Insulating multiple glazing including two low-emissivity stacks

The invention claimed is: 1. A multiple glazing unit obtained by associating a plurality of glass substrates separated by gas-filled cavities, a front face of a first glass substrate defining an external wall of the multiple glazing unit and a back face of a last glass substrate defining an internal wall of the multiple glazing unit, wherein the multiple glazing unit comprises: a first low-E film multilayer comprising at least one functional metallic film; and a second low-E film multilayer comprising at least one functional film comprising a transparent conductive oxide, wherein the second low-E film multilayer is deposited on the back face of the last glass substrate, forming the internal wall of the glazing unit, wherein the first low-E film multilayer is deposited on the other face of the last glass substrate or on the face of a preceding glass substrate facing the other face, and wherein a film essentially of silicon oxide and having a physical thickness from 40 to 90 nm is placed, in the second low-E film multilayer and, relative to the surface of the last glass substrate, on the functional film comprising the transparent conductive oxide. 2. The multiple glazing unit of claim 1 , which is a double glazing unit obtained by associating two glass substrates separated by a gas-filled cavity, the first substrate defining faces 1 and 2 of the double glazing unit, the second substrate defining faces 3 and 4 of the double glazing unit, face 1 defining the external wall and face 4 defining the internal wall, wherein the double glazing unit comprises: the first low-E film multilayer comprising the at least one functional metallic film, wherein the first low-E film multilayer is deposited on face 2 or 3 of the double glazing unit; and the second low-E film multilayer comprising the at least one functional film comprising a transparent conductive oxide, wherein the second low-E film multilayer is deposited on the second substrate on face 4 of the double glazing unit, wherein the film made essentially of silicon oxide is placed, on face 4 and, relative to the surface of the second glass substrate, on the functional film comprising the transparent conductive oxide, in the second low-E film multilayer. 3. The multiple glazing unit of claim 1 , which is a triple glazing unit obtained by associating three glass substrates separated by gas-filled cavities, the first glass substrate defining faces 1 and 2 of the triple glazing unit, the second glass substrate defining faces 3 and 4 of the triple glazing unit, the third glass substrate defining faces 5 and 6 of the glazing unit, face 1 defining the external wall and face 6 defining the internal wall, wherein the triple glazing unit comprises: the first low-E film multilayer comprising at least one functional metallic film, wherein the first low-E film multilayer is deposited on face 4 or 5 of the triple glazing unit; and the second low-E film multilayer comprising at least one functional film comprising a transparent conductive oxide, wherein the second low-E film multilayer is deposited on the second glass substrate on face 6 of the triple glazing unit, wherein the film made essentially of silicon oxide is placed, on face 6 and, relative to the surface of the third glass substrate, on the functional film comprising the transparent conductive oxide, in the second low-E film multilayer. 4. The multiple glazing unit of claim 1 , wherein the film made essentially of silicon oxide contacts the transparent conductive oxide film of the second low-E film multilayer. 5. The multiple glazing unit of claim 1 , wherein the film made essentially of silicon oxide is the outermost film of the second low-E film multilayer. 6. The multiple glazing unit of claim 1 , wherein the metallic film is a silver film or a silver alloy film. 7. The multiple glazing unit of claim 1 , wherein the transparent conductive oxide film is selected from the group consisting of a mixed indium tin oxide (ITO, a tin oxide doped with fluorine (SnO 2 :F), a tin oxide doped with antimony (Sb), aluminum-doped ZnO (AZO), gallium-doped ZnO (GZO), gallium and aluminum codoped ZnO (AGZO), and niobium-doped titanium oxide (TiO 2 :Nb). 8. The multiple glazing unit of claim 1 , wherein the physical thickness of the metallic film is from 6 to 16 nm and wherein the thickness of the transparent conductive oxide film is from 50 to 400 nm. 9. The multiple glazing unit of claim 8 , wherein the physical thickness of the metallic film is from 6 to 10 nm and wherein the thickness of the transparent conductive oxide film is from 80 to 300 nm. 10. The multiple glazing unit of claim 8 , wherein the physical thickness of the metallic film is from 10 to 12 nm and wherein the thickness of the transparent conductive oxide film is from 50 to 200 nm. 11. The multiple glazing unit of claim 8 , wherein the physical thickness of the metallic film is from 12 to 16 nm and wherein the thickness of the transparent conductive oxide is from 100 to 400 nm. 12. The multiple glazing unit of claim 1 , wherein the second low-E film multilayer comprises, under the functional film comprising the transparent conductive oxide, at least one nitride dielectric film. 13. The multiple glazing unit of claim 1 , wherein the second low-E film multilayer comprises the following films in succession, from the surface of the glass substrate: glass/silicon nitride/silicon oxide/ITO/optionally silicon nitride/silicon oxide, and optionally comprises additional intermediate films inserted between these various films. 14. The multiple glazing unit of claim 1 , wherein the second low-E film multilayer comprises the following films in succession, from the surface of the glass substrate: glass/silicon oxide or oxycarbide/SnO 2 :F/silicon oxide, and optionally comprises additional intermediate films inserted between these various films. 15. The multiple glazing unit of claim 1 , wherein the film made essentially of silicon oxide has a physical thickness from 40 to 80 nm. 16. The multiple glazing unit of claim 7 , wherein the transparent conductive oxide is a mixed indium tin oxide having an In 2 O 3 /SnO 2 mass ratio of 90/10 or more. 17. The multiple glazing unit of claim 12 , wherein the nitride dielectric film is silicon nitride, aluminum nitride, or a mixture thereof. 18. The multiple glazing unit of claim 2 , wherein the film made essentially of silicon oxide is the outermost film of the second low-E film multilayer. 19. The multiple glazing unit of claim 3 , wherein the film made essentially of silicon oxide is the outermost film of the second low-E film multilayer.