Rotary coater with coating element that substantially maintains speed during use, and device for the additive manufacture of an object using the rotary coater

The invention claimed is: 1. A coater for a device for additive manufacture of an object, comprising: a support rotatably connected to the device at an axis of rotation; said support rotatably movable about said axis of rotation within a build field; the build field being in a plane perpendicular to the axis of rotation; a coating element coupled to the support and configured to smooth a powder layer in the build field during a rotational motion of the support, a first guide plate and a second guide plate attached to the device at a location where the support is connected to the device at the axis of rotation, the first guide plate having a first guide profile and the second guide plate having a second guide profile; a first force-transmitting element and a second force-transmitting element respectively having a first sliding element and a second sliding element and which are guided on the support such that, during the rotational motion of the support, the first sliding element of the first force-transmitting element slides on the first guide profile and the second sliding element of the second force-transmitting element slides on the second guide profile and the force-transmitting elements thus slide relative to the support; wherein the coating element is configured to maintain its orientation during the rotational motion of the support within the build field; and wherein the coating element is configured to move in translation over a straight movement path within a predetermined rotational range of the support. 2. The coater as claimed in claim 1 , wherein the support has, at a distance from the axis of rotation, a slot that is oriented in the direction of the axis of rotation or a peg arranged parallel to the axis of rotation; the coating element having a peg arranged parallel to the axis of rotation or a slot which is oriented in the direction of the axis of rotation, wherein the peg of the coating element is received and can move in the slot of the support or the peg of the support is received and can move in the slot of the coating element; the first force-transmitting element is applied to the coating element via a first pivot member and the second force-transmitting element is applied to the coating element via a second pivot member, and the first and second pivot members are spaced apart from the peg of the support or of the coating element. 3. The coater as claimed in claim 2 , wherein the coating element is suspended from the support via the peg of the support or of the coating element. 4. The coater as claimed in claim 2 , wherein the guide plates are cam plates. 5. The coater as claimed in claim 4 , wherein at least one of the guide profiles are defined by a sine or cosine function that is a function of a length of the support and of a rotation angle range in which the coating element executes a movement profile. 6. A device for the additive manufacture of an object comprising the coater according to claim 1 . 7. An apparatus for applying successive layers of powder material in a build field of a device for additive manufacture of an object, comprising: a support to which is coupled a coating element having a length extending in a longitudinal direction over the build field, the coating element being adapted to move and thereby smooth a layer of powder supplied to the build field over the build field in the course of additive manufacture; the support being mounted so as to rotate about an axis where the axis is perpendicular to a plane defining the build field, with the coating element moving over the build field from a first edge of the build field to a second edge of the build field, the coating element being coupled to the support during a rotational motion of the support within the build field; a compensation mechanism communicating with the coating element, the compensation mechanism including at least a first guide plate having a first guide profile and at least a first force-transmitting element having a first sliding element which are guided on the support such that, during the rotational motion of the support, the first sliding element of the first force-transmitting element slides on the first guide profile, moving the coating element relative to the support so as to maintain the coating element in a straight movement path relative to the build field without movement of the coating element in the longitudinal direction during the rotational motion of the support within the build field. 8. The coater as claimed in claim 2 , wherein the coating element is suspended from the force-transmitting elements via the first and second pivot members.