CN204221382U

CN204221382U - Multi-cutter synchronizing mechanism of computer lathe

Info

Publication number: CN204221382U
Application number: CN201420512704.2U
Authority: CN
Inventors: 郭钦辉
Original assignee: Individual
Current assignee: Individual
Priority date: 2013-09-27
Filing date: 2014-09-05
Publication date: 2015-03-25
Anticipated expiration: 2024-09-05
Also published as: JP3194785U; KR200489459Y1; KR20150001353U

Abstract

The utility model relates to a computer lathe multitool lazytongs, it is equipped with a main shaft group, at least biaxial main shaft blade holder and a biaxial hackle blade holder on a unit, and this main shaft group has a main shaft seat, and on this main shaft seat was located respectively to this biaxial main shaft blade holder, and this biaxial main shaft blade holder had the cutter in a directional work piece axle center respectively, and main shaft group the place ahead was located to this biaxial hackle blade holder. Therefore, because the cutter seats of the double-axial main shaft are not interfered with each other, the machined workpiece of the main shaft group can be machined at the same time point, and the double-axial comb-type cutter seat can also be used for turning and drilling the outer diameter and the inner diameter at the same time point, so that at least two cutters can be used at the same time point, the number of the cutters is increased, the machining time can be greatly reduced, the cutter replacing time can be greatly shortened, and the machining efficiency is effectively improved.

Description

Computer lathe multitool lazy-tongs

Technical field

The utility model belongs to the technical field of computer lathe, in particular to a kind of computer lathe multitool lazy-tongs that can manipulate much knives tool and carry out processing simultaneously.

Background technology

The lathe of CNC(computer numerical control (CNC) in recent years) industry develops rapidly, because lathe profit is computerizedd control, therefore servo motor and relevant corresponding accessory thereof is needed, and the volume that servo motor has it certain, also cannot break through according to prior art, as shown in Figure 1, it is a kind of CNC computer lathe 10 of tool comb formula tool rest 15, each processing can furnish much knives tool on comb formula tool rest 15, but it cannot allow the different cutters on comb formula tool rest 15 process at one time in adding man-hour, and each cutter all needs mutual wait.It is another that it is a kind of conventional cam formula lathe 20 as shown in Figure 2, three tool rests 25 are had above the main shaft 21 of this cam-type lathe 20, each tool rest 25 is driven by a cam set 26 respectively, and respectively this tool rest 25 can have a cutter respectively, every tool rest 25 can only move up and down, and every tool rest needs mutually to wait for, in addition main shaft 21 front of this cam-type lathe 20 is separately provided with a comb formula tool rest (not shown), this comb formula tool rest has two cutters, and this comb formula tool rest can only do and advances, the boring work retreated, because all starts of cam-type lathe 20 are for this reason all by cam mechanism is driven, therefore cam-type lathe 20 all needs by experienced master worker's instruction when school cutter adjusts, otherwise will directly have influence on the efficiency and precision of following process.

Because aforementioned active computer lathe 10 all can be restricted in time designing, so active computer lathe 10 is adding man-hour, operable number of cutters of same time and process velocity will slow than aforementioned cam formula lathe 20, but because conventional cam formula lathe 20 itself is drive respectively this tool rest 25 by cam mechanism 26, all need man-hour by experienced master worker's operation in adding, and this cam-type lathe 20 all needs to use forming cutter, commercially available Disposable cutting blade can be used unlike active computer lathe 10, easy left-hand seat and simple to operate, and this cam-type lathe 20 machining accuracy is unstable, precisely cannot carry out again the abrasion correction of cutter, Here it is repugnance both it.

In other words, because the design of active computer lathe 10 and cam-type lathe 20 is not attained perfect, and have the same time respectively and only can use that a kind of cutter, machining accuracy are poor, not easily correction and the school cutter problem such as not easily, and have influence on precision and the efficiency of overall processing, reduce its practicality, therefore how solving this problem, is the problem that industry is important.

Utility model content

In view of this, the purpose of this utility model is to provide a kind of computer lathe multitool lazy-tongs, with the external diameter processing that much knives tool can be allowed to carry out different size simultaneously, and can carry out the internal diameter processing of major axes orientation simultaneously, can effectively improve its working (machining) efficiency.

To achieve the above object, the utility model provides a kind of computer lathe multitool lazy-tongs, and it includes:

One board;

One main shaft group, it has one and is locked on spindle drum on this board, and this main shaft group have one can by the spindle axis of Spindle Motor high-speed rotation, and this spindle axis front end has a folder cylinder group, and this spindle axis other end has a main shaft oil cylinder pressure, and this main shaft oil cylinder pressure presss from both sides a work piece of pulling with driving this folder cylinder group selection;

At least one biaxially main shaft tool rest, this biaxially main shaft tool rest have one respectively and can lock the Z axis pedestal of pulling in this spindle drum, and this Z axis pedestal is slidably equipped with a Z axis slide, and this Z axis pedestal is provided with the Z axis screw rod that can drive Z axis slide, and this Z axis screw rod can by a Z axis servo motor driven, and this Z axis slide other end has a Y-axis pedestal, a Y-axis screw rod is provided with in this Y-axis pedestal, and this Y-axis pedestal leading flank is slidably equipped with a Y-axis slide that can be driven by Y-axis screw rod, and this Y-axis screw rod can drive by the Y-axis servo motor, and the leading flank of this biaxially Y-axis slide of main shaft tool rest is provided with a lock tool rest, this lock tool rest is optionally locked respectively and is established a cutter, and the work piece of difference or synchronous relative main group produces the displacement of Y-axis and Z axis,

One biaxially comb formula tool rest, it is located at the main shaft group front of this board, this biaxially comb formula tool rest there is the Z axis slide that is slidedly arranged on board, this Z axis slide is driven by the Z axis servo motor of a tool Z axis screw rod, and this Z axis slide one end has an X-axis pedestal, this X-axis base interior is provided with an X-axis screw rod, and this X-axis base top surface is slidably equipped with an X-axis slide that can be driven by this X-axis screw rod, and this X-axis screw rod can by an X-axis servo motor driven, and this X-axis slide end face is provided with a comb formula lock tool rest, this comb formula lock tool rest is optionally locked and is established at least one cutter, and this cutter produces the displacement of X-axis and Z axis respectively to the work piece of main shaft group.

Preferably, wherein the Spindle Motor of this main shaft group is locked on this board by a fixed head, and the output shaft of this Spindle Motor has a motor belt pulley, and this spindle axis is provided with the axle center belt pulley of a correspondence, and established by the relative ring of a belt, and this Spindle Motor synchronously can drive this spindle axis High Rotation Speed, and this spindle axis is separately provided with an encoder and a Positioning Gear, and this main shaft oil cylinder pressure is arranged with the oil return cover of a tool chuck detector.

Preferably, wherein the spindle drum of this main shaft group is locked and is provided with three groups of biaxially main shaft tool rests, and the cutter of this biaxially main shaft tool rest is non-interference.

Preferably, wherein this biaxially main shaft tool rest Z axis pedestal rear end lock be provided with a Z axis screw rod holder, and one end that this Z axis screw rod passes this Z axis screw rod holder is provided with a screw belt wheel, and this Z axis screw rod holder establishes this Z axis servo motor by a fixed head lock, and this Z axis servo motor have a pair should screw belt wheel motor belt pulley, and established by the corresponding ring of a belt, and this Z axis servo motor can synchronously drive Z axis screw rod to rotate, and this Y-axis pedestal is positioned at one end that this Z axis slide differs from Z axis screw rod holder, this Y-axis base interior is slidably equipped with a Y-axis screw rod holder, and this Y-axis screw rod is located between this Y-axis pedestal and this Y-axis screw rod holder, and this Y-axis slide is locked on this Y-axis screw rod holder, and one end that this Y-axis screw rod passes this Y-axis pedestal is provided with a screw belt wheel, and this Y-axis servo motor is locked on this Y-axis pedestal by a fixed head, this Y-axis servo motor have a pair should screw belt wheel motor belt pulley, and established by the corresponding ring of a belt, and this Y-axis servo motor drives the relative Y-axis pedestal of this Y-axis slide to produce the displacement of Y-axis by this Y-axis screw drive Y-axis screw rod holder.

Preferably, wherein this biaxially comb formula tool rest be provided with in this board the extensible cover that can cover this Z axis servo motor and this Z axis screw rod, and this X-axis base interior is slidably equipped with an X-axis screw rod holder, and this X-axis screw rod is located between this X-axis pedestal and this X-axis screw rod holder, and this X-axis slide is locked on this X-axis screw rod holder, and this X-axis servo motor is linked by a shaft coupling and this X-axis screw rod.

Computer lathe multitool lazy-tongs provided by the utility model, can due to respectively this biaxially main shaft tool rest is non-interference, therefore the work piece can put at one time toward main shaft group is processed, and the same time biaxially comb formula tool rest also can carry out external diameter, internal diameter turning and Drilling operation, make it put at one time and can use at least two cutters, not only increase number of cutters, more can greatly reduce process time and change the cutter time, effective raising working (machining) efficiency, increase its practicality, to improve its surcharge; The correction of tool wear can be carried out simultaneously, its machining accuracy can be improved further, thus improve its practicality.

Accompanying drawing explanation

Fig. 1 is the schematic appearance of known computer lathe;

Fig. 2 is the main view plane schematic diagram of known cam-type lathe;

Fig. 3 is the schematic appearance of the utility model computer lathe multitool lazy-tongs;

Fig. 4 is the internal structure schematic diagram of the utility model computer lathe multitool lazy-tongs side-looking;

Fig. 5 is the internal structure schematic diagram that the utility model computer lathe multitool lazy-tongs master looks;

Fig. 6 is the decomposing schematic representation of main shaft group in the utility model computer lathe multitool lazy-tongs;

Fig. 7 is the decomposing schematic representation of biaxially main shaft tool rest in the utility model computer lathe multitool lazy-tongs;

Fig. 8 is the decomposing schematic representation of biaxially comb formula tool rest in the utility model computer lathe multitool lazy-tongs.

[main element symbol description]

Computer lathe-10; Cutter-100; Comb formula tool rest-15; Cutter-150;

Cam-type lathe-20; Main shaft-21; Tool rest-25; Cam mechanism-26;

Board-50;

Main shaft group-60; Spindle drum-61; Spindle Motor-62; Fixed head-620; Motor belt pulley-621; Spindle axis-63; External bushing-631; Neck bush-632; Folder cylinder group-64; Axle center-641 fixed by collet chuck; Collet chuck fixed cover-642; Lining-643; Main shaft collet chuck-645; Axle center belt pulley-65; Belt-651; Encoder-652; Positioning Gear-653; Gripper shoe-66; Main shaft oil cylinder pressure-67; Oil return cover-68; Chuck detector-681;

Biaxially main shaft tool rest-70; Z axis pedestal-71; Z axis screw rod holder-72; Z axis slide-73; Z axis screw rod-731; Screw belt wheel-732; Z axis servo motor-74; Fixed head-741; Motor belt pulley-742; Belt-743; Y-axis pedestal-75; Y-axis screw rod holder-751; Y-axis screw rod-76; Screw belt wheel-761; Y-axis slide-77; Y-axis servo motor-78; Fixed head-781; Motor belt pulley-782; Belt-783; Lock tool rest-79;

Biaxially comb formula tool rest-80; Z axis slide-81; Z axis servo motor-810; Z axis screw rod-811; Extensible cover-82; X-axis pedestal-83; X-axis screw rod holder-831; X-axis screw rod-84; X-axis slide-85; X-axis servo motor-86; Shaft coupling-861; Comb formula lock tool rest-88;

Work piece-90.

Detailed description of the invention

The utility model provides a kind of computer lathe multitool lazy-tongs, the figure that encloses illustrates in specific embodiment of the utility model and component thereof, with rear, left and right, top and bottom, top and bottom and level and vertical reference before all about, only for being conveniently described, and unrestricted the utility model, also non-its component is limited to any position or direction in space.

And about the formation of the utility model computer lathe multitool lazy-tongs, as Fig. 3, shown in Fig. 4 and Fig. 5, it is provided with a main shaft group 60 in a board 50, at least one biaxially main shaft tool rest 70 and one biaxially comb formula tool rest 80, the utility model with three groups biaxially main shaft tool rest 70 for main embodiment, and respectively this biaxially main shaft tool rest 70 be located in this main shaft group 60 respectively, respectively this biaxially main shaft tool rest 70 relative main group 60 can produce the displacement of Y-axis and Z axis, and this biaxially comb formula tool rest 80 be located at the front of main shaft group 60, and this biaxially comb formula tool rest 80 displacement of Z axis and X-axis can be produced by relative main group 60 work piece.

And the detailed formation of described main shaft group 60, then referring to Fig. 4, shown in Fig. 5 and Fig. 6, this main shaft group 60 has a spindle drum 61, and main shaft group 60 utilizes a fixed head 620 to lock in board 50 is provided with a Spindle Motor 62, the output shaft of this Spindle Motor 62 has a motor belt pulley 621, again aforementioned spindle drum 61 utilize an external bushing 631 and a neck bush 632 to be pivoted with a spindle axis 63, and one end of the corresponding front of spindle axis 63 biaxially comb formula tool rest 80 is provided with a folder cylinder group 64, this folder cylinder group 64 includes a collet chuck and fixes axle center 641, one collet chuck fixed cover 642, one lining 643 and a main shaft collet chuck 645, selective property presss from both sides a work piece 90 of pulling, and can by spindle axis 63 high-speed driving, and spindle axis 63 other end is provided with an axle center belt pulley 65, for utilizing the corresponding ring of a belt 651 to establish aforesaid motor belt pulley 621, make Spindle Motor 62 can synchronous drive shaft axle center 63 High Rotation Speed, again spindle axis 63 is separately provided with encoder 652 and a Positioning Gear 653, for the rotary speed calculating spindle axis 63, another spindle drum 61 utilizes a gripper shoe 66 to be provided with a main shaft oil cylinder pressure 67 in spindle axis 63 rear end, and main shaft oil cylinder pressure 67 is arranged with the oil return cover 68 of a tool chuck detector 681, this main shaft oil cylinder pressure 67 can for the folder cylinder group 64 of start spindle axis 63 other end, pull for the selective folder of start folder cylinder group 64 or discharge work piece 90.

The detailed formation of biaxially main shaft tool rest 70 described again, then referring to Fig. 4, shown in Fig. 5 and Fig. 7, the utility model with three groups biaxially main shaft tool rest 70 for main embodiment, respectively this biaxially main shaft tool rest 70 have one respectively and can lock the Z axis pedestal 71 of pulling in aforementioned spindle drum 61 Different Plane, and mutually do not interfere, Z axis pedestal 71 rear end lock is provided with a Z axis screw rod holder 72 again, and Z axis pedestal 71 is slidably equipped with the Z axis slide 73 of a corresponding Z axis screw rod holder 72, moreover be provided with a Z axis screw rod 731 between Z axis slide 73 and Z axis screw rod holder 72, and one end that this Z axis screw rod 731 passes Z axis screw rod holder 72 is provided with a screw belt wheel 732, again Z axis screw rod holder 72 utilizes fixed head 741 to lock and be provided with a Z axis servo motor 74, this Z axis servo motor 74 has the motor belt pulley 742 of a corresponding screw belt wheel 732, for utilizing the corresponding ring of a belt 743 to establish, Z axis servo motor 74 is made can synchronously to drive Z axis screw rod 731 to rotate, with the displacement driving the relative Z axis pedestal 71 of Z axis slide 73 to produce Z-axis direction, moreover one end that Z axis slide 73 differs from Z axis screw rod holder 72 has a Y-axis pedestal 75, this Y-axis pedestal 75 inside is slidably equipped with a Y-axis screw rod holder 751, a Y-axis screw rod 76 is provided with between another Y-axis pedestal 75 and Y-axis screw rod holder 751, and Y-axis pedestal 75 leading flank is slidably equipped with the Y-axis slide 77 that a lock is pulled on this Y-axis screw rod holder 751, one end that this Y-axis screw rod 76 aforementioned passes Y-axis pedestal 75 is again provided with a screw belt wheel 761, again Y-axis pedestal 75 utilizes fixed head 781 to lock and be provided with a Y-axis servo motor 78, this Y-axis servo motor 78 has the motor belt pulley 782 of a corresponding screw belt wheel 761, for utilizing the corresponding ring of a belt 783 to establish, Y-axis servo motor 78 is made can synchronously to drive Y-axis screw rod 76 to rotate, with the displacement being driven the relative Y-axis pedestal 75 of Y-axis slide 77 to produce Y-axis by Y-axis screw rod holder 751, and this Y-axis slide 77 leading flank bottom is provided with a lock tool rest 79, respectively the lock tool rest 79 of this biaxially main shaft tool rest 70 can establish a cutter 100 for selective lock respectively, respectively this biaxially main shaft tool rest 70 cutter 100 and the work piece 90 of synchronous relative main group 60 can produce the displacement of Y-axis and Z axis, for the different size external diameter of synchronous processing work piece 90.

As for the detailed formation of described biaxially comb formula tool rest 80, then referring to Fig. 4, shown in Fig. 5 and Fig. 8, this biaxially comb formula tool rest 80 on aforementioned board 50, be slidably equipped with a Z axis slide 81, this Z axis slide 81 utilizes the Z axis servo motor 810(of a tool Z axis screw rod 811 as shown in Figure 4), and board 50 is provided with the extensible cover 82 that can cover Z axis servo motor 810 and Z axis screw rod 811, Z axis servo motor 810 is made to drive the relative board 50 of Z axis slide 81 to produce the displacement of Z-axis direction by Z axis screw rod, moreover one end that this Z axis slide 81 differs from extensible cover 82 has an X-axis pedestal 83, this X-axis pedestal 83 inside is slidably equipped with an X-axis screw rod holder 831, an X-axis screw rod 84 is provided with between another X-axis pedestal 83 and X-axis screw rod holder 831, and X-axis pedestal 83 end face is slidably equipped with the X-axis slide 85 that a lock is pulled on this X-axis screw rod holder 831, one end that this X-axis screw rod 84 aforementioned passes X-axis pedestal 83 is again provided with an X-axis servo motor 86, this X-axis servo motor 86 utilizes a shaft coupling 861 to link with X-axis screw rod 84, X-axis servo motor 86 is made can synchronously to drive X-axis screw rod 84 to rotate, and drive the relative X-axis pedestal 83 of X-axis slide 85 to produce the displacement of X axis by X-axis screw rod holder 831, and these X-axis slide 85 end face central authorities are provided with a comb formula lock tool rest 88, the comb formula lock tool rest 88 of this biaxially comb formula tool rest 80 can establish at least one cutter 150 for selective lock respectively, make respectively this cutter 150 of this biaxially comb formula tool rest 80 can produce the displacement of X-axis and Z axis respectively to the work piece 90 of main shaft group 60, for carrying out external diameter, internal diameter turning and Drilling operation,

Therefore, the work piece 90 of each this biaxially synchronous relative main group 60 of cutter 100 of main shaft tool rest 70 of order carries out the external diameter processing of Y-axis and Z axis, and make respectively this cutter 150 of this biaxially comb formula tool rest 80 respectively work piece 90 be carried out to external diameter, the processing such as internal diameter turning and boring of X-axis and Z axis, and organize formation one and can improve working (machining) efficiency and the good computer lathe multitool lazy-tongs of practicality.

And computer lathe multitool lazy-tongs of the present utility model are when practical application, then as shown in Fig. 3, Fig. 4 and Fig. 5, in operation, utilize the folder cylinder group 64 of the main shaft oil cylinder pressure 67 start spindle axis 63 of main shaft group 60 to press from both sides the work piece 90 of pulling for processing, and drive this spindle axis 63 to drive folder cylinder group 64 and work piece 90 High Rotation Speed by Spindle Motor 62.

Then, and by computer program respectively or synchronously drive respectively this biaxially main shaft tool rest 70, make respectively this biaxially main shaft tool rest 70 Z axis servo motor 74 or Y-axis servo motor 78 can be utilized to drive Z axis slide 73 or Y-axis slide 77 respectively, and can cutter 100 on the lock tool rest 79 of start this Y-axis slide 77 relatively work piece 90 produce the displacement of Y-axis or Z-axis direction, make respectively this biaxially main shaft tool rest 70 cutter 100 can respectively or locking phase the external diameter processing of Y-axis and Z axis is carried out to work piece 90.

Moreover, this biaxially comb formula tool rest 80 also can with respectively this biaxially main shaft tool rest 70 is respectively or same time effect, its make this biaxially comb formula tool rest 80 Z axis servo motor 810 or X-axis servo motor 86 can be utilized to drive Z axis slide 81 or X-axis slide 85 respectively, and can respectively this cutter 150 on the comb formula lock tool rest 88 of start this X-axis slide 85 respectively relative work piece 90 produce the displacement of Z-axis direction or X axis, make this biaxially comb formula tool rest 80 cutter 150 can respectively relatively work piece 90 carry out the processing such as the external diameter of Z axis and X-axis, internal diameter turning or boring.

Via aforesaid structural design and action specification known, computer lathe multitool lazy-tongs of the present utility model can utilize respectively this characteristic that biaxially main shaft tool rest 70 is non-interference, and respectively the cutter 100 of this biaxially main shaft tool rest 70 can work piece 90 in relative main group 60, the external diameter carrying out Z-axis direction and Y-axis is at one time processed, and the same time also can utilize the work piece 90 in the cutter 150 relative main group 60 of biaxially comb formula tool rest 80, respectively or carry out the processing of Z-axis direction and X axis at one time, and external diameter can be carried out, the processing such as internal diameter turning and boring, computer lathe multitool lazy-tongs of the present utility model are put at one time and can use at least two cutters 100, 150, not only increase number of cutters, more can greatly reduce process time and change the cutter time, effective raising working (machining) efficiency, increase its practicality, and its surcharge can be improved.

The above; be only preferred embodiment of the present utility model; not thereby scope of patent protection of the present utility model is limited, therefore the equalization change of such as using the utility model description and accompanying drawing to do and modification, be all protection domain of the present utility model and contain.

Claims

1. computer lathe multitool lazy-tongs, is characterized in that, include:

One board;

2. computer lathe multitool lazy-tongs as claimed in claim 1, it is characterized in that, the Spindle Motor of this main shaft group is locked on this board by a fixed head, and the output shaft of this Spindle Motor has a motor belt pulley, and this spindle axis is provided with the axle center belt pulley of a correspondence, and established by the relative ring of a belt, and this Spindle Motor synchronously can drive this spindle axis High Rotation Speed, and this spindle axis is separately provided with an encoder and a Positioning Gear, and this main shaft oil cylinder pressure is arranged with the oil return cover of a tool chuck detector.

3. computer lathe multitool lazy-tongs as claimed in claim 1, it is characterized in that, the spindle drum of this main shaft group is locked and is provided with three groups of biaxially main shaft tool rests, and the cutter of this biaxially main shaft tool rest is non-interference.

4. the computer lathe multitool lazy-tongs as described in claim 1 or 3, it is characterized in that, this biaxially main shaft tool rest Z axis pedestal rear end lock be provided with a Z axis screw rod holder, and one end that this Z axis screw rod passes this Z axis screw rod holder is provided with a screw belt wheel, and this Z axis screw rod holder establishes this Z axis servo motor by a fixed head lock, and this Z axis servo motor have a pair should screw belt wheel motor belt pulley, and established by the corresponding ring of a belt, and this Z axis servo motor can synchronously drive Z axis screw rod to rotate, and this Y-axis pedestal is positioned at one end that this Z axis slide differs from Z axis screw rod holder, this Y-axis base interior is slidably equipped with a Y-axis screw rod holder, and this Y-axis screw rod is located between this Y-axis pedestal and this Y-axis screw rod holder, and this Y-axis slide is locked on this Y-axis screw rod holder, and one end that this Y-axis screw rod passes this Y-axis pedestal is provided with a screw belt wheel, and this Y-axis servo motor is locked on this Y-axis pedestal by a fixed head, this Y-axis servo motor have a pair should screw belt wheel motor belt pulley, and established by the corresponding ring of a belt, and this Y-axis servo motor drives the relative Y-axis pedestal of this Y-axis slide to produce the displacement of Y-axis by this Y-axis screw drive Y-axis screw rod holder.

5. computer lathe multitool lazy-tongs as claimed in claim 1, it is characterized in that, this biaxially comb formula tool rest be provided with in this board the extensible cover that can cover this Z axis servo motor and this Z axis screw rod, and this X-axis base interior is slidably equipped with an X-axis screw rod holder, and this X-axis screw rod is located between this X-axis pedestal and this X-axis screw rod holder, and this X-axis slide is locked on this X-axis screw rod holder, and this X-axis servo motor is linked by a shaft coupling and this X-axis screw rod.