outer glass substrates being substantially parallel to one another; a multi-layer low-emissivity (low-E) ultraviolet (UV) blocking coating comprising first and second IR reflecting layers comprising silver supported by an inner surface of the outer glass substrate, the low-E UV blocking coating blocking significant amounts of UV in the range of from about 380-400 nm; a liquid crystal inclusive layer disposed between at least the inner and outer glass substrates; first and second substantially transparent conductive layers, the first and second substantially transparent conductive layers being provided between the liquid crystal inclusive layer and the outer and inner glass substrates, respectively; first and second polymer inclusive laminating layers, the first laminating layer provided between at least the liquid crystal inclusive layer and the outer glass substrate and the second laminating layer provided between at least the liquid crystal inclusive layer and the inner glass substrate; at least one bus bar in electrical communication with at least one of the first and second transparent conductive layers so as to cause the liquid crystal inclusive layer to become activated when a voltage is applied thereto; and a polymer barrier at a periphery of the liquid crystal inclusive layer, the polymer barrier being positioned to reduce (a) migration of the first and/or second polymer inclusive laminating layers over time, and (b) an amount of pushing against the liquid crystal inclusive layer, wherein the multi-layer low-E UV blocking coating comprises at least one IR reflecting layer and at least one UV blocking layer so that no more than about 20% of ambient light having a wavelength of from 380-400 nm reaches the liquid crystal inclusive layer, and wherein the window has a visible transmission of at least about 55% when the liquid crystal inclusive layer is activated. 2. The window of claim 1 , wherein the first and second polymer inclusive laminating layers are encapsulated at edges thereof. 3. The window of claim 1 , wherein off-axis haze is less than or equal to about 4 at an incidence of approximately 45° when the liquid crystal inclusive layer is activated. 4. The window of claim 1 , wherein off-axis haze is less than or equal to about 3 at an incidence of approximately 45° when the liquid crystal inclusive layer is activated. 5. The window of claim 1 , wherein off-axis haze is less than or equal to about 2 at an incidence of approximately 45° when the liquid crystal inclusive layer is activated. 6. The window of claim 1 , wherein the liquid crystal inclusive layer is stable up to at least about 110° C. 7. The window of claim 1 , wherein the liquid crystal inclusive layer is stable up to at least about 120° C. 8. The window of claim 1 , wherein the window has a visible transmission of no more than 1.815% when the liquid crystal inclusive layer is deactivated. 9. An insulating glass window unit, comprising: at least first, second and third substantially parallel glass substrates; a multi-layer low-E UV blocking coating comprising first and second IR reflecting layers comprising silver supported by a surface of the second glass substrate facing the third substrate; a liquid crystal inclusive layer disposed between the second and third glass substrates; first and second transparent conductive layers, the first and second transparent conductive layers being provided between at least the liquid crystal inclusive layer and the second and third glass substrates, respectively; at least one bus bar electrically connected to at least one of the first and second transparent conductive layers so as to cause the liquid crystal inclusive layer to become activated when at least a predetermined voltage is applied to the bus bar, wherein the first and second glass substrates are spaced apart from each other, wherein the multi-layer low-E UV blocking coating comprises at least one UV blocking layer in order to block significant amounts of UV radiation in the range of from 380-400 nm so that no more than about 20% of ambient light having a wavelength of from 380-400 nm reaches the liquid crystal inclusive layer, and wherein the insulating glass unit has a visible transmission of at least about 50% and is clear when the liquid crystal inclusive layer is activated, and appears whitish when the liquid crystal inclusive layer is deactivated as a result of light scattering caused by the liquid crystal inclusive layer. 10. The insulating glass window unit of claim 9 , further comprising first and second polymer inclusive laminating layers that are encapsulated at edges thereof. 11. The insulating glass window unit of claim 9 , wherein off-axis haze is less than or equal to about 4 at an incidence of approximately 45° when the liquid crystal inclusive layer is activated. 12. The insulating glass window unit of claim 9 , wherein off-axis haze is less than or equal to about 3 at an incidence of approximately 45° when the liquid crystal inclusive layer is activated. 13. The insulating glass window unit of claim 9 , wherein off-axis haze is less than or equal to about 2 at an incidence of approximately 45° when the liquid crystal inclusive layer is activated. 14. The insulating glass window unit of claim 9 , wherein the liquid crystal inclusive layer is stable up to at least about 110° C. 15. The insulating glass window unit of claim 9 , wherein the liquid crystal inclusive layer is stable up to at least about 120° C. 16. The insulating glass window unit of claim 9 , wherein the insulating glass unit has a visible transmission of no more than 1.815% when the liquid crystal inclusive layer is deactivated.