CN115194893A - Double-head processing equipment - Google Patents

Abstract

The invention relates to the technical field of wood product processing equipment such as wood doors and the like, in particular to double-head processing equipment which comprises a cross beam, a first head device and a second head device; the first machine head device comprises a first mounting substrate, a spindle assembly and a rotary driving assembly for driving the spindle assembly to rotate; the second machine head device comprises a second mounting base plate, a drilling assembly, a milling assembly and a first lifting driving assembly; the two groups of machine head devices are respectively arranged on two opposite surfaces of the cross beam, so that the two groups of machine head components can independently process wood, the occupied space of the two groups of machine head devices is reduced, and the structure is compact; simultaneously, the main shaft assembly both ends all are equipped with the blade holder, and it is rotatory through rotation driving subassembly drive main shaft assembly, switch the position at main shaft assembly both ends to realize the change of blade holder, need not to stop the quick-witted tool changing operation, effectively promote machining efficiency.

Description

Double-head processing equipment

Technical Field

The invention relates to the technical field of wood product processing equipment such as wood doors and the like, in particular to double-head processing equipment.

Background

In the existing wood processing, two independent machine head processing devices are generally configured to improve the efficiency of wood processing; in practical application, however, independent movement and processing spaces for two independent machine head processing devices are required to be reserved, and the occupied space is large; meanwhile, in the existing wood processing, if a tool needs to be changed, the machine head processing equipment needs to be stopped, and then the original milling cutter (drill bit) is disassembled and then the target milling cutter (drill bit) is replaced, so that the steps are complicated, and the processing efficiency is influenced.

Disclosure of Invention

The invention aims to provide double-machine-head processing equipment which is compact in structure and high in processing efficiency.

In order to solve the technical problems, the invention adopts the following technical scheme: the double-machine-head processing equipment comprises a cross beam, a first machine head device and a second machine head device, wherein the first machine head device and the second machine head device are respectively arranged on two sides of the cross beam; the first machine head device comprises a first mounting substrate, a main shaft assembly and a rotary driving assembly, wherein the first mounting substrate is slidably mounted on the cross beam, the main shaft assembly is arranged on the first mounting substrate, the rotary driving assembly is used for driving the main shaft assembly to rotate, tool holders are arranged at two ends of the main shaft assembly, and the output end of the rotary driving assembly is in transmission connection with the main shaft assembly; the second machine head device comprises a second mounting substrate, a drilling assembly, a milling assembly and a first lifting driving assembly, wherein the second mounting substrate is slidably mounted on the cross beam, the drilling assembly is mounted on the second mounting substrate, the milling assembly is arranged on the second mounting substrate, and the first lifting driving assembly is used for driving the second mounting substrate to move up and down;

the drilling assembly comprises a base body arranged on the second mounting base plate, a Z-direction gang drill rotatably arranged on the base body, and an X-direction sidetrack and a Y-direction sidetrack which are detachably arranged on the base body.

Preferably, two groups of sliding driving assemblies which are respectively used for bearing and driving the first machine head device and the second machine head device to move in the X direction are respectively arranged on two sides of the cross beam; the sliding driving assembly comprises a sliding driving piece, a first sliding block and a first sliding rail, the first sliding block is installed on one surface, close to the cross beam, of the first mounting substrate or the second mounting substrate, the first sliding rail is installed on one surface, close to the first mounting substrate or the second mounting substrate, of the cross beam, and the output end of the sliding driving piece is in transmission connection with the first sliding block.

Preferably, the sliding driving assembly further comprises a rack, a transmission gear and a connecting seat; the rack is arranged on the cross beam and extends along the length direction of the cross beam, the transmission gear is arranged at the output end of the sliding driving piece and is meshed with the rack, and two ends of the connecting seat are fixedly connected with the sliding driving piece and the first sliding block respectively.

Preferably, first tool holders are arranged at two ends of the X-direction sidetrack, and the first tool holders at the two ends of the X-direction sidetrack are oppositely arranged along the X direction; and second tool holders are arranged at two ends of the Y-direction sidetrack, and the second tool holders at two ends of the Y-direction sidetrack are oppositely arranged along the Y direction.

Preferably, the first lifting driving assembly comprises a first lifting driving member, a first sliding block and a first sliding rail, wherein the first sliding block and the first sliding rail are in sliding fit; the transmission structure comprises a screw rod connected with the output end of the first lifting driving piece and a threaded seat matched with the screw rod for use, and one surface, close to the base, of the second mounting substrate is arranged on the threaded seat.

Preferably, the milling assembly comprises a milling spindle arranged on the second mounting substrate and a rotary driving member for driving the milling spindle to rotate, third tool seats are arranged at two ends of the milling spindle, and the third tool seats at two ends of the milling spindle are arranged oppositely along the X direction; and the output end of the rotary driving piece is in transmission connection with the milling spindle.

Preferably, the lifting device further comprises a second lifting driving component; the second lifting driving assembly comprises a second lifting seat arranged on the second mounting base plate, a second sliding block arranged on one surface, close to the second mounting base plate, of the second lifting seat, a second sliding rail arranged on one surface, close to the second lifting seat, of the second mounting base plate and matched with the second sliding block, and a second lifting driving piece used for driving the second sliding block to slide back and forth on the second sliding rail, the output end of the second lifting driving piece is fixedly connected with the second lifting seat, and the milling spindle is arranged on the second lifting seat.

Preferably, the first machine head device further comprises a third lifting driving component for driving the spindle component to move up and down back and forth; the third lift drive assembly is including locating third lift driving piece, transmission structure and third lift seat, the third lift driving piece the transmission structure and the third lift seat is all located first mounting substrate, just the both ends of transmission structure respectively with the output of third lift driving piece and the transmission of third lift seat are connected, spindle unit locates the third lift seat.

Preferably, the rotary driving assembly comprises a rotary seat and a rotary driving piece, the rotary seat is arranged on the third lifting seat, and an output end of the rotary driving piece is in transmission connection with the rotary seat; the spindle assembly is arranged on the rotating seat.

Preferably, the spindle assembly comprises a motor with double output shafts, and the tool holders at the two ends of the spindle assembly are in one-to-one transmission connection with the two output ends of the motor with the double output shafts respectively

The invention has the beneficial effects that: in practical application, the two groups of first machine head devices are respectively arranged on two opposite surfaces of the cross beam, so that the two groups of machine head components can independently process wood, the occupied space of the two groups of first machine head devices is reduced, and the structure is compact; simultaneously, the main shaft assembly both ends all are equipped with the blade holder, and it is rotatory through rotation driving subassembly drive main shaft assembly, switch the position at main shaft assembly both ends to realize the change of blade holder, need not to stop the quick-witted tool changing operation, effectively promote machining efficiency.

Drawings

Fig. 1 is a schematic perspective view of a first viewing angle of the dual-head processing apparatus of the present invention.

Fig. 2 is a schematic perspective view of a second view angle of the dual-head processing apparatus according to the present invention.

Fig. 3 is an exploded perspective view of the first head device of the dual-head processing apparatus according to the present invention.

Fig. 4 is a schematic perspective view of a second head device in the dual-head processing apparatus according to the present invention.

Fig. 5 is a schematic perspective view of another angle of view of the second head device in the dual-head processing apparatus according to the present invention.

Fig. 6 is an exploded perspective view of a second head assembly of the dual-head processing apparatus of the present invention.

Detailed Description

The present invention will be further described with reference to the following examples for facilitating understanding of those skilled in the art, and the description of the embodiments is not intended to limit the present invention.

As shown in fig. 1 to 6, the double-head processing equipment is characterized in that: the machine head device comprises a cross beam 1, and a first machine head device and a second machine head device which are respectively arranged on two sides of the cross beam 1; the first machine head device comprises a first mounting substrate 11 which is slidably mounted on the cross beam 1, a spindle assembly which is arranged on the first mounting substrate 11, and a rotary driving assembly 13 which is used for driving the spindle assembly to rotate, wherein tool holders 14 are arranged at two ends of the spindle assembly, and the output end of the rotary driving assembly 13 is in transmission connection with the spindle assembly; the second machine head device comprises a second mounting base plate 12 which is slidably mounted on the cross beam 1, a drilling assembly 20 which is mounted on the second mounting base plate 12, a milling assembly 30 which is arranged on the second mounting base plate 12, and a first lifting driving assembly 40 which is used for driving the second mounting base plate 12 to move up and down; the drilling assembly 20 includes a base 210 disposed on the second mounting substrate 12, a Z-directional gang drill 220 rotatably mounted on the base 210, and an X-directional sidetrack 230 and a Y-directional sidetrack 240 detachably mounted on the base 210.

The two groups of machine head assemblies can independently process wood, meanwhile, the occupied space of the two groups of first machine head devices is reduced, and the structure is compact; meanwhile, the tool apron 140 is arranged at the two ends of the spindle assembly, the spindle assembly is driven to rotate through the rotary driving assembly 130, and the positions of the two ends of the spindle assembly are switched, so that the tool apron 140 is replaced, the tool changing operation is not required to be stopped, and the machining efficiency is effectively improved.

In this embodiment, two sets of sliding driving assemblies 15 for respectively carrying and driving the first head device and the second head device to move in the X direction are respectively installed on two sides of the beam 1; the sliding driving assembly 15 includes a sliding driving member (151), and a first sliding block 152 and a first sliding rail 153 which are in sliding fit, the first sliding block 152 is installed on one surface of the first mounting substrate 11 or the second mounting substrate 12 close to the cross beam 1, the first sliding rail 153 is installed on one surface of the cross beam 1 close to the first mounting substrate 11 or the second mounting substrate 12, and an output end of the sliding driving member (151) is in transmission connection with the first sliding block 152.

In practical application, the drilling assembly 200 and the milling assembly 300 are simultaneously arranged on the second mounting substrate 100, so that the occupied space is small, and the drilling assembly 200 and the milling assembly 300 can independently work, thereby effectively improving the processing efficiency; simultaneously, drill bits in different drilling directions are respectively installed through the Z-direction gang drill 220, the X-direction sidetracking drill 230 and the Y-direction sidetracking drill 240, so that different drilling requirements of users are met, and the applicability is wide.

In this embodiment, the sliding driving assembly 15 further includes a rack 154, a transmission gear 155, and a connecting seat 156; the rack 154 is installed on the cross beam 1 and extends along the length direction of the cross beam 1, the transmission gear 155 is installed on the output end of the sliding driving member (151) and is engaged with the rack 154, and two ends of the connecting seat 156 are respectively connected and fixed with the sliding driving member (151) and the first slider 152.

Specifically, the sliding driving member 151 is a motor, and an output end of the motor is in transmission connection with the first sliding block 152; in practical application, the first sliding block 152 is driven by the motor to slide back and forth on the first sliding rail 153, so that the first machine head device can slide back and forth along the length direction of the cross beam 100, the position of the first machine head device can be adjusted, different production requirements can be met, and meanwhile, the accuracy of the moving position of the first machine head device can be effectively guaranteed.

As shown in fig. 4 to 6, in the present embodiment, first tool holders 231 are disposed at both ends of the X-directional sidedrill 230, and the first tool holders 231 at both ends of the X-directional sidedrill 230 are disposed oppositely along the X direction; two ends of the Y-directional sidetrack 240 are provided with second tool holders 241, and the second tool holders 241 at the two ends of the Y-directional sidetrack 240 are oppositely arranged along the Y direction. In practical application, the first tool holders 231 at the two ends of the X-directional sidetracking drill 230 can simultaneously process the wood in the directions of the two ends of the X-directional sidetracking drill 230, so that the processing efficiency is effectively improved, and different use requirements are met. The second tool apron 241 at the two ends of the Y-direction sidetrack 240 can simultaneously process wood in the two end directions of the Y-direction sidetrack 240, so that the processing efficiency is effectively improved, and different use requirements are met.

In this embodiment, the first lifting driving assembly 40 includes a first lifting driving element 410, and a first sliding block 420 and a first sliding rail 430 which are in sliding fit, the first sliding block 420 is installed on one surface of the second mounting substrate 12 close to the base 500, the first sliding rail 430 is installed on one surface of the base 500 close to the second mounting substrate 12, and an output end of the first lifting driving element 410 is in transmission connection with the second mounting substrate 12 through a transmission structure; the transmission structure includes a screw rod 440 connected to the output end of the first lifting driving member 410 and a screw seat 450 used in cooperation with the screw rod 440, and one surface of the second mounting substrate 12 close to the base 500 is mounted on the screw seat 450. In practical application, the motor is started to drive the screw rod 440 to rotate, so that the screw seat 450 moves back and forth on the screw rod 440, and the second mounting substrate 100 moves back and forth, and the transmission structure is stable and the use stability is high.

In this embodiment, the milling assembly 30 includes a milling spindle 310 disposed on the second mounting substrate 12 and a rotary driving element 320 for driving the milling spindle 310 to rotate, wherein both ends of the milling spindle 310 are provided with third tool seats 330, and the third tool seats 330 at both ends of the milling spindle 310 are disposed oppositely along the X direction; the output end of the rotary drive 320 is in transmission connection with the milling spindle 310. The rotary drive 320 is a motor; in practical application, the milling spindle 310 is driven to rotate by the motor, and the positions of the two ends of the milling spindle 310 are switched, so that the third tool apron 330 is replaced without stopping the machine for tool changing, and the machining efficiency is effectively improved.

In this embodiment, a second lifting drive assembly 60 is also included; the second lifting driving assembly 60 includes a second lifting seat 610 disposed on the second mounting substrate 12, a second slider 620 mounted on the second lifting seat 610 near one surface of the second mounting substrate 12, a second slide rail 630 mounted on the second mounting substrate 12 near one surface of the second lifting seat 610 and used in cooperation with the second slider 620, and a second lifting driving member 640 for driving the second slider 620 to slide back and forth on the second slide rail 630, wherein an output end of the second lifting driving member 640 is connected and fixed with the second lifting seat 610, and the milling spindle 310 is disposed on the second lifting seat 610. In practical application, the motor is started to drive the second lifting seat 610 to move up and down, and the accuracy of the lifting position of the second lifting seat 610 is ensured by the matched use of the second sliding block 620 and the second sliding rail 630, so that the processing precision is effectively ensured; when the second lifting seat 610 moves up and down, the milling spindle 310 is driven to move up and down, so that the lifting position of the milling spindle 310 can be adjusted to meet different use requirements.

As shown in fig. 2 to 3, in the present embodiment, the first head device further includes a third lifting driving assembly 16 for driving the spindle assembly to move back and forth; third lift drive assembly 16 is including locating third lift driving piece 161, transmission structure and third lift seat 162, third lift driving piece 161 transmission structure and third lift seat 162 all locates first mounting substrate 11, just transmission structure's both ends respectively with the output of third lift driving piece 161 and the transmission of third lift seat 162 are connected, spindle unit locates third lift seat 162.

In this embodiment, the rotation driving assembly 13 includes a rotating base 131 and a rotation driving element 132, the rotating base 131 is disposed on the third lifting base 162, and an output end of the rotation driving element 132 is in transmission connection with the rotating base 131; the spindle assembly is disposed on the rotary base 131. The spindle assembly comprises a double-output-shaft motor 121, and the tool apron 14 at the two ends of the spindle assembly is in one-to-one transmission connection with two output ends of the double-output-shaft motor 121 respectively. In practical application, the dual output shaft motor 120 is started, and the tool holders 140 at the two ends of the main shaft assembly rotate simultaneously; during tool changing, only the main shaft assembly is driven to rotate through the rotary driving assembly 130, so that the switching of the positions of the two ends of the main shaft assembly is realized, the tool changing operation is realized, and the operation is simple and easy.

In the description of the present invention, it should be noted that, for the terms of orientation, such as "central", "transverse (X)", "longitudinal (Y)", "vertical (Z)", "length", "width", "thickness", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", "clockwise", "counterclockwise", etc., indicate that the orientation and positional relationship are based on the orientation or positional relationship shown in the drawings, only for the convenience of describing the present invention and simplifying the description, but not for indicating or implying that the device or element referred to must have a specific orientation, be constructed and operated in a specific orientation, and should not be construed as limiting the specific scope of the present invention.

Furthermore, if the terms "first" and "second" are used for descriptive purposes only, they are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features. Thus, a definition of "a first" or "a second" feature may explicitly or implicitly include one or more of the features, and in the description of the invention, "a number" means two or more unless explicitly defined otherwise.

In the present invention, unless otherwise expressly specified or limited, the terms "assembled", "connected", and "connected" are to be construed broadly, e.g., as meaning fixedly connected, detachably connected, or integrally connected; or may be a mechanical connection; the two elements can be directly connected or connected through an intermediate medium, and the two elements can be communicated with each other. The specific meanings of the above terms in the present invention can be understood by those of ordinary skill in the art according to specific situations.

The above-mentioned embodiments only express a plurality of embodiments of the present invention, and the description thereof is more specific and detailed, but not to be construed as limiting the scope of the present invention. It should be noted that, for a person skilled in the art, several variations and modifications can be made without departing from the inventive concept, which falls within the scope of the present invention. Therefore, the protection scope of the present patent should be subject to the appended claims.

Claims (10)

1. Two aircraft nose processing equipment, its characterized in that: comprises a cross beam (1) and a first machine head device and a second machine head device which are respectively arranged on two sides of the cross beam (1); the first machine head device comprises a first mounting substrate (11) which is slidably mounted on the cross beam (1), a main shaft assembly which is arranged on the first mounting substrate (11), and a rotary driving assembly (13) which is used for driving the main shaft assembly to rotate, tool holders (14) are arranged at two ends of the main shaft assembly, and the output end of the rotary driving assembly (13) is in transmission connection with the main shaft assembly;

the second machine head device comprises a second mounting base plate (12) which is slidably mounted on the other side of the cross beam (1), a drilling assembly (20) which is mounted on the second mounting base plate (12), a milling assembly (30) which is arranged on the second mounting base plate (12), and a first lifting driving assembly (40) which is used for driving the second mounting base plate (12) to move up and down;

the drilling assembly (20) comprises a base body (210) arranged on the second mounting base plate (12), a Z-direction gang drill (220) rotatably arranged on the base body (210), and an X-direction sidetrack (230) and a Y-direction sidetrack (240) detachably arranged on the base body (210).

2. The double-head processing apparatus according to claim 1, wherein: two groups of sliding driving components (15) which are respectively used for bearing and driving the first machine head device and the second machine head device to move in the X direction are respectively arranged on two sides of the cross beam (1);

the sliding driving assembly (15) comprises a sliding driving piece (151), a first sliding block (152) and a first sliding rail (153) which are in sliding fit, the first sliding block (152) is arranged on one surface, close to the cross beam (1), of the first mounting substrate (11) or the second mounting substrate (12), the first sliding rail (153) is arranged on one surface, close to the first mounting substrate (11) or the second mounting substrate (12), of the cross beam (1), and the output end of the sliding driving piece (151) is in transmission connection with the first sliding block (152).

3. The double-head machining apparatus according to claim 2, wherein: the sliding driving assembly (15) further comprises a rack (154), a transmission gear (155) and a connecting seat (156); the rack (154) is arranged on the cross beam (1) and extends along the length direction of the cross beam (1), the transmission gear (155) is arranged on the output end of the sliding driving piece (151) and is meshed with the rack (154), and two ends of the connecting seat (156) are respectively connected and fixed with the sliding driving piece (151) and the first sliding block (152).

4. The double-head machining apparatus according to claim 1, wherein: two ends of the X-direction sidetrack (230) are respectively provided with a first cutter seat (231), and the first cutter seats (231) at the two ends of the X-direction sidetrack (230) are oppositely arranged along the X direction; and two ends of the Y-direction sidetrack (240) are respectively provided with a second tool apron (241), and the second tool apron (241) at the two ends of the Y-direction sidetrack (240) are oppositely arranged along the Y direction.

5. The double-head processing apparatus according to claim 1, wherein: the first lifting driving assembly (40) comprises a first lifting driving piece (410), a first sliding block (420) and a first sliding rail (430), wherein the first sliding block (420) and the first sliding rail are in sliding fit, the first sliding block (420) is arranged on one surface, close to the base (500), of the second mounting substrate (12), the first sliding rail (430) is arranged on one surface, close to the second mounting substrate (12), of the base (500), and the output end of the first lifting driving piece (410) is in transmission connection with the second mounting substrate (12) through a transmission structure; the transmission structure comprises a screw rod (440) connected with the output end of the first lifting driving piece (410) and a threaded seat (450) matched with the screw rod (440) for use, and one surface, close to the base (500), of the second mounting substrate (12) is arranged on the threaded seat (450).

6. The double-head processing apparatus according to claim 1, wherein: the milling assembly (30) comprises a milling spindle (310) arranged on the second mounting substrate (12) and a rotary driving element (320) used for driving the milling spindle (310) to rotate, third tool seats (330) are arranged at two ends of the milling spindle (310), and the third tool seats (330) at the two ends of the milling spindle (310) are oppositely arranged along the X direction; the output end of the rotary driving piece (320) is in transmission connection with the milling spindle (310).

7. The double-head processing apparatus according to claim 6, wherein: the lifting device also comprises a second lifting driving component (60); the second lifting driving component (60) comprises a second lifting seat (610) arranged on the second mounting substrate (12), a second sliding block (620) arranged on the second lifting seat (610) and close to one surface of the second mounting substrate (12), a second sliding rail (630) arranged on the second mounting substrate (12) and close to one surface of the second lifting seat (610) and matched with the second sliding block (620), and a second lifting driving piece (640) used for driving the second sliding block (620) to slide back and forth on the second sliding rail (630), wherein the output end of the second lifting driving piece (640) is fixedly connected with the second lifting seat (610), and the milling spindle (310) is arranged on the second lifting seat (610).

8. The double-head processing apparatus according to claim 1, wherein: the first machine head device also comprises a third lifting driving component (16) for driving the spindle component to move up and down back and forth;

third lift drive assembly (16) is including locating third lift driving piece (161), transmission structure and third lift seat (162), third lift driving piece (161) transmission structure and third lift seat (162) are all located first mounting substrate (11), just transmission structure's both ends respectively with the output of third lift driving piece (161) and third lift seat (162) transmission are connected, spindle assembly locates third lift seat (162).

9. The double-head processing apparatus according to claim 8, wherein: the rotary driving component (13) comprises a rotary seat (131) and a rotary driving part (132), the rotary seat (131) is arranged on the third lifting seat (162), and the output end of the rotary driving part (132) is in transmission connection with the rotary seat (131); the main shaft assembly is arranged on the rotating seat (131).

10. The double-head processing apparatus according to claim 1, wherein: the main shaft assembly comprises a double-output-shaft motor (121), and the tool holders (14) at the two ends of the main shaft assembly are in one-to-one transmission connection with two output ends of the double-output-shaft motor (121) respectively.

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