CN211248792U - High numerical control engraver of machining precision - Google Patents

Abstract

The utility model discloses a numerical control engraving machine with high processing precision, which comprises a supporting component, a supporting base, a positioning component, an engraving component and a driving component; supporting the base: the supporting base comprises a connecting box seat, four supporting foot columns are arranged at four corners of the lower surface of the connecting box seat, and L-shaped plates are arranged at the upper ends of the front side and the rear side of the connecting box seat; a support component: the support component comprises two first sliding rods arranged inside the connecting box seat, the first sliding rods are provided with connecting lug plates in sliding connection, a placing plate is arranged between the upper ends of the connecting lug plates, the front and back positions of a workpiece can be positioned through the cylinder telescopic rod and the positioning inclined plate, the left and right positions of the workpiece can be positioned through the U-shaped plate, the numerical control engraving machine with high machining precision is simple in structure, and the numerical control engraving machine is simple and convenient to operate, not only can be used for positioning the workpiece more quickly, but also can be used for positioning more accurately, and enables engraving to be more accurate, and convenience is brought to people.

Description

High numerical control engraver of machining precision

Technical Field

The utility model relates to an engraver technical field specifically is a numerical control engraver that machining precision is high.

Background

The numerical control engraving machine comprises a woodworking engraving machine, a stone engraving machine, an advertisement engraving machine, a glass engraving machine, a laser engraving machine, a plasma engraving machine and a laser cutting machine, but the existing numerical control engraving machine is complex in structure, inaccurate in workpiece positioning, low in machining precision and incapable of meeting the requirements of people.

SUMMERY OF THE UTILITY MODEL

The to-be-solved technical problem of the utility model is to overcome current defect, provide a numerical control engraver that machining precision is high, simple structure, it is easy and simple to handle, not only make to work piece location quicker, fix a position more accurately moreover to make the sculpture more accurate, for people provide convenience, can effectively solve the problem in the background art.

In order to achieve the above object, the utility model provides a following technical scheme: a numerical control engraving machine with high processing precision comprises a supporting component, a supporting base, a positioning component, an engraving component and a driving component;

supporting the base: the supporting base comprises a connecting box seat, four supporting foot columns are arranged at four corners of the lower surface of the connecting box seat, and L-shaped plates are arranged at the upper ends of the front side and the rear side of the connecting box seat;

a support component: the supporting assembly comprises two first sliding rods arranged inside the connecting box seat, connecting lug plates in sliding connection are arranged on the two first sliding rods, a placing plate is arranged between the upper ends of the connecting lug plates, the center of the lower surface of the placing plate is connected with a linear motor through a bolt, and two ends of a stator of the linear motor are connected with the connecting box seat;

a positioning component: the number of the positioning assemblies is two, and the two positioning assemblies are arranged at the left end and the right end of the placing plate;

the engraving component comprises: the engraving assembly comprises two sliding rods II arranged at the upper end between the L-shaped plates, sliding seats in sliding connection are arranged on the two sliding rods II, an electric telescopic rod II is arranged on the lower surface of each sliding seat, and a laser engraving machine is arranged at the telescopic end of each electric telescopic rod II;

a driving component: the driving assembly comprises a motor arranged on the upper surface of the sliding seat, a gear is arranged at the end part of an output shaft of the motor, racks which are meshed with each other are arranged at the lower end of the gear, and two ends of each rack are connected with the L-shaped plate vertical plate;

wherein: the laser engraving machine further comprises a PLC, the output end of an external power supply is electrically connected with the input end of the PLC, and the input end of the electric telescopic rod II, the linear motor and the laser engraving machine is electrically connected with the output end of the PLC.

Further, the locating component is including setting up the engaging lug board of placing the board upper surface, one side of engaging lug board is equipped with a set of electric telescopic handle one, is equipped with the U template between the flexible end of every electric telescopic handle one of group, two horizontal board one sides of U template are connected with the location swash plate through the cylinder telescopic link, can drive the U template through electric telescopic handle one and remove, can be to the front and back position location of work piece through cylinder telescopic link and location swash plate, can be to the left and right sides position location of work piece through the U template for the location is more accurate.

Further, still include infrared distance detector, infrared distance detector sets up the one side at the sliding seat, the input of PLC controller is connected to infrared distance detector's output electricity, can detect the front and back position of laser engraving machine through infrared distance detector for the location is more accurate.

Furthermore, a 120-degree oblique angle is arranged between the two positioning oblique plates on each U-shaped plate, so that the front position and the rear position of the workpiece are positioned more accurately through the two positioning oblique plates, and convenience is brought to people.

Compared with the prior art, the beneficial effects of the utility model are that: this numerical control engraver that machining precision is high has following benefit:

1. the utility model discloses on set up the connecting box seat, can support the device through the connecting box seat to through linear electric motor, can drive positioning assembly and place the board through linear electric motor and remove about, with this removal about the position of work piece, it is more convenient to make the removal.

2. The utility model discloses on set up the motor, can drive gear revolve through the motor, can drive the laser engraving machine back-and-forth movement through the gear to can detect laser engraving machine's front and back position through infrared distance detector, make the location more accurate.

3. The utility model discloses on set up electric telescopic handle one, can drive the U template through electric telescopic handle one and control and remove, can be to the front and back position location of work piece through cylinder telescopic link and location swash plate, can be to the left and right sides position location of work piece through the U template, this numerical control engraver that machining precision is high simple structure, and is easy and simple to handle, not only makes to fix a position the work piece faster, fixes a position more accurately moreover to make the sculpture more accurate, provide convenient for people.

Drawings

FIG. 1 is a schematic structural view of the present invention;

fig. 2 is a schematic view of the cross-sectional structure of the present invention.

In the figure: the device comprises a PLC (programmable logic controller) 1, a supporting component 2, a first sliding rod 21, a 22 placing plate, a linear motor 23, a connecting lug plate 24, a supporting base 3, a supporting foot post 31, a connecting box seat 32, a 33L-shaped plate, a positioning component 4, a connecting lug plate 41, a first electric telescopic rod 42, a 43U-shaped plate 44, a positioning inclined plate 5, a carving component 51, a second sliding rod 51, a sliding seat 52, a second electric telescopic rod 53, a laser carving machine 54, a 6 infrared distance detector 7, a driving component 71, a motor 72 gear and a 73 rack.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Example one

Referring to fig. 1-2, the present invention provides a technical solution: a numerical control engraving machine with high processing precision comprises a supporting component 2, a supporting base 3, a positioning component 4, an engraving component 5 and a driving component 7;

the supporting base 3: the supporting base 3 comprises a connecting box seat 32, four supporting foot columns 31 are arranged at four corners of the lower surface of the connecting box seat 32, and L-shaped plates 33 are arranged at the upper ends of the front side and the rear side of the connecting box seat 32;

the supporting component 2: the supporting assembly 2 comprises two first sliding rods 21 arranged inside the connecting box seat 32, connecting lug plates 24 in sliding connection are arranged on the two first sliding rods 21, a placing plate 22 is arranged between the upper ends of the connecting lug plates 24, the center of the lower surface of the placing plate 22 is connected with a linear motor 23 through a bolt, and two ends of a stator of the linear motor 23 are connected with the connecting box seat 32;

the positioning component 4: the number of the positioning assemblies 4 is two, and the two positioning assemblies 4 are arranged at the left end and the right end of the placing plate 22;

the engraving assembly 5: the engraving component 5 comprises two sliding rods 51 arranged at the upper end between the L-shaped plates 33, sliding seats 52 in sliding connection are arranged on the two sliding rods 51, electric telescopic rods 53 are arranged on the lower surfaces of the sliding seats 52, laser engraving machines 54 are arranged at the telescopic ends of the electric telescopic rods 53, the laser engraving machines 54 can be driven to move up and down through the electric telescopic rods 53, and engraving can be performed through the laser engraving machines 54, so that engraving is more convenient;

the driving assembly 7: the driving assembly 7 comprises a motor 71 arranged on the upper surface of the sliding seat 52, a gear 72 is arranged at the end part of an output shaft of the motor 71, racks 73 which are meshed with each other are arranged at the lower ends of the gears 72, two ends of each rack 73 are connected with the vertical plate of the L-shaped plate 33, the gear 72 can be driven to rotate through the motor 71, and the laser engraving machine 54 can be driven to move back and forth through the gear 72;

wherein: the positioning device comprises a PLC (programmable logic controller) 1, wherein the input end of the PLC 1 is electrically connected with the output end of an external power supply, the output end of the PLC 1 is electrically connected with a second electric telescopic rod 53, the linear motor 23 and the input end of a laser engraving machine 54, a positioning component 4 comprises a connecting lug plate 41 arranged on the upper surface of a placing plate 22, one side of the connecting lug plate 41 is provided with a group of first electric telescopic rods 42, a U-shaped plate 43 is arranged between the telescopic ends of each group of first electric telescopic rods 42, one side of two transverse plates of the U-shaped plate 43 is connected with a positioning inclined plate 44 through an air cylinder telescopic rod, the U-shaped plate 43 can be driven to move left and right through the first electric telescopic rods 42, the front and back positions of a workpiece can be positioned through the air cylinder telescopic rods and the positioning inclined plates 44, the left and right positions of the workpiece can be positioned through, PLC controller 1's input is connected to infrared ray distance detection ware 6's output electricity, can detect laser engraving machine 54's front and back position through infrared ray distance detection ware 6, make the location more accurate, be equipped with 120 degrees oblique angles between two location swash plates 44 on every U template 43, make the front and back position location to the work piece more accurate through two location swash plates 44, for people provide convenience, the numerical control engraving machine simple structure that this machining precision is high, and is simple and convenient to operate, not only make the location to the work piece quicker, and the location is more accurate, and make the sculpture more accurate, for people provide convenience.

When in use: can support the device through connecting box seat 32, and through linear electric motor 23, can drive locating component 4 and place the board 22 through linear electric motor 23 and remove about, with this remove about the position of work piece, can drive gear 72 through motor 71 and rotate, can drive laser engraving machine 54 back-and-forth movement through gear 72, and can detect laser engraving machine 54's fore-and-aft position through infrared ray distance detector 6, can drive U template 43 through electric telescopic handle 42 and remove about, can fix a position the fore-and-aft position of work piece through cylinder telescopic link and location swash plate 44, can be to the left and right sides position location of work piece through U template 43, can drive laser engraving machine 54 through electric telescopic handle two 53 and reciprocate, and can carve through laser engraving machine 54.

It should be noted that the core chip of the PLC controller 1 disclosed in this embodiment is a PLC single chip, the specific model is siemens S7-1200, and the PLC controller 1 controls the external distance detector 6, the electric telescopic rod ii 53, the linear motor 23, and the laser engraving machine 54 to operate by a method commonly used in the prior art.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (4)

1. The utility model provides a numerical control engraver that machining precision is high which characterized in that: comprises a supporting component, a supporting base, a positioning component, a carving component and a driving component;

supporting the base: the supporting base comprises a connecting box seat, four supporting foot columns are arranged at four corners of the lower surface of the connecting box seat, and L-shaped plates are arranged at the upper ends of the front side and the rear side of the connecting box seat;

a support component: the supporting assembly comprises two first sliding rods arranged inside the connecting box seat, connecting lug plates in sliding connection are arranged on the two first sliding rods, a placing plate is arranged between the upper ends of the connecting lug plates, the center of the lower surface of the placing plate is connected with a linear motor through a bolt, and two ends of a stator of the linear motor are connected with the connecting box seat;

a positioning component: the number of the positioning assemblies is two, and the two positioning assemblies are arranged at the left end and the right end of the placing plate;

the engraving component comprises: the engraving assembly comprises two sliding rods II arranged at the upper end between the L-shaped plates, sliding seats in sliding connection are arranged on the two sliding rods II, an electric telescopic rod II is arranged on the lower surface of each sliding seat, and a laser engraving machine is arranged at the telescopic end of each electric telescopic rod II;

a driving component: the driving assembly comprises a motor arranged on the upper surface of the sliding seat, a gear is arranged at the end part of an output shaft of the motor, racks which are meshed with each other are arranged at the lower end of the gear, and two ends of each rack are connected with the L-shaped plate vertical plate;

wherein: the laser engraving machine further comprises a PLC, the output end of an external power supply is electrically connected with the input end of the PLC, and the input end of the electric telescopic rod II, the linear motor and the laser engraving machine is electrically connected with the output end of the PLC.

2. The numerical control engraving machine with high machining precision as claimed in claim 1, characterized in that: the positioning assembly comprises a connecting lug plate arranged on the upper surface of the placing plate, one side of the connecting lug plate is provided with a group of electric telescopic rods, a U-shaped plate is arranged between the telescopic ends of each group of electric telescopic rods, and one side of two transverse plates of each U-shaped plate is connected with a positioning inclined plate through an air cylinder telescopic rod.

3. The numerical control engraving machine with high machining precision as claimed in claim 1, characterized in that: still include infrared ray distance detection ware, infrared ray distance detection ware sets up the one side at the sliding seat, the input of PLC controller is connected to infrared ray distance detection ware's output electricity.

4. The numerical control engraving machine with high machining precision as claimed in claim 2, characterized in that: and a 120-degree oblique angle is arranged between the two positioning oblique plates on each U-shaped plate.

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