CN217551922U - Numerical control machine tool with multiple machining stations - Google Patents

Abstract

The utility model aims at providing a numerical control machine tool of many machining-position, including the base, install portal frame on the base, install two at least processing main shafts on the portal frame, install two at least processing platforms on the base, every processing platform linkage all is connected with its Y axle drive assembly who removes along the Y axle on the base of drive. Each processing main shaft of the machine tool can process the workpiece on the corresponding processing platform according to the set processing program, even the processing workpieces and the processing programs of different processing main shafts can be independent, the processing efficiency and the practicability are improved, and all the processing main shafts can process any position of any processing platform.

Description

Numerical control machine tool with multiple machining stations

Technical Field

The utility model relates to a numerical control machine tool, more specifically say, relate to a numerical control machine tool of many processing stations.

Background

The invention patent with the application number of CN108422787A discloses a double-spindle full-screen engraving and milling machine with a tool magazine, wherein the engraving and milling machine is provided with 2 processing spindles, 2Y-axis processing platforms and 2 cross beams which are respectively used for mounting one processing spindle. The engraving and milling machine needs to be provided with 2Y-axis driving assemblies, 2X-axis driving assemblies and 2Z-axis driving assemblies, so that the production and manufacturing cost is increased; different products can be processed simultaneously, but during feeding and discharging, temporary stopping is needed, and the working efficiency is not high enough.

Utility model patent with application number CN201822203934.1 discloses a two main shaft cnc engraving and milling machines, this cnc engraving and milling machine has set up 2 processing main shafts, 1Y axle processing platform, 1 crossbeam that is used for installing a processing main shaft. Although the engraving and milling machine is provided with 2 processing main shafts, only one processing platform is required to be stopped temporarily during loading and unloading, and the engraving and milling machine cannot be lifted to the maximum.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a numerical control machine tool of many machining-position rational in infrastructure, machining efficiency is high.

The utility model provides a numerical control machine tool of many processing stations, includes the base, installs a portal frame on the base, install two at least processing main shafts on the portal frame, be equipped with two at least processing platforms on the base, every processing platform linkage all is connected with its Y axle drive assembly who moves along the Y axle on the base of drive, and the processing main shaft linkage is connected with its Z axle drive assembly who goes up and down along Z axle direction of drive, drives its X axle drive assembly who is X axle direction motion above the processing platform.

Preferably, each processing platform is independently connected with a Y-axis driving assembly, each Y-axis driving assembly comprises a Y-axis driving motor, a Y-axis lead screw in linkage connection with the Y-axis driving motor and a Y-axis connecting block in threaded connection with the Y-axis lead screw, and each Y-axis connecting block is fixedly connected with the processing platform.

Preferably, the Z-axis driving component comprises a Z-axis driving motor, a Z-axis screw rod in linkage connection with the Z-axis driving motor, and a Z-axis connecting block in threaded connection with the Z-axis screw rod, and the Z-axis connecting block is fixedly connected with the processing spindle.

Preferably, the X-axis driving assembly comprises an X-axis driving motor, an X-axis lead screw linked with the X-axis driving motor, and an X-axis connecting block in threaded connection with the X-axis lead screw, and the number of the X-axis connecting blocks is the same as that of the processing spindles, and the X-axis driving motor and the X-axis lead screw are fixedly connected in a one-to-one correspondence manner.

Preferably, a first waste oil recovery box is connected below the Y-axis driving motor and connected with the base.

Preferably, a second waste oil recovery box is connected below the X-axis driving motor and is connected with a beam of the portal frame.

Preferably, a tool magazine is installed below the beam of the portal frame and is located above the machining platform.

By adopting the technical scheme, the utility model has the advantages of as follows:

1. each processing platform is linked with a Y-axis driving assembly for driving the processing platform to move on the base along a Y axis, each processing platform can be independently processed and can be sequentially processed on different processing platforms in turn, a plurality of processing main shafts are arranged on the processing platforms, the processing main shafts can be moved to all the processing platforms for processing, one platform is used for loading and unloading, and the other platform is used for processing, so that the product clamping time is effectively reduced, and the processing efficiency of the product is improved;

2. the arrangement of the first waste oil recovery box and the second waste oil recovery box can effectively prevent waste oil drops on the driving motor from polluting products and even scrapping the products;

3. because need set up a plurality of processing platforms on the base, so base surface mounting space is limited, sets up the tool magazine in the crossbeam below of portal frame, can save the installation space on base surface, can not influence other parts yet, and is rational in infrastructure.

Drawings

FIG. 1 is a schematic structural diagram of a numerical control machine tool with multiple machining stations;

FIG. 2 is a first schematic structural diagram of a multi-station numerical control machine tool (without a machining spindle);

FIG. 3 is a schematic structural diagram II of a multi-station numerical control machine tool (without a machining spindle);

1. a base; 2. a gantry; 21. a cross beam; 22. a column; 3. a tool magazine; 4. processing a main shaft; 5. a processing platform; 6. a Y-axis drive assembly; a Y-axis drive motor; 62.Y-axis lead screw; 63.Y-axis connecting block; an x-axis drive assembly; an X-axis drive motor; 72.X axis lead screw; 81.Z-axis drive motors; 82.Z-axis slide rails; 91. a first waste oil recovery box; 92. and a second waste oil recovery box.

Detailed Description

Embodiments of the present invention are further described below with reference to fig. 1-3.

A numerical control machine tool with multiple machining stations comprises:

the base 1 is used for installing a portal frame 2 and at least two processing platforms 5;

the portal frame 2 is arranged on the base 1 and comprises a cross beam 21 and two stand columns 22 which are respectively connected to two ends of the cross beam 21, a tool magazine 3 is arranged below the cross beam 21 of the portal frame 2, and the tool magazine 3 is positioned above the processing platform 5;

at least two processing main shafts 4 are arranged, and each processing main shaft 4 uses the same X-axis driving component 7 together but independently uses different Z-axis lifting components; the X-axis driving assembly 7 comprises an X-axis driving motor 71, an X-axis screw 72 in linkage connection with the X-axis driving motor 71 and an X-axis connecting block in threaded connection with the X-axis screw 72, and the X-axis connecting block is fixedly connected with the machining spindle 4; the plurality of processing spindles 4 share an X-axis driving motor 71 and an X-axis lead screw 72;

a Z-axis sliding rail 82 is arranged on a cross beam 21 of the portal frame 2, a Z-axis driving component is connected to the Z-axis sliding rail 82 in a sliding manner and comprises a Z-axis driving motor 81 positioned above the Z-axis sliding rail 82, a Z-axis lead screw connected with the Z-axis driving motor 81 in a linkage manner and a Z-axis connecting block in threaded connection with the Z-axis lead screw, the Z-axis connecting block is fixedly connected with the processing main shafts 4, and each processing main shaft 4 independently uses one Z-axis driving component;

a second waste oil recovery box 92 is connected below the X-axis driving motor 71, the Z-axis slide rail 82 is positioned above the second waste oil recovery box 92, the second waste oil recovery box 92 is connected with the cross beam 21 of the portal frame 2, and the second waste oil recovery box 92 is of a long strip structure, the length of the second waste oil recovery box is approximately equal to that of the cross beam 21 of the portal frame 2, so that the cost of the X-axis driving motor 61 and the cost of the Z-axis driving motor 81 can finally fall into the second waste oil recovery box 92;

the machining platforms 5 are arranged on the base 1 and located below the machining main shafts 4, all the machining main shafts 4 can machine any position of any machining platform 5 (a plurality of machining platforms 5 can machine in a rotating mode, and the time for loading and unloading can be saved), each machining platform 5 is linked with a Y-axis driving assembly 7 which drives the machining platform 5 to move on the base 1 along the Y axis independently, each Y-axis driving assembly 7 comprises a Y-axis driving motor 71, a Y-axis lead screw 72 in linkage connection with the Y-axis driving motor 71 and a Y-axis connecting block 73 in threaded connection with the Y-axis lead screw 72, the Y-axis connecting block 73 is fixedly connected with the machining platforms 5, a first oil waste recovery box 91 is connected below the Y-axis driving motor 71, and the first oil waste recovery box 91 is connected with the base 1;

in addition, a pair of tool setting gauges 93 can be independently arranged on each processing platform 5, and the two processing platforms 5 use the two tool setting gauges 93, so that the processing error of the product can be reduced, and the product precision is improved.

The above embodiments are only preferred embodiments of the present invention, and the protection scope of the present invention cannot be limited thereby, and any insubstantial changes and substitutions made by those skilled in the art on the basis of the present invention are all within the protection scope of the present invention.

Claims (7)

1. The utility model provides a numerical control machine tool of many machining-position, includes the base, installs a portal frame on the base, its characterized in that: the gantry is provided with at least two processing main shafts, the base is provided with at least two processing platforms, each processing platform is linked with a Y-axis driving assembly for driving the processing platform to move on the base along a Y axis, and the processing main shafts are linked with a Z-axis driving assembly for driving the processing platform to lift along the Z axis direction and an X-axis driving assembly for driving the processing platform to move in the X axis direction above the processing platform.

2. A multi-station numerical control machine tool according to claim 1, characterized in that: each processing platform is independently connected with a Y-axis driving assembly, the Y-axis driving assembly comprises a Y-axis driving motor, a Y-axis screw rod in linkage connection with the Y-axis driving motor and a Y-axis connecting block in threaded connection with the Y-axis screw rod, and the Y-axis connecting block is fixedly connected with the processing platform.

3. A multi-station numerical control machine tool according to claim 1, characterized in that: and the Z-axis driving assembly comprises a Z-axis driving motor, a Z-axis lead screw in linkage connection with the Z-axis driving motor and a Z-axis connecting block in threaded connection with the Z-axis lead screw, and the Z-axis connecting block is fixedly connected with the processing spindle.

4. A multi-station numerical control machine tool according to claim 1, characterized in that: the X-axis driving assembly comprises an X-axis driving motor, an X-axis screw rod in linkage connection with the X-axis driving motor, and an X-axis connecting block in threaded connection with the X-axis screw rod.

5. A multi-station numerical control machine tool according to claim 2, characterized in that: y axle driving motor below is connected with first waste oil recovery box, and first waste oil recovery box is connected with the base.

6. A multi-station CNC machine tool as claimed in claim 4, wherein: and a second waste oil recovery box is connected below the X-axis driving motor and is connected with a beam of the portal frame.

7. A multi-station numerical control machine tool according to claim 1, characterized in that: and a tool magazine is arranged below the cross beam of the portal frame and is positioned above the processing platform.

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