TH13613B - A method for hollow injection molding to form a combined shaft rotator and a casting product created from it. - Google Patents

Abstract

The invention is particularly concerned with a method for injecting medium-type compression. It then involves a hollow injection compression method to form a rotator made of resin. Integrated shaft design with excellent productivity Casting products created by the method Of this invention are absolutely accurate in size, proportion, strength, surface appearance and ability to be recycled.

Claims (8)

1. Methods for providing a combined shaft rotator containing at least One shape that is required to perform a function is rotated on a shaft axis. Where the rotators are involved A hollow inside is created along the axial shaft. The method consists of inside a template where the injection hole, the runway, the entry hole and the pattern cavity are arranged sequentially according to the flow direction of the molten resin, a template placement with holes being assembled at the point. Intersection of the axis of the rotator And area surface The edge of the pattern cavity so that the surface at the edge has an entrance hole that consists of the lower part of the pattern cavity and the axis is vertical. And the operation to achieve the effect of hollow compression. 2. Method for arranging rotators according to claim 1, in which the compression type The hollow injection type is applied by means of a pressurized fluid through the through-hole cavity. 3. Method for arranging rotators according to claim 1 or 2. Hollow injection type It is accomplished by injecting the molten resin into the mold cavity, with the remaining unloaded resin part. And later, to supply fluid with pressure into the cavity to Spread the resin evenly over the part that is not filled with the resin. 4. Method for arranging the rotators according to claim 3. The hollow injection type is accomplished by injecting the resin into the mold cavity with an amount equal to 50 to 90% of the cavity volume. Type 5. Method for arranging rotators according to claim 1 or 2 in which the compression The hollow injection type is accomplished by supplying a pressurized fluid into the cavity during Injection of fused resin into cavity 6. Method for arranging rotators according to claim 1 or 2. The hollow injection type is accomplished by injecting the molten resin into the hollow section, with an auxiliary cavity connected to the hollow without the remaining resin-filled parts and subsequently. The pressurized fluid is applied to the resin. 7. Method for arranging rotators according to claim 6. The hollow injection type is accomplished with a template. Which was provided to have an additional cavity above the hollow pattern And connect it to the drone-based cavity, which is provided in the upper part of the follow-up cavity Axial boundary line 8. Method for arranging rotators according to claim 6, in which the compression part The hollow injection type is accomplished by providing a block valve on the path to which it connects. Cavity with a reinforced cavity And distribute the molten resin into the cavity while the valve is in The closed state and the pressurized fluid is supplied into the cavity while the valve is in the open state. 9. Method for arranging the rotators according to claim 1. Hollow injection type is performed to achieve dole effect, injecting the resin into one part. Or the entire part of the free space Between the nozzle of the compression molding machine and the inlet And supplying fluid with pressure from a dispenser that is Prepared is located at the point near the nozzle of the compression machine that is arranged prior to the directional nozzle. The flow of resin is greater than the point at which the amount of resin required for molding is supplied. 1 0. Method for arranging rotators according to claim 9, in which the extrusion section The hollow injection type is accomplished by injecting a part of the molten resin. Or the whole part Of the space between the nozzle of the compression molding and the inlet bore under the condition that the blocking valve provided Between the runway part of the template And the model cavity will be in a closed state. And later the fluid dispensing There is pressure under the condition in which the valve is closed. 1. Method for arranging rotators according to claim 1 or 2. The hollow injection type is achieved by using a template. Which has segments of one or more angles of Curved or cut cavity 1 2. Method for arranging rotators according to claim 11, in which the compression part Hollow injection type is achieved by using a template. The corners are curved. 1. Method for arranging rotators according to claim 12, in which the compression part. The hollow type is accomplished by using a template. Which has the corner portion is curved where the entry hole is inserted This corresponds to the relationship established by the following formula: 0.1 mm is less than or equal to Te is less than or equal to (2-1) x Gt, where Gt represents the length of the CE segment (C is the intersection. Of segment AB and segment DE, where A is the point on the lateral cavity surface.Each entry hole B and D represents an intersection. Of curved corner surfaces And the surface of the cavity above the entry hole, and E represents the boundary Between the entry hole plane and the injection hole or the runway part of the template) and Te denotes the length of the segment CF (F is the intersection of the angled surface, the angled bisector ACE). 4. Method for arranging rotators according to claim 12, which, as part of the compression Hollow injection type is achieved by using a template. In which the corners are rounded apart from The portion of the angle at which the holes enter corresponds to the relationship established by the following formula: a) 0.4 mm less than or equal to Tg, less than or equal to (2-1) / 2 x (T2-T1) in the case Where 5 mm less than or equal to (T2-T1) is less than or equal to T3 x 2, and b) 0.4 mm less than or equal to Tg less than or equal to x T3 in case 5 mm is less, or Equal to T3 x 2, less than or equal to T2-T1, where Tg represents the length of the NQ segment (N is the intersection of the LM segment and the OP segment, where L is the point on the surface of the cavity where Their angles are curved. Each M and O represent the intersection of the curved corner surface and the cavity surface. On the sides, the entry holes P represent the boundary. Between the entry hole plane and the injection hole or the template runway part, and Q is the intersection of the angled surface. Curved and Bisected LNP angles), T3 represents the length of the LN segment; T1 and T2 represent the shaft diameter. And the roller section respectively When both parts are formed into a cylinder; T1 and / or T2 represent the diameter of the pitch loop. When both parts or Each segment is molded into a gear: and T1 and / or T2 represent the smallest ball diameter. Crooked when both parts Or each part is molded into a cam. 1. 5. Method for arranging rotators according to claim 11, in which the compression model. The hollow injection type was accomplished by using a template with a milled corner section 1 6. Method for arranging rotators according to claim 15, in which the compression of the type is applied. The hollow injection type is accomplished by using a template in which the corner portion is slotted where the inlet is inserted. This corresponds to the relationship established by the following formula: 0.1 mm is less than or equal to Tf, less than or equal to (2-1) x Gt, where Gt represents the length of the CE segment (C is the intersection. Segment AB and segment AB and segment DE, where A is the point on the lateral cavity surface. Each entry hole B and D represent the intersection of the corner surface to be cut. And the surface of the cavity on the side of the entry hole and E represents the boundary between the entry hole planes. And the injection hole or the runway part of the template) 1 7. Method for arranging rotators according to claim 15, in which the compression of the pattern The hollow injection type is achieved by using a template in which the corners are milled in addition to the corners. Where the entry holes correspond to the relationship established by the following formula: a) 0.4 mm less than or equal to Th less than or equal to 2/4 x (T5-T4) in case 5 mm less. Or equal to T5-T4 less than or equal to T6 x 2 b) 0.4 mm less than or equal Tg less than or equal 2/2 x T6 in the case of 5 mm less than or equal to T6 x 2 less than or equal to T5 -T4, where Th denotes the length of the NQ segment (N is the intersection of the LM segment and the OP segment, where L is the point on the surface of the model cavity where its angles are slotted, M and O each. Representative The intersection of the surface of the rounded corners. And the surface of the cavity on the side, the entrance hole P represents the boundary between The entry and injection holes or runway sections of the template and Q are the intersection of the angled surface and the LNP corner bisector) .The T6 represents the lengths of the LNT4 segments, and the T5 represents the diameter. Of the shaft and roller sections, respectively, when both cylindrical sections are formed, T4 and / or T5 represent the pitch diameter. When both or individual segments are geared and the T4 and / or T5 represent the smallest diameter of the eccentricity. When either two or each part is formed into a cam 1 8. Combined shaft rotator formed by the method of claim 1, in which the angle One or more angles are rounded or flattened. 1 9. Combined shaft rotators according to claim 18, in which one or more angles will make a bend 2 0. Right 18 in which parts of one or more corners will be rounded 2 1. A combined shaft rotor formed by the method of claim 1, in which the ratio The length of the axial hollow section to the total length of the axial rotor is 80% or greater than 2. 2. Combined shaft rotators according to claim 18 or 21, in the shape of a hollow Of the rotators corresponds to the relationship established by the following formula: 0 is less than or equal to (d1-d2) / d1 is less than or equal to 0.1, where d1 and d2 represent the longest and shortest. Between the axis and Rotor inner surface, respectively 2 3. Combined shaft rotators with a hollow on the inside, which are prepared by means of a template arrangement with an entrance hole being assembled at the point of contact of the axis of the rotator and the floor. The surface at the edge of the pattern cavity so that the edge surface has a recess that consists of the lower part of the pattern cavity. And the axis is vertical, and the operation achieves a hollow injection type compression where one or more angles are Curled or cut And the groove part is arranged on the surface of the rotor 2 4.Combined shaft rotators with a hollow on the inside, prepared by a method consisting of a template arrangement with an entrance hole being assembled at the intersection of the rotor axis and the peripheral surface of the pattern cavity. So that the surface at the edge has an inlet hole consisting of the lower part of the hollow pattern and The core is vertical and the operation is achieved in hollow injection type compression where the section length ratio The axial hollow to the total length of the rotator is 80% or more, and the groove is Placed on the surface of the rotators 2. 5. Combined shaft rotators according to claim 23 or 24, in which the groove and section The hollow corresponds to a relationship established by the following formula: 0.7 is less than or equal to (R2-r2) / (R1-r1) less than or equal to 1, in which the cross-section in the vertical to axial direction will Including the grooves R1 and R2 represent the longest. And the shortest distance between the centers of the axes And the outer surface of Rotators, respectively, and r1 and r2 represent the longest and shortest between the axes. And the inner surface of the rotators respectively 2 6. Combined shaft rotators according to claim 23 or 24, where the angles of the grooves are eliminated. Exit by making bends 2 7. Combined shaft rotators according to claim 23 or 24, in which the groove is the cam groove 2. 8. Combined shaft rotators according to claim 23 or 24, where the grooves are key grooves.