JPS593583B2 - Glass fiber molding equipment - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention seeks to provide a glass fiber molding apparatus having a novel configuration.

Hereinafter, one embodiment of the present invention will be described in detail with reference to the drawings.

1 is a glass fiber molding apparatus of the present invention.

The structure is that suction chambers 4 and 5 having rotary tables 2 and 3 on the upper surface are arranged on the left and right sides with a partition wall 6 interposed therebetween, and the rotary tables have suction openings 2' and 3' of a predetermined shape. The left and right damper cases 7 and 8 are connected to both the suction chambers, and the left and right damper cases have suction openings. A, 8A and hot air openings 7B, 8B are respectively formed, and the suction damper 7A' is provided in the suction opening.
, 8A' are configured such that when the left side is in an open state, the right side is in a sealed state, and the hot air dampers 7B' and 8B' provided in the hot air openings TB and 8B are connected to the adjacent suction dampers. A hot air case 9 is formed in the suction case K, which has an insulated partition wall 9A and shares the hot air openings TB and 8B. , the left and right suction ducts 1 correspond to the left and right suction openings mentioned above.
0 and 11, and filters 10A and IIA) dampers IOB and II are connected to this suction duct, respectively.
A hot air duct 12 having a proar 12A is connected to the proar IOC and IIC via a proar B, and a hot air duct 12 having a proar 12A is installed in communication with the hot air case 9, while a rail 13 is provided in the left and right direction on the upper surface of the suction chamber. The heating chamber 14 is placed on the rail so as to be movable in the left and right direction,
The left and right side walls 15 of the side walls of the heating chamber are configured to be openable and closable, and a hot air vent 14 formed in the ceiling of the heating chamber
A hot air duct 16 is rotatably connected to A, and further,
The hot air duct is rotatably connected to the hot air duct 12 via the hot air generator IT. Therefore, the duct 16 swings in the left-right direction using the duct 12 as a fulcrum when the heating chamber 14 moves left and right. Therefore, the connecting portion between the duct 16 and the hot air outlet 14A forms a frame 14B having a rectangular plane on the upper surface of the hot air outlet 14A, and a flat plate 16A attached to the tip of the duct 16 can freely slide into this frame. It is fitted. Next, the method of using the present invention will be explained together with its effects. Referring to FIG. 1, among the left and right chambers 4 and 5, the heating chamber 14 is moved to the one-force chamber 5, and placed on the rotary table 2 of the other-force chamber 4, such as in a bathtub. A mold 18 for which molding is desired is fixed.

This mold 18 is provided with a group of ventilation holes 18A. Then, while rotating the table 2, the glass fiber G
Cut it into about 50n with a roping cutter (not shown, but consisting of a drum cutter and a pro-a-fan), and spray it with water-soluble adhesive (not shown, consisting of a gear high-pressure pump and a spray gun). Spray with hose 19. In this case, since the damper TA' of the suction opening TA is in the open state, suction is being performed by the suction ducts 10 and 11, so that the suction is not completed. The air holes 18A of the mold draw suction, and the cut glass fibers fully adhere to the surface of the mold to form a layer. Thereafter, the heating chamber 14 is moved onto the table 2, the left and right side walls 15 are lowered, and the mold and the glass fiber layer attached to the mold are placed therein.
A separately prepared mold is mounted on the other table 3, and when the damper 8A' is opened while rotating the table, the suction action is started by the ducts 10 and 11, so that the cut glass fibers are sprayed. do the work. With the opening of this damper 48A', the hot air damper 8B
', the damper TA' is closed and the hot air damper TB' is opened. Therefore, a suction action is performed from the hot air opening TB on the table 2 side. The air sucked through the opening TB passes through the hot air case 9 and reaches the duct 12, where it is heated to hot air by the hot air generator IT.
The hot air is supplied into the heating chamber from the hot air port 14A. A molded object onto which glass fibers have been sprayed together with a water-soluble adhesive is placed on the table 2 rotating in the heating chamber, so that it is dried by the hot air blown into it. As a result, the drying work of the molded object can be performed on the table 2, and the work of blowing the glass fiber onto the mold can be performed simultaneously on the table 3. When the drying process on the table 2 is completed, the left and right side walls 15 are raised, the heating chamber is moved toward the table 3, the dried molded object is taken out, and a new mold is set on the table 2. Perform spraying work. At this time, drying work is performed on the table 3 at the same time. After completing the drying process, the molded object is demolded and transferred to the next process, the resin pressing process. As described above, the present invention is useful because glass fiber molding can be carried out continuously and with labor-saving operations.

The mold 18 is attached to the openings 2', 3'.

[Brief explanation of the drawing]

The drawings show one embodiment of the present invention, and FIG. 1 is a plan view, FIG. 2 is a sectional view taken along the line A-A of the same, FIG. 3 is a plan view with the heating chamber removed, and FIG. The figure is a sectional view taken along the line B-B as above.
Fig. 5 is a partially cutaway perspective view showing the relationship between the suction chamber and each damper, Fig. 6 is a partially cutaway side view of the upper part of the heating chamber, and Fig. 7 is a cross section taken along line C-C of the same. It is a diagram. 1...Glass fiber molding equipment, 2,3...
...Rotary table, 4,5...Suction chamber, T,8...Damper case, 7A',
8A'... Suction damper, TB',
8B'・・・Hot air damper, 9・・・・・・
Hot air case, 10, 11...Suction duct, 12...Hot air duct, 14...
heating chamber.

Claims (1)

[Claims] 1. Suction chambers each having a rotary table on the upper surface are disposed on the left and right through a partition wall, a suction opening of a predetermined shape is formed in the rotary table, and left and right damper cases are connected to both the suction chambers. The left and right damper cases are respectively formed with a suction opening and a hot air opening, and the suction damper provided in the suction opening is such that when the left side is in an open state, the right side is in a sealed state. The hot air damper provided in the hot air opening is configured to open and close according to the opening and closing of the adjacent suction damper, and the suction case has an insulated partition wall to prevent hot air from being used. A hot air case with a common opening is formed, and left and right suction ducts are communicated with the suction case so as to correspond to the left and right suction openings, and these suction ducts are connected through filters and dampers, respectively. A hot air duct connected to a blower and having a blower is installed in communication with the hot air case, while a rail is laid on the upper surface of the suction chamber in the left and right direction, and the heating chamber is connected to the left and right on the rail. The left and right side walls of the heating chamber are configured to be freely openable and closable, and a hot air duct is rotatably connected to a hot air opening formed in the ceiling of the heating chamber. A glass fiber molding apparatus characterized in that the hot air duct is rotatably connected to the hot air duct via a hot air generator.