Humidification system

What is claimed is: 1. A humidification system for humidifying respiratory gases provided to a patient, the humidification system comprising: a heater plate; a flat heating element configured to heat the heater plate, the flat heating element comprising a non-conductive core and a filament wound around the non-conductive core, the filament having an at least partially flat cross-sectional shape with a first flat surface facing towards the non-conductive core and a second flat surface facing away from the non-conductive core, the flat heating element comprising a single layer of the filament on each side of the non-conductive core; a base supporting the heater plate and configured to receive a portion of a removable chamber that is configured to hold a liquid; and one or more springs applying an upward force to the heater plate and urging the heater plate into contact with the removable chamber wherein the heater plate comprises a first surface at a periphery of the heater plate, a second surface at least partially surrounded by the first surface, and a recess defined within the second surface that is recessed relative to the first surface and the second surface, the recess configured to receive the heating element therein. 2. The humidification system of claim 1 , wherein the upward force is about 35 Newtons (N). 3. The humidification system of claim 1 , comprising a spring assembly comprising: a first spring assembly platform supporting a base of the spring; and a screw secured to and extending downward from a bottom of the heater plate, wherein a body of the screw passes through an opening of the first spring assembly platform and a head of the screw is below the first spring assembly platform, wherein the opening of the first spring assembly platform is large enough to allow the screw body to pass through the opening without resistance but not large enough to allow the screw head to pass through the opening. 4. The humidification system of claim 3 , comprising a spring preloading assembly comprising a second spring assembly platform located below the first spring assembly platform, the second spring assembly platform including an opening that is large enough to allow the screw body to pass through the opening without resistance but not large enough to allow the screw head to pass through the opening. 5. The humidification system of claim 1 , wherein the one or more springs are preloaded so that when the chamber is inserted into the base, the heater plate is required to travel 1-3 mm without diminishing the upward force exerted by the springs on the heater plate. 6. The humidification system of claim 1 , wherein the flat heating element comprises a first end and a second end electrically connected to a respective one of a first connector and a second connector located on opposite sides of the filament wound around the non-conductive core, the system further comprising a first wire and a second wire electrically connected to a respective one of the first connector and the second connector; a first insulatory piece providing electrical insulation for the first end, the first connector, and the first wire; and a second insulatory piece providing electrical insulation for the second end, the second connector, and the second wire. 7. The humidification system of claim 6 , further comprising an insulation layer, wherein at least one of the first insulatory piece or the second insulatory piece is clamped to the insulation layer. 8. The humidification system of claim 6 , wherein the first insulatory piece comprises a first insulatory piece associated with the first end, the first connector, and the first wire and a second insulatory piece associated with the second end, the second connector, and the second wire. 9. The humidification system of claim 8 , wherein each of the first insulatory piece and the second insulatory piece comprise an annular flange. 10. The humidification system of claim 1 , comprising at least two insulation layers between the filament and the heater plate. 11. The humidification system of claim 1 , wherein an upper wall defines a continuous top surface of the base that only partially surrounds a perimeter of the heater plate. 12. The humidification system of claim 11 , wherein the base further includes a rim edge extending downward from one end of the upper wall, the one end being away from a side wall of the base, and wherein, when the removable chamber is disposed in the base, the heater plate is configured to press upward on the removable chamber while the rim edge is configured to resist an upward movement of a lip of the removable chamber, the lip protruding beyond a body of the removable chamber. 13. The humidification system of claim 11 , wherein the upper wall is configured to substantially enclose at least a portion of the heater plate. 14. The humidification system of claim 1 , wherein the one or more springs are preloaded so that when the chamber is inserted into the base, the heater plate is allowed to travel downward without diminishing the upward force exerted by the springs on the heater plate. 15. The humidification system of claim 1 , wherein the base comprises a side wall that at least partially surrounds the heater plate and an upper wall that extends inwardly from the side wall towards the heater plate to create a space beneath the upper wall configured to receive a portion of a removable chamber that is configured to hold a liquid. 16. A heating assembly in a humidification system, the heating assembly comprising: a heating plate; a non-conductive core; a base supporting the heating plate and configured to receive a portion of a removable chamber that is configured to hold a liquid; and an at least partially flat filament configured to heat the heating plate, the at least partially flat filament wound around the non-conductive core, the filament having a first flat surface facing towards the non-conductive core and a second flat surface facing away from the non-conductive core; wherein a combination of the at least partially flat filament and the non-conductive core cooperate to form a flat heating element that is configured to heat the heating plate in use, the flat heating element comprising a single layer of the filament on each side of the non-conductive core, wherein the heating plate comprises a first surface at a periphery of the heating plate, a second surface at least partially surrounded by the first surface, and a recess defined within the second surface that is recessed relative to the first surface and the second surface, the recess configured to receive the heating element therein. 17. The heating assembly of claim 16 , wherein the at least partially flat filament provides higher heating power at lower temperatures than a round filament of equivalent cross-sectional area. 18. The heating assembly of claim 16 , wherein the heating assembly is configured to heat liquid sufficient to humidify a gas flow of 80 liters per minute (Lpm) at 37 degrees Celsius. 19. The heating assembly of claim 16 , comprising at least one insulation layer between the at least partially flat filament and the heating plate. 20. The heating assembly of claim 16 , comprising a back plate, a first insulation layer between the at least partially flat filament and the back plate, and a second insulation layer between the at least partially flat filament and the heating plate. 21. The heating assembly of claim 20 , comprising an insulator piece positioned on the first in