JPS609713A - Inverting device of shaped material - Google Patents

Abstract

PURPOSE:To make continuity of a transfer line of a shaped material favorable, by a method wherein the shaped material is fixed on the center of a pair of wheels having a communicating hole and the wheel is turned by an angle of 180 deg.. CONSTITUTION:When a shaped material 1 being sent while it is placed between conveyor belts 18, 19 is moved rightward by a feed roller 16, entered into a communicating hole 22 of the center of a wheel 21 of an inverting device 17 and the tip part of the shaped material 1 interrupts an optical path of a phototube switch 35, a roller 25 is pressed against the shaped material by acting a cylinder 24 and the shaped material is fixed at the center of the wheel 21. The wheel 21 is turned by a timer by an angle of 180 deg. in succession to the action. A turning angle of the wheel 21 is detected by contact between a microswitch 29 and a contact-maker 30. When inversion of the shaped material 1 is completed, the roller 25 is made to recede from the shaped material 1, the released shaped material 1 is pressed by a next shaped material and moved leftward.

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention provides a method for manufacturing a long member for making a heat insulating sash, for example, when the long member is turned over in order to fill the injection grooves on both sides of the long member with a heat insulating material. This invention relates to a reversing device to be used.

Conventionally, it is known that a heat insulating sash is constructed from a member in which a synthetic resin heat insulating material is filled into an injection groove formed in a hollow extruded member. In this case, injection grooves are usually installed on both sides of the member.First, fill the injection groove on one side with synthetic resin insulation material, then turn it over and fill the injection groove on the other side with synthetic resin insulation material. Filling is performed. This inversion work is usually done manually and is therefore inefficient.

Additionally, the present applicant has previously proposed a device in which the shape is inverted by gripping the shape with the free end of an arm whose one end is pivoted and swinging the arm 180 degrees. This is undesirable from the viewpoint of layout, which requires continuity of the movement line of the sections, since the sections have to move significantly laterally.

The present invention aims to implement this effectively, and an embodiment applied to the continuous production of heat insulating sash members will be described below with reference to the drawings.

Figure 1 is a perspective view of the entire structure, showing an extruded sash member 1.
A plurality of cylinders are placed on the first moving mounting table 2, and the cylinder 3.3-
During this time, the sheets 1 to 15 supplied by the supply roller 20 are placed in the injection groove 5, and then both ends of the injection groove 5 are closed with caps 6 by the cap fitting device 4. The sash member whose both ends of the injection groove 5 are closed with the cap 6 is pushed out with the cylinder 7 and continuously passed under the synthetic resin insulation solution injection device 8, so that the synthetic resin insulation solution 9 is poured into the injection groove 5. inject.

The sash member 1 into which the synthetic resin heat insulating material solution 9 has been injected is placed on the second movable mounting table 10 and moved by the cylinders 11 and 11', and the synthetic resin heat insulating material solution 9 is solidified, and the synthetic resin heat insulating material is form 12.

Next, the sash member 1 is pushed out using the cylinder 13, the bottom of the injection groove 5. , after turning the lower injection 111i5- upward, it is pushed out by the next shape member that moves forward while cutting off the bottom surface, and is placed on the first movable mounting table 2 again.
N and fill the injection if/i 5'' with the synthetic resin heat insulating material 12 in the same order as above.

FIG. 2 shows a cross section of the ridge member 1 according to the above-mentioned two culm orders. (b) Lay the sheet 15 at the bottom of the groove 5, and (C) fill the injection groove 5.
The end face is closed with the cap 6 and the sheet 15 is closed.
(d) Inject the synthetic resin heat insulating material solution 9 from the injection device 8, and (e) use the cutting device @14 to insert the injection groove 5.
．． Cut the bottom of 5-, then (f) invert and (0)
Lay sheets 1 to 15 on the bottom of the injection groove 5', (h) close the end face of the injection groove 5- with a cap 6 and fix the sheet 15, and (i) place a synthetic resin heat insulating material inside the injection groove 5-. Solution 9 is injected from injection device 8.

FIG. 3 is a front view of the reversing device 17 of the present invention viewed from the direction of the cutting device 14, and FIGS. 4a to 4f are explanatory views of the operation of the reversing device of the present invention.

To explain this reversing device 17, it has a pair of wheels 21, F, which have teeth on the outer periphery, have a through hole 22 in the center through which a section can pass, and are connected to each other by brackets 1 to 23. A presser roller 25 that is located around the marking hole 22 and can fix or release the profile to the center of the wheel, a cylinder 24 that moves it, and a pair of drives that support the wheel 21 and rotate it. The wheel 21 is composed of a gear 26, and the wheel 21 is placed on the driving gear 26 and the floating gear 28 so that the teeth on the outer periphery mesh with these gears. The drive gear 26 is driven by a motor 27 via a belt 36.

The drive gears are interconnected by a rotating shaft 37 and support the wheels 21 in pairs.

The bearing stand 35 of the rotating shaft 37 of the driving gear is simultaneously mounted on the wheel 2.
1 is prevented from moving in the vertical direction. This reversing device 17 is assembled on a substrate 31, and the substrate 31 is a foundation 3.
The height 5 provided in the first part of 4 is supported by an adjustment mechanism (consisting of a link mechanism 32 and its drive device 33), so that the position of the through hole 22 can be adjusted to the height of the line along which the profile moves. It can be adjusted as follows.

The operation of this reversing device will be explained with reference to FIG.
Conveyor bell h18 as shown in a) and (b)
．． 19, the bottom surface of the injection groove is cut, and the profile that comes out of the cutting device is sent by the feed roller 16 and moved to the right, and is passed through the through hole 2 in the center of the wheel 21.
2, and as shown in (C), when the tip of the profile sent by the roller blocks the optical path of the phototube switch 35, the cylinder 24 is actuated to press the roller 25 against the profile, and the profile is removed. is fixed to the center of the wheel 21. Following this activation by the timer, the wheel 21 is rotated by 180 degrees as shown in (d), and the profile is inverted, with the injection groove 5' facing upward. The rotation angle of the wheel 21 is sensed by contact between a microswitch 29 and a contactor 30, as shown in FIG. Once the inversion of profile 6- is complete, cylinder 24 is actuated to retract roller 25 from the profile and the released profile 4A is (e
) and (f), it is pushed by the next section coming out of the cutting device to open the movement ζ1 towards the right.

The thus-inverted profile is again placed on the first moving table 2, and the process of injecting the heat insulating material into the injection groove 5- is completed.

As explained above, the reversing device of the present invention does not change the flow of the H-shaped line by reversing operation unlike the previously proposed device (Utility Application No. 57-195325).
Moreover, since the profile is centered at the center of rotation, not only the area or space occupied by the entire line is small, but also the speed of reversal can be significantly improved, and the reversing device also has the advantage of being smaller. This has the following effects.

[Brief explanation of the drawing]

Fig. 1 is a perspective view of the entire apparatus for explaining the present invention in detail, Fig. 2 is an explanatory view of the process order of the above-mentioned apparatus, Fig. 3 is a front view of one embodiment of the invention, and Fig. 4 is 3A and 3B are side views illustrating the operation of the apparatus of FIG. 3, respectively. 1...Sash member 2...First movable mounting table 3.3-...Cylinder 4...Cap attachment device 5.5-... ... Injection groove 6 ... Cap 7 ... Cylinder 8 ... Injection device 9
...Synthetic resin heat insulating material solution 10...Second moving mounting table 11.11'...Cylinder 12...Synthetic resin heat insulating material 13...・Cylinder 14... Cutting device 15... Sheet 16... Feed roller 17...
Reversing devices 18, 19... Conveyor belt 20.
...Supply roller 21 ...Wheel 2
2...Through hole 23...Bracket 24
...... Cylinder 25 ... Presser roller 26 ... Drive gear 27 ... Motor 28 ... Idle gear 29 ... Micro Switch 30...Contactor 31...
Board 32...Link mechanism 33...Motor 34...Basic 35...Phototube switch patent applicant Yoshida Kogyo Co., Ltd. agent Patent attorney Takeshi Komatsu Agent Patent Attorney Hiroshi Asahi 9- Figure 2 (a) (b) (Ctsuk (f) tgno (h) (d) O○ ○ 0 口 口○ OQO O ○0 00 56- ○ ○ 口○0

Claims (1)

[Claims] a pair of wheels having a through hole in the center through which the profile can pass; a fixing device located around the through hole that can fix or release the profile from the center of the wheel; and a synchronous rotation of the wheels. A shape reversing device comprising at least a pair of drive devices for rotating the wheels, and a control device for regulating the amount of rotation of the wheels.