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The invention relates to a method and a device for applying for a flowable material, especially a particulate material, in individual superimposed layers across a support (50), the flowable material being first filled from a stationary feed station (10) into a storage container (24) of an applicatio

The invention relates to a method and a device for applying for a flowable material, especially a particulate material, in individual superimposed layers across a support (50), the flowable material being first filled from a stationary feed station (10) into a storage container (24) of an application device. In the application device (30), which travels back and forth across the support, the flowable material is distributed inside the storage container across the entire length of the device and is then metered through a slot into a metering shaft in such a manner that the filling level in the metering shaft remains constant during application of the flowable material from the metering shaft onto the support.

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The invention claimed is: 1. A method of applying flowable particulate material across the surface of a substrate in individual superimposed layers to produce a three-dimensional object by selective solidification of the successive layers, in which method the flowable particulate material is introd

The invention claimed is: 1. A method of applying flowable particulate material across the surface of a substrate in individual superimposed layers to produce a three-dimensional object by selective solidification of the successive layers, in which method the flowable particulate material is introduced, from a material supply which has been introduced into a charging container, into an elongate, cross-sectionally hopper metering shaft over the entire length thereof, the metering shaft is moved back and forth over the substrate and, during the movement, the particulate material introduced is discharged downward in a continuous layer from a slot on the underside of the metering shaft and distributed uniformly, wherein the supply of flowable particulate material is uniformly distributed in the charging container, the charging container is moved over the substrate together with the metering shaft and, during the movement, the metering shaft is filled with flowable particulate material from the material supply such that the filling height in the metering shaft remains constant. 2. A method of applying flowable particulate material across a surface of a substrate in individual superimposed layers to produce a three-dimensional object by selective solidification of the successive layers, said method comprising: uniformly distributing flowable particulate material within a charging container, transferring flowable particulate material from the charging container to a metering shaft, discharging flowable particulate material downward in a continuous layer onto a surface of a substrate forming a uniform surface by moving the metering shaft and the charging container back and forth together over the surface of the substrate; while the metering shaft is depositing flowable particulate material, refilling the metering shaft to maintain a constant filling height of flowable particulate material in the metering shaft by transferring flowable particulate material from the charging container to the metering shaft. 3. An application apparatus for applying flowable particulate material across a surface of a substrate in individual superimposed layers, said apparatus comprising: an elongated metering shaft having a pair of opposing walls angled relative to each other, an open top formed between said pair of opposing walls, and a slot along a bottom of said measuring shaft between said pair of opposing walls, the slot is narrower between said opposing walls than the opening; a charging container which is open in an upward direction away from said metering shaft and located above said metering shaft, said charging container having a slot in a side wall proximate to a bottom of said charging container with a cavity from the slot to a top of said charging container, the slot is in communication with the open top of said metering shaft; said charging container includes a distribution device in the cavity spaced from the slot of said charging container; said metering shaft and said charging container move together across a substrate and form a pathway for flowable particulate material to travel and be deposited on the substrate from said metering shaft while maintaining a substantially constant filing height of flowable particulate material in said metering shaft. 4. An application apparatus for applying flowable particulate material across a surface of a substrate in individual superimposed layers, said apparatus comprising: an elongated metering shaft having a pair of opposing walls angled relative to each other, an open top formed between said pair of opposing walls, and a slot along a bottom of said measuring shaft between said pair of opposing walls, the slot is narrower between said opposing walls than the opening; a charging container which is open in an upward direction away from said metering shaft and located above said metering shaft, said charging container having a slot in a side wall proximate to a bottom of said charging container with a cavity from the slot to a top of said charging container, the slot is in communication with the open top of said metering shaft; said metering shaft and said charging container move together across a substrate and form a pathway for flowable particulate material to travel and be deposited on the substrate from said metering shaft while maintaining a substantially constant filing height of flowable particulate material in said metering shaft. 5. The apparatus according to claim 4, further comprising a vibrating beam below said charging container. 6. The apparatus according to claim 5, wherein said vibrating beam is along a side of said metering shaft, and a means for maintaining the substantially constant filling height of the flowable particulate material during use of the apparatus is a top boundary of the slot of said charging container. 7. The apparatus according to claim 4, wherein said charging container includes a base wall dividing said charging container into two areas and obliquely descending to said slot at an angle. 8. The apparatus according to claim 7, wherein the angle of said base wall is adjustable. 9. The apparatus according to claim 4, wherein said charging container includes a roller along a length of the slot of said charging container, said roller arranged to rotate in the cavity of said charging container to discharge flowable particulate material through the slot to said metering shaft. 10. The apparatus according to claim 9, further comprising a control unit connected to said roller, and a fill sensor in said metering shaft connected to said control unit; and wherein said control unit operates said roller to maintain a substantially constant height of flowable particulate material in said metering shaft. 11. The apparatus according to claim 4, wherein said charging container includes a driven belt arranged to move flowable particulate material from said charging container through the slot to said metering shaft. 12. The apparatus according to claim 11, further comprising a control unit connected to said driven belt, and a fill sensor in said metering shaft connected to said control unit; and wherein said control unit operates said driven belt to maintain a substantially constant height of flowable particulate material in said metering shaft. 13. The apparatus according to claim 11, wherein said driven belt is the bottom of said charging container. 14. The apparatus according to claim 4, wherein said charging container includes a door in sliding engagement with said side wall with the slot and orientated to move over the slot of said charging container to adjust a height of the slot. 15. The apparatus according to claim 4, wherein said charging container includes a base wall extending upward from a bottom of said charging container at a point spaced from said slot and tapering the cavity for flowable particulate material toward the slot. 16. The apparatus according to claim 4, wherein one side wall of said metering shaft is aligned with said side wall with the slot of said charging container. 17. The apparatus according to claim 4, wherein said charging container includes a distribution device in the cavity spaced from the slot of said charging container; said charging container receives a material supply of the particulate material; and the slot discharges particulate material from the material supply into said metering shaft.