Abstract: A 3D printing apparatus and a method thereof are provided. The apparatus includes base, forming platform, nozzle module, curing module, first sensor and second sensors and control module. The forming platform is movably disposed on the base along an axial direction. The nozzle module and the curing module are disposed on the base and located above the forming platform. The first and second sensors are movably disposed on the base and located at two opposite sides of the nozzle module and the curing module along the axial direction. A predetermined range of the 3D object on the forming platform has first and second endpoints along the axial direction, and the first and second sensors respectively correspond to the first and second endpoints. The control module determines whether the nozzle module impacts the 3D object according to a sensing time difference of the first and second sensors.

Abstract: A 3D printing apparatus including a light source, a DMD, a projection lens and a photo sensor is provided. The light source emits a light. The DMD is disposed on a transmission path of the light, and has multiple first micromirrors and second micromirrors. The first micromirrors reflect a first part of the light to the projection lens. The projection lens projects the first part of the light to a working liquid to cure the same. The second micromirrors reflect a second part of the light to the outside of the projection lens. By monitoring intensity of the second part of the light, it is determined whether an intensity of the light is decayed. Since the photo sensor is disposed on the transmission path of the second part of the light, allocation of the photo sensor does not influence image resolution and/or image range.

Abstract: An automotive intraoral scanner applied in a mouth includes a biting piece, a track piece and at least one mobile image processing set. The biting piece is sandwiched between two rows of teeth. The track piece is installed in the biting piece and disposed corresponding to the rows of teeth, and a shape of the track piece is similar to a shape of the rows of teeth. The mobile image processing set is installed on the track piece and moved along the track piece, and the mobile image processing set is disposed corresponding to the rows of teeth. Therefore, the automotive intraoral scanner has advantages of easy operation.

Abstract: A slicing printing method for color 3D model is disclosed. The method comprises following steps of: building a color 3D object into a coloring model; dividing the coloring model into a plurality of color cells, wherein a shell of each of the color cells forms an accommodating space configured to accommodate a color material; setting respectively the color of the color material accommodated by each color cell according to the color of the color 3D object and generating a printing color data corresponding to the color 3D model; generating a printing object data associated with the printing color data according to the color cells. The disclosed example can effectively realize the printing of the color 3D model through the inkjet manner via generating color cells configured to accommodate color materials.

Abstract: A photocuring type 3D printer includes a sink (31) containing forming liquid (30), a membrane (312) disposed on the internal bottom of the sink (31), an emitting unit (33) disposed below the sink (31), a forming platform (32) disposed above the sink (31), and a peeling detector (34). When printing, the 3D printer (3) controls the forming platform (32) to move along a z axis to a printing height of the model (4), and controls the emitting unit (33) to emit lights. After solidifying, the 3D printer (3) controls the forming platform (32) to raise along the z axis for performing a peeling procedure, and the peeling detector (34) to continue detecting the attachment status between the model (4) and the membrane (312). When the peeling detector (34) detects the model (4) peeled from the membrane (312), the 3D printer (3) controls the forming platform (32) to stop raising.

Abstract: A photocuring type 3D printer (4) includes a sink (41) for containing a forming liquid (40), a glass layer (42) disposed on the sink (41), a membrane (43) disposed above the glass layer (42), an emitting unit (46) disposed below the sink (41), and a forming platform (45) arranged to immerse in the forming liquid (40) for constructing a model (5). The 3D printer (4) further includes an adjusting unit (44) disposed at one side of the sink (41). One end of the membrane (43) is connected to the adjusting unit (44), and another end of the membrane (43) is connected to the other side of the sink (41) opposite to the adjusting unit (44). The 3D printer (4) controls the adjusting unit (44) to execute homing for tightening the membrane (43) before solidifying the model (5) and controls the adjusting unit (44) to move for relaxing the membrane (43) after the model (5) is solidified, and controls the forming platform (45) to move after the membrane (43) is relaxed for peeling the model (5) from the membrane (43).

Abstract: A 3D printer and a liquid level sensing method are provided. The 3D printer includes a tank and at least one capacitive sensing module for sensing a liquid level of the liquid forming material in the tank. The at least one capacitive sensing module includes a first electrode pair disposed beside the tank, and the first electrode pair is used for producing an electric field, where the electric field passes through the liquid forming material.

Abstract: A multiple light source correction apparatus and a method of use thereof are disclosed. The multiple light source correction apparatus (10) comprises a transparent thin plate (1) having a first correction pattern (12), a second correction pattern (13) and at least one third correction pattern (14). The first correction pattern (12) includes a first straight line (121) having first and second end points (1211, 1212). The second correction pattern (13) includes a second straight line (131) and two U-shaped frames (132). The second straight line (131) includes third and fourth end points (1311, 1312). The two U-shaped frame (132) is installed at externals of the third and fourth end points (1311, 1312) respectively. The third correction pattern (14) includes a third straight line (141) having fifth and sixth end points (1411, 1412). The first, second and third straight lines (121, 131, 141) are arranged parallel to each other.

Abstract: A 3D object forming device and a method thereof are provided. The device includes a tank used for containing a liquid forming material. A light source irradiates the liquid forming material to cure a 3D object layer-by-layer on a moving platform. In the irradiation process, when a target position currently irradiated by the light source is located on a first layer next to the moving platform, the light source is maintained to an original intensity; when the target position is not located on the first layer next to the moving platform, and when it is determined that a non-cured hollow layer exists in a predetermined number of layers at one side of the target position opposite to the light source according to the slicing data, the intensity of the light source is correspondingly decreased according to the number of layers between the hollow layer and the target position.

Abstract: An automotive intraoral scanner applied in a mouth includes a biting piece, a track piece and at least one mobile image processing set. The biting piece is sandwiched between two rows of teeth. The track piece is installed in the biting piece and disposed corresponding to the rows of teeth, and a shape of the track piece is similar to a shape of the rows of teeth. The mobile image processing set is installed on the track piece and moved along the track piece, and the mobile image processing set is disposed corresponding to the rows of teeth. Therefore, the automotive intraoral scanner has advantages of easy operation.

Abstract: A 3D printing apparatus and a method thereof are provided. The apparatus includes base, forming platform, nozzle module, curing module, first sensor and second sensors and control module. The forming platform is movably disposed on the base along an axial direction. The nozzle module and the curing module are disposed on the base and located above the forming platform. The first and second sensors are movably disposed on the base and located at two opposite sides of the nozzle module and the curing module along the axial direction. A predetermined range of the 3D object on the forming platform has first and second endpoints along the axial direction, and the first and second sensors respectively correspond to the first and second endpoints. The control module determines whether the nozzle module impacts the 3D object according to a sensing time difference of the first and second sensors.

Abstract: A slicing printing method for color 3D model is disclosed. The method comprises following steps of: building a color 3D object into a coloring model; dividing the coloring model into a plurality of color cells, wherein a shell of each of the color cells forms an accommodating space configured to accommodate a color material; setting respectively the color of the color material accommodated by each color cell according to the color of the color 3D object and generating a printing color data corresponding to the color 3D model; generating a printing object data associated with the printing color data according to the color cells. The disclosed example can effectively realize the printing of the color 3D model through the inkjet manner via generating color cells configured to accommodate color materials.

Abstract: A resistive touch panel is provided. The resistive touch panel includes a first conductive layer and a second conductive layer, and a plurality of electrodes is disposed on the first conductive layer and the second conductive layer. A detection area of the resistive touch panel is separated into at least two sub-detection areas through configuration of the electrodes. Thus, the resistive touch panel can calculate coordinates of a contact point corresponding to each sub-detection area at the same time, so as to achieve functions of detecting multiple touch points at the same time and detecting touch point sliding.

Abstract: A resistive touch panel is provided. The resistive touch panel includes a first conductive layer and a second conductive layer, and a plurality of electrodes is disposed on the first conductive layer and the second conductive layer. A detection area of the resistive touch panel is separated into at least two sub-detection areas through configuration of the electrodes. Thus, the resistive touch panel can calculate coordinates of a contact point corresponding to each sub-detection area at the same time, so as to achieve functions of detecting multiple touch points at the same time and detecting touch point sliding.