Molten-resin extrusion device and extrusion method as well as molten resin molding machine and molding method

The invention claimed is: 1. A molten-resin extruder comprising: an accumulator extending vertically and provided with a space coupled to a head, the head having an extrusion port at a lower end thereof, the accumulator including a core configured to adjust opening area of the extrusion port; a piston that is fitted to the space and is able to move vertically in the space, wherein a charging space into which a molten resin can be charged is formed under the piston in the space; a shaft inserted into the core of the accumulator, the shaft configured to move the core upward and downward to adjust the opening area of the extrusion port; a lower plate disposed over the accumulator and coupled to the piston from above; a level detector configured to detect a level of the lower plate; a screw shaft that extends vertically; an electric motor configured to rotationally drive the screw shaft; a nut secured to the screw shaft and capable of making a vertical linear motion along the screw shaft, wherein the screw shaft is rotated around a vertical direction by the electric motor; and an upper plate coupled to the nut and disposed over the lower plate so as to be able to surface-contact the lower plate, wherein the molten-resin extruder comprises only one upper plate, and the upper plate and the lower plate respectively include openings through which the shaft passes, after the upper plate is retracted upward by the electric motor, the molten resin is charged into the charging space while applying back pressure based on a self-weight of the lower plate to the molten resin in the charging space, and the charged molten resin is extruded from the extrusion port downward. 2. The molten-resin extruder of claim 1 , wherein the space is a ring-shaped space, the piston is a ring-shaped piston having a shape complementary to a shape of the ring-shaped space, and the charged molten resin is extruded from the extrusion port downward in the form of a parison. 3. The molten-resin extruder of claim 2 , wherein the lower plate is coupled to the piston through a piston rod, wherein the piston rod extends vertically in the space, and the level detector comprises: a magnet disposed on the piston rod; and a magnetic sensor fixed near the piston rod and configured to convert a change in a magnetic field of the magnet into an electric signal and to output the electric signal. 4. The molten-resin extruder of claim 2 , wherein the lower plate is coupled to the piston through a piston rod, wherein the piston rod extends vertically in the space, and the level detector comprises an infrared sensor fixed near the piston rod and configured to detect a level of the piston rod by detecting that radiant energy of an infrared ray radiated from the piston rod is equal to or higher than a predetermined level. 5. The molten-resin extruder of claim 2 , wherein the upper plate and the lower plate are disposed horizontally, have surface-contact portions having an identical shape, and are disposed in such a manner that peripheries of the surface-contact portions match each other. 6. A molten resin molding machine comprising: the molten-resin extruder of claim 1 ; a resin-sheet forming apparatus configured to form extruded molten resin into a resin sheet; a mold clamping apparatus disposed under the molten-resin extruder, wherein the mold clamping apparatus comprises: a pair of split molds configured to be moved in directions perpendicular to a lowering direction of a lowering molten resin sheet between open positions and closed positions with the molten resin sheet interposed between the split molds, the split molds having cavities in opposite surfaces thereof; a mold moving unit configured to move the pair of split molds in the directions perpendicular to the lowering direction of the molten resin sheet between the open positions and the close positions; and a decompression unit configured to decompress an enclosed space formed between the molten resin sheet and the pair of split molds, wherein the molten resin sheet is disposed between the pair of split molds located in the open positions and the pair of split molds. 7. The molten resin molding machine of claim 6 , wherein the resin-sheet forming apparatus is a T die disposed so as to communicate with a lower portion of the extrusion port of the molten-resin extruder, and the T die has a flat, rectangular extrusion slit at a lower end thereof. 8. The molten resin molding machine of claim 6 , further comprising: a pair of rollers positioned in predetermined positions located under the resin-sheet forming apparatus and over the pair of split molds, rotational axes of the rollers being disposed so as to be parallel with each other and horizontal, one of the rollers being a driving roller, the other roller being a driven roller; a roller driving unit configured to rotationally drive the driving roller; a roller moving unit configured to move one of the pair of rollers relative to a corresponding roller in a plane containing the pair of rollers or move both the rollers in the plane; and a roller rotational speed controller configured to control a rotational speed of the driving roller so that a speed at which the pair of rollers feed the resin sheet downward becomes equal to or higher than an extrusion speed of the resin sheet, in accordance with the extrusion speed with the resin sheet sandwiched between the pair of rollers. 9. A molten resin blow-molding machine comprising: the molten-resin extruder of claim 2 ; and a mold clamping apparatus disposed under the molten-resin extruder, wherein the mold clamping apparatus comprises: split molds configured to be moved between open positions and closed positions in directions perpendicular to a lowering direction of a lowering molten parison with the molten parison interposed between the split molds, the split molds having cavities in opposite surfaces thereof; a mold moving unit configured to move the split molds in the directions perpendicular to the lowering direction of the molten parison between the open positions and the closed positions; and a blow pressurizing unit configured to blow-pressurize inside of an enclosed space formed by closing the split molds. 10. A molten resin blow-molding method comprising: a step of melting and kneading thermoplastic resin; a step of storing a predetermined amount of the molten and kneaded thermoplastic resin, a step of intermittently extruding the stored thermoplastic resin in a predetermined extrusion amount per unit time using the molten-resin extruder of claim 2 so that the thermoplastic resin lowers from the extrusion port in the form of a molten parison and thus extruding the molten parison downward from the extrusion port at a predetermined extrusion speed; a step of locating the extruded molten parison on sides of split molds; a step of forming an enclosed space in the molds by closing the split molds so that the molten parison is sandwiched therebetween; and a step of molding the molten parison into a shape corresponding to shapes of the molds by blow-pressurizing the formed enclosed space and pressing the molten parison against the molds. 11. A method using the molten-resin extruder of claim 1 for extruding molten resin in the charging space from the head by converting a rotational motion of the electric motor into a linear motion of the piston disposed in the charging space through a ball screw and thus causing the piston to move vertically, the charging space being a space into which the molten resin can be charged and formed in the accumulator of the molten-resin extruder, the method comprising: a step of separating the upper p