CN222060824U - A spindle structure of a diamond wire slicer - Google Patents

Abstract

The utility model discloses a diamond wire slicing machine spindle structure, which belongs to the technical field of cutting equipment and comprises a supporting plate, wherein a first side plate and a second side plate are fixed on the supporting plate, a spindle mechanism is arranged between the first side plate and the second side plate, two first movable shafts are movably connected to the side surface of the first side plate, a turntable is fixed at one end of each of the two first movable shafts, and a driving rod is movably connected to the side surface edge of each of the two turntables through the first shafts; the support plate is also provided with a telescopic cylinder, the telescopic rod of the telescopic cylinder is connected with a moving rod, both ends of the moving rod are respectively fixed with moving blocks, and the two moving blocks are respectively and movably connected with the other ends of the two driving rods through second rotating shafts; by using the structure, the main shaft mechanism can be driven to rotate through the telescopic cylinder, so that the enterprise cost is not increased, the design is reasonable, and the popularization is convenient.

Description

Main shaft structure of diamond wire slicing machine

Technical Field

The utility model relates to the technical field of cutting equipment, in particular to a main shaft structure of a diamond wire slicing machine.

Background

The multi-wire cutting technology is an advanced silicon wafer processing technology in the world at present, the principle of the multi-wire cutting technology is that a steel wire moving at high speed drives a cutting blade material attached to the steel wire to rub hard and brittle materials such as a semiconductor and the like, so that the cutting purpose is achieved, a slicing machine is a machine for cutting thin and uniform tissue slices, and a diamond wire slicing machine is one of various types of the diamond wire slicing machine.

At present, the diamond wire slicing machine is driven by a single motor to drive a single spindle, so that the cost of enterprises can be increased, and the actual use of users is inconvenient, so that the design of a spindle structure of the diamond wire slicing machine is needed to solve the problems.

Disclosure of utility model

The utility model aims to provide a main shaft structure of a diamond wire slicing machine, which aims to solve the problems that the cost of enterprises is increased and the actual use of users is inconvenient because a single motor drives a single main shaft on the diamond wire slicing machine.

In order to solve the technical problems, the utility model provides a diamond wire slicing machine spindle structure, which comprises a supporting plate, wherein a first side plate and a second side plate are fixed on the supporting plate, a spindle mechanism is arranged between the first side plate and the second side plate, two first movable shafts are movably connected to the side surface of the first side plate, a turntable is fixed at one end of each of the two first movable shafts, and the edges of the side surfaces of the two turntables are movably connected with a driving rod through the first rotary shafts;

Still install flexible cylinder in the backup pad, its telescopic link is connected with the movable rod, the movable rod both ends all are fixed with the movable block, two the movable block respectively with two the actuating lever other end is all through second pivot swing joint.

Optionally, the spindle mechanism includes two spindle bodies and two first bearings, the two first bearings are connected with a rotating rod, the other end of the rotating rod is provided with a first groove and a second movable shaft, one ends of the first movable shaft and the second movable shaft are provided with a connecting groove, the other end of the second movable shaft is positioned in the first groove and provided with a thread groove, and connecting rods positioned in the connecting grooves are fixed at two ends of the spindle body; a second bearing is fixed in the first groove, a screw is connected to the second bearing, a first bevel gear is fixed on the screw, and the other end of the screw is positioned in the thread groove and is in threaded connection with the thread groove;

the two outer surfaces of the rotating rods are respectively provided with a connecting block, connecting rods are respectively fixed on the connecting blocks, the connecting rods are movably connected with the rotating rods, the other ends of the connecting rods are positioned in the rotating rods, and second bevel gears meshed with the first bevel gears are fixed on the connecting rods.

Optionally, two opposite limiting grooves are formed in the inner wall of the groove, and two limiting blocks which are located in the limiting grooves are fixed on the side face of the other end of the second movable shaft.

Optionally, two guide grooves are formed in the inner wall of the connecting groove, and two guide blocks which are located in the guide grooves are fixed on the connecting rod.

Optionally, a second groove is formed in the supporting plate, a driving motor is mounted on one side wall of the second groove, a third bearing is fixed on the other side wall of the second groove, the output end of the driving motor is connected with a screw rod, the other end of the screw rod is connected with the third bearing, and a screw tube in threaded connection with the screw rod is further fixed at the bottom end of the second side plate.

Optionally, the four corners of the supporting plate are all provided with mounting holes.

The utility model provides a spindle structure of a diamond wire slicing machine, which comprises a supporting plate, wherein a first side plate and a second side plate are fixed on the supporting plate, a spindle mechanism is arranged between the first side plate and the second side plate, two first movable shafts are movably connected to the side surfaces of the first side plate, a turntable is fixed at one end of each of the two first movable shafts, and driving rods are movably connected to the side edges of the two turntable through the first movable shafts; the support plate is also provided with a telescopic cylinder, the telescopic rod of the telescopic cylinder is connected with a moving rod, both ends of the moving rod are respectively fixed with moving blocks, and the two moving blocks are respectively and movably connected with the other ends of the two driving rods through second rotating shafts; by using the structure, the main shaft mechanism can be driven to rotate through the telescopic cylinder, so that the enterprise cost is not increased, the design is reasonable, and the popularization is convenient.

Drawings

Fig. 1 is a schematic diagram of a spindle structure of a diamond wire slicer provided by the utility model;

fig. 2 is a top view of a spindle structure of the diamond wire slicer provided by the utility model;

FIG. 3 is a cross-sectional view A-A of FIG. 2;

Fig. 4 is an enlarged view of B in fig. 3.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

It will be understood that when an element is referred to as being "fixed to" another element, it can be directly on the other element or intervening elements may also be present. When a component is considered to be "connected" to another component, it can be directly connected to the other component or intervening components may also be present. When an element is referred to as being "disposed on" another element, it can be directly on the other element or intervening elements may also be present. The terms "vertical," "horizontal," "left," "right," and the like are used herein for illustrative purposes only.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this utility model belongs. The terminology used herein in the description of the utility model is for the purpose of describing particular embodiments only and is not intended to be limiting of the utility model. The term "and/or" as used herein includes any and all combinations of one or more of the associated listed items.

The utility model provides a diamond wire slicing machine spindle structure, which is shown in figures 1-4, and comprises a support plate 1, wherein a first side plate 2 and a second side plate 3 are fixed on the support plate 1, a spindle mechanism is arranged between the first side plate 2 and the second side plate 3, two first movable shafts 5 are movably connected to the side surface of the first side plate 2, one ends of the two first movable shafts 5 are respectively fixed with a rotary table 6, and the edges of the side surfaces of the two rotary tables 6 are respectively movably connected with a driving rod 9 through a first rotary shaft 7; the support plate 1 is also provided with a telescopic cylinder 8, a telescopic rod of the telescopic cylinder is connected with a movable rod 10, two ends of the movable rod 10 are respectively fixed with movable blocks 11, and the two movable blocks 11 are respectively movably connected with the other ends of the two driving rods 9 through second rotating shafts 12. The spindle structure of the diamond wire slicing machine can be driven to rotate through the telescopic cylinder 8, so that the enterprise cost is not increased, the design is reasonable, and the popularization is convenient.

Specifically, the spindle mechanism comprises two spindle bodies 4 and two first bearings 13, wherein the two first bearings 13 are connected with a rotating rod 14, the other end of the rotating rod 14 is provided with a first groove 16 and a second movable shaft 15, one ends of the first movable shaft 5 and the second movable shaft 15 are provided with a connecting groove 19, the other ends of the second movable shaft 15 are positioned in the first groove 16 and provided with a thread groove 18, and connecting rods 20 positioned in the connecting groove 19 are fixed at two ends of the spindle body 4; a second bearing 17 is fixed in the first groove 16, a screw 21 is connected to the second bearing 17, a first bevel gear 22 is fixed on the screw 21, and the other end of the first bevel gear 22 is positioned in the thread groove 18 and is in threaded connection with the thread groove 18; the connecting blocks 23 are arranged on the outer surfaces of the two rotating rods 14, connecting rods 24 are fixed on the connecting blocks 23, the connecting rods 24 are movably connected with the rotating rods 14, the other ends of the connecting rods are located in the rotating rods 14, second bevel gears 25 meshed with the first bevel gears 22 are fixed on the connecting rods, the two second bevel gears 25 are driven to be meshed with the two first bevel gears 22 respectively through rotation of the two connecting rods 24, so that connecting rods 20 at the two ends of the main shaft body 4 are located in the two connecting grooves 19 respectively, at the moment, the telescopic rods of the telescopic cylinders 8 drive the moving rods 10, the two moving blocks 11 and one ends of the two driving rods 9 to move up and down, and the other ends of the two driving rods 9 drive the rotary table 6 to rotate to enable the rotary table 6 to rotate so as to drive the main shaft body 4 to rotate.

Further, two opposite limiting grooves 26 are formed in the inner wall of the first groove 16, two limiting blocks 27 which are located in the limiting grooves 26 are fixed on the side face of the other end of the second movable shaft 15, and the second movable shaft 15 is limited to avoid being separated from the first groove 16, so that the main shaft body 4 is assembled.

Further, two guide grooves 28 are formed in the inner wall of the connecting groove 19, and two guide blocks 29 which are located in the guide grooves 28 are fixed on the connecting rod 20, so that the connecting rod 20 can conveniently enter the connecting groove 19, and the installation of the main shaft body 4 is realized.

Further, a second groove 30 is formed in the support plate 1, a driving motor 32 is mounted on one side wall of the second groove 30, a third bearing 31 is fixed on the other side wall of the second groove 30, a screw rod 33 is connected to the output end of the driving motor 32, the other end of the screw rod 33 is connected with the third bearing 31, a screw tube 34 in threaded connection with the screw rod 33 is further fixed at the bottom end of the second side plate 3, and the screw tube 34 drives the second side plate 3 to move to assist the installation of the main shaft body 4 by driving the screw rod 33 to rotate through the output end of the driving motor 32.

Further, the four corners of the supporting plate 1 are provided with mounting holes 36, so that the supporting plate 1 is convenient to mount.

The working principle of the utility model is as follows: firstly, two connecting rods 24 are rotated to drive two second bevel gears 25 to be respectively meshed with two first bevel gears 22 for transmission, at the moment, two screw rods 21 are rotated and all drive second movable shafts 15 to move, so that connecting rods 20 at two ends of a main shaft body 4 are respectively located in two connecting grooves 19, installation of the main shaft body 4 is completed, then a telescopic cylinder 8 is started, a telescopic rod drives a moving rod 10 to move up and down, the moving rod 10 drives one ends of two driving rods 9 to move up and down through two moving blocks 11, and finally the other ends of the two driving rods 9 drive a turntable 6 to rotate and the main shaft body 4 to rotate.

The above description is only illustrative of the preferred embodiments of the present utility model and is not intended to limit the scope of the present utility model, and any alterations and modifications made by those skilled in the art based on the above disclosure shall fall within the scope of the appended claims.

Claims (6)

1. A spindle structure of a diamond wire slicer, comprising a support plate (1), characterized in that a first side plate (2) is fixed on the support plate (1) and a second side plate (3) is provided, a spindle mechanism is provided between the first side plate (2) and the second side plate (3), and two first movable shafts (5) are movably connected to the side of the first side plate (2), a rotating disk (6) is fixed to one end of the two first movable shafts (5), and the side edges of the two rotating disks (6) are movably connected to a driving rod (9) through a first rotating shaft (7); A telescopic cylinder (8) is also installed on the support plate (1), and the telescopic rod is connected to a moving rod (10). Moving blocks (11) are fixed at both ends of the moving rod (10). The two moving blocks (11) are respectively movably connected to the other ends of the two driving rods (9) through second rotating shafts (12). 2. The spindle structure of a diamond wire slicer according to claim 1, characterized in that the spindle mechanism comprises two spindle bodies (4) and two first bearings (13), the two first bearings (13) are connected to a rotating rod (14), the other end of the rotating rod (14) is provided with a first groove (16) and a second movable shaft (15), one end of the first movable shaft (5) and the second movable shaft (15) are both provided with a connecting groove (19), and the other end of the second movable shaft (15) is located in the first groove (16) and has a threaded groove (18), and connecting rods (20) located in the connecting groove (19) are fixed at both ends of the spindle body (4); a second bearing (17) is fixed in the first groove (16), a screw rod (21) is connected to the second bearing (17), a first bevel gear (22) is fixed to the screw rod (21), and the other end of the screw rod is located in the threaded groove (18) and is threadedly connected thereto; The outer surfaces of the two rotating rods (14) are each provided with a connecting block (23), and a connecting rod (24) is fixed on each of the connecting blocks (23). The connecting rod (24) is movably connected to the rotating rod (14), and the other end of the connecting rod (24) is located in the rotating rod (14) and is fixed with a second bevel gear (25) meshing with the first bevel gear (22) for transmission. 3. The spindle structure of the diamond wire slicer as described in claim 2 is characterized in that two limiting grooves (26) located opposite to each other are formed on the inner wall of the groove (16), and two limiting blocks (27) located in the limiting grooves (26) are fixed to the side surface of the other end of the second movable shaft (15). 4. The spindle structure of a diamond wire slicer as described in claim 2 is characterized in that two guide grooves (28) are formed on the inner wall of the connecting groove (19), and two guide blocks (29) are fixed on the connecting rod (20) and are both located in the guide grooves (28). 5. The spindle structure of a diamond wire slicer as described in claim 1 is characterized in that a second groove (30) is opened on the support plate (1), a driving motor (32) is installed on one side wall of the second groove (30), and a third bearing (31) is fixed on the other side wall, the output end of the driving motor (32) is connected to a screw rod (33), the other end of the screw rod (33) is connected to the third bearing (31), and a screw tube (34) threadedly connected to the screw rod (33) is also fixed at the bottom end of the second side plate (3). 6. The spindle structure of a diamond wire slicer according to claim 1, characterized in that mounting holes (36) are provided at four corners of the support plate (1).