CN208468508U - A kind of dise knife die-cutting machine station power mechanism - Google Patents

Abstract

The utility model discloses a kind of dise knife die-cutting machine station power mechanisms.The mechanism includes one piece of horizontally disposed bottom end fixed plate, is equipped with the mounting rack that can be slided in the horizontal direction in the fixed plate of bottom end, the inside of mounting rack is equipped with the main shaft frame that can be slided in the vertical direction；One spindle servo electric machine is mounted on main shaft frame, and is connected by a Pneumatic rotary collet with a line shaft；One Y-axis servo motor is mounted on the side of mounting rack and is connected with main shaft frame；Line shaft and a driven roll shaft are sequentially connected.Dise knife die-cutting machine station power mechanism in the utility model can be applied not only to install a plurality of types of dise knife molds, additionally it is possible to carry out mobile adjusting in tri- directions X, Y, Z, and support to cut, in cut, the die cutting operations such as incision and side trimming patch.In addition, having the effect of quick-clamping and adjust automatically school position, also to facilitate the cross cutting processing work for accurately and efficiently carrying out electronic product.

Description

Station power mechanism of circular knife die-cutting machine

Technical Field

The utility model relates to a processing equipment field, in particular to circular knife cross cutting machine station power unit.

Background

With the development of the electronic industry, electronic products are more and more precise, the volume of the electronic products is smaller and smaller, and the processing requirements of the electronic products are increasingly increased. In order to meet the processing requirements of electronic products, various related processing devices, such as die cutting machines, need to be upgraded continuously, and the precision and efficiency thereof also need to be increased.

With regard to an existing die cutting machine, for example, a circular die cutting machine, when the circular die cutting machine is used for machining, a station structure is continuously changed along with the change of the precision of a die cutting piece, and if a product or a die cannot be placed in time to be matched with the station, the machining precision and the machining efficiency of the product can be influenced. However, the station of a single circular cutting machine is often fixed and not adjustable, and only a single type and function of circular cutting die can be installed, so that an operator must constantly adjust the position of the material and the die during the use process to maintain the accuracy of the arrangement of the material and the die so as to ensure that the processed size and quality of the product meet the requirements. This adjustment process is not only consuming time longer, and the operation is also inconvenient, needs to consume a large amount of manpower and materials to need rely on operating personnel's proficiency, size precision often is lower, and the machining effect is difficult to obtain effectively guaranteeing.

SUMMERY OF THE UTILITY MODEL

In order to solve the problem, the utility model provides a circular knife cross cutting machine station power unit.

According to one aspect of the utility model, a station power mechanism of a circular knife die-cutting machine is provided, which comprises a horizontally arranged bottom fixing plate, a main shaft servo motor, a Y-axis servo motor, a Z-axis servo motor and a horizontal power shaft; wherein,

one end of the bottom end fixing plate is fixedly provided with two vertical station wallboards, the other end of the bottom end fixing plate is provided with an installation frame capable of sliding in the horizontal direction, and a main shaft frame capable of sliding in the vertical direction is installed inside the installation frame;

the main shaft servo motor is arranged on the main shaft frame and is connected with one end of a pneumatic rotary chuck, and the other end of the pneumatic rotary chuck is connected with the power shaft;

the Y-axis servo motor is arranged on the side surface of the mounting frame and is connected with the mounting frame through a horizontal Y-axis lead screw;

the Z-axis servo motor is arranged at the top of the mounting frame and is connected with the main shaft frame through a vertical Z-axis lead screw;

the power shaft is in transmission connection with a driven roller shaft and is parallel to the driven roller shaft, and the two ends of the power shaft and the two ends of the driven roller shaft are respectively arranged on the two station wallboards.

The utility model provides a circular knife cross cutting machine station power unit not only can be applicable to the circular knife mould of installation polytype, can also remove the regulation in X, Y, Z three directions to support to surely, in cut, cut down and the limit is cut die cutting work such as subsides. In addition, the die-cutting machine has the effects of quick clamping and automatic position adjustment, so that the die-cutting machining work of electronic products can be conveniently, accurately and efficiently carried out.

In some embodiments, a wall plate reinforcing rib is arranged on each of the front side and the rear side between the two station wall plates. From this, can couple together two station wallboards in the front and back both sides, strengthen the atress of station wallboard.

In some embodiments, the spindle servo motor is coupled to a spindle coupling via a spindle reducer, which is coupled to the pneumatic rotating chuck. Therefore, the spindle servo motor can be connected with the pneumatic rotary chuck to control the pneumatic rotary chuck to rotate and clamp through the spindle servo motor.

In some embodiments, the pneumatic rotary chuck is coupled to the power shaft by a power shaft coupling, and the power shaft is geared to the follower roller shaft. From this, can set up pneumatic rotatory chuck and power shaft and driven roller shaft interconnect to the rotatory control power shaft and the driven roller shaft through pneumatic rotatory chuck carry out rotary motion, and then realize the effect that the motion through driven roller axle drives the material and carries out the motion.

In some embodiments, the Y-axis servo motor is connected to a Y-axis coupler through a Y-axis reducer, and the Y-axis coupler is connected to the Y-axis lead screw; wherein, Y axle feed screw installs on a Y axle installation piece, and Y axle installation piece is connected with the mounting bracket. From this, set up being connected between Y axle servo motor and the mounting bracket to make Y axle servo motor can control the mounting bracket and carry out horizontal slip on the bottom mounting plate.

In some embodiments, the Z-axis servo motor is coupled to the Z-axis lead screw via a Z-axis reducer mounted on a Z-axis mounting block coupled to the mounting bracket. From this, be connected between Y axle servo motor and the mounting bracket to make Y axle servo motor can control the main spindle frame and carry out vertical slip on the mounting bracket.

In some embodiments, two horizontal Y-axis guide rails are laid on the bottom end fixing plate, wherein a plurality of Y-axis sliders are slidably mounted on the Y-axis guide rails, and the mounting rack is mounted on the Y-axis sliders. From this, the mounting bracket can be through Y axle slider and Y axle slider slidable mounting on the bottom mounting plate to carry out the horizontal slip under Y axle servo motor's effect.

In some embodiments, the mounting bracket comprises a horizontal Y-axis moving plate at the bottom, a horizontal Z-axis end cover plate at the top, and two vertical Z-axis end support plates at the front and rear sides; the Y-axis moving plate is mounted on the Y-axis sliding blocks, the Y-axis servo motor is mounted on the Y-axis moving plate, the Z-axis servo motor is mounted on the Z-axis end cover plate, two vertical Z-axis guide rails are paved on the Z-axis end supporting plate, and a plurality of Z-axis sliding blocks are mounted on the Z-axis guide rails in a sliding mode. From this, set up the concrete structure of mounting bracket, not only can be used for installing Y axle servo motor and Z axle servo motor, can also be used for slidable mounting main shaft frame.

In some embodiments, the spindle frame comprises a vertical spindle motor mounting plate and a vertical spindle front end connection plate on the left and right sides, two vertical spindle support plates on the front and rear sides, and a horizontal spindle cover plate on the top; the main shaft servo motor is arranged on a main shaft motor mounting plate, the main shaft coupler is arranged on a main shaft front end connecting plate, the main shaft supporting plate is arranged on a Z-axis sliding block, and a Z-axis lead screw is connected with a main shaft cover plate. From this, set up the concrete structure of main shaft frame, not only can be used for installing main shaft servo motor, still make main shaft frame can be through Z axle slider and Z axle slider slidable mounting on the mounting bracket to carry out vertical slip under Z axle servo motor's effect.

In some embodiments, a horizontal sensor bracket extends from each of the front and rear sides of the spindle front end connecting plate, and a spindle sensor is mounted on each of the opposite sides of the two sensor brackets. Therefore, the main shaft sensor can be arranged to scan and detect the power shaft, and the installation position of the power shaft can be adjusted and calibrated in time.

Drawings

Fig. 1 is a schematic view of a station power mechanism of a circular knife die-cutting machine according to an embodiment of the present invention;

fig. 2 is an exploded view of a station power mechanism of the circular knife die cutting machine shown in fig. 1.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings.

Fig. 1 schematically shows a circular knife die cutting machine station power mechanism according to an embodiment of the present invention, and fig. 2 shows a disassembled structure of the circular knife die cutting machine station power mechanism in fig. 1. As shown in fig. 1-2, the power mechanism includes a bottom end fixing plate 1 horizontally disposed, two vertical station wall plates 11 oppositely arranged left and right are fixedly disposed at one end above the bottom end fixing plate 1, and the two station wall plates 11 are both provided with upward openings. And both sides all are equipped with a wallboard strengthening rib 12 around between two station wallboards 11, and every wallboard strengthening rib 12 all is connected with two station wallboards 11, and its bearing capacity that can increase station wallboard 11.

Two horizontal left-right Y-axis guide rails 13 are laid at the other end above the bottom end fixing plate 1, wherein a plurality of Y-axis sliding blocks 14 are slidably mounted on the Y-axis guide rails 13, and preferably, two Y-axis sliding blocks 14 are slidably mounted on each Y-axis guide rail 13; the same mount frame 6 is mounted on all the Y-axis sliders 14, so that the mount frame 6 can slide on the bottom end fixing plate 1 along the Y-axis guide rails 13. And a spindle bracket 7 is installed inside the mounting bracket 6, wherein the spindle bracket 7 can slide in the vertical direction along the side wall of the mounting bracket 6.

A main shaft servo motor 2 is mounted on the main shaft frame 7, wherein the main shaft servo motor 2 is connected with a main shaft coupling 23 through a main shaft reducer 22, the main shaft coupling 23 is connected with one end of a pneumatic rotary chuck 21, and the other end of the pneumatic rotary chuck 21 is connected with a horizontal power shaft 5 through a power shaft coupling 52. Two ends of the power shaft 5 are respectively arranged on the two station wallboards 11. And a driven roller shaft 51 parallel to the power shaft 5 is further installed between the two station wall boards 11, wherein the power shaft 5 is in transmission connection with the driven roller shaft 51 through a gear.

A Y-axis servo motor 3 is installed on the side of the mounting frame 6 opposite to the direction of the station wall plate 11, the Y-axis servo motor 3 is connected with a Y-axis coupler 33 through a Y-axis reducer 32, the Y-axis coupler 33 is connected with a horizontal Y-axis lead screw 31, the Y-axis lead screw 31 is installed on a Y-axis installation block 34, and the Y-axis coupler 33 and the Y-axis installation block 34 are both connected with the mounting frame 6, so that the Y-axis servo motor 3 and related components thereof are connected with the mounting frame 6, and when the Y-axis servo motor 3 operates, the mounting frame 6 can be driven to slide on the bottom end fixing plate 1.

A Z-axis servo motor 4 is installed on the top of the mounting frame 6, the Z-axis servo motor 4 is connected with a vertical Z-axis lead screw 41 through a Z-axis reducer 42, wherein the Z-axis reducer 42 is installed on a Z-axis mounting block 43, and the Z-axis mounting block 43 is connected with the mounting frame 6. And the Z-axis lead screw 41 is connected to the main spindle frame 7. It can be seen that the Z-axis servo motor 4 and its related components are connected to the mounting frame 6 and the spindle frame 7, so that when the Z-axis servo motor 4 operates, the spindle frame 7 can be driven to slide on the side wall of the mounting frame 6.

The bottom of the mounting rack 6 is a horizontal Y-axis moving plate 61, the top is a horizontal Z-axis end cover plate 62, and the front side and the rear side are two vertical Z-axis end supporting plates 63. Wherein, the Y-axis moving plate 61 is installed on the Y-axis slider 14, so that the installation frame 6 can slide on the bottom end fixing plate 1 along the Y-axis guide rail 13; the Y-axis servo motor 3 is mounted on the Y-axis moving plate 61 through a Y-axis mounting block 34 and the like so that it can control the sliding of the mounting frame 6; the Z-axis servomotor 4 is mounted on the Z-axis end cover 62 via the Z-axis mounting block 43 and other relevant components. Preferably, the upper portions of the left and right sides between the two Z-axis end face cover plates 62 are provided with a Z-axis cover plate reinforcing plate 66, the lower portions are provided with a Z-axis lower reinforcing plate 67, each Z-axis cover plate reinforcing plate 66 and each Z-axis lower reinforcing plate 67 are connected with the two Z-axis end support plates 63, and the two can increase the bearing force of the Z-axis end face cover plates 62 and the Y-axis moving plate 61 respectively.

In addition, two vertical Z-axis guide rails 64 are laid on the two Z-axis end support plates 63, and a plurality of Z-axis sliders 65 are slidably mounted on the Z-axis guide rails 64, preferably two Z-axis sliders 65 are slidably mounted on each Z-axis guide rail 64.

The spindle frame 7 has a vertical spindle motor mounting plate 71 and a vertical spindle front end connecting plate 72 on the left and right sides, two vertical spindle support plates 73 on the front and rear sides, and a vertical spindle cover plate 74 on the top. The spindle servo motor 2 is arranged on a spindle motor mounting plate 71, and the spindle coupler 23 is arranged on a spindle front end connecting plate 72; the two main shaft supporting plates 73 are respectively arranged on the Z-axis sliding blocks 65 on the two Z-axis end supporting plates 63, so that the main shaft frame 7 can slide on the Z-axis end supporting plates 63 along the Z-axis guide rails 64; and the Z-axis lead screw 41 is connected with the main spindle cover 74 so that the Z-axis servomotor 4 can control the sliding of the main spindle frame 7.

And a horizontal sensor support 81 extends from the front side and the rear side of the spindle front end connecting plate 72 to the direction of the station wall plate 11, wherein a spindle sensor 8 is mounted on two opposite surfaces of the two sensor supports 81, the length of the sensor support 81 is properly set, and under normal conditions, the two spindle sensors 8 are respectively located on the front side and the rear side of the connection position of the power shaft 5 and the power shaft coupler 52, but the power shaft 5 cannot be detected.

When the circular knife die-cutting machine station power mechanism is used, firstly, components such as the power shaft 5 and the driven roller shaft 51 are installed on the mechanism, specifically, two ends of the power shaft 5 and two ends of the driven roller shaft 51 are conveniently placed and clamped from openings on two station wall plates 11, meanwhile, gears of the power shaft 5 and the driven roller shaft 51 are clamped, and the power shaft 5 is connected with the pneumatic rotary chuck 21 through the power shaft coupler 52; then, starting the two main shaft sensors 8 for scanning detection, if the main shaft sensors 8 do not sense the power shaft 5, the installation is normal, and if the main shaft sensors 8 sense the side line of the power shaft 5, the servo motors can be automatically controlled to operate, and the positions of other parts are adjusted, so that the power shaft 5 is arranged at a proper position; after the adjustment is completed, the appropriate circular knife die and related parts thereof are connected with the driven roller shaft 51, so that the circular knife die can be controlled to move in X, Y, Z three directions by operating the operation of each servo motor, and die cutting work such as up cutting, middle cutting, down cutting, edge cutting and pasting can be performed. Wherein the driven roller shaft 51 is provided to be able to be used for mounting various types of circular knife molds.

When the circular knife mold needs to be adjusted in the X direction, the operation enables the spindle servo motor 2 to operate, and the pneumatic rotary chuck 21 is controlled to rotate sequentially through the spindle speed reducer 22, the spindle coupler 23 and the like, so that the pneumatic rotary chuck 21 clamps the power shaft 5 through the power shaft coupler 52 and drives the power shaft 5 to rotate, the driven roller shaft 51 rotates through transmission, and the circular knife mold is driven to move in the X direction.

When the circular knife mold needs to be adjusted in the Y direction, the Y-axis servo motor 3 is operated to rotate, the Y-axis lead screw 31 is controlled to rotate through the Y-axis speed reducer 32, the Y-axis coupler 33 and the like, so that the Y-axis mounting block 34 connected with the Y-axis lead screw horizontally moves, the mounting frame 6 is driven to horizontally slide along the bottom fixing plate 1, and the circular knife mold is driven to move in the Y direction.

When the circular knife mold needs to be adjusted in the Z direction, the Z-axis servo motor 4 is operated to rotate, and the Z-axis lead screw 41 is controlled to rotate through the Z-axis reducer 42 and the like, so that the main shaft cover plate 74 connected with the main shaft cover plate vertically moves, the main shaft frame 7 is driven to vertically slide along the Z-axis end support plate 63, and the circular knife mold is driven to move in the Z direction.

What has been described above are only some embodiments of the invention. For those skilled in the art, without departing from the inventive concept, several modifications and improvements can be made, which are within the scope of the invention.

Claims (10)

1. The utility model provides a circular knife cross cutting machine station power unit which characterized in that: the device comprises a bottom fixing plate (1), a main shaft servo motor (2), a Y-axis servo motor (3), a Z-axis servo motor (4) and a horizontal power shaft (5), wherein the bottom fixing plate is horizontally arranged; wherein,

one end of the bottom end fixing plate (1) is fixedly provided with two vertical station wall plates (11), the other end of the bottom end fixing plate is provided with a mounting rack (6) capable of sliding in the horizontal direction, and a main shaft bracket (7) capable of sliding in the vertical direction is mounted inside the mounting rack (6);

the main shaft servo motor (2) is arranged on the main shaft frame (7) and is connected with one end of a pneumatic rotary chuck (21), and the other end of the pneumatic rotary chuck (21) is connected with the power shaft (5);

the Y-axis servo motor (3) is arranged on the side surface of the mounting frame (6) and is connected with the mounting frame (6) through a horizontal Y-axis lead screw (31);

the Z-axis servo motor (4) is arranged at the top of the mounting frame (6) and is connected with the main shaft frame (7) through a vertical Z-axis lead screw (41);

the power shaft (5) is in transmission connection with a driven roll shaft (51) and is parallel to the driven roll shaft, and the two ends of the power shaft (5) and the two ends of the driven roll shaft (51) are respectively arranged on the two station wall plates (11).

2. The station power mechanism of the circular cutter die-cutting machine according to claim 1, characterized in that: two wallboard reinforcing ribs (12) are arranged on the front side and the rear side between the station wallboards (11).

3. The station power mechanism of the circular cutter die-cutting machine according to claim 1, characterized in that: the spindle servo motor (2) is connected with a spindle coupler (23) through a spindle reducer (22), and the spindle coupler (23) is connected with the pneumatic rotary chuck (21).

4. The station power mechanism of the circular cutter die-cutting machine according to claim 1, characterized in that: the pneumatic rotary chuck (21) is connected with the power shaft (5) through a power shaft coupler (52), and the power shaft (5) is connected with the driven roll shaft (51) through gear transmission.

5. The station power mechanism of the circular cutter die-cutting machine according to claim 1, characterized in that: the Y-axis servo motor (3) is connected with a Y-axis coupler (33) through a Y-axis speed reducer (32), and the Y-axis coupler (33) is connected with the Y-axis lead screw (31); the Y-axis lead screw (31) is mounted on a Y-axis mounting block (34), and the Y-axis mounting block (34) is connected with the mounting frame (6).

6. The station power mechanism of the circular cutter die-cutting machine according to claim 1, characterized in that: z axle servo motor (4) through a Z axle speed reducer (42) with Z axle lead screw (41) are connected, wherein, Z axle speed reducer (42) are installed on a Z axle installation piece (43), Z axle installation piece (43) with mounting bracket (6) are connected.

7. The station power mechanism of the circular cutter die-cutting machine according to claim 3, characterized in that: bottom end fixed plate (1) upper berth is equipped with two horizontally Y axle guide rails (13), wherein slidable mounting has a plurality of Y axle sliders (14) on Y axle guide rail (13), mounting bracket (6) are installed on Y axle slider (14).

8. The station power mechanism of the circular cutter die-cutting machine according to claim 7, characterized in that: the mounting rack (6) comprises a horizontal Y-axis moving plate (61) positioned at the bottom, a horizontal Z-axis end surface cover plate (62) positioned at the top and two vertical Z-axis end supporting plates (63) positioned at the front side and the rear side; wherein, Y axle movable plate (61) is installed on Y axle slider (14), Y axle servo motor (3) are installed on Y axle movable plate (61), and Z axle servo motor (4) are installed on Z axle head face apron (62), and Z axle head backup pad (63) upper berth is equipped with two vertical Z axle guide rails (64), slidable mounting has a plurality of Z axle sliders (65) on Z axle guide rail (64).

9. The station power mechanism of the circular cutter die-cutting machine according to claim 8, characterized in that: the spindle frame (7) comprises a vertical spindle motor mounting plate (71) and a vertical spindle front end connecting plate (72) which are positioned at the left side and the right side, two vertical spindle supporting plates (73) which are positioned at the front side and the rear side, and a horizontal spindle cover plate (74) which is positioned at the top; the spindle servo motor (2) is mounted on the spindle motor mounting plate (71), the spindle coupler (23) is mounted on the spindle front end connecting plate (72), the spindle supporting plate (73) is mounted on the Z-axis sliding block (65), and the Z-axis lead screw (41) is connected with the spindle cover plate (74).

10. The station power mechanism of the circular cutter die-cutting machine according to claim 9, characterized in that: a horizontal inductor support (81) extends out of the front side and the rear side of the spindle front end connecting plate (72), and two spindle inductors (8) are mounted on two opposite surfaces of the inductor supports (81).