CN105731776B - Quick tool changing device for full-automatic slitting machine - Google Patents

Abstract

The invention provides a quick tool changing device for a full-automatic slitting machine, which comprises a guide rail fixed on a knife board, wherein a first sliding block and a second sliding block are connected with the guide rail and slide along the guide rail; the proximity switch, the cutting locking assembly and the tool changing locking assembly are fixed on the knife board, the proximity switch is arranged close to the cutting locking assembly, the cutting locking assembly and the tool changing locking assembly are arranged at intervals, the first sliding block mounting plate is provided with an extending part, and an accommodating space is formed between the extending part and the knife board; the locking cylinder is fixed on the top surface of the extension part and drives the locking shaft to be in locking connection with the cutting locking assembly or the tool changing locking assembly. The invention has convenient operation and saves the time for changing the cutter, and the cutter head can be directly cut without repositioning after the cutter wheel is changed at the original cutting position.

Description

Quick tool changing device for full-automatic slitting machine

Technical Field

The invention belongs to the technical field of float glass cutting, and particularly relates to a quick tool changing device for a full-automatic slitting machine.

Background

Float glass is a product frequently used in our daily life, and has wide application, and the float glass is mainly divided into colored glass, float silver mirror, float glass/automobile windshield grade, float glass/various deep processing grades, float glass/scanner grade, float glass/coating grade and float glass/mirror making grade. The ultra-white float glass has wide application and wide market prospect, and is mainly applied to the fields of high-grade buildings, high-grade glass processing and solar photoelectric curtain walls, high-grade glass furniture, decorative glass, crystal-like products, lamp glass, precise electronic industry, special buildings and the like. The need to produce these delicate household and industrial products often requires cutting the float glass, which is often handled by fully automated slitters.

The full-automatic slitting machine is an important cutting device on a high-end float glass production line, is arranged across a glass conveying roller way and is used for longitudinally cutting a glass belt. Because the cutting knife wheel on the full-automatic slitting machine continuously works, the cutting knife wheel is quickly abraded, and the cutting knife wheel needs to be frequently replaced for ensuring the cutting quality. Especially when thick glass is cut, the cutter wheel is required to be replaced for several hours.

At present, when a cutting knife wheel of a full-automatic slitting machine needs to be replaced, a knife head needs to be stopped, the knife head is moved out of a conveying roller way along a cross beam and is moved into an operable space at the end part of the cross beam, and if other knife heads block in the moving-out direction, the knife head needs to be stopped and moved to the end part of the cross beam. After the cutter wheel is replaced, the cutter wheel needs to be repositioned to continue cutting. However, the conventional process is time-consuming for the entire tool changing process, and workers often spend a lot of time on the replacement process, and complain about this.

Disclosure of Invention

Aiming at the technical defects in the prior art, the invention aims to provide a quick tool changing device for a full-automatic slitting machine, which comprises: the first sliding block and the second sliding block are sequentially connected with the guide rail along the length direction of the guide rail and can slide along the guide rail, the fixed assembly and the first sliding block are respectively connected to two side surfaces of the first sliding block mounting plate along the width direction of the guide rail, and the moving assembly and the second sliding block are respectively connected to two side surfaces of the second sliding block mounting plate along the width direction of the guide rail;

along the length direction of the knife board, a proximity switch, a cutting locking assembly and a tool changing locking assembly are sequentially fixed on the knife board, the proximity switch is arranged close to the cutting locking assembly, the cutting locking assembly and the tool changing locking assembly are arranged at intervals, the first slider mounting plate is provided with an extending part, an accommodating space is formed between the extending part and the knife board, and the accommodating space is used for accommodating the cutting locking assembly or the tool changing locking assembly;

the locking cylinder is fixed on the top surface of the extension part, a cylinder rod of the locking cylinder is connected with the locking shaft, and the locking cylinder drives the locking shaft to be in locking connection with the cutting locking assembly or the tool changing locking assembly.

Preferably, when the tool changer is in a working state, the accommodating space accommodates the cutting locking assembly, and the locking cylinder drives the locking shaft to extend into the locking hole of the cutting locking assembly and fix the locking shaft.

Preferably, when the tool changer is in a tool changing state, the accommodating space accommodates the tool changing locking assembly, and the locking cylinder drives the locking shaft to extend into a locking hole of the tool changing locking assembly and fix the locking shaft.

Preferably, the locking cylinder is further connected with a guide sleeve, and the guide sleeve is located below the extension portion.

Preferably, the proximity switch is fixed on an adjusting bolt, the adjusting bolt is fixed on a bracket, and the bracket is fixed on the knife board.

Preferably, a locking and unlocking button and an electromagnetic valve are arranged on the cutting board, the locking and unlocking button is connected with the electromagnetic valve, and the electromagnetic valve is connected with the locking cylinder.

Preferably, the fixed component is connected to a handle.

The invention has the beneficial effects that: the cutter wheel is convenient to operate, the cutter changing time is saved, and after the original cutting position is changed, the cutter head is directly cut without repositioning. And does not affect the normal use of other cutting heads on the same side. The quick tool changing device is necessarily favored by workers on the production line of the float glass.

Drawings

Other features, objects and advantages of the invention will become more apparent upon reading of the detailed description of non-limiting embodiments with reference to the following drawings:

fig. 1 is a schematic view showing the overall structure of a quick tool changer in a cutting state according to an embodiment of the present invention.

FIG. 2 is a schematic view showing the overall structure of the quick tool changer in a tool changing state according to an embodiment of the present invention;

FIG. 3 is a schematic view of the construction of one embodiment of the present invention with the cut-lock assembly not engaged with the lock cylinder; and

fig. 4 shows a schematic view of the cutting lock assembly in engagement with the lock cylinder, in accordance with one embodiment of the present invention.

Detailed Description

In order to better and clearly show the technical scheme of the invention, the invention is further described with reference to the attached drawings.

Fig. 1 shows a schematic diagram of an overall structure of a quick tool changer in a cutting state according to an embodiment of the present invention, and it is understood by those skilled in the art that fig. 1 only shows a part of the structure of the quick tool changer, and the part of the structure shown is a connection structure of the quick tool changer that can best embody the technical solution of the present invention, but this does not mean that the quick tool changer only includes the structure shown in the figure, and details are not repeated here.

Specifically, quick tool changer is including fixing guide rail 1 on cutting board 100, guide rail 1 is through connecting cutting board 100, cutting board 100 supports guide rail 1, specifically, along 1 length direction first slider 2 of guide rail and second slider 6 in proper order with guide rail 1 is connected and can be followed guide rail 1 slides, guide rail 1 is preferred to be the cuboid structure, the guide rail is followed guide rail length direction has been divided into two parts guide rail, first slider 2 and second slider 6 is set up respectively on the two parts guide rail, and can follow guide rail 1's length direction freely slides.

Further, the first slider mounting plate 7 is connected to the fixing component 101 and the first slider 2 along two lateral sides of the guide rail 1 in the width direction, as shown in fig. 1, the first slider mounting plate 7 is connected to the first slider 2 and can move along with the movement of the first slider 2, and the first slider mounting plate 7 is further connected to the fixing component 101.

Further, the second slider mounting plate 13 is connected to the moving assembly 102 and the second slider 6 along two sides of the width direction of the guide rail 1, i.e. the second slider 6 is disposed on one side of the second slider mounting plate 13, and the moving assembly 102 is disposed on the other side of the second slider mounting plate 13, so that when the second slider 6 moves, the moving assembly 102 on the second slider mounting plate 13 moves. Specifically, the moving assembly 102 is further connected to the fixed assembly 101, and in the cutting process, the cylinder of the fixed assembly 101 extends or retracts, and meanwhile, the moving assembly 102 is controlled to move, so that a cutter wheel below the moving assembly 102 is driven.

Further, along the length direction of the knife board 100, a proximity switch 8, a cutting locking component 3 and a knife changing locking component 14 are sequentially fixed on the knife board 100, specifically, the proximity switch 8 is used for sensing whether the extension part 71 reaches the position of the proximity switch 8, and when the cutting locking component 3 reaches the position of the proximity switch 8, the proximity switch 8 sends a control command capable of cutting. Proximity switch 8, cutting lock assembly 3, and tool changing lock assembly 14 are preferably arranged in a straight line and on knife plate 100.

Further, the first slider mounting plate 7 has an extending portion 71, and those skilled in the art understand that the first slider mounting plate 7 is preferably "L" shaped, and the extending portion 71 is a portion extending below the "L" shape, in such an embodiment, as shown in fig. 1, an accommodating space is formed between the extending portion 71 and the knife plate 100, the accommodating space is adapted to the size and shape of the cutting locking assembly or the tool changing locking assembly, further, in the cutting state or in the tool changing state, the accommodating space is used for accommodating the cutting locking assembly 3 or the tool changing locking assembly 14, and the manner of the accommodating space for accommodating the cutting locking assembly 3 or the tool changing locking assembly 14 will be described in detail in the specific embodiments described later, and will not be described herein again.

Furthermore, a locking cylinder 9 is fixed on the top surface of the extension portion 71, a cylinder rod of the locking cylinder 9 is connected with a locking shaft 11, and the locking cylinder 9 drives the locking shaft 11 to be in locking connection with the cutting locking assembly 3 or the tool changing locking assembly 14. Specifically, fig. 3 and fig. 4 show respectively the structural schematic diagram of the unconnected state and the connected state of cutting locking assembly 3 and locking cylinder 9, locking shaft 11 with extension 71 is perpendicular setting, and when cutting locking assembly 3 and locking cylinder 9 were not connected, locking shaft 11 did not insert in the locking hole of cutting locking assembly 3, when cutting locking assembly 3 and locking cylinder 9 need be connected, locking shaft 11 was in under the drive of locking cylinder 9, insert in the locking hole of cutting locking assembly 3, the realization is fastened and is fixed. More specifically, the connection between the locking cylinder 9 and the tool changing locking assembly 14 is similar, and will not be described herein.

Further, the quick tool changer has two different states, one is a cutting state, as shown in fig. 1, at this time, the cutting locking assembly 3 is located at the accommodating space, and the locking shaft 11 penetrates through the accommodating space and is fixedly connected with the cutting locking assembly 3. In another state, when a cutting knife wheel is replaced, as shown in fig. 2, the first slider 2 and the second slider 6 slide on the guide rail 7 to drive the extension 71 to move to the position above the knife changing locking assembly 14, so that the knife changing locking assembly 14 is located in the accommodating space, and the locking shaft 11 passes through the accommodating space and is fixedly connected with the knife changing locking assembly 14.

Further, after tool changing is finished, the first sliding block 2 and the second sliding block 6 slide on the guide rail 7 to drive the extending portion 71 to move to the position above the cutting locking assembly 3, so that the cutting locking assembly 3 is located at the accommodating space, the locking shaft 11 of the cutting locking assembly 3 penetrates through the accommodating space and is fixedly connected with the cutting locking assembly 14, at the moment, the extending portion 71 reaches the position of the proximity switch, and the proximity switch 8 sends a control command capable of cutting.

In a specific embodiment, the guide sleeve 10 is sleeved on the locking shaft 11, in such an embodiment, the guide sleeve 10 is located between the extension portion 71 and the cutting locking assembly 3 (or the tool changing locking assembly), the guide sleeve 10 is connected to the locking cylinder 9, and when the locking shaft 11 needs to be connected to the cutting locking assembly 3, the guide sleeve 10 can play a role in guiding, so as to ensure the stability of the position of the locking shaft 11.

In another embodiment, the proximity switch 8 and the adjusting bolt 5 are fixed to a bracket 4, and the bracket 4 is fixed to the knife board 100. The support 4 sets up on the cutting board 100, the support 4 is located first slider mounting panel 7 with between the second slider mounting panel 13, specifically, when first slider 2 and the slip drive of second slider 6 on guide rail 7 extension 71 removes when cutting locking Assembly 3's top, extension 71 touches adjusting bolt 5, adjusting bolt 5 is used for limiting displacement, promptly when extension 71 reachs adjusting bolt 5, first slider 2 and second slider 6 no longer slide, show simultaneously that the cutting position has been reachd, and later locking cylinder 9's locking shaft 11 stretches into it is fixed in the cutting fixing Assembly 3. More specifically, by screwing or unscrewing the adjusting bolt 5, the position of the adjusting bolt 5, and thus the position where the extending portion 71 touches the adjusting bolt 5, can be adjusted.

In another embodiment, the knife plate 100 is provided with a locking and unlocking button 15 and a solenoid valve 16, the locking and unlocking button 15 is connected with the solenoid valve 16, and the solenoid valve 16 is connected with the locking cylinder 9. Specifically, the locking and unlocking button 15 is preferably provided with two buttons, namely a locking button and an unlocking button, which are respectively used for controlling the electromagnetic valve 16 to change directions. More specifically, the lock cylinder 9 is controlled to be pressurized or depressurized by reversing the solenoid valve 16. For example, the locking cylinder 9 is in a pressurized state, at this time, the locking shaft 11 extends into the cutting locking assembly 3 or the tool changing locking assembly 14 and is fixed, after the locking and unlocking button 15 is pressed, the electromagnetic valve 16 is reversed, the locking cylinder 9 is switched to a pressure relief state, and the locking shaft 11 is pulled out from the cutting locking assembly 3 or the tool changing locking assembly 14; after the locking and unlocking button 15 is pressed again, the electromagnetic valve 16 is reversed again, the locking cylinder 9 is switched to a pressurizing state, and the locking shaft 11 extends into the cutting and locking assembly 3 or the tool changing and locking assembly 14 again and is fixed. Those skilled in the art will appreciate that slide 2 and slide 6 first need to be converted to a pressure relief state by lock cylinder 9 before moving along guide 7 to allow withdrawal of lock shaft 11 from either cut lock assembly 3 or tool change lock assembly 14.

In another embodiment, the fixing assembly 101 is connected to a handle 12, so that when the first slider 2 and the second slider 6 are required to drive the extension 71 to move to the position of the tool changing locking assembly 14, the handle 12 is firstly and then lifted by hand, the locking cylinder 9 is switched to a pressure relief state, so that the locking shaft 11 is drawn out from the cutting locking assembly 3 or the tool changing locking assembly 14, and then a pushing force is applied to the handle 12, so as to drive the slider 2 and the slider 6 to move along the guide rail 7 towards the direction of the tool changing locking assembly 14. When the first slider 2 and the second slider 6 are required to drive the extension portion 71 to move to the position of the cutting locking assembly 3, the handle 12 is firstly held up by hand, the locking cylinder 9 is switched to a pressure relief state by hand, the locking shaft 11 is further pulled out from the cutting locking assembly 3 or the tool changing locking assembly 14, then the slider 2 and the slider 6 move towards the cutting locking assembly 3 along the guide rail 7 under the action of gravity, the handle 12 is still held by hand at the moment to exert a buffering action force, and the slider 2 and the slider 6 are prevented from sliding too fast.

The foregoing description of specific embodiments of the present invention has been presented. It is to be understood that the present invention is not limited to the specific embodiments described above, and that various changes and modifications may be made by one skilled in the art within the scope of the appended claims without departing from the spirit of the invention.

Claims (7)

1. A quick tool changer for on full-automatic slitter, its characterized in that includes:

the cutting device comprises a guide rail fixed on a cutting board, a first sliding block and a second sliding block which are sequentially connected with the guide rail along the length direction of the guide rail and can slide along the guide rail, a first sliding block mounting plate is respectively connected with a fixing component and the first sliding block along two side surfaces of the guide rail in the width direction, a second sliding block mounting plate is respectively connected with a moving component and the second sliding block along two side surfaces of the guide rail in the width direction, the moving component is connected with the fixing component, and a cutter wheel below the moving component is driven by controlling the moving component to move in the cutting process;

along the length direction of the knife board, a proximity switch, a cutting locking assembly and a tool changing locking assembly are sequentially fixed on the knife board, the proximity switch is arranged close to the cutting locking assembly, the cutting locking assembly and the tool changing locking assembly are arranged at intervals, the first slider mounting plate is provided with an extending part, an accommodating space is formed between the extending part and the knife board, and the accommodating space is used for accommodating the cutting locking assembly or the tool changing locking assembly;

the locking cylinder is fixed on the top surface of the extension part, a cylinder rod of the locking cylinder is connected with the locking shaft, and the locking cylinder drives the locking shaft to be in locking connection with the cutting locking assembly or the tool changing locking assembly.

2. The tool changer of claim 1, wherein the receiving space receives the cutting lock assembly when the tool changer is in an operating state, and the locking cylinder drives the locking shaft to extend into a locking hole of the cutting lock assembly and fix the locking shaft.

3. The tool changer according to claim 1, wherein the accommodation space accommodates the tool changer locking assembly when the tool changer is in a tool changing state, and the locking cylinder drives the locking shaft to extend into the locking hole of the tool changer locking assembly and fix the locking shaft.

4. The tool changer according to any of claims 1 to 3, characterized in that the locking cylinder is further connected to a guide sleeve, which is located below the extension.

5. The tool changer of claim 4, wherein the proximity switch is secured to an adjustment bolt secured to a bracket secured to the blade.

6. The tool changer according to claim 5, characterized in that a locking and unlocking button and a solenoid valve are arranged on the knife plate, the locking and unlocking button is connected with the solenoid valve, and the solenoid valve is connected with the locking cylinder.

7. The tool changer of claim 6, wherein the securing assembly is coupled to a handle.

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