Slit nozzle and method for manufacturing high-silicon steel strip

1 . A slit nozzle having a double-tube structure, the slit nozzle comprising: an outer tube having a delivery port for a treatment gas in an axial direction and a closed end; an inner tube having a feeding port for the treatment gas on one end and an open end that is another end inside the closed end of the outer tube, the treatment gas configured to be fed through the feeding port and blown through the delivery port; and a flow-control plate disposed between the open end of the inner tube and an end of the delivery port, flow-control plate closing a gap between the inner tube and the outer tube, wherein an opening is formed in a plane in which the flow-control plate is disposed only in a range of the flow-control plate of 27.5° or more and 332.5° or less in terms of a central angle with respect to a reference line passing through an axis of the outer tube and a central position in a width direction of the delivery port. 2 . The slit nozzle according to claim 1 , wherein the flow-control plate is disposed at the open end of the inner tube. 3 . The slit nozzle according to claim 1 , wherein the opening is formed symmetrically with respect to the reference line in the plane in which the flow-control plate is disposed. 4 . A method for manufacturing a high-silicon steel strip including a siliconizing treating method using a plurality of slit nozzles according to claim 1 , the method comprising: arranging the slit nozzles in a threading direction of a steel strip in a siliconizing treating furnace such that adjacent slit nozzles or adjacent groups of slit nozzles adjacent to each other in the threading direction are arranged so that feeding ports for the treatment gas of the slit nozzles face opposite directions from each other; and feeding the treatment gas through the feeding ports for the treatment gas into the slit nozzles and blowing the treatment gas through the delivery ports for the treatment gas of the slit nozzles onto the steel strip during transport, wherein the treatment gas contains silicon tetrachloride. 5 . The slit nozzle according to claim 2 , wherein the opening is formed symmetrically with respect to the reference line in the plane in which the flow-control plate is disposed. 6 . A method for manufacturing a high-silicon steel strip including a siliconizing treating method using a plurality of slit nozzles according to claim 2 , the method comprising: arranging the slit nozzles in a threading direction of a steel strip in a siliconizing treating furnace such that adjacent slit nozzles or adjacent groups of slit nozzles adjacent to each other in the threading direction are arranged so that feeding ports for the treatment gas of the slit nozzles face opposite directions from each other; and feeding the treatment gas through the feeding ports for the treatment gas into the slit nozzles and blowing the treatment gas through the delivery ports for the treatment gas of the slit nozzles onto the steel strip during transport, wherein the treatment gas contains silicon tetrachloride. 7 . A method for manufacturing a high-silicon steel strip including a siliconizing treating method using a plurality of slit nozzles according to claim 3 , the method comprising: arranging the slit nozzles in a threading direction of a steel strip in a siliconizing treating furnace such that adjacent slit nozzles or adjacent groups of slit nozzles adjacent to each other in the threading direction are arranged so that feeding ports for the treatment gas of the slit nozzles face opposite directions from each other; and feeding the treatment gas through the feeding ports for the treatment gas into the slit nozzles and blowing the treatment gas through the delivery ports for the treatment gas of the slit nozzles onto the steel strip during transport, wherein the treatment gas contains silicon tetrachloride. 8 . A method for manufacturing a high-silicon steel strip including a siliconizing treating method using a plurality of slit nozzles according to claim 5 , the method comprising: arranging the slit nozzles in a threading direction of a steel strip in a siliconizing treating furnace such that adjacent slit nozzles or adjacent groups of slit nozzles adjacent to each other in the threading direction are arranged so that feeding ports for the treatment gas of the slit nozzles face opposite directions from each other; and feeding the treatment gas through the feeding ports for the treatment gas into the slit nozzles and blowing the treatment gas through the delivery ports for the treatment gas of the slit nozzles onto the steel strip during transport, wherein the treatment gas contains silicon tetrachloride.