CN203792669U - Photoelectric induction control mold - Google Patents

Abstract

The utility model discloses a photoelectric induction control mold. The photoelectric induction control mold comprises a photoelectric sensing probe, an induction gear, a synchronizing wheel I, a synchronizing wheel II and an idle wheel, wherein the induction gear and the synchronizing wheel I are arranged on a hydraulic motor; the hydraulic motor is arranged outside the mold; the photoelectric sensing probe is arranged on two sides of the induction gear; the synchronizing wheel II is arranged on a shaft inside the mold; the synchronizing wheel I and the synchronizing wheel II are connected through a synchronous belt; the idle wheel is arranged between the synchronizing wheel I and the synchronizing wheel II; a shaft with the synchronizing wheel II is connected with a gear drive structure; the gear drive structure drives rotation of a threaded screw rod. The product is fixed in the mold, the hydraulic motor starts rotating, precise movement of the screw rod is driven through a synchronous belt transmission device and the gear drive structure, a complete thread is formed, the thread size is precise, and complete molding is realized.

Description

Optoelectronic induction is controlled mould

Technical field

The utility model relates to a kind of optoelectronic induction and controls mould.

Background technology

At present, mould is controlled by injection machine, threaded screw rod rotation, this situation screw position is constant, and product relies on spring force to release die cavity, owing to not controlling product in this situation, and spring force is uncontrollable, product screw thread age of a draught animal end is fragile, produces a large amount of defective products.Injection moulding process, such threaded product is that hand reaches injection machine inside and screws down after die sinking, manually completes, automaticity is not high, inefficiency and very dangerous.Therefore, need to provide a kind of new technical scheme to solve the problems referred to above.

Utility model content

For addressing the above problem, the utility model provides the complete optoelectronic induction of a kind of age of a draught animal moulding to control mould.

The technical solution adopted in the utility model is:

Optoelectronic induction is controlled mould, it also comprises photoelectric sensing probe, induction gear, synchronizing wheel I, synchronizing wheel II and idle pulley, described induction gear and synchronizing wheel I are arranged on hydraulic motor, described hydraulic motor is arranged on mould outside, described photoelectric sensing probe is arranged on induction gear both sides, described synchronizing wheel II is arranged on mould inside axle, described synchronizing wheel I is connected by Timing Belt with synchronizing wheel II, between described synchronizing wheel I and synchronizing wheel II, idle pulley is installed, axle with synchronizing wheel II connects gear transmission structure, described gear transmission structure drives the rotation of thread screw.

Described idle pulley is installed on fixed mount.

Described gear transmission structure comprises gear I and gear II, and described gear II is placed on mould inside axle, and two gear I are symmetrically distributed in gear II both sides and are meshed with gear I.

The beneficial effects of the utility model: fixed product in mould, hydraulic motor starts rotation, by synchronous belt transmission device and gear transmission structure, drives the precision of screw rod to move, and forms complete thread, age of a draught animal precision size, moulding is complete.

Accompanying drawing explanation

Fig. 1 is mould external structure schematic diagram of the present utility model.

Fig. 2 is mould inside structural representation of the present utility model.

Fig. 3 is optoelectronic induction controller schematic appearance of the present utility model.

Wherein: 1, photoelectric sensing probe, 2, induction gear, 3, synchronizing wheel I, 4, synchronizing wheel II, 5, idle pulley, 6, hydraulic motor, 7, axle, 8, Timing Belt, 9, idle pulley, 10, fixed mount, 11, optoelectronic induction controller, 12, thread screw, 13, gear I, 14, gear II, 15, screw product.

The specific embodiment

In order to deepen understanding of the present utility model, below in conjunction with embodiment and accompanying drawing, the utility model is described in further detail, and this embodiment only, for explaining the utility model, does not form the restriction to protection domain of the present utility model.

As shown in Figures 1 to 3, optoelectronic induction of the present utility model is controlled mould, it also comprises photoelectric sensing probe 1, induction gear 2, synchronizing wheel I 3, synchronizing wheel II 4 and idle pulley 5, induction gear 2 and synchronizing wheel I 3 are arranged on hydraulic motor 6, hydraulic motor 6 is arranged on mould outside, photoelectric sensing probe 1 is arranged on induction gear 2 both sides, synchronizing wheel II 4 is arranged on mould inside axle 7, synchronizing wheel I 3 is connected by Timing Belt 8 with synchronizing wheel II 4, between synchronizing wheel I 3 and synchronizing wheel II 4, idle pulley 9 is installed, idle pulley 9 is installed on fixed mount 10, axle 7 with synchronizing wheel II 4 connects gear transmission structure, gear transmission structure drives the rotation of thread screw 12.

Gear transmission structure comprises gear I 13 and gear II 14, and gear II 14 is placed on mould inside axle 7, and two gear I 13 are symmetrically distributed in gear II 14 both sides and are meshed with gear I 13.

Idle pulley 9 shown in Fig. 1 is fixed by fixed mount 10, is arranged on two synchronizing wheel centre positions, is used for controlling Timing Belt 8 degrees of tightness.

Axle 7 with synchronizing wheel II 4 connects gear transmission structure, drives the rotation of thread screw 12, and product does not rotate, and under bolt rotary, the mould of back-outing reaches Automatic-falling effect.Induction gear 2 often turns over lattice, photoelectric sensing probe 1 counting once, the number of turns of back-outing from screw rod according to product is set hydraulic motor 6 rotation parameters by optoelectronic induction controller 11, when rotating to product, induction gear 2 just comes off, controller provides signal to stop operating to hydraulic motor 6, and this is the short period.

After die sinking, hydraulic motor 6 starts to rotate drive Timing Belt 8 and synchronizing wheel, and thread screw 12 rotates, the screw product 15 of back-outing, and after hydraulic motor 6 completes the rotation number of turns of setting, product just drops, and mould closes and carries out next group production.

Make injection moulding screw product in injection moulding process reach fully-automatic production, the moulding of the product age of a draught animal is complete, and efficiency improves, the risk existing while eliminating product on artificial contact mould.

Claims (3)

1. optoelectronic induction is controlled mould, it is characterized in that: it also comprises photoelectric sensing probe, induction gear, synchronizing wheel I, synchronizing wheel II and idle pulley, described induction gear and synchronizing wheel I are arranged on hydraulic motor, described hydraulic motor is arranged on mould outside, described photoelectric sensing probe is arranged on induction gear both sides, described synchronizing wheel II is arranged on mould inside axle, described synchronizing wheel I is connected by Timing Belt with synchronizing wheel II, between described synchronizing wheel I and synchronizing wheel II, idle pulley is installed, axle with synchronizing wheel II connects gear transmission structure, described gear transmission structure drives the rotation of thread screw.

2. optoelectronic induction according to claim 1 is controlled mould, it is characterized in that: described idle pulley is installed on fixed mount.

3. optoelectronic induction according to claim 1 is controlled mould, it is characterized in that: described gear transmission structure comprises gear I and gear II, and described gear II is placed on mould inside axle, and two gear I are symmetrically distributed in gear II both sides and are meshed with gear I.