CN211255129U - A feed bin elevating gear for circuit board automated production - Google Patents

Abstract

The utility model discloses a feed bin elevating gear for circuit board automated production, the main content is: the left slider install on left linear guide, left nut is installed on left nut seat and left nut is installed on left ball, left ball top is connected with left connecting axle through left coupling, left driven bevel gear is installed on left connecting axle and left driven bevel gear meshes, left drive bevel gear is installed on left transmission shaft, servo motor installs on the motor mount pad, drive sprocket installs on servo motor output shaft, left transmission shaft right-hand member is connected with right transmission shaft through last coupling, right drive bevel gear is installed on right transmission shaft and right drive bevel gear meshes, equidistant a plurality of connecting plate of installing on left slide right flank and the right slide left surface. The utility model discloses simple structure, it is very convenient that the installation is maintained, has realized the promotion operation of circuit board automatically, has improved its work efficiency.

Description

A feed bin elevating gear for circuit board automated production

Technical Field

The utility model belongs to the technical field of a circuit board production, concretely relates to feed bin elevating gear for circuit board automated production.

Background

The existing bin lifting device for circuit board automatic production is complex in structure, very complex in installation and maintenance, poor in stability and reliability, incapable of meeting the requirements of circuit board production, poor in positioning effect, incapable of realizing automatic feeding of circuit boards, greatly reduced in working efficiency and improved in production cost.

SUMMERY OF THE UTILITY MODEL

The utility model aims to solve the technical problem that not enough to above-mentioned prior art provides a feed bin elevating gear for circuit board automated production, its simple structure, and it is very convenient to install and maintain, has realized the promotion operation of circuit board automatically, has improved its work efficiency.

In order to realize the technical purpose, the utility model discloses the technical scheme who takes does:

the utility model provides a feed bin elevating gear for circuit board automated production, wherein: comprises a frame, a right slide block, a left guide rail seat, a left slide seat, a left linear guide rail, a left coupler, a left bearing seat, a pillar, a left connecting shaft, a transmission chain, a servo motor, a motor mounting seat, a right connecting shaft, a right bearing seat, a right coupler, a right linear guide rail, a right guide rail seat, a right slide seat, a connecting plate, a left transmission shaft, a right transmission shaft, a driven sprocket, a first bearing seat, a left driving bevel gear, a left driven bevel gear, a second bearing seat, a left ball screw, a left nut seat, a right nut, a right ball screw, a third bearing seat, a right driven bevel gear, a right driving bevel gear, a fourth bearing seat, an upper coupler and a driving sprocket, wherein the left guide rail seat is fixedly arranged on the left side surface of the inner side of the frame, the left linear guide rail is fixedly, the left sliding seat is fixedly arranged on the left sliding block, the left nut seat is fixedly arranged on the left side surface of the left sliding seat, the left nut is arranged on the left nut seat, the left nut is arranged on the left ball screw, two ends of the left ball screw are arranged on the second bearing seat through bearings, the left bearing seat and the second bearing seat are fixedly arranged on the rack, the top end of the left ball screw is connected with a left connecting shaft through a left coupler, the left connecting shaft is arranged on the left bearing seat through a bearing, the left driven bevel gear is arranged on the left connecting shaft, the left driven bevel gear is meshed with the left driving bevel gear, the left driving bevel gear is arranged on a left transmission shaft, the left transmission shaft is arranged on the first shaft through a bearing, the first bearing seat and the fourth bearing seat are fixedly arranged on the rack, and the motor mounting seat is arranged on the top end of the rack through a support column, the servo motor is arranged on the motor mounting seat, the driving sprocket is arranged on an output shaft of the servo motor, the driven sprocket is arranged on a left transmission shaft, the transmission chain is arranged on the driven sprocket and the driving sprocket, the right end of the left transmission shaft is connected with a right transmission shaft through an upper coupler, the right transmission shaft is arranged on a fourth bearing seat through a bearing, the right driving bevel gear is arranged on the right transmission shaft, the right driving bevel gear is meshed with the right driven bevel gear, the right driven bevel gear is arranged on a right connecting shaft, the right connecting shaft is arranged on the right bearing seat through a bearing, the right bearing seat and the third bearing seat are both fixedly arranged on the frame, the lower end of the right connecting shaft is connected with the top end of a right ball screw through a right coupler, the right ball screw is arranged on the third bearing seat through a bearing, right nut seat fixed mounting on the right slide right flank, right nut install on right nut seat and right nut install on right ball, right guide rail seat fixed mounting in the frame, right linear guide fixed mounting on right guide rail seat, right slider install on right linear guide, right slide fixed mounting on right slider, left slide right flank and right slide left flank on equidistant a plurality of connecting plate of installing.

In order to optimize the technical scheme, the specific measures adopted further comprise:

the adjustable workpiece guide block is fixedly arranged on the top surface of the connecting plate, and the adjustable support is arranged on the bottom surface of the rack.

The rack is formed by welding and installing square steel and steel plates.

The connecting plate is provided with a rectangular groove.

The utility model discloses a theory of operation: the circuit board is placed in a positioning groove formed by four workpiece guide blocks arranged on the top surface of the connecting plate, a servo motor drives a left transmission shaft to rotate through a transmission chain, and meanwhile, the left transmission shaft drives a right transmission shaft to rotate through an upper coupler; the left transmission shaft drives a left connecting shaft to rotate through a left driving bevel gear on the left transmission shaft, and the left connecting shaft drives a left ball screw to rotate through a left coupler, so that a left sliding seat is driven to move up and down along a left linear guide rail; meanwhile, the right transmission shaft drives a right connecting shaft to rotate through a right driving bevel gear on the right transmission shaft, and the right connecting shaft drives a right ball screw to rotate through a right coupler, so that a right sliding seat is driven to synchronously move up and down along a right linear guide rail; thereby realized reciprocating of connecting plate, taken the back away when the circuit board of top layer, servo motor drive connection upward movement moves to the top layer until the lower one deck of top layer to realize circulation operation, until taking away all circuit boards.

The utility model has the advantages of following several: simple structure, the installation is maintained very conveniently, has realized the promotion operation of circuit board automatically, has improved its work efficiency, has alleviateed operating personnel's intensity of labour greatly.

Drawings

FIG. 1 is a front view of the structure of the present invention;

fig. 2 is a top view of the structure of the present invention;

FIG. 3 is a left side view of the structure of the present invention;

FIG. 4 is a right side view of the structure of the present invention;

fig. 5 is a sectional view of the structure a-a of the present invention.

Wherein the reference numerals are: the device comprises a rack 1, a right slide block 2, a workpiece guide block 3, an adjustable support 4, a left slide block 5, a left guide rail seat 6, a left slide seat 7, a left linear guide rail 8, a left coupler 9, a left bearing seat 10, a strut 11, a left connecting shaft 12, a transmission chain 13, a servo motor 14, a motor mounting seat 15, a right connecting shaft 16, a right bearing seat 17, a right coupler 18, a right linear guide rail 19, a right guide rail seat 20, a right slide seat 21, a connecting plate 22, a left transmission shaft 23, a right transmission shaft 24, a driven sprocket 25, a first bearing seat 26, a left driving bevel gear 27, a left driven bevel gear 28, a second bearing seat 29, a left ball screw 30, a left nut 31, a left nut seat 32, a right nut seat 33, a right nut 34, a right ball screw 35, a third bearing seat 36, a right driven bevel gear 37, a right driving bevel gear 38, a fourth shaft 39, an upper.

Detailed Description

The following further description of the embodiments of the present invention is made with reference to the accompanying drawings:

the utility model provides a feed bin elevating gear for circuit board automated production, wherein: comprises a frame 1, a right slide block 2, a left slide block 5, a left guide rail seat 6, a left slide seat 7, a left linear guide rail 8, a left coupler 9, a left bearing seat 10, a pillar 11, a left connecting shaft 12, a transmission chain 13, a servo motor 14, a motor mounting seat 15, a right connecting shaft 16, a right bearing seat 17, a right coupler 18, a right linear guide rail 19, a right guide rail seat 20, a right slide seat 21, a connecting plate 22, a left transmission shaft 23, a right transmission shaft 24, a driven sprocket 25, a first bearing seat 26, a left driving bevel gear 27, a left driven bevel gear 28, a second bearing seat 29, a left ball screw 30, a left nut 31, a left nut seat 32, a right nut seat 33, a right nut 34, a right ball screw 35, a third bearing seat 36, a right driven bevel gear 37, a right driving bevel gear 38, a fourth bearing seat 39, an upper coupler 40 and a driving sprocket 41, wherein the left guide rail seat 6 is fixedly arranged on, the left linear guide rail 8 is fixedly arranged on the left guide rail seat 6, the left slide block 5 is arranged on the left linear guide rail 8, the left slide seat 7 is fixedly arranged on the left slide block 5, the left nut seat 32 is fixedly arranged on the left side surface of the left slide seat 7, the left nut 31 is arranged on the left nut seat 32, the left nut 31 is arranged on the left ball screw 30, two ends of the left ball screw 30 are arranged on the second bearing seat 29 through bearings, the left bearing seat 10 and the second bearing seat 29 are both fixedly arranged on the machine frame 1, the top end of the left ball screw 30 is connected with the left connecting shaft 12 through the left coupling 9, the left connecting shaft 12 is arranged on the left bearing seat 10 through bearings, the left driven bevel gear 28 is arranged on the left connecting shaft 12, the left driven bevel gear 28 is meshed with the left driving bevel gear 27, the left driving bevel gear 27 is arranged on the left transmission shaft 23, the left transmission shaft 23 is mounted on the first bearing seat 26 through a bearing, the first bearing seat 26 and the fourth bearing seat 39 are both fixedly mounted on the frame 1, the motor mounting seat 15 is mounted on the top end of the frame 1 through a strut 11, the servo motor 14 is mounted on the motor mounting seat 15, the driving sprocket 41 is mounted on the output shaft of the servo motor 14, the driven sprocket 25 is mounted on the left transmission shaft 23, the transmission chain 13 is mounted on the driven sprocket 25 and the driving sprocket 41, the right end of the left transmission shaft 23 is connected with the right transmission shaft 24 through an upper coupling 40, the right transmission shaft 24 is mounted on the fourth bearing seat 39 through a bearing, the right driving bevel gear 38 is mounted on the right transmission shaft 24, the right driving bevel gear 38 is meshed with the right driven bevel gear 37, the right driven bevel gear 37 is mounted on the right connecting shaft 16, the right connecting shaft 16 is arranged on a right bearing seat 17 through a bearing, the right bearing seat 17 and a third bearing seat 36 are both fixedly arranged on the frame 1, the lower end of the right connecting shaft 16 is connected with the top end of a right ball screw 35 through a right coupling 18, the right ball screw 35 is mounted on a third bearing seat 36 through a bearing, the right nut seat 33 is fixedly mounted on the right side surface of the right sliding seat 21, the right nut 34 is mounted on the right nut holder 33 and the right nut 34 is mounted on the right ball screw 35, the right guide rail seat 20 is fixedly arranged on the frame 1, the right linear guide rail 19 is fixedly arranged on the right guide rail seat 20, the right sliding block 2 is arranged on the right linear guide rail 19, the right sliding seat 21 is fixedly arranged on the right sliding block 2, and a plurality of connecting plates 22 are arranged on the right side surface of the left sliding seat 7 and the left side surface of the right sliding seat 21 at equal intervals.

In the embodiment, the workpiece guide block device further comprises a workpiece guide block 3 and an adjustable support 4, wherein the workpiece guide block 3 is fixedly arranged on the top surface of the connecting plate 22, and the adjustable support 4 is arranged on the bottom surface of the machine frame 1.

In the embodiment, the frame 1 is formed by welding and installing square steel and steel plates.

In the embodiment, the connection plate 22 is provided with a rectangular groove.

Above only the utility model discloses an it is preferred embodiment, the utility model discloses a scope of protection not only limits in above-mentioned embodiment, and the all belongs to the utility model discloses a technical scheme under the thinking all belongs to the utility model discloses a scope of protection. It should be noted that, for those skilled in the art, a plurality of modifications and decorations without departing from the principle of the present invention should be considered as the protection scope of the present invention.

Claims (4)

1. The utility model provides a feed bin elevating gear for circuit board automated production which characterized in that: the device comprises a rack (1), a right slider (2), a left slider (5), a left guide rail seat (6), a left slider (7), a left linear guide rail (8), a left coupler (9), a left bearing seat (10), a strut (11), a left connecting shaft (12), a transmission chain (13), a servo motor (14), a motor mounting seat (15), a right connecting shaft (16), a right bearing seat (17), a right coupler (18), a right linear guide rail (19), a right guide rail seat (20), a right slider (21), a connecting plate (22), a left transmission shaft (23), a right transmission shaft (24), a driven sprocket (25), a first bearing seat (26), a left driving bevel gear (27), a left driven bevel gear (28), a second bearing seat (29), a left ball screw (30), a left nut (31), a left nut seat (32), a right nut seat (33), a right nut (34), A right ball screw (35), a third bearing seat (36), a right driven bevel gear (37), a right drive bevel gear (38), a fourth bearing seat (39), an upper coupler (40) and a drive sprocket (41), wherein the left guide rail seat (6) is fixedly arranged on the left side surface of the inner side of the frame (1), the left linear guide rail (8) is fixedly arranged on the left guide rail seat (6), the left slider (5) is arranged on the left linear guide rail (8), the left slider (7) is fixedly arranged on the left slider (5), the left nut seat (32) is fixedly arranged on the left side surface of the left slider (7), the left nut (31) is arranged on the left nut seat (32) and the left nut (31) is arranged on the left ball screw (30), two ends of the left ball screw (30) are arranged on the second bearing seat (29) through bearings, and the left bearing seat (10) and the second bearing seat (29) are both fixedly arranged on the frame (1), the top end of the left ball screw (30) is connected with a left connecting shaft (12) through a left coupler (9), the left connecting shaft (12) is installed on a left bearing seat (10) through a bearing, a left driven bevel gear (28) is installed on the left connecting shaft (12) and meshed with a left driving bevel gear (27), the left driving bevel gear (27) is installed on a left transmission shaft (23), the left transmission shaft (23) is installed on a first bearing seat (26) through a bearing, the first bearing seat (26) and a fourth bearing seat (39) are both fixedly installed on a rack (1), a motor installation seat (15) is installed at the top end of the rack (1) through a strut (11), a servo motor (14) is installed on a motor installation seat (15), and a driving chain wheel (41) is installed on an output shaft of the servo motor (14), the driven chain wheel (25) is arranged on a left transmission shaft (23), the transmission chain (13) is arranged on the driven chain wheel (25) and a driving chain wheel (41), the right end of the left transmission shaft (23) is connected with a right transmission shaft (24) through an upper coupler (40), the right transmission shaft (24) is arranged on a fourth bearing seat (39) through a bearing, a right driving bevel gear (38) is arranged on the right transmission shaft (24) and the right driving bevel gear (38) is meshed with the right driven bevel gear (37), the right driven bevel gear (37) is arranged on a right connecting shaft (16), the right connecting shaft (16) is arranged on a right bearing seat (17) through a bearing, the right bearing seat (17) and the third bearing seat (36) are fixedly arranged on the machine frame (1), the lower end of the right connecting shaft (16) is connected with the top end of a right ball screw (35) through a right coupler (18), right ball (35) pass through the bearing and install on third bearing frame (36), right nut seat (33) fixed mounting on right slide (21) right flank, right nut (34) install on right nut seat (33) and right nut (34) are installed on right ball (35), right guide rail seat (20) fixed mounting on frame (1), right linear guide (19) fixed mounting on right guide rail seat (20), right slider (2) install on right linear guide (19), right slide (21) fixed mounting on right slider (2), left slide (7) right flank and right slide (21) left flank on the equidistant a plurality of connecting plate (22) of installing.

2. The bin lifting device for the automatic production of the circuit boards, according to claim 1, is characterized in that: the workpiece guide block (3) is fixedly arranged on the top surface of the connecting plate (22), and the adjustable support (4) is arranged on the bottom surface of the rack (1).

3. The bin lifting device for the automatic production of the circuit boards, according to claim 1, is characterized in that: the rack (1) is formed by welding and installing square steel and steel plates.

4. The bin lifting device for the automatic production of the circuit boards, according to claim 1, is characterized in that: the connecting plate (22) is provided with a rectangular groove.

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