CN209937356U - Double-knife cutting mechanism - Google Patents

Abstract

The utility model discloses a double knives cutting mechanism for the cutting of rock plate, including being used for the broken glaze spindle motor subassembly that cuts off rock plate surface glazed layer, still including setting up the complete main shaft motor subassembly that cuts off of rock plate that is used for cutting off glazed layer at broken glaze spindle motor subassembly side. The utility model discloses a double knives cutting mechanism during the cutting, breaks the glaze earlier and cuts off again to effectively solve the glaze and collapse the limit problem, have the advantage that the glaze is difficult for collapsing the limit, the tail sword is difficult for collapsing the angle, greatly improved the cutting efficiency of rock plate.

Description

Double-knife cutting mechanism

Technical Field

The utility model relates to a rock plate processing equipment, concretely relates to double knives cutting mechanism for rock plate.

Background

The rock plate is a novel ceramic thin plate which is made by burning natural stone and inorganic clay at 1200 ℃ by a special process and adopting the most advanced vacuum extrusion forming equipment and a full-automatic closed computer temperature control roller kiln. The rock plate has the ultra-high hardness of Mohs 6-7, and when a common cutting machine is used for cutting, the efficiency is low, the edge and the corner are easy to break, and secondary edge grinding is required.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a cutting efficiency is high, the glaze is difficult for collapsing the limit, the tail sword is difficult for collapsing the double knives cutting mechanism at angle for the high-efficient cutting of rock plate.

In order to achieve the above purpose, the technical scheme of the utility model is that:

the utility model provides a double knives cutting mechanism for the cutting of rock plate, is including being used for the broken glaze spindle motor subassembly that cuts apart rock plate surface glaze layer, still including setting up the complete cutting off spindle motor subassembly that cuts open of rock plate that is used for cutting apart glaze layer at broken glaze spindle motor subassembly side.

As an improvement of the utility model, the rock cutting device further comprises a pressing wheel mechanism used for pressing the rock plate during cutting.

Further, the pinch roller mechanism including install connection curb plate, pinch roller group on the double dynamical cutting mechanism of double knives and install the change gear board on connecting the curb plate, pinch roller group includes two rows of pinch rollers, one row rotates and installs on connecting the curb plate, another row rotates and installs on the change gear board, the direction of rolling of pinch roller is the same with the double dynamical cutting mechanism of double knives's blade rotation direction, and this blade lower extreme can follow and pass between two rows of pinch rollers.

As an improvement of the utility model, still including being used for adjusting the front and back adjusting part who cuts off the front and back position of spindle motor subassembly and being used for adjusting the upper and lower adjusting part of broken glaze spindle motor subassembly upper and lower position.

Furthermore, the double-cutter double-power cutting mechanism further comprises a cutter disc water cover used for protecting and cooling blades of the cutting-off spindle motor component and the glaze-breaking spindle motor component.

Compared with the prior art, the utility model has the advantages of it is following:

the utility model discloses a double knives cutting mechanism breaks the glaze earlier and cuts off again, has the glaze and is difficult for collapsing the advantage of limit, the difficult angle that collapses of tail sword, has greatly improved the cutting efficiency of rock plate.

Drawings

Fig. 1 is a schematic structural diagram of a double-blade cutting mechanism of the present invention;

fig. 2 is a schematic structural diagram of a double-blade cutting mechanism of the present invention, in which a pressing wheel mechanism is removed;

FIG. 3 is a schematic structural view of the pinch roller mechanism of the present invention;

description of reference numerals: 601-rotating the support; 602-switching off the spindle motor assembly; 603-breaking glaze surface spindle motor components; 604-a front-to-back adjustment assembly; 605-up-down adjustment assembly; 606-dish water cover; 701-connecting side plates; 702-a press wheel group; 703-hanging wheel plate.

Detailed Description

In order to make the above objects, features and advantages of the present invention more comprehensible, the present invention is described in detail with reference to the accompanying drawings and the detailed description.

As shown in fig. 1 and 2, the utility model discloses a double knives cutting mechanism installs the locomotive position at the cutting machine for the high-efficient cutting of rock plate, the innovation point is just broken the glaze earlier and is cut off again, thereby effectively solve the glaze and collapse the limit problem, mainly include runing rest 601, set up the main shaft motor subassembly 602 that cuts off in runing rest 601, set up broken glaze main shaft motor subassembly 603 other at runing rest 601, set up pinch roller mechanism 7 before runing rest 601. The rotating bracket 601 is installed at the bottom of a lifting box of the cutting machine and is connected with a rotating shaft of a servo motor, so that three-way movement is performed while rotation around a Z axis is realized. The cutting spindle motor assembly 602 comprises a servo motor and a cutting blade which are matched, the glaze breaking spindle motor assembly 603 comprises a servo motor and a glaze breaking blade which are matched, the glaze breaking blade and the cutting blade are located on the same plane, during cutting, the glaze breaking spindle motor assembly 603 firstly cuts a glaze layer on the surface of a rock plate to be cut, and the cutting spindle motor assembly 602 cuts the rock plate completely. It should be noted that the specific structures of the cutting spindle motor assembly 602 and the glaze breaking spindle motor assembly 603 are the prior art, and the difference lies in the selection of the blade, and detailed descriptions thereof are omitted here. Of course, the glaze breaking blade and the cutting blade can be driven by only one servo motor, and the glaze breaking blade and the cutting blade can be realized by changing the meshing position of a motor rotating shaft and a blade base or other existing modes.

In order to realize the position adjustment of the glaze breaking blade and the cutting blade, the double-blade double-power cutting mechanism 6 further comprises a front-back adjusting assembly 604 for adjusting the front-back position of the cutting spindle motor assembly 602, an up-down adjusting assembly 605 for adjusting the up-down position of the glaze breaking spindle motor assembly 603, and the front-back adjusting assembly 604 and the up-down adjusting assembly 605 can realize the position adjustment through a conventional threaded screw or guide rail structure, and the specific structure thereof is not described herein again.

In addition, in order to protect and cool the blades of the cutting spindle motor assembly 602 and the glaze breaking spindle motor assembly 603, a cutter disc water cover 606 is further arranged at the positions of the blades of the two, the cutter disc water cover 606 is a shell with an open front side surface and an open bottom surface, the front end of the rotating bracket 601 is installed, and the rear side surface is provided with a through hole for the motor rotating shaft to pass through.

As shown in fig. 3, when the pinch roller mechanism 7 is used for the double-blade double-power cutting mechanism 6 to cut, the rock plate to be cut is applied with appropriate pressure, so as to prevent the tail knife from breaking the angle, and the pinch roller mechanism comprises a connecting side plate 701, a pinch roller group 702 and a hanging wheel plate 703. The connecting side plate 701 is fixed on the cutter dish water cover 606 in front of the rotating bracket 601, and two ends of the hanging wheel plate 703 are respectively installed at the lower part of the connecting side plate 701 at intervals through a fixed shaft. The pinch roller group 702 is positioned between the connecting side plate 701 and the hanging wheel plate 703 and comprises two rows of pinch rollers which are distributed at intervals, the pinch rollers positioned at two ends are rotatably arranged on a fixed shaft, the pinch roller in the middle is rotatably arranged on the connecting side plate 701, the other row is rotatably arranged on the hanging wheel plate 703, and a gap for a glaze breaking blade and a cutting blade to extend into is formed between the two rows of pinch rollers. During cutting, the pressing wheel group 702 can roll along the same direction as the moving direction of the double-cutter double-power cutting mechanism 6, and the aim of preventing the tail cutter from breaking the angle is fulfilled by pressing the rock plate at the cutting position.

During cutting, the glaze-breaking spindle motor assembly 603 firstly cuts off the glaze layer on the surface of the rock plate to be cut, and then the spindle motor assembly 602 is cut off to completely cut off the rock plate.

The pressing wheel mechanism 7 synchronously compresses the cutting position of the rock plate when the double-cutter double-power cutting mechanism 6 cuts, so that the rock plate is prevented from loosening, the efficient cutting of the rock plate is realized, the edge is not broken, and the cutting processing is completed at one time.

The above detailed description is specific to possible embodiments of the present invention, and the embodiments are not intended to limit the scope of the present invention, and all equivalent implementations or modifications that do not depart from the scope of the present invention should be included within the scope of the present invention.

Claims (5)

1. A double knives cutting mechanism for the cutting of rock plates which characterized in that: the cutting device comprises a broken glaze spindle motor component (603) for cutting off a glaze layer on the surface of a rock plate, and a cutting spindle motor component (602) which is arranged beside the broken glaze spindle motor component (603) and is used for completely cutting off the rock plate with the cut glaze layer.

2. A dual blade cutting mechanism as claimed in claim 1, wherein: and a pressing wheel mechanism (7) used for pressing the rock plate during cutting.

3. A dual blade cutting mechanism as claimed in claim 2, wherein: the pinch roller mechanism (7) comprises a connecting side plate (701) arranged on a rotating support (601), a pinch roller set (702) and a pinch roller plate (703) arranged on the connecting side plate (701), wherein the pinch roller set (702) comprises two rows of pinch rollers, one row of pinch rollers are rotatably arranged on the connecting side plate (701), the other row of pinch rollers are rotatably arranged on the pinch roller plate (703), the rolling direction of the pinch rollers is the same as the rotating direction of a blade of the double-blade double-power cutting mechanism (6), and the lower end of the blade can penetrate through the space between the two rows of pinch rollers.

4. A double-bladed cutting mechanism according to any of claims 1-3, characterized in that: the device also comprises a front and rear adjusting component (604) for adjusting the front and rear positions of the cutting spindle motor component (602) and an up and down adjusting component (605) for adjusting the up and down positions of the glaze breaking spindle motor component (603).

5. The dual blade cutting mechanism of claim 4, wherein: and the cutter disc water cover (606) is used for protecting and cooling blades of the cutting-off spindle motor component (602) and the glaze-breaking spindle motor component (603).

Images