Resin switching assist method and apparatus for molding machine

1 . A resin switching assist method for a molding machine, the method assisting an operator in performing a resin switching process of discharging a former resin from a heating cylinder and then supplying a succeeding resin to the heating cylinder, the method comprising: in advance of the resin switching process, for each of different resins, estimating a zero shear viscosity of each resin by using a conversion function expression whose parameters are a melt flow rate and a set temperature of the heating cylinder, registering the estimated zero shear viscosity in a first database in a molding machine controller, and registering a purge resin required amount in a second database in the molding machine controller, the purge resin required amount corresponding to a viscosity difference between the zero shear viscosity of the former resin and the zero shear viscosity of the succeeding resin; and in the resin switching process, obtaining the zero shear viscosity of the former resin and the zero shear viscosity of the succeeding resin from the first database by inputting a melt flow rate of the former resin and a melt flow rate of the succeeding resin to the molding machine controller, obtaining a viscosity difference between the zero shear viscosity of the former resin and the zero shear viscosity of the succeeding resin, obtaining an amount of a purge resin required for resin switching, as a purge resin required amount, from the second database, and displaying at least the obtained purge resin required amount. 2 . The resin switching assist method for a molding machine according to claim 1 , wherein the succeeding resin includes an intermediate material. 3 . The resin switching assist method for a molding machine according to claim 1 , wherein, when the zero shear viscosity of the succeeding resin is lower than the zero shear viscosity of the former resin, a message indicating that a purge material is necessary is displayed. 4 . The A resin switching assist method for a molding machine according to claim 1 , wherein the heating cylinder is divided into three regions in an axial direction such that the heating cylinder has a forward portion, a middle portion, and a rear portion, a region containing the forward portion and a portion located forward of the forward portion is defined as a high-temperature-side region, a region containing the middle portion and a portion located rearward of the middle portion is defined as a low-temperature-side region, and a temperature difference between the high-temperature-side region and the low-temperature-side region is set to fall within the range of 0° C. to 50° C. 5 . The resin switching assist method for a molding machine according to claim 1 , wherein the resins include general-purpose resins, engineering plastics, super engineering plastics, composite materials, purge materials, and special resins other than the purge materials. 6 . A resin switching assist apparatus for a molding machine, the apparatus assisting an operator in performing a resin switching process of discharging a former resin from a heating cylinder and then supplying a succeeding resin to the heating cylinder, the apparatus comprising a molding machine controller which comprises: a first database in which zero shear viscosities of different resins are registered, the zero shear viscosity of each resin being estimated by using a conversion function expression whose parameters are a melt flow rate and a set temperature of the heating cylinder; a second database in which a purge resin required amount corresponding to a viscosity difference between the zero shear viscosity of the former resin and the zero shear viscosity of the succeeding resin is registered; a melt flow rate inputting functional section for inputting a melt flow rate of the former resin and a melt flow rate of the succeeding resin; a viscosity difference calculating functional section which obtains the zero shear viscosity of the former resin and the zero shear viscosity of the succeeding resin from the first database on the basis of the input melt flow rates of the former and succeeding resins and calculates the viscosity difference between the zero shear viscosity of the former resin and the zero shear viscosity of the succeeding resin; a required amount calculating functional section which obtains, as a purge resin required amount, an amount of a purge resin required for the resin switching, from the second database on the basis of the obtained viscosity difference; and a display processing functional section which performs at least processing for displaying the obtained purge resin required amount. 7 . The resin switching assist apparatus for a molding machine according to claim 6 , wherein, when the zero shear viscosity of the succeeding resin is lower than the zero shear viscosity of the former resin, the viscosity difference calculating functional section outputs a message indicating that a purge material is necessary, and the display processing functional section has a purge material recommendation display section which is provided on a display and displays the message indicating that the purge material is necessary. 8 . The resin switching assist apparatus for a molding machine according to claim 6 , wherein the molding machine is an injection molding machine. 9 . The resin switching assist method for a molding machine according to claim 2 , wherein, when the zero shear viscosity of the succeeding resin is lower than the zero shear viscosity of the former resin, a message indicating that a purge material is necessary is displayed. 10 . The resin switching assist method for a molding machine according to claim 2 , wherein the heating cylinder is divided into three regions in an axial direction such that the heating cylinder has a forward portion, a middle portion, and a rear portion, a region containing the forward portion and a portion located forward of the forward portion is defined as a high-temperature-side region, a region containing the middle portion and a portion located rearward of the middle portion is defined as a low-temperature-side region, and a temperature difference between the high-temperature-side region and the low-temperature-side region is set to fall within the range of 0° C. to 50° C.