CN205129114U - Six soldering tin robots - Google Patents

Abstract

This scheme provides a six-axis soldering robot, including a frame (1), an X-axis assembly (2), a Y-axis assembly (3), a ZR-axis assembly (4) and a soldering tin head (5), and a ZR-axis assembly (4 ) comprises an R shaft (4-1) and a synchronous pulley (4-2) fixed at the lower end of the R shaft (4-1), and the synchronous pulley (4-2) surrounds the R shaft (4 -1) Rotation, also includes: M-axis assembly (6) and N-axis assembly (7), M-axis (6-1) is perpendicular to R-axis (4-1), and N-axis (7-1) is respectively connected to the The R axis (4-1) is perpendicular to the M axis (6-1). The robot adds R-axis, M-axis and N-axis components on the basis of the existing X-axis, Y-axis and Z-axis components, so that the solder tip connected to the N-axis component can freely rotate at multiple angles in space , to realize the six-axis free movement of the solder tin head, which can meet a variety of different welding requirements, and overcome the problem of inapplicability due to different welding products.

Description

Six axle tin soldering robots

Technical field

The utility model relates to six axiation technical fields, is specifically related to a kind of six axle tin soldering robots.

Background technology

Six axle tin soldering robots are a kind of special machine people that can replace the manual welding manually carrying out straight cutting original paper, six current axle tin soldering robots or six axle tin soldering machines are 3 axles or 4 axle forms substantially, 3 general axles include X, Y, Z tri-rectangular axes, enable tin soldering machine at XYZ tri-axle linear motion, six axle tin soldering robots of 4 axle forms also comprise the rotating shaft R axle in a flatiron direction, and by manual setting flatiron attitude, therefore, often change a collection of welding product and will readjust the flatiron attitude of tin soldering machine by hand to meet scolding tin demand.

Existing tin soldering robot is in the process of welding, when solder horn moves to after tin-soldering working position puts and carry out scolding tin, can rise to move to next tin-soldering working position and put, therefore when carrying out the welding of large batch of same level operating position, the space that Universal arm or up-down mechanism need when driving solder horn work is larger, move dumb, especially for the welding product that degree of precision requires, be difficult to the exact posture controlling solder horn, in addition, because modern factories needs the product category of welding various, specification is different, therefore, simple 3 axles or 4 axle welding robots can not meet the demand of welding product wide variety, welding industry is produced and is subject to certain limitation.

Utility model content

For overcoming above-mentioned technical problem, the disclosure provides a kind of six axle tin soldering robots.

A kind of six axle tin soldering robots, comprise frame, X-axis assembly, Y-axis assembly, ZR shaft assembly and scolding tin tin head, it is characterized in that, ZR shaft assembly comprises R axle and is fixed on the synchronous pulley of lower end of described R axle, and described synchronous pulley rotates around described R axle;

Wherein, described robot also comprises: M shaft assembly and N shaft assembly, and wherein, M shaft assembly comprises M axle and M axle fixture, wherein, M axle is vertical with R axle, and M shaft assembly is fixed on the bottom of R axle by M axle fixture, and N shaft assembly comprises N axle and N axle fixture, N axle respectively with described R axle and described M axle perpendicular, and N shaft assembly is connected with M shaft assembly by N axle fixture, N shaft assembly rotates around M axle, and described scolding tin tin head is connected with the N axle of N shaft assembly.

Preferably, described ZR shaft assembly also comprises R axle synchronous pulley, ZR axis fixing plate, R spindle motor and Timing Belt, wherein, R spindle motor is fixed on ZR axis fixing plate, R axle synchronous pulley is arranged on the bottom of R spindle motor, synchronous pulley is through R axle and with R axle synchronous pulley in same level position, described synchronous pulley is connected by Timing Belt with R axle synchronous pulley.

Preferably, described M shaft assembly also comprises the first housing, the first snail, the first worm gear and M spindle motor, wherein, M axle fixture is fixed on the upper end of the first housing, the first worm screw and the first worm gear is provided with in first housing, one end of first worm screw is connected with M spindle motor, and M axle passes the first worm gear and connects with described first worm gear, and the first worm screw drives the first worm gear wheel by M spindle motor.

Preferably, described M axle fixture comprises the first groove, the second groove and M axle screw, and wherein, the first groove is connected by M axle screw with the second groove, first groove is connected with the second groove formation circular cavity, and diameter and the R shaft diameter size of described circular cavity match.

Preferably, described N shaft assembly also comprises the second housing, the second worm screw, the second worm gear and N spindle motor, wherein, N axle fixture is fixed on the upper end of the second housing, the second worm screw and the second worm gear is provided with in second housing, one end of second worm screw is connected with N spindle motor, and N axle passes the second worm gear and connects with described second worm gear, and the second worm screw drives the second worm gear wheel by N spindle motor.

Preferably, described frame is made up of two side stand components and the crossbeam be positioned on described two side stand components, and wherein, described X-axis assembly comprises sliding support, described Y-axis assembly comprises sliding panel, and Y-axis assembly is connected by sliding panel and is connected with the sliding support on X-axis assembly.

Preferably, described robot also comprises electric cabinet and inductive switch, wherein X-axis assembly, Y-axis assembly, ZR shaft assembly, M shaft assembly and N shaft assembly are respectively provided with a described inductive switch, and each described inductive switch is connected with electric cabinet 8.

Preferably, described robot also comprises temperature control assembly and send tin component, and described temperature control assembly is connected with electric cabinet respectively with the described tin component that send, and send tin component to send tin described in described electric cabinet controls according to the temperature of the soldered thing of temperature control component detection.

Preferably, described electric cabinet comprises electric-controlled switch, electric controller, power line and memory, wherein, electric cabinet is powered by power line, electric-controlled switch controls electric controller and opens and turn off, and memory stores the welding procedure of different welding thing, welding parameter and welding instruction.

Preferably, described robot also comprises CCD camera assembly, and wherein, described CCD camera assembly comprises camera link and camera, and wherein camera link is connected on described ZR axis fixing plate, and described camera is arranged on described camera link.

The technical scheme that embodiment of the present disclosure provides can comprise following beneficial effect:

This programme provides a kind of six axle tin soldering robots, the basis of original X-axis, Y-axis, Z axis assembly adds R axle, M axle and N shaft assembly, and N axle is respectively perpendicular to R axle, M axle, make the scolding tin tin head be connected with this N shaft assembly can realize Multi-angle free in space to rotate, R axle, M axle or N shaft assembly drive scolding tin tin head freely movable among a small circle, save activity space, and six axles achieving scolding tin tin head are freely movable, multiple different welding requirements can be met, overcome inapplicable problem due to the product difference of welding.

In the six axle tin soldering robots that this programme provides, ZR shaft assembly realizes synchronous pulley by Timing Belt and horizontally rotates around R axle, and synchronous pulley and R axle synchronous pulley are arranged on same level position, ensure in R direction of principal axis smooth rotation.

In the six axle tin soldering robots that this programme provides, the assembly of each axle is connected with progressive motor, also worm and worm wheel are comprised in M shaft assembly and N shaft assembly, worm screw is driven by motor, make worm screw drive coupled worm gear, worm gear wheel makes to rotate motion with worm gear connecting axle or assembly.The motor that each assembly is installed can drive coupled assembly, to realize automatic motor function.

In the six axle tin soldering robots that this programme provides, the circular cavity of M axle fixture in M shaft assembly, and mate with the diameter of R axle, therefore, it is possible to be connected with R axle, and by the screw fastening on M axle fixture, ensure the stability of syndeton.

In the six axle tin soldering robots that this programme provides, X-axis assembly is arranged on the crossbeam of frame, Y-axis assembly is connected with X-axis assembly by fixed head, because Y-axis assembly is positioned on X-axis assembly, one end of Y-axis assembly connects ZR shaft assembly, in the reservation operations space, lower end of ZR shaft assembly, change operating space and can coordinate production line, enable in the environment of robot application online production, avoiding existing robot due to Y-axis assembly is arranged on operating table surface, occupy the segment space of solder horn, therefore can not be used in the middle of factory lines production.

In the six axle tin soldering robots that this programme provides, also comprise electric cabinet and inductive switch, matched with inductive switch by electric cabinet, make six axle tin soldering robots can locate scolding tin attitude accurately, improve welding quality.In addition, then coordinate M shaft assembly and N shaft assembly movable among a small circle, the adjustment of scolding tin attitude angle flexibly and fast, further increases scolding tin efficiency.

In the six axle tin soldering robots that this programme provides, also comprise temperature control assembly and send tin component, and temperature control assembly with send tin component and be connected with electric cabinet respectively, electric cabinet can according to the temperature of the soldered thing of temperature control component detection, the speed that control send tin component to send tin and Xi Si thickness, further increase accuracy and the welding quality of scolding tin.

In the six axle tin soldering robots that this programme provides, electric cabinet comprises electric-controlled switch, electric controller, power line and memory, wherein, memory can store the welding procedure of different welding thing or welding product, welding parameter and welding instruction etc., the six axle tin soldering robots that memory makes the application provide have memory function, and according to electric controller send instruction six axial adjustment scolding tin attitude and scolding tin order, compare and greatly improve with the attitude accuracy of existing manual adjustments solder horn, and save time, the production requirement of different welding product can be applicable to, applicability is strong.

In the six axle tin soldering robots that this programme provides, also comprise CCD camera assembly, the camera in this CCD camera assembly can monitor pad in the moment, play the effect of calibration welding position, further increase welding precision, improve welding efficiency, save manual verification process, save production cost.

Accompanying drawing explanation

Accompanying drawing to be herein merged in description and to form the part of this description, shows and meets embodiment of the present utility model, and is used from description one and explains principle of the present utility model.

Fig. 1 is the structure chart that an embodiment illustrates a kind of six axle tin soldering robots;

Fig. 2 is the partial enlarged drawing of a kind of six axle tin soldering robots shown in an embodiment;

Fig. 3 is the structure chart of the ZR shaft assembly shown in an embodiment;

Fig. 4 is the structure chart of the another kind of ZR shaft assembly shown in an embodiment;

Fig. 5 is the overall structure figure of a kind of M shaft assembly shown in an embodiment;

Fig. 6 is the cut-away view of a kind of M shaft assembly shown in an embodiment;

Fig. 7 is the front view of the illustrative a kind of M shaft assembly of an enforcement;

Fig. 8 is the overall structure figure of a kind of N shaft assembly in an embodiment;

Fig. 9 is the cut-away view that an embodiment illustrates a kind of N shaft assembly;

Figure 10 is the cut-away view of a kind of N shaft assembly shown in an embodiment;

Figure 11 is the decomposition chart of a kind of X-axis assembly shown in an embodiment and Y-axis assembly;

Figure 12 is the structure chart that another embodiment illustrates another kind of six axle tin soldering robots.

Detailed description of the invention

Here will be described exemplary embodiment in detail, its sample table shows in the accompanying drawings.When description below relates to accompanying drawing, unless otherwise indicated, the same numbers in different accompanying drawing represents same or analogous key element.Embodiment described in following exemplary embodiment does not represent all embodiments consistent with the utility model.On the contrary, they only with as in appended claims describe in detail, the example of robot that aspects more of the present utility model are consistent and method.

As shown in figs 1-9, for a kind of six axle tin soldering robots, comprise frame 1, X-axis assembly 2, Y-axis assembly 3, ZR shaft assembly 4 and scolding tin tin head 5, it is characterized in that, ZR shaft assembly 4 comprises R axle 4-1 and is fixed on the synchronous pulley 4-2 of lower end of described R axle 4-1, and described synchronous pulley 4-2 rotates around described R axle 4-1;

Figure 2 shows that the partial enlarged drawing of six axle tin soldering robots, described in this six axles tin soldering robot, robot also comprises: M shaft assembly 6 and N shaft assembly 7, wherein, M shaft assembly 6 comprises M axle 6-1 and M axle fixture 6-2, wherein, M axle 6-1 is vertical with R axle 4-1, M shaft assembly 6 is fixed on the bottom of R axle 4-1 by M axle fixture 6-2, N shaft assembly 7 comprises N axle 7-1 and N axle fixture 7-2, N axle 7-1 is perpendicular with described R axle 4-1 and described M axle 6-1 respectively, and N shaft assembly 7 is connected with M shaft assembly 6 by N axle fixture 7-2, N shaft assembly 7 rotates around M axle 6-1, described scolding tin tin head 5 is connected with the N axle 7-1 of N shaft assembly 7.

The frame 1 of the tin soldering robot that the present embodiment provides is provided with X-axis assembly 2, and Y-axis assembly 3 is arranged on X-axis assembly 2, can X-axis activity in the horizontal direction by the first slideway on X-axis assembly 2; Y-axis assembly 3 can in Y direction activity by the second slideway, and ZR shaft assembly 4 upper end is provided with Z axis synchronous pulley 4-8 and Z axis Timing Belt 4-7 and the Z axis of ZR shaft assembly 4 can be driven to do move both vertically up and down; Synchronous pulley 4-2 is fixed on the lower end of R axle 4-1, can rotate, realize the 4th axle rotary moveable around R axle 4-1; M shaft assembly 6 is fixed on the bottom of ZR shaft assembly 4, and realizes the rotary moveable of the 5th axle by the M axle 6-1 vertical with R axle 4-1; N shaft assembly 7 is connected with M shaft assembly 6 by N axle fixture 7-2, and by realizing the rotary moveable of the 6th axis with R axle 4-1 and M axle 6-1 perpendicular N axle 7-1 respectively, one end of last N axle 7-1 is connected with scolding tin tin head 5, and then drives scolding tin tin head 5 staying an axially activity.

This programme provides a kind of six axle tin soldering robots, the basis of original X-axis, Y-axis, Z axis assembly adds R axle, M axle and N shaft assembly, and N axle is respectively perpendicular to R axle, M axle, make the scolding tin tin head be connected with this N shaft assembly can realize Multi-angle free in space to rotate, R axle, M axle or N shaft assembly drive scolding tin tin head freely movable among a small circle, save activity space, and six axles achieving scolding tin tin head are freely movable, multiple different welding requirements can be met, overcome inapplicable problem due to the product difference of welding.

In one embodiment, as shown in Figure 3 and Figure 4, the six axle tin soldering robots that above-described embodiment provides are at the partial enlarged drawing of ZR shaft assembly, wherein, described ZR shaft assembly 4 also comprises R axle synchronous pulley 4-3, ZR axis fixing plate 4-4, R spindle motor 4-5 and Timing Belt 4-6, wherein, R spindle motor 4-5 is fixed on ZR axis fixing plate 4-4, R axle synchronous pulley 4-3 is arranged on the bottom of R spindle motor 4-5, synchronous pulley 4-2 is through R axle 4-1 and with R axle synchronous pulley 4-3 in same level position, described synchronous pulley 4-2 is connected by Timing Belt 4-6 with R axle synchronous pulley 4-3.

In the six axle tin soldering robots that the present embodiment provides, ZR shaft assembly realizes synchronous pulley by Timing Belt and horizontally rotates around R axle, and synchronous pulley and R axle synchronous pulley are arranged on same level position, ensure in R direction of principal axis smooth rotation.

In ZR shaft assembly, as shown in Figures 3 and 4, also comprise bearing block, ZR spindle motor fixed head, R spindle motor 4-5, R axle synchronous pulley 4-3 and Timing Belt 4-6, wherein, bearing block is arranged on synchronous pulley 4-2 upper end through R axle 4-1, R spindle motor 4-5 is fixed on bearing block by R spindle motor fixed head, and R axle synchronous pulley 4-3 is connected with R spindle motor 4-5, and R axle synchronous pulley 4-3 is connected with synchronous pulley 4-2 by Timing Belt 4-6.

As shown in Figure 3, in ZR shaft assembly 4, synchronous pulley 4-2 is fixed on R axle 4-1 by deep groove ball bearing 60074-13, deep groove ball bearing 60074-13 is connected with bearing block 4-3 by screw bolt and nut, R spindle motor 4-5 drives R axle synchronous pulley 4-3 to rotate, R axle synchronous pulley 4-3 drives synchronous pulley 4-2 to rotate by Timing Belt 4-6, and then makes synchronous pulley 4-2 drive R axle 4-1 to rotate, and the M shaft assembly 6 be connected with R axle 4-1 bottom is also along with rotation.

In addition, wherein ZR axle also assembly comprise: the tight jam plate 4-10 of bearing, ball screw spiral shell screw rod 4-12, deep groove ball bearing (6007) 4-13, R spindle motor fixed head 4-14, axis of guide 4-15, linear bearing 4-16, bearing plate 4-17, ZR axle panel beating cover 4-18, bearing block and connect the screw bolt and nut of Z axis each assembly, and other is connected and fixed the part of ZR shaft assembly, be as the criterion with the assembly shown in Fig. 3 and Fig. 4, will not enumerate at this.

Wherein, the annexation of each part in each ZR shaft assembly shown, Z axis synchronous pulley 4-8 connects Z axis Timing Belt 4-7, Z axis progress motor 4-9 is fixed on ZR bracing strut, and be positioned at the lower end of Z axis synchronous pulley 4-8, wherein Z axis synchronous pulley 4-8 comprises small one and large one two wheels, one end of described bull wheel is connected with Z axis progress motor 4-9, the lower end of described steamboat is connected with ball screw spiral shell screw rod 4-12 by bolt, ball screw nut or Bob Lanier 4-11, and is fixed on bearing block 4-3.When this six axles tin soldering robot starts, Z axis synchronous pulley 4-8 drives axis of guide 4-15 and ball screw spiral shell screw rod 4-12 to do by Z axis Timing Belt 4-7 and moves both vertically up and down, make the scolding tin tin head be connected with described R axle 4-1 can do upper and lower vertical motion in Z-direction perpendicular to horizontal plane.

In another embodiment, as illustrated in figs. 5-7, for the structural representation of M shaft assembly 6, described M shaft assembly 6 also comprises the first housing 6-3, the first worm screw 6-4, the first worm gear 6-5 and M spindle motor 6-6, wherein, M axle fixture 6-2 is fixed on the upper end of the first housing 6-3, the first worm screw 6-4 and the first worm gear 6-5 is provided with in first housing 6-3, one end of first worm screw 6-4 is connected with M spindle motor 6-6, M axle 6-1 passes the first worm gear 6-5 and connects with described first worm gear 6-5, and the first worm screw 6-4 drives the first worm gear 6-5 to rotate by M spindle motor 6-6.

Described first worm screw 6-4 is connected by engaged sawtooth with between the first worm gear 6-5, drives the first worm gear 6-5 also along with rotation when the first worm screw 6-4 rotates.When spindle motor 6-6 starts, M spindle motor 6-6 drives the first worm screw 6-4 and the first worm gear 6-5 movable, and M axle 6-1, through the center of circle of the first worm gear 6-5, when the first worm gear 6-5 rotates, M axle 6-1 can be driven to rotate together, and M axle 6-1 is perpendicular to R axle 4-1.

Preferably, described M spindle motor is progressive motor.

In the six axle tin soldering robots that this programme provides, the assembly of M axle is connected with M axle progress motor, drives worm screw by motor, makes the first worm screw drive the first coupled worm gear, and the first worm gear wheel makes the N axle be connected with the first worm gear rotate motion.By the progressive motor installed at M shaft assembly, and then coupled assembly can be driven, to realize automatic motor function.In addition, it is movable among a small circle on M axle that M shaft assembly also achieves tin soldering robot, adds the flexibility of robot.

Described M axle fixture 6-2 comprises the first groove 6-21, second groove 6-22 and M axle 6-23 screw, wherein, first groove 6-21 is connected by M axle screw 6-23 with the second groove 6-22, first groove 6-21 is connected with the second groove 6-22 formation circular cavity, diameter and the R axle 4-1 diameter of described circular cavity match, make the bottom of R axle 4-1 just in time can pass this circular hole, M axle fixture 6-2 also comprises several screw and nuts, described screw and nut is used for fastening R axle 4-1, M shaft assembly is connected with ZR shaft assembly, on the other hand, this screw and nut is also for being fixed on the first housing 6-3 by M axle fixture 6-2.

In the present embodiment, the circular cavity of M axle fixture in M shaft assembly, and mate with the diameter of R axle, therefore, it is possible to be connected with R axle, and fastening by the screw-nut on M axle fixture, ensure the stability of syndeton.

As seen in figs. 8-10, for the structural representation of N shaft assembly 7, wherein said N shaft assembly 7 also comprises the second housing 7-3, the second worm gear 7-5, the second worm screw 7-4 and N spindle motor 7-6, wherein, the second worm gear 7-5 and the second worm screw 7-4 is provided with in second housing 7-3, one end of described second worm gear 7-4 is connected by connecting axle 7-7 with N spindle motor 7-6, this N spindle motor 7-6 rotates for driving the second scroll bar 7-4, second scroll bar 7-4 and the second worm gear 7-5 are engaged by sawtooth and connect, and N spindle motor 7-6 is fixed on the outside of the second housing 7-3.N axle 7-1 is through the center of circle of the second worm gear 7-5, second worm screw 7-4 and the second worm gear 7-5 is respectively equipped with concavo-convex sawtooth, and the second worm screw 7-4 is connected by described concavo-convex sawtooth with the second worm gear 7-5, N spindle motor 7-6 is fixed on the outside of the second housing 7-3 by N spindle motor holder, and N axle fixture 7-2 is arranged on the upper end of the second housing 7-3.

Similar to the M axle fixture 6-2 in M shaft assembly 6, N axle fixture 7-2 mainly comprises two parts, as shown in Figure 9, comprise the 3rd groove 7-21 and the 4th groove 7-22, wherein the 3rd groove 7-21 is connected by some screw and nuts with the 4th groove 7-22, described 3rd groove 7-21 and the 4th groove 7-22 is semi-circular recesses, 3rd groove 7-21 is connected with the 4th groove 7-22 formation circular cavity, diameter and the M axle 6-1 diameter of described circular cavity match, make the bottom of M axle 6-1 just in time can pass this circular cavity, N axle fixture 7-2 also comprises several screw and nuts, described screw and nut is used for fastening M axle 6-1, N shaft assembly is connected with M shaft assembly, on the other hand, screw and nut is also for being fixed on the second housing 7-3 by N axle fixture 7-2.

In the present embodiment, the circular cavity of N axle fixture in N shaft assembly, and mate with the diameter of M axle, therefore, it is possible to be connected with M axle, and fastening by the screw-nut on N axle fixture, ensure the stability of syndeton.

In N shaft assembly, N spindle motor 7-6 drives the second worm screw 7-4 to rotate, second worm screw 7-4 connects with the second worm gear 7-5 sawtooth, therefore the second worm gear 7-5 is driven to rotate, contact due to N axle 7-1 and pass the second worm gear 7-5, therefore, when the second worm gear 7-5 rotates, N axle 7-1 can be driven to rotate, and then the scolding tin tin head 5 be connected with N axle 7-1 is rotated with the second worm gear 7-5.

In the embodiment of above-mentioned M shaft assembly and N shaft assembly, according to the interphase interaction of worm and gear, and worm and gear locking principle, be all drive worm gear wheel by worm screw, and do not drive worm screw to rotate by worm gear.

The 6th axle that N shaft assembly achieves this robot by the M axle 6-1 of M shaft assembly rotates, and scope of activities reduces further, make this robot just can complete the rotation of multi-angle in local by increase N shaft assembly and M shaft assembly, and then reduce existing robot owing to only having R axle, therefore scope of activities is large, movable inflexible shortcoming, in addition, because M axle and N axle moving rotary further reduce the scope of activities of robot, therefore, save activity space.

In conjunction with such as shown in Fig. 1 and Figure 11, Figure 11 is the decomposition texture schematic diagram of X-axis assembly 2 and Y-axis assembly 3, wherein, described frame 1 is made up of two side stand component 1-1 and the crossbeam 1-2 be positioned on described two side stand components, wherein, described X-axis assembly 2 comprises sliding support 2-1, and described Y-axis assembly 3 comprises sliding panel 3-1, and Y-axis assembly 3 is connected by sliding panel 3-1 and is connected with the sliding support 2-1 on X-axis assembly 2.

Particularly X-axis assembly also comprises: inductive switch, X-axis export connecting plate, spring washer, X-axis Timing Belt fixed head, X-axis Timing Belt, rectilinear orbit slide block, rectilinear orbit, X-axis Timing Belt connecting plate, progressive motor, driven seat, plain washer, some screw and nuts etc.Y-axis assembly is connected by the sliding support of sliding panel with X-axis assembly, and this sliding support is slided on rectilinear orbit by X-axis Timing Belt, X-axis synchronous pulley, and the movable part that can achieve this robot is movable in X-axis.

Similarly, described Y-axis assembly also comprises Y-axis protective cover oralia, Y-axis progress motor, standard spring washer, fixing reinforcement gusset, driven seat, Y-axis protective cover, Y-axis progress motor, Y-axis linear bearing slide block, Y-axis stretches out stiffener, Y-axis Timing Belt joins clamping plate, fixing reinforcement gusset 3-2, Y-axis synanche plate, Y-axis Timing Belt, Y-axis synchronous pulley, Y-axis holder, Y-axis line slideway, Y-axis protective cradle, some screw bolt and nut etc.Wherein, Y-axis assembly is connected with ZR shaft assembly by the fixing gusset 3-2 that strengthens, and it is freely movable in Y-axis that Y-axis assembly realizes ZR shaft assembly by Y-axis slide block and Y Timing Belt assembly.

Include but not limited to above-mentioned part in above-mentioned X-axis assembly and Y-axis assembly, other part that tin soldering robot can be made to slide in X-axis and Y-axis, be also included within this programme, example screw and nut if necessary etc.

X-axis assembly is arranged on the crossbeam of frame, Y-axis assembly is connected with X-axis assembly by fixed head, because Y-axis assembly is positioned on X-axis assembly, one end of Y-axis assembly connects ZR shaft assembly, and in the reservation operations space, lower end of ZR shaft assembly, changing operating space can coordinate production line, enable in the environment of robot application online production, avoid existing robot and be arranged on operating table surface due to Y-axis assembly, occupy the segment space of solder horn, therefore can not be used in the middle of factory lines production.

Preferably, as shown in figure 12, in another embodiment, scolding tin attitude is located more accurately for enabling tin soldering robot, described robot also comprises electric cabinet 8 and inductive switch, wherein X-axis assembly 2, Y-axis assembly 3, ZR shaft assembly 4, M shaft assembly 6 and N shaft assembly 7 are respectively provided with a described inductive switch, and each described inductive switch is connected with electric cabinet 8.

Particularly, each inductive switch also comprises support, inductor and sensing chip, wherein, Bracket setting in the side of M shaft assembly or N shaft assembly housing, for being connected with M shaft assembly or N shaft assembly; Inductor is fixing on the bracket, and sensing chip can be arranged on axle or other position.When sensing chip near inductor can the region of perception time, in the scope of inductor induction, the posture position of scolding tin tin head can be regulated in conjunction with electric cabinet, and then ensure that scolding tin position is accurate.

The six axle tin soldering robots provided in the present embodiment, are matched with inductive switch by electric cabinet, make six axle tin soldering robots can locate scolding tin attitude accurately, improve welding quality.In addition, then coordinate M shaft assembly and N shaft assembly movable among a small circle, the adjustment of scolding tin attitude angle flexibly and fast, further increases scolding tin efficiency.

Described robot also comprises temperature control assembly 9 and send tin component 10, and described temperature control assembly 9 is connected with electric cabinet 8 respectively with the described tin component 10 that send, and send tin component 10 to send tin described in the temperature control of the soldered thing that described electric cabinet 8 detects according to temperature control assembly 9.Specifically send the position of tin component can determine according to producing the actual needs installed.

The six axle tin soldering robots provided in the present embodiment, and temperature control assembly with send tin component and be connected with electric cabinet respectively, electric cabinet can according to the temperature of the soldered thing of temperature control component detection, the speed that control send tin component to send tin and Xi Si thickness, further increase accuracy and the welding quality of scolding tin.

Preferably, in above-mentioned tin soldering robot, described electric cabinet comprises electric-controlled switch, electric controller, power line and memory, wherein, electric cabinet is powered by power line, and electric-controlled switch is opened for controlling electric controller and turned off, and memory stores the welding procedure of different welding thing, welding parameter and welding instruction are that robot has memory function.

In the six axle tin soldering robots provided in the present embodiment, electric cabinet comprises electric-controlled switch, electric controller, power line and memory, wherein, memory can store the welding procedure of different welding thing or welding product, welding parameter and welding instruction etc., the six axle tin soldering robots that memory makes the application provide have memory function, and according to electric controller send instruction six axial adjustment scolding tin attitude and scolding tin order, compare and greatly improve with the attitude accuracy of existing manual adjustments solder horn, and save time, the production requirement of different welding product can be applicable to, applicability is strong.

Because memory can store the welding process flow of different products to be welded, then by input instruction, electric controller can control different welding products, meets different welding demands.In addition, six axle program scolding tin, overcome manually-operated error, improve the accuracy of welding, and production efficiency.

Preferably, in above-mentioned tin soldering robot, described robot also comprises CCD camera assembly 11, wherein, described CCD camera assembly comprises camera link and camera, and wherein camera link is connected on described ZR axis fixing plate, and described camera is arranged on described camera link.

Camera in this CCD camera assembly can monitor pad in the moment, plays the effect of calibration welding position, further increases welding precision, improve welding efficiency, saves manual verification process, saves production cost.

Those skilled in the art, at consideration description and after putting into practice utility model disclosed herein, will easily expect other embodiment of the present utility model.The application is intended to contain any modification of the present utility model, purposes or adaptations, and these modification, purposes or adaptations are followed general principle of the present utility model and comprised the undocumented common practise in the art of the disclosure or conventional techniques means.Description and embodiment are only regarded as exemplary, and true scope of the present utility model and spirit are pointed out by claim below.

Should be understood that, the utility model is not limited to precision architecture described above and illustrated in the accompanying drawings, and can carry out various amendment and change not departing from its scope.Scope of the present utility model is only limited by appended claim.

Claims (10)

1. A six-axis soldering robot, comprising a frame (1), an X-axis assembly (2), a Y-axis assembly (3), a ZR-axis assembly (4) and a soldering tin head (5), characterized in that the ZR-axis The assembly (4) includes an R shaft (4-1) and a synchronous pulley (4-2) fixed at the lower end of the R shaft (4-1), and the synchronous pulley (4-2) surrounds the R Axis (4-1) rotation; The robot also includes: an M-axis assembly (6) and an N-axis assembly (7), wherein the M-axis assembly (6) includes an M-axis (6-1) and an M-axis fixture (6-2), wherein the M The axis (6-1) is perpendicular to the R-axis (4-1), the M-axis assembly (6) is fixed on the bottom of the R-axis (4-1) through the M-axis fixture (6-2), and the N-axis assembly (7 ) includes an N-axis (7-1) and an N-axis fixture (7-2), and the N-axis (7-1) is perpendicular to the R-axis (4-1) and the M-axis (6-1) respectively , and the N-axis assembly (7) is connected with the M-axis assembly (6) through the N-axis fixture (7-2), the N-axis assembly (7) rotates around the M-axis (6-1), and the solder tin head ( 5) Connect with the N-axis (7-1) of the N-axis assembly (7). 2. robot according to claim 1, is characterized in that, described ZR shaft assembly (4) also comprises R shaft synchronous pulley (4-3), ZR shaft fixed plate (4-4), R shaft motor ( 4-5) and synchronous belt (4-6), wherein, the R axis motor (4-5) is fixed on the ZR axis fixed plate (4-4), and the R axis synchronous pulley (4-3) is arranged on the R axis At the bottom of the motor (4-5), the synchronous pulley (4-2) passes through the R axis (4-1) and is at the same horizontal position as the R axis synchronous pulley (4-3), and the synchronous pulley ( 4-2) is connected with the R-axis synchronous pulley (4-3) through the synchronous belt (4-6). 3. The robot according to claim 2, characterized in that, the M-axis assembly (6) further comprises a first housing (6-3), a first worm (6-4), a first worm wheel (6- 5) and the M-axis motor (6-6), wherein the M-axis fixing member (6-2) is fixed on the upper end of the first housing (6-3), and the first housing (6-3) is provided with a second A worm (6-4) and the first worm gear (6-5), one end of the first worm (6-4) is connected with the M-axis motor (6-6), and the M-axis (6-1) passes through the first The worm wheel (6-5) is connected to the first worm wheel (6-5), and the first worm (6-4) drives the first worm wheel (6-5) to rotate through the M-axis motor (6-6). 4. The robot according to claim 3, characterized in that, the M-axis fixture (6-2) comprises a first groove (6-21), a second groove (6-22) and an M-axis ( 6-23) screw, wherein, the first groove (6-21) and the second groove (6-22) are connected by the M axis screw (6-23), and the first groove (6-21) and the second groove The two grooves (6-22) are connected to form a circular cavity, and the diameter of the circular cavity matches the diameter of the R-axis (4-1). 5. The robot according to claim 4, characterized in that, the N-axis assembly (7) further comprises a second housing (7-3), a second worm (7-4), a second worm wheel (7- 5) and the N-axis motor (7-6), wherein the N-axis fixture (7-2) is fixed on the upper end of the second housing (7-3), and the second housing (7-3) is provided with a first Two worms (7-4) and the second worm gear (7-5), one end of the second worm (7-4) is connected with the N-axis motor (7-6), and the N-axis (7-1) passes through the second The worm wheel (7-5) is connected to the second worm wheel (7-5), and the second worm (7-4) drives the second worm wheel (7-5) to rotate through the N-axis motor (7-6). 6. The robot according to claim 5, characterized in that, the frame (1) consists of two side support frames (1-1) and a beam (1-2) positioned on the two side support frames composition, wherein the X-axis assembly (2) includes a sliding bracket (2-1), the Y-axis assembly (3) includes a sliding plate (3-1), and the Y-axis assembly (3) passes through the sliding plate (3- 1) Connect to the sliding bracket (2-1) on the X-axis assembly (2). 7. The robot according to claim 6, characterized in that, the robot also includes an electric control box (8) and an induction switch, wherein the X-axis assembly (2), the Y-axis assembly (3), the ZR-axis assembly (4 ), the M-axis assembly (6) and the N-axis assembly (7) are respectively provided with one said inductive switch, and each said inductive switch is connected with the electric control box (8). 8. The robot according to claim 7, characterized in that, the robot further comprises a temperature control assembly (9) and a tin feeding assembly (10), and the temperature control assembly (9) and the tin feeding assembly (10) ) are respectively connected with the electric control box (8), and the electric control box (8) controls the tin feeding assembly (10) to send tin according to the temperature of the object to be welded detected by the temperature control assembly (9). 9. The robot according to claim 8, wherein the electric control box includes an electric control switch, an electric controller, a power cord and a memory, wherein the electric control box is powered by the power cord, and the electric control switch controls the electric control The device is turned on and off, and the memory stores welding programs, welding parameters and welding instructions for different weld materials. 10. The robot according to any one of claims 2 to 9, characterized in that, the robot also includes a camera assembly (11), wherein the camera assembly includes a camera connection frame and a camera, wherein the camera connection frame is connected to On the ZR axis fixing plate, the camera is arranged on the camera connecting frame.