CN212892697U - Material transfer device is used in processing of stone material heat preservation intergral template - Google Patents

Abstract

The utility model discloses a stone material heat preservation body board processing material transfer device for technical field of stone material heated board processing equipment, which comprises a fixing frame, insulation material board and thin stone material board have been put to the mount below through the dolly sign indicating number, the both sides of mount all are provided with first slide rail, one side of two first slide rails all is provided with the rack, sliding connection has the movable plate on two first slide rails, bearing in the bearing frame is passed through to one side of movable plate upper end rotates and connects the gear shaft, the equal fixedly connected with gear in both ends of gear shaft, two gears mesh respectively and are connected with two racks, the gear shaft passes through motor drive, motor fixed connection is on the movable plate, the opposite side fixedly connected with of movable plate upper end drives actuating cylinder, the extension end fixedly connected with second slide rail that drives actuating cylinder, the equal sliding connection in both ends. The device is convenient for the transfer of material, and can make things convenient for the assembly of insulation material board and thin stone material board at the transfer in-process, improves production efficiency.

Description

Material transfer device is used in processing of stone material heat preservation intergral template

Technical Field

The utility model relates to a stone material heated board processing equipment field specifically is a material transfer device is used in processing of stone material heat preservation intergral template.

Background

The stone insulation board is also called as an external wall insulation stone composite board, a granite insulation composite board, a stone insulation decoration integrated board, a composite insulation stone and the like, and practically, no unified call exists at present, but the meanings are similar, namely, the stone insulation board is a product formed by compounding natural stone and an insulation material. Stone material board all will pass through material transfer device's transportation so that reach the place that needs the pre-installation to bond before making the finished product, because the thinner split of being not convenient for of piling up together of stone material board, like ultra-thin stone and ceramic tile etc. insulation material is thick simultaneously and is difficult for pressing from both sides and get.

The processing of current stone material heat preservation intergral template is with material transfer device still is many for manual cart, with stone material board and insulation material board together propelling movement to set pre-installation region, then puts things in good order through the manual work, glues the barrel and rolls the glue bonding, and this kind of transfer mode inefficiency, the amount of labour is big, the accurate positioning processing of being not convenient for, and production efficiency is low.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a material transfer device is used in processing of stone material heat preservation intergral template to solve this kind of artifical transfer mode inefficiency of dolly that proposes in the above-mentioned background art, the accurate positioning processing of being not convenient for, the problem that artifical stacking labor capacity is big.

In order to achieve the above object, the utility model provides a following technical scheme:

a material transfer device for processing a stone heat-insulation integrated plate comprises a fixed frame, wherein a heat-insulation material plate and a thin stone plate are stacked below the fixed frame through a trolley, first slide rails are arranged on two sides of the fixed frame, racks are arranged on one sides of the two first slide rails, a moving plate is connected on the two first slide rails in a sliding manner, one side of the upper end of the moving plate is rotatably connected with a gear shaft through a bearing in a bearing seat, gears are fixedly connected to two ends of the gear shaft, the two gears are respectively connected with the two racks in a meshing manner, the gear shaft is driven by a motor, the motor is fixedly connected to the moving plate, a driving cylinder is fixedly connected to the other side of the upper end of the moving plate, a second slide rail is fixedly connected to the extending end of the driving cylinder, and corresponding clamping plates are respectively, two all be provided with the rubber locating piece on the medial surface of splint, two splint are connected respectively and are held at two stretches of two-way telescoping cylinder, the both sides of second slide rail all are provided with the double-stroke cylinder, the end that stretches out of double-stroke cylinder passes the movable plate and is connected with vacuum chuck, the fixing base of double-stroke cylinder is fixed to be set up on the movable plate.

As a further aspect of the present invention: the second slide rail is a T-shaped slide groove, the upper end of the clamping plate is matched with the T-shaped slide groove, so that the clamping plate is more stable when sliding on the slide rail, the smaller the bearing tension of the extending end of the two-way telescopic cylinder is, and the service life of the two-way telescopic cylinder is prolonged.

And the sliding surface of the upper end of the clamping plate, which is in contact with the T-shaped sliding groove, is correspondingly provided with a ball and a ball groove. Further, the clamping plate can slide in the T-shaped sliding groove conveniently, so that the whole device can be operated without clamping stagnation, and the service life of the bidirectional telescopic cylinder is prolonged

As a further aspect of the present invention: the two ends of the first sliding rail are provided with limiting blocks, the middle of each limiting block is provided with a through hole, and a photoelectric displacement sensor is arranged in each through hole. The photoelectric displacement sensor can assist in detecting the sliding position of the moving plate, so that the photoelectric displacement sensor can be accurately positioned at the position of a material or can accurately control the starting and stopping of a motor.

As a further aspect of the present invention: the first sliding rail and the moving plate slide through rollers. Therefore, the moving plate can slide on the first sliding rail more flexibly, and the whole device can operate conveniently.

As a further aspect of the present invention: and the front end of the moving plate is provided with a plurality of position sensors for sensing the position of the material. The position sensor can be further used for locking the relative position displacement of the material to assist the automatic control of the actions of the bidirectional telescopic cylinder, the two-way cylinder, the vacuum chuck and the driving cylinder.

As a further aspect of the present invention: the inner surface of the rubber positioning block is an arc-shaped surface. The arc-shaped surface material-saving structure is light, the clamping effect on the heat-insulating material plate is good, and the tension provided by the arc-shaped surface is larger during pressing, so that the heat-insulating material plate is not easy to slide.

Compared with the prior art, the beneficial effects of the utility model are that:

1. in the utility model, the heat insulation material plate and the thin stone plate are respectively placed at the specific position below the fixing frame by stacking the trolley, the gear is driven to rotate relative to the rack by the motor to drive the gear to drive the movable plate to slide on the first slide rail, when the movable plate slides to the position above the thin stone plate, the vacuum chuck is driven by controlling the extension of the double-stroke cylinder to adsorb and lift the thin stone plate to the proper position at the upper side in the clamping plate, the clamping plate with the belt moves to the position above the heat insulation material plate along with the movable plate, the driving cylinder extends out and the two rubber positioning blocks on the clamping plate clamp the heat insulation material under the drive of the double-stroke cylinder, at the moment, the rubber barrel is rolled for a circle on the upper surface of the heat insulation material by manpower, after the aviation glue with strong cohesive force is coated on the heat insulation material, under the control of the double-stroke cylinder, the vacuum chuck drives the thin stone plate to move down along the upper surface of the clamping, and meanwhile, the driving cylinder retracts to complete powerful pressing and bonding operation, when the material is transferred to the position of the material conveying belt, the pressure of the vacuum sucker is only removed, then the bidirectional telescopic cylinder is controlled to extend, and the bonded finished product falls onto the conveying belt and then is transferred away. This material transfer device is used in processing of stone material heat preservation intergral template is convenient for the transfer of material, accomplishes the transfer to the material through mechanical electrification mode, has lightened manual operation's the amount of labour, and is convenient for accurate positioning and processing.

2. The utility model discloses in, overall structure is simple, and first slide rail, second slide rail, ball, pearl groove, gyro wheel, slip are convenient, are convenient for transport.

Drawings

Fig. 1 is a first schematic structural diagram of the present invention;

FIG. 2 is a second schematic structural view of the present invention;

FIG. 3 is a schematic view of the connection of the rubber positioning block of the present invention;

fig. 4 is a schematic view of the connection of the middle roller of the present invention.

In the figure: 1. a fixed mount; 2. a first slide rail; 3. a rack; 4. moving the plate; 5. a bearing seat; 6. a gear shaft; 7. a gear; 8. an arcuate surface; 9. a motor; 10. a driving cylinder; 11. a second slide rail; 12. a splint; 13. a rubber positioning block; 14. a bidirectional telescopic cylinder; 15. a two-stroke cylinder; 16. a vacuum chuck; 17. a ball bearing; 18. a bead groove; 19. a limiting block; 20. a photoelectric displacement sensor; 21. a roller; 22. a position sensor.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Referring to fig. 1 to 4, in an embodiment of the present invention, a material transferring device for processing a stone insulation integrated plate includes a fixing frame 1, an insulation material plate and a thin stone plate are stacked below the fixing frame 1 by a cart, first sliding rails 2 are disposed on both sides of the fixing frame 1, racks 3 are disposed on one sides of the first sliding rails 2, a moving plate 4 is slidably connected to the first sliding rails 2, one side of an upper end of the moving plate 4 is rotatably connected to a gear shaft 6 through a bearing in a bearing seat 5, gears 7 are fixedly connected to both ends of the gear shaft 6, the two gears 7 are respectively engaged with the two racks 3, the gear 7 is driven by a motor 9, the motor 9 is fixedly connected to the moving plate 4, a driving cylinder 10 is fixedly connected to the other side of the upper end of the moving plate 4, an extending end of the driving cylinder 10 is fixedly connected to a second sliding rail 11, both ends of the second sliding rail 11, the inner side surfaces of the two clamping plates 12 are respectively provided with a rubber positioning block 13, the two clamping plates 12 are respectively connected to two extending ends of a two-way telescopic cylinder 14, two sides of the second sliding rail 11 are respectively provided with a two-way cylinder 15, the extending ends of the two-way cylinders 15 penetrate through the movable plate 4 and are connected with a vacuum sucker 16, and a fixed seat of the two-way cylinder 15 is fixedly arranged on the movable plate 4.

The utility model discloses a theory of operation is: the thermal insulation material plate and the thin stone plate are respectively placed at specific positions below the fixing frame 1 through the trolley, the gear shaft 6 is driven to rotate through the motor 9, the gear 7 is driven to be meshed with the rack 3, the moving plate 4 slides on the first sliding rail 2, when the thin stone plate slides to the upper side of the thin stone plate, the vacuum sucker 16 is driven to be stretched out by controlling the double-stroke cylinder 15 to adsorb and lift the thin stone plate to a proper position on the inner upper side of the clamping plate 12, the clamping plate 12 moves to the upper side of the thermal insulation material plate along with the moving plate 4, the driving cylinder 10 stretches out, the rubber positioning blocks 13 on the two clamping plates 12 clamp the thermal insulation material under the driving of the double-stroke telescopic cylinder 14, at the moment, the rubber barrel rolls for a circle on the upper surface of the thermal insulation material through manpower, after the thermal insulation material is coated with aviation glue with strong bonding force, and under the control of the double-stroke cylinder 15, the vacuum sucker 16 drives the thin stone plate to move downwards On the upper surface, the cylinder 10 is driven to retract at the same time to complete the powerful pressing and bonding operation, when the material is transferred to the position of the material conveying belt, the pressure of the vacuum sucker 16 is only removed, then the bidirectional telescopic cylinder 14 is controlled to extend, and the bonded finished product falls on the conveying belt and then flows away. This material transfer device is used in processing of stone material heat preservation intergral template is convenient for the transfer of material, accomplishes the transfer to the material through mechanical electrification mode, has lightened manual operation's the amount of labour, and is convenient for accurate positioning and processing.

The second slide rail 11 is a T-shaped slide groove, and the upper end of the clamping plate 12 is matched with the T-shaped slide groove, so that the clamping plate 12 is more stable when sliding on the slide rail, the smaller the bearing tension of the extending end of the bidirectional telescopic cylinder 14 is, and the service life of the bidirectional telescopic cylinder 14 is prolonged.

The sliding surface of the upper end of the clamping plate 12, which is contacted with the T-shaped sliding groove, is correspondingly provided with a ball 17 and a ball groove 18. Further, the clamping plate 12 can slide in the T-shaped sliding groove conveniently, so that the whole device can not be stuck when being operated, and the service life of the bidirectional telescopic cylinder 14 is prolonged.

Both ends of first slide rail 2 all are provided with stopper 19, and the middle part of stopper 19 is provided with the through-hole, is provided with photoelectric displacement sensor 20 in the through-hole. Here, the photoelectric displacement sensor 20 may assist in detecting the sliding position of the moving plate 4, so that it can be accurately located to the position of the material or can accurately control the start and stop of the motor 9.

The first slide rail 2 and the moving plate 4 slide through the roller 21. Therefore, the moving plate 4 can slide on the first sliding rail 2 more flexibly, and the operation of the whole device is convenient.

The front end of the moving plate 4 is provided with a plurality of position sensors 22 for sensing the position of the material, wherein the position sensors 22 can be magnetic proximity switches or ultrasonic position sensors, and the types of the position sensors can be various E2B-M30LN30-WZ-C1 NPN outputs or E2B-M30LN30-WZ-B1 PNP outputs. The position sensor 22 can further be used to lock the relative position displacement of the material to assist in automatically controlling the actions of the two-way telescopic cylinder 14, the two-way cylinder 15, the vacuum chuck 16 and the driving cylinder 10.

The inner surface of the rubber positioning block 13 is an arc-shaped surface 8. The arc-shaped surface 8 is light in material saving structure, good in clamping effect on the heat-insulating material plate, and larger in tension provided by the arc-shaped surface 8 during pressing, so that the heat-insulating material plate is not easy to slide.

The above, only be the concrete implementation of the preferred embodiment of the present invention, but the protection scope of the present invention is not limited thereto, and any person skilled in the art is in the technical scope of the present invention, according to the technical solution of the present invention and the utility model, the concept of which is equivalent to replace or change, should be covered within the protection scope of the present invention.

Claims (7)

1. The utility model provides a material transfer device is used in processing of stone material heat preservation intergral template, includes mount (1), insulation material board and thin stone material board, its characterized in that have been put through the dolly sign indicating number to mount (1) below: the two sides of the fixing frame (1) are respectively provided with a first sliding rail (2), one side of each of the two first sliding rails (2) is provided with a rack (3), the two first sliding rails (2) are connected with a moving plate (4) in a sliding manner, one side of the upper end of the moving plate (4) is rotatably connected with a gear shaft (6) through a bearing in a bearing seat (5), two ends of the gear shaft (6) are respectively and fixedly connected with a gear (7), the two gears (7) are respectively connected with the two racks (3) in a meshing manner, a shaft of the gear (7) is driven by a motor (9), the motor (9) is fixedly connected onto the moving plate (4), the other side of the upper end of the moving plate (4) is fixedly connected with a driving cylinder (10), the extending end of the driving cylinder (10) is fixedly connected with a second sliding rail (11), and two ends of the second sliding rail (, two all be provided with rubber locating piece (13), two on the medial surface of splint (12) are connected respectively and are held in two stretches of two-way telescoping cylinder (14), the both sides of second slide rail (11) all are provided with two-way cylinder (15), the end that stretches out of two-way cylinder (15) passes movable plate (4) and is connected with vacuum chuck (16), the fixed setting of the fixing base of two-way cylinder (15) is in on movable plate (4).

2. The material transfer device for processing the stone thermal insulation integrated plate as claimed in claim 1, which is characterized in that: the second slide rail (11) is a T-shaped slide groove, and the upper end of the clamping plate (12) is matched with the T-shaped slide groove.

3. The stone material heat preservation intergral template processing of claim 2 uses material transfer device which characterized in that: and the sliding surface of the upper end of the clamping plate (12) in contact with the T-shaped sliding groove is correspondingly provided with a ball (17) and a ball groove (18).

4. The material transfer device for processing the stone thermal insulation integrated plate as claimed in claim 1, which is characterized in that: both ends of the first sliding rail (2) are provided with limiting blocks (19), the middle of each limiting block (19) is provided with a through hole, and a photoelectric displacement sensor (20) is arranged in each through hole.

5. The material transfer device for processing the stone thermal insulation integrated plate as claimed in claim 1, which is characterized in that: the first sliding rail (2) and the moving plate (4) slide through a roller (21).

6. The material transfer device for processing the stone thermal insulation integrated plate as claimed in claim 1, which is characterized in that: the front end of the moving plate (4) is provided with a plurality of position sensors (22) used for sensing the position of the material.

7. The material transfer device for processing the stone thermal insulation integrated plate as claimed in claim 1, which is characterized in that: the inner surface of the rubber positioning block (13) is an arc-shaped surface (8).

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