Three-dimensional printing system

What is claimed is: 1. A tank assembly, comprising: a tank sidewall, wherein a bottom rim of the tank sidewall comprises a groove; a tension sensor coupled to the tank sidewall; a radiation-transparent flexible membrane; and a frame secured to a perimeter of the radiation-transparent flexible membrane, wherein the frame comprises a lip that engages with the groove of the bottom rim of the tank sidewall, and wherein the tension sensor is configured to detect a movement of the radiation-transparent flexible membrane upon a loss of tension of the radiation-transparent flexible membrane. 2. The tank assembly of claim 1 , wherein the frame is configured to stretch the radiation-transparent flexible membrane along a first plane, wherein the frame comprises a top planar surface that extends parallel to the first plane, a bottom planar surface that extends parallel to the first plane, and wherein the perimeter of the radiation-transparent flexible membrane is secured to a portion of the frame between the top and bottom planar surfaces of the frame. 3. A three-dimensional (3D) printing system, comprising: a tank assembly comprising: a tank sidewall, wherein a bottom rim of the tank sidewall comprises a groove; a radiation-transparent flexible membrane; and a first frame secured to a perimeter of the radiation-transparent flexible membrane, wherein the first frame comprises a lip that engages with the groove of the bottom rim of the tank sidewall; a lighting assembly comprising: a glass plate secured within a second frame; and a liquid crystal display (LCD) secured within a third frame, wherein the second frame is secured to the third frame, wherein the second frame is configured to displace a portion of the radiation-transparent flexible membrane away from a first plane into a second plane parallel to the first plane, and wherein the first plane defines a region in which the radiation-transparent flexible membrane lies absent the displacement of the portion of the radiation-transparent flexible membrane by the second frame; a base portion configured to support at least one of the third frame or the LCD; and a height adjustment mechanism disposed between the first frame and the base portion, the height adjustment mechanism configured to adjust a vertical position of the first frame with respect to the base portion, and in turn adjust the displacement of the portion of the radiation-transparent flexible membrane with respect to the first plane. 4. The 3D printing system of claim 3 , further comprising a tension adjustment mechanism coupled to the radiation-transparent flexible membrane and configured to adjust a tension of the radiation-transparent flexible membrane. 5. The 3D printing system of claim 3 , further comprising a tension sensor affixed to a surface of the radiation-transparent flexible membrane and configured to measure a tension of the radiation-transparent flexible membrane. 6. The 3D printing system of claim 5 , wherein the tension sensor comprises a strain gauge affixed to the surface of the radiation-transparent flexible membrane. 7. The 3D printing system of claim 3 , further comprising a tension sensor embedded within the radiation-transparent flexible membrane and configured to measure a tension of the radiation-transparent flexible membrane. 8. A three-dimensional (3D) printing system, comprising: a tank assembly comprising: a tank sidewall, wherein a bottom rim of the tank sidewall comprises a groove; a radiation-transparent flexible membrane; and a first frame secured to a perimeter of the radiation-transparent flexible membrane, wherein the first frame comprises a lip that engages with the groove of the bottom rim of the tank sidewall; a lighting assembly comprising: a glass plate secured within a second frame; and a liquid crystal display (LCD) secured within a third frame, wherein the second frame is secured to the third frame, wherein the second frame is configured to displace a portion of the radiation-transparent flexible membrane away from a first plane into a second plane parallel to the first plane, and wherein the first plane defines a region in which the radiation-transparent flexible membrane lies absent the displacement of the portion of the radiation-transparent flexible membrane by the second frame; a base portion configured to support the first frame; and a height adjustment mechanism disposed between the base portion and at least one of the third frame or the LCD, the height adjustment mechanism configured to adjust a vertical position of the LCD with respect to the base portion, and in turn adjust the displacement of the portion of the radiation-transparent flexible membrane with respect to the first plane. 9. The 3D printing system of claim 7 , wherein the tension sensor comprises a conductive strip. 10. The 3D printing system of claim 8 , further comprising a tension adjustment mechanism coupled to the radiation-transparent flexible membrane and configured to adjust a tension of the radiation-transparent flexible membrane. 11. The 3D printing system of claim 8 , further comprising a tension sensor affixed to a surface of the radiation-transparent flexible membrane and configured to measure a tension of the radiation-transparent flexible membrane. 12. The 3D printing system of claim 11 , wherein the tension sensor comprises a strain gauge affixed to the surface of the radiation-transparent flexible membrane. 13. The 3D printing system of claim 8 , further comprising a tension sensor embedded within the radiation-transparent flexible membrane and configured to measure a tension of the radiation-transparent flexible membrane. 14. The 3D printing system of claim 13 , wherein the tension sensor comprises a conductive strip. 15. A three-dimensional (3D) printing system, comprising: a tank assembly comprising: a tank sidewall, wherein a bottom rim of the tank sidewall comprises a groove; a radiation-transparent flexible membrane; and a first frame secured to a perimeter of the radiation-transparent flexible membrane and configured to stretch the radiation-transparent flexible membrane along a first plane, wherein the first frame comprises a top planar surface that extends parallel to the first plane, a bottom planar surface that extends parallel to the first plane, and a lip extending from the top planar surface in a direction perpendicular to the first plane, wherein the perimeter of the radiation-transparent flexible membrane is secured to a portion of the first frame between the top and bottom planar surfaces of the first frame, and wherein the lip engages with the groove of the bottom rim of the tank sidewall; and a liquid crystal display (LCD) secured within a second frame, wherein the second frame is configured to displace a portion of the radiation-transparent flexible membrane away from the first plane into a second plane parallel to the first plane, wherein the first plane defines a region in which the radiation-transparent flexible membrane lies absent the displacement of the portion of the radiation-transparent flexible membrane by the second frame. 16. The 3D printing system of claim 15 , further comprising a tension adjustment mechanism coupled to the radiation-transparent flexible membrane and configured to adjust a tension of the radiation-transparent flexible membrane. 17. The 3D printing system of claim 15 , further comprising a tension sensor affixed to a surface of the radiation-transparent flexible membrane and configured to measure a tension of the radiation-transparent flexible membrane.