CN211053676U - Last guiding mechanism of triaxial manipulator - Google Patents

Abstract

The utility model provides an last guiding mechanism of triaxial manipulator belongs to electromechanical technical field. This manipulator includes third rocking arm and drive plate, first driving motor's casing, second driving motor's casing, third driving motor's casing is all fixed at the aircraft nose, the one end at first rocking arm is fixed to first pivot, guiding mechanism including setting up spout on the third rocking arm and setting on the drive plate with spout complex slide rail, equidistant a plurality of locating holes of having seted up on the slide rail, the slide rail bottom is provided with a clamp plate, the locating pin that has a plurality of and locating hole one-to-one on the clamp plate, the both ends of slide rail are overlapped respectively and are equipped with a sliding sleeve, the middle part of sliding sleeve has a kicking block, the kicking block can compress tightly the clamp plate and make the locating pin stretch out on the. The utility model has the advantages of convenient adjustment, firm fixation and the like.

Description

Last guiding mechanism of triaxial manipulator

Technical Field

The utility model belongs to the technical field of electromechanics, a guiding mechanism on triaxial manipulator is related to.

Background

On a PCB production line, the manipulator has wide application, and the manipulator is required to have a large control range under the condition that the installation end is fixed.

The existing three-axis manipulator generally adopts a mode that three motors respectively and directly control one axis, except a fixed end motor, other two motors occupy the load of the manipulator, so that the actual load is greatly reduced.

SUMMERY OF THE UTILITY MODEL

The utility model aims at the above-mentioned problem that exists to current technique, provide an adjustment mechanism on the triaxial manipulator, the utility model aims to solve the technical problem how realize that the adjustment is convenient, the adjustment after-fixing is firm.

The purpose of the utility model can be realized by the following technical proposal: the utility model provides an last guiding mechanism of triaxial manipulator, its characterized in that, this manipulator includes third rocking arm and drive plate, first driving motor's casing, second driving motor's casing, third driving motor's casing are all fixed at the aircraft nose, the one end at first rocking arm is fixed to first pivot, guiding mechanism including set up spout on the third rocking arm and set up on the drive plate with spout complex slide rail, equidistant a plurality of locating holes have been seted up on the slide rail, the slide rail bottom is provided with a clamp plate, the locating pin that has a plurality of and locating hole one-to-one on the clamp plate, the both ends of slide rail are overlapped respectively and are equipped with a sliding sleeve, the middle part of sliding sleeve has an kicking block, the kicking block can compress tightly the clamp plate and make the locating pin stretch out on the locating hole.

In fact, the direction perpendicular to the sliding rail is also provided with a translation structure and can be fixed, and because the mechanical arm is likely to have uneven stress during operation, after the positions of the driving plate and the third rotating arm can be adjusted, the driving plate and the third rotating arm are required not to be loosened due to uneven stress, the top of the sliding groove can be pressed through the extending mode of the positioning pin, and the two ends of the third rotating arm where the sliding groove is located can be limited through the positioning pin.

The clamp plate is an elastic part, so that after the two ends are limited and compressed, the middle part can be compressed to the top of the sliding groove by elastic deformation, and the part which is not contacted with the sliding groove can limit the two ends of the third rotating arm where the sliding groove is located.

Drawings

Fig. 1 is a schematic perspective view of the present three-axis robot.

Fig. 2 is a front view of fig. 1.

Fig. 3 is a schematic diagram of the present three-axis robot.

Fig. 4 is a schematic perspective view of the adjustment mechanism.

Fig. 5 is a schematic diagram of an adjustment mechanism.

In the figure, 1, a machine head; 21. a first drive motor; 22. a second drive motor; 23. a third drive motor; 31. a first rotating shaft; 32. a second rotating shaft; 33. a third rotating shaft; 41. a first rotating arm; 42. a second rotating arm; 43. a third rotating arm; 5. a drive plate; 61. a first belt wheel; 62. a second belt wheel; 63. a third belt wheel; 64. a belt wheel IV; 65. a fifth belt wheel; 66. a sixth belt wheel; 71. a chute; 72. a slide rail; 73. positioning holes; 74. pressing a plate; 75. positioning pins; 76. a sliding sleeve; 77. and (7) a top block.

Detailed Description

The following are specific embodiments of the present invention and the accompanying drawings are used to further describe the technical solution of the present invention, but the present invention is not limited to these embodiments.

As shown in fig. 1, 2 and 3, the manipulator comprises a machine head 1, a first driving motor 21, a second driving motor 22, a third driving motor 23, a first rotating shaft 31 and a second rotating shaft 32, a third rotating shaft 33, a first rotating arm 41, a second rotating arm 42, a third rotating arm 43 and a driving plate 5, wherein a shell of the first driving motor 21, a shell of the second driving motor 22 and a shell of the third driving motor 23 are all fixed on the handpiece 1, the first rotating shaft 31 is fixed at one end of the first rotating arm 41, the second rotating shaft 32 is fixed at one end of the second rotating arm 42, the first rotating arm 41 and the second rotating arm 42 are hinged through the second rotating shaft 32, the third rotating shaft 33 is fixed at one end of the third rotating arm 43, the second rotating arm 42 and the third rotating arm 43 are hinged through the third rotating shaft 33, the other end of the third rotating arm 43 is connected with the driving plate 5, and the first rotating arm 41 is hinged with the handpiece 1 through the first rotating shaft 31;

the first rotating shaft 31 is provided with a first belt wheel 61 fixedly connected with the first rotating shaft 31, a second belt wheel 62 rotatably connected with the first rotating shaft 31 and a third belt wheel 63 rotatably connected with the first rotating shaft 31, the second rotating shaft 32 is provided with a fourth belt wheel 64 fixedly connected with the second rotating shaft 32 and a fifth belt wheel 65 rotatably connected with the second rotating shaft 32, and the third rotating shaft 33 is fixedly provided with a sixth belt wheel 66;

the first belt wheel 61, the second belt wheel 62 and the third belt wheel 63 are respectively connected with the first driving motor 21, the second driving motor 22 and the third driving motor 23 through belts, the second belt wheel 62 is connected with the fourth belt wheel 64 through a belt, the third belt wheel 63 is connected with the fifth belt wheel 65 through a belt, and the fourth belt wheel 64 is connected with the sixth belt wheel 66 through a belt.

The first driving motor 21 controls the rotation of the first rotating shaft 31, that is, the swing of the first rotating arm 41, the second driving motor 22 controls the swing of the second rotating arm 42, which is synchronized by the pulley three 63 freely rotating on the first rotating arm 41 and the pulley five 65 fixed on the second rotating shaft 32, the third driving motor 23 controls the swing of the third rotating arm 43, and the torque transmission path is: the purpose that all the belts are arranged in the first rotating arm 41 and the second rotating arm 42 is achieved by arranging all the belts in the third driving motor 23, the second belt wheel, the fourth belt wheel, the sixth belt wheel and the third rotating shaft 33, the first rotating shaft 31, the second rotating arm 42 and the third rotating arm 43 only bear the self weight, the actual load of the driving plate 5 is improved, the machine head 1 is fixed on a machine table operated by a manipulator, and the driving plate 5 is used for operation or connection of workpieces for operation.

The first driving motor 21, the second driving motor 22 and the third driving motor 23 are all planetary gear motors.

As shown in fig. 4 and 5, an adjusting mechanism is arranged between the third rotating arm 43 and the driving plate 5 for adjusting the connecting position of the third rotating arm 43 on the driving plate 5; the adjusting mechanism comprises a sliding groove 71 arranged on the third rotating arm 43 and a sliding rail 72 arranged on the drive plate 5 and matched with the sliding groove 71, a plurality of positioning holes 73 are formed in the sliding rail 72 at equal intervals, a pressing plate 74 is arranged at the bottom of the sliding rail 72, a plurality of positioning pins 75 corresponding to the positioning holes 73 one by one are arranged on the pressing plate 74, a sliding sleeve 76 is respectively sleeved at two ends of the sliding rail 72, a jacking block 77 is arranged in the middle of the sliding sleeve 76, and the jacking block 77 can press the pressing plate 74 to enable the positioning pins 75 to extend out of the positioning holes 73.

In fact, the direction perpendicular to the sliding rail 72 is also provided with a translation structure and can be fixed, and since the mechanical arm may not be uniformly stressed during operation, after the positions of the driving plate 5 and the third rotating arm 43 can be adjusted, the driving plate 5 and the third rotating arm 43 are required not to be loosened due to uneven stress, the top of the sliding groove 71 can be pressed through the way that the positioning pin 75 extends, and the two ends of the third rotating arm 43 where the sliding groove 71 is located can be limited through the positioning pin 75.

The pressing plate 74 is an elastic member, so that after the two ends are limited and pressed, the middle part can be elastically deformed to press the top of the sliding groove 71, and the part not in contact with the sliding groove 71 can limit the two ends of the third rotating arm 43 where the sliding groove 71 is located.

The specific embodiments described herein are merely illustrative of the spirit of the invention. Various modifications, additions and substitutions for the specific embodiments described herein may be made by those skilled in the art without departing from the spirit of the invention or exceeding the scope of the invention as defined in the accompanying claims.

Claims (1)

1. The utility model provides an last guiding mechanism of triaxial manipulator, its characterized in that, this manipulator includes third rocking arm (43) and drive plate (5), guiding mechanism including setting up spout (71) on third rocking arm (43) and setting on drive plate (5) with spout (71) complex slide rail (72), a plurality of locating holes (73) have been seted up to equidistant on slide rail (72), slide rail (72) bottom is provided with a clamp plate (74), locating pin (75) that have a plurality of and locating hole (73) one-to-one on clamp plate (74), the both ends of slide rail (72) are overlapped respectively and are equipped with a sliding sleeve (76), the middle part of sliding sleeve (76) has a kicking block (77), kicking block (77) can compress tightly clamp plate (74) and make locating pin (75) stretch out on locating hole (73).

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