Device for coating a carrier substrate with a powdered material and machine for producing a product strand with a dry film applied to a carrier substrate

The invention claimed is: 1. A device ( 100 ; 100 *) for coating a carrier substrate ( 006 ) with a powdered material ( 003 ), the device comprising; a first application unit ( 101 ), which comprises a first roller ( 102 ; 102 ′) and a second roller ( 103 ; 103 ′) which form a first gap ( 104 ; 104 ′) in a nip between respective outer cylindrical surfaces thereof, wherein a dry powder mixture ( 004 ) is conveyed through the first gap ( 104 ; 104 ′) in order to form a first dry film ( 003 ′), a first counter-pressure roller ( 103 ′; 106 ) which, together with the second roller ( 103 ; 103 ′), forms a second gap ( 107 ; 107 ′) through which a carrier substrate ( 006 ) to be coated is guided for having the first dry film ( 003 )-formed in the first gap ( 104 ; 104 ′) applied to a first side of the carrier substrate ( 006 ), and the first gap ( 104 ; 104 ′) between the first and second rollers ( 102 ; 102 ′; 103 ; 103 ′) being adjustable based on a position-based positioning drive ( 109 ; 109 ′), wherein the position-based positioning drive ( 109 , 109 ′) is selectively set to provide at least one of a constant or defined gap width, characterized in that the second gap ( 107 ; 107 ′) between the counter-pressure roller ( 106 ; 106 ′; 103 ′; 103 ) and the second roller ( 103 ; 103 ′) of the first application unit ( 101 ; 101 ′) is adjusted based on a force-based positioning drive ( 111 ; 111 ′) by being set to at least one of a constant or defined compression force or line force. 2. The device according to claim 1 , characterized in that a second application unit ( 101 ′) is provided in a path of the carrier substrate ( 006 ), the second application unit ( 101 ′) comprising a first roller ( 102 ; 102 ′) and a second roller ( 103 ; 103 ′) which form a first gap ( 104 ; 104 ′) of the second application unit ( 101 ′) in a nip between respective outer cylindrical surfaces thereof, wherein the dry powder mixture ( 004 ) is conveyed through the first gap ( 104 ; 104 ′) of the second application unit ( 101 ′) in order to form a second dry film ( 003 ′). 3. The device according to claim 2 , characterized in that a second counter-pressure roller ( 106 ′) is provided which, together with the second roller ( 103 ′; 103 ) of the second application unit ( 101 ′; 101 ), forms a second gap ( 107 ′) of the second application unit ( 101 ′), which differs from the second gap ( 107 ) of the first application unit ( 101 ; 101 ′) and is spaced apart in the path of the carrier substrate ( 006 ), and through which the carrier substrate ( 006 ) to be coated is guided, and to a second side of which the dry film ( 106 ) formed in the first gap ( 104 ; 104 ′) of the second application unit ( 101 ′; 101 ) is applied, and that the first gap ( 104 ′; 104 ) between the first and second rollers ( 102 ′; 102 ; 103 ′; 103 ) of the second application unit ( 101 ′; 101 ) is adjustable based on a position-based positioning drive ( 109 ′; 109 ), that is selectively settable to at least one of a constant or defined gap width, and that the second gap ( 107 ′; 107 ) between the second counter-pressure roller ( 106 ′; 106 ; 103 ; 103 ′) and the second roller ( 103 ; 103 ′) of the second application unit ( 101 ′; 101 ) is adjustable based on a force-based positioning drive ( 111 ; 111 ′), that is selectively settable to at least one of a constant or defined compression force or line force. 4. The device according to claim 2 , characterized in that the second roller ( 103 ; 103 ′) of the second application unit ( 101 ′; 101 ), together with the second roller ( 103 ; 103 ′) of the first application unit ( 101 ; 101 ′) form a shared second gap ( 107 ) in a nip between the respective outer cylindrical surfaces thereof, wherein the shared second gap ( 107 ) serves as a two-sided laminating gap ( 107 ) and through which the carrier substrate ( 006 ) to be coated is guided for having the second dry film ( 003 ′) formed in the first gap ( 104 ; 104 ′) of the second application unit ( 101 ′; 101 ) applied to a second side of the carrier substrate ( 006 ), that the shared second gap ( 107 ) is adjustable by a positioning drive ( 111 ; 111 ′) thereof at least in a force-based manner, and that the first gap ( 104 ′; 104 ) between the first and second rollers ( 102 ′; 102 ; 103 ′; 103 ) of the second application unit ( 101 ′; 101 ) is adjustable based on a position-based positioning drive ( 109 ′; 109 ) that is selectively settable to at least one of a constant or defined gap width. 5. The device according to claim 1 , characterized in that the gap width of the first gap ( 104 ; 104 ′) is selectively settable via position-based drive means or via at least one-sided stop means, which limit a placement position toward the nip and are adjustable in terms of a position thereof. 6. The device according to claim 1 , characterized in that the first gap ( 104 ; 104 ′) between the first and second rollers ( 102 ; 102 ′; 103 ; 103 ′) of the first application unit ( 101 ; 101 ′) is at least one of: selectively adjustable in a position-based or force-based manner based on a combined positioning drive ( 109 , 111 ; 109 ′, 111 ′), selectively settable to at least one of a constant or defined gap width, or selectively settable toward at least one of a constant or defined compression force or line force; and/or that one of the first or second rollers ( 102 ; 102 ′; 103 ; 103 ′) involved in the first gap ( 104 ; 104 ′) is mounted so as to be selectively adjustable in a position-based or force-based manner by a combined positioning mechanism ( 112 ; 113 ; 112 , 113 ). 7. The device according to claim 1 , characterized in that the second gap ( 107 ; 107 ′) between the second roller ( 103 ; 103 ′) of the first application unit ( 101 ′; 101 ) and the counter-pressure roller ( 106 ; 106 ′; 103 ′; 103 ) cooperating with the second roller ( 103 ; 103 ′) is at least one of: selectively adjustable in a position-based or force-based manner based on a combined positioning drive ( 109 , 111 ; 109 ′, 111 ′), selectively settable to at least one of a constant or defined gap width, or selectively settable toward at least one of a constant or defined compression force or line force; and/or that one of the second roller ( 103 ; 103 ′) or first counter-pressure roller ( 103 ′, 106 ) involved in the second gap 107 ; 107 ′) is mounted so as to be selectively adjustable in a position-based or force-based manner by a combined positioning mechanism ( 112 ; 113 ; 112 ′, 113 ′). 8. The device according to claim 6 , characterized in that the combined positioning drive ( 109 ; 109 ′; 111 ; 111 ′) is formed by a force-based positioning drive ( 111 ; 111 ′) comprising a positioning mechanism ( 112 ; 112 ′; 113 ; 113 ′), in an adjustment path of which a positionable stop is selectively introduced for limiting a roller position. 9. The device according to claim 6 , characterized in that the combined positioning mechanism ( 109 ; 109 ′; 111 ; 111 ′) is formed by a positioning drive ( 109 ; 109 ′; 111 ; 111 ′) that comprises, as the drive means, a motor that is operated selectively in a closed loop position-controlled or open loop position-controlled or closed loop moment-controlled or open loop moment-controlled manner. 10. The device according to claim 1 , characterized in that the first roller ( 102 ; 102 ′) is mounted so as to be adjustable in a direction having at least one movement component toward the second roller ( 103 ; 103 ′) and/or away therefrom by way of a bearing mechanism ( 113 ; 113 ′; 112 ; 112 ′) and the position-based positioning drive ( 109 ; 109 ′). 11. The device according to