CN220995138U - Energy-conserving stable multiple spot mode locking device structure - Google Patents

Abstract

The utility model relates to the technical field of mold locking devices and discloses an energy-saving stable multi-point mold locking device structure, which comprises a bottom plate, wherein the rear end of the front surface of the top of the bottom plate is fixedly connected with a support column, one side of the support column is provided with a limit groove, the top of one side of the support column is movably connected with a first clamping plate, two sides of the first clamping plate are fixedly connected with clamping blocks, the outside of the clamping blocks is movably connected with the limit groove, the front surface of the top of the support column is fixedly connected with a motor bin, the bottom of the inner surface of the motor bin is fixedly connected with a servo motor, the bottom of one side of the support column is movably connected with a second clamping plate, the back surface of the support column is movably connected with a reverse-pulling mold locking cylinder, the front surface of the reverse-pulling mold locking cylinder is movably connected with a telescopic rod, and the front end of the outer surface of the telescopic rod is movably connected with a fixed block, so that the device is suitable for molds with different heights, the assembly time of the device can be reduced, and the working efficiency can be improved.

Description

Energy-conserving stable multiple spot mode locking device structure

Technical Field

The utility model relates to the technical field of mode locking devices, in particular to an energy-saving stable multipoint mode locking device structure.

Background

The mold locking device is a device for locking an upper mold and a lower mold to prevent falling off between the upper mold and the lower mold during molding, and the mold is a cavity tool with a certain shape and a certain size, and is matched with various systems or auxiliary equipment in the mold for use, and various high-temperature liquid materials are filled into the cavity of the mold, so that industrial parts with specific shapes, sizes, functions and qualities can be produced.

The existing mold locking device must keep consistent with the height of the device when the mold is locked, otherwise, the mold is clamped and fixed, and when the mold is locked, the mold is mainly fixed and compacted by bolts and nuts, and the mold is huge in size, so that the time and the labor are wasted, and the working efficiency is affected.

Disclosure of utility model

In order to overcome the above-mentioned drawbacks of the prior art, the present utility model provides an energy-saving stable multi-point mode locking device structure, so as to solve the above-mentioned problems in the prior art.

The utility model provides the following technical scheme: the utility model provides an energy-conserving stable multiple spot mode locking device structure, includes the bottom plate, the positive rear end fixedly connected with support column in bottom plate top, the spacing groove has been seted up to one side of support column, the top swing joint of support column one side has first splint, the both sides fixedly connected with fixture block of first splint, the outside swing joint of fixture block has the spacing groove, the positive fixedly connected with motor storehouse at support column top, the bottom fixedly connected with servo motor of motor storehouse internal surface, the bottom swing joint of support column one side has the second splint, the back swing joint of support column has the anti-stretch-draw mode locking hydro-cylinder, the front swing joint of anti-stretch-draw mode locking hydro-cylinder has the telescopic link, the front end swing joint fixed block of telescopic link surface, the front fixedly connected with removal slider of fixed block;

Further, the back fixedly connected with backplate of first splint, the top fixedly connected with overhead gage of first splint, the contained angle between overhead gage and the backplate is ninety degrees, the top fixedly connected with two first connecting blocks of backplate back, threaded hole has been seted up at the top of first connecting block.

Further, the positive fixedly connected with first gear of servo motor bottom, the both sides swing joint of first gear surface has the second gear, the size specification of first gear and second gear equals and intermesh, the positive middle part fixedly connected with threaded rod of second gear bottom, the top swing joint of threaded rod surface has first connecting block, the bottom swing joint of threaded rod surface has the second connecting block, the back swing joint of second connecting block has the second splint, the size specification of second splint and first splint equals, screw hole and screw thread opposite direction are all seted up at the top of second connecting block and first connecting block.

Further, one side fixedly connected with diaphragm of fixed block, the positive fixedly connected with push-and-pull cylinder of diaphragm, the opposite side fixedly connected with of push-and-pull cylinder removes the slider, the bottom fixedly connected with template of fixed block.

Further, the back fixedly connected with fixed block of removal slider, two movable mouths have been seted up to the front of removing the slider, the front swing joint at removal slider top has the slider to move the guide rail, the spout has been seted up to the bottom of slider moving the guide rail, the width of spout and the width of removal slider are wide by two millimeters, the front end fixedly connected with spacing piece of slider moving the guide rail bottom, first fixed orifices has been seted up to one side of spacing piece, the internal surface swing joint of movable mouths has lock nut, the second fixed orifices has been seted up to lock nut's surface.

Further, the diameters of the two movable ports differ by a little five centimeters.

The utility model has the technical effects and advantages that:

1. According to the utility model, the baffle is arranged between the baffle and the template, the servo motor is started, the first gear starts to rotate after the servo motor is started, the second gear starts to rotate after the first gear starts to rotate, the threaded rod starts to rotate after the second gear starts to rotate, the first connecting block moves downwards after the threaded rod starts to rotate, the second connecting block moves upwards, and at the moment, the first clamping plate and the second clamping plate of the die cup are clamped between the first clamping plate and the second clamping plate, so that the equipment can meet the working requirements of dies with different heights.

2. According to the utility model, the anti-die locking oil cylinder is arranged, the telescopic rod is driven to move backwards by using the anti-die locking oil cylinder, the fixed block moves backwards after the telescopic rod moves backwards, the die plate moves backwards and clamps the die after the fixed block moves backwards, the sliding block is pushed by the push-pull air cylinder at the moment, the front end of the telescopic rod moves transversely under the action of the sliding block moving guide rail 702, the front end of the telescopic rod is fixed at the movable port and rotates the locking nut, and the telescopic rod passes through the first fixing hole and the second fixing hole 707 to be secondarily fixed so as to prevent displacement in the compression die process, so that the working time of shortening a set of die is shortened, and the working efficiency is greatly improved.

Drawings

Fig. 1 is a schematic diagram of the overall structure of the present utility model.

Fig. 2 is a schematic view of the back structure of the present utility model.

Fig. 3 is a schematic view of the structure of the threaded rod of the present utility model.

Fig. 4 is a schematic view of the structure of the clamping plate of the present utility model.

Fig. 5 is a schematic diagram of a template structure according to the present utility model.

Fig. 6 is a schematic view of a moving slide according to the present utility model.

FIG. 7 is a schematic diagram of an explosion structure of a movable slider according to the present utility model.

The reference numerals are: 1. a bottom plate; 2. a support column; 201. a limit groove; 3. a first clamping plate; 301. a clamping block; 302. a rear baffle; 303. an upper baffle; 304. a first connection block; 305. a threaded hole; 4. a motor bin; 401. a servo motor; 402. a first gear; 403. a second gear; 404. a threaded rod; 5. a second clamping plate; 501. a second connection block; 6. a reverse pulling mold locking oil cylinder; 601. a telescopic rod; 602. a fixed block; 603. a cross plate; 7. moving the slide block; 701. a movable opening; 702. the slide block moves the guide rail; 703. a chute; 704. a limiting piece; 705. a first fixing hole; 706. a lock nut; 707. a second fixing hole; 708. a push-pull cylinder; 8. and (5) a template.

Detailed Description

The embodiments of the present utility model will be clearly and completely described below with reference to the drawings in the present utility model, and the configurations of the structures described in the following embodiments are merely examples, and the structure of the energy-saving stable multipoint mold locking device according to the present utility model is not limited to the structures described in the following embodiments, and all other embodiments obtained by a person having ordinary skill in the art without making any inventive effort are within the scope of the present utility model.

Referring to fig. 1-7, the utility model provides an energy-saving stable multipoint mold locking device structure, which comprises a bottom plate 1, wherein the rear end of the front surface of the top of the bottom plate 1 is fixedly connected with a support column 2, one side of the support column 2 is provided with a limit groove 201, the top of one side of the support column 2 is movably connected with a first clamping plate 3, two sides of the first clamping plate 3 are fixedly connected with clamping blocks 301, the outer surfaces of the clamping blocks 301 are movably connected with limit grooves 201, the front surface of the top of the support column 2 is fixedly connected with a motor bin 4, the bottom of the inner surface of the motor bin 4 is fixedly connected with a servo motor 401, the bottom of one side of the support column 2 is movably connected with a second clamping plate 5, the back surface of the support column 2 is movably connected with a reverse mold locking cylinder 6, the front surface of the reverse mold locking cylinder 6 is movably connected with a telescopic rod 601, the front end of the outer surface of the telescopic rod 601 is movably connected with a fixed block 602, the front surface of the fixed block 602 is fixedly connected with a movable sliding block 7, the device is favorable for adapting to molds with different heights, the assembly time of the device can be reduced, and the working efficiency can be improved.

In a preferred embodiment, the back of the first clamping plate 3 is fixedly connected with a rear baffle 302, the top of the first clamping plate 3 is fixedly connected with an upper baffle 303, an included angle between the upper baffle 303 and the rear baffle 302 is ninety degrees, the top of the back of the rear baffle 302 is fixedly connected with two first connecting blocks 304, and screw holes 305 are formed in the tops of the first connecting blocks 304.

In a preferred embodiment, a first gear 402 is fixedly connected to the front surface of the bottom of the servo motor 401, two sides of the outer surface of the first gear 402 are movably connected with a second gear 403, the size specifications of the first gear 402 and the size specifications of the second gear 403 are equal and meshed with each other, a threaded rod 404 is fixedly connected to the middle part of the front surface of the bottom of the second gear 403, a first connecting block 304 is movably connected to the top of the outer surface of the threaded rod 404, a second connecting block 501 is movably connected to the bottom of the outer surface of the threaded rod 404, a second clamping plate 5 is movably connected to the back surface of the second connecting block 501, the size specifications of the second clamping plate 5 and the first clamping plate 3 are equal, threaded holes 305 are formed in the tops of the second connecting block 501 and the first connecting block 304, and the directions of threads are opposite.

In a preferred embodiment, one side of the fixed block 602 is fixedly connected with a transverse plate 603, the front surface of the transverse plate 603 is fixedly connected with a push-pull cylinder 708, the other side of the push-pull cylinder 708 is fixedly connected with a movable sliding block 7, and the bottom of the fixed block 602 is fixedly connected with a template 8.

In a preferred embodiment, a fixed block 602 is fixedly connected to the back of the moving slide 7, two movable ports 701 are formed in the front of the moving slide 7, a slide moving guide rail 702 is movably connected to the front of the top of the moving slide 7, a sliding groove 703 is formed in the bottom of the slide moving guide rail 702, the width of the sliding groove 703 is two millimeters wider than the width of the moving slide 7, a limiting plate 704 is fixedly connected to the front end of the bottom of the slide moving guide rail 702, a first fixing hole 705 is formed in one side of the limiting plate 704, a locking nut 706 is movably connected to the inner surface of the movable port 701, and a second fixing hole 707 is formed in the outer surface of the locking nut 706.

In a preferred embodiment, the diameters of the two ports 701 differ by a few five centimeters.

The working principle of the utility model is as follows: when the moulds with different heights are required to be used for operation, the moulds are placed between the rear baffle plate 302 and the template 8, the servo motor 401 is started, the first gear 402 starts to rotate after the servo motor 401 starts to rotate, the second gear 403 starts to rotate after the first gear 402 starts to rotate, the threaded rod 404 starts to rotate after the second gear 403 starts to rotate, the first connecting block 304 moves downwards after the threaded rod 404 starts to rotate, the second connecting block 501 moves upwards at the moment, and the first clamping plate 3 and the second clamping plate 5 of the mould cup are clamped between the first clamping plate and the second clamping plate, so that the equipment can meet the working requirements of the moulds with different heights; when the mold is required to be transversely clamped, the reverse zipper cylinder 6 is used for driving the telescopic rod 601 to move backwards, the rear fixing block 602 moves backwards when the telescopic rod 601 moves backwards, the rear die plate 8 moves backwards and clamps the mold when the fixing block 602 moves backwards, the push-pull cylinder 708 is used for pushing the movable slide block 7 to transversely move under the action of the slide block movable guide rail 702, at the moment, the front end of the telescopic rod 601 is fixed at the movable opening 701 and the locking nut 706 is rotated to fix the telescopic rod, and the telescopic rod passes through the first fixing hole 705 and the second fixing hole 707 at the fixing bolt to be secondarily fixed so as to prevent displacement in the compression molding process, so that the working time of a set of mold is shortened, and the working efficiency is greatly improved.

Claims (6)

1. The utility model provides an energy-conserving stable multiple spot mode locking device structure, includes bottom plate (1), its characterized in that: positive rear end fixedly connected with support column (2) in bottom plate (1) top, spacing groove (201) have been seted up to one side of support column (2), the top swing joint of support column (2) one side has first splint (3), the both sides fixedly connected with fixture block (301) of first splint (3), the outside swing joint of fixture block (301) has spacing groove (201), the positive fixedly connected with motor storehouse (4) at support column (2) top, the bottom fixedly connected with servo motor (401) of motor storehouse (4) internal surface, the bottom swing joint of support column (2) one side has second splint (5), the back swing joint of support column (2) has reverse mode locking hydro-cylinder (6), the positive swing joint of reverse mode locking hydro-cylinder (6) telescopic link (601), the front end swing joint fixed block (602) of telescopic link (601) surface, the front fixedly connected with slider (7) of fixed block (602).

2. The energy-saving stable multipoint mold locking device structure according to claim 1, wherein: the back fixedly connected with backplate (302) of first splint (3), the top fixedly connected with overhead gage (303) of first splint (3), the contained angle between overhead gage (303) and backplate (302) is ninety degrees, the top fixedly connected with two first connecting blocks (304) at backplate (302) back, screw hole (305) have been seted up at the top of first connecting block (304).

3. The energy-saving stable multipoint mold locking device structure according to claim 1, wherein: the utility model discloses a servo motor, including servo motor (401), servo motor, first gear (402), second gear (403), first gear (402) and second gear (403) are equal and intermeshed in size specification of both sides swing joint of first gear (402) surface, screw rod (404) are fixedly connected with in positive middle part in second gear (403) bottom, the top swing joint of screw rod (404) surface has first connecting block (304), the bottom swing joint of screw rod (404) surface has second connecting block (501), the back swing joint of second connecting block (501) has second splint (5), the size specification of second splint (5) and first splint (3) equals, screw hole (305) and screw thread opposite direction are all seted up at the top of second connecting block (501) and first connecting block (304).

4. The energy-saving stable multipoint mold locking device structure according to claim 1, wherein: one side fixedly connected with diaphragm (603) of fixed block (602), the front fixedly connected with push-and-pull cylinder (708) of diaphragm (603), the opposite side fixedly connected with of push-and-pull cylinder (708) removes slider (7), the bottom fixedly connected with template (8) of fixed block (602).

5. The energy-saving stable multipoint mold locking device structure according to claim 1, wherein: the utility model discloses a movable sliding block, including slider (7), fixed block (602) is fixed on the back fixedly connected with of slider (7), two movable ports (701) have been seted up to the front of slider (7), the front swing joint at slider (7) top has slider movable guide rail (702), spout (703) have been seted up to the bottom of slider movable guide rail (702), the width of spout (703) and the width of slider (7) are two millimeters wide, the front end fixedly connected with spacing piece (704) of slider movable guide rail (702) bottom, first fixed orifices (705) have been seted up to one side of spacing piece (704), the internal surface swing joint of movable port (701) has lock nut (706), second fixed orifices (707) have been seted up to the surface of lock nut (706).

6. The energy-saving stable multipoint mold locking device structure according to claim 5, wherein: the diameters of the two movable ports (701) differ by a little five centimeters.