CN111517110B - Push rotary controller applied to filling processing line - Google Patents

Abstract

The invention relates to a pushing rotary controller applied to a filling processing line, which comprises a workbench, a conveying belt and a pair of limiting frames, wherein the conveying belt and the pair of limiting frames are arranged on the workbench; a rotating disc is arranged on the front side of the right part of the conveying belt; the arc surface of the rotating disc is uniformly provided with clamping grooves. A main control dial box and a motor are fixedly arranged on the workbench; the motor is connected with an incomplete bevel gear, and the incomplete bevel gear is respectively meshed with a small bevel gear and a large bevel gear; and a transmission assembly connected with the large bevel gear and the rotating disc is arranged between the large bevel gear and the rotating disc. The automatic stirring and feeding device has high automation degree, and can accurately and stably stir and feed a single filling bottle into the corresponding clamping groove in each rotation stop period of the rotating disc on the basis of controlling the rotating disc to rotate intermittently, so that the effect of conveniently controlling the filling bottle to feed the filling bottle to the rotating disc is achieved.

Description

Push rotary controller applied to filling processing line

Technical Field

The invention relates to the field of transmission, transportation and distribution, in particular to a pushing rotary controller applied to a filling processing line.

Background

In the process of making and processing the filled beverage, a disc type transportation carrier such as a rotary disc is usually adopted to carry out rotary transportation by bearing the filled bottle so as to conveniently carry out beverage filling or packaging paper pasting on the filled bottle, but the problem is that the whole rotary disc is inevitably implemented in an intermittent rotary mode due to the requirements of filling and other assembly, and therefore the traditional manual feeding mode or mechanical equipment is difficult to stably feed the filled bottle to the rotary disc.

Disclosure of Invention

The invention provides a pushing rotary controller applied to a filling processing line, aiming at overcoming the defects of the prior art and facilitating the distribution and feeding of filling bottles.

The technical problem to be solved by the invention is realized by adopting the following technical scheme:

the pushing rotary controller applied to the filling processing line comprises a workbench, a conveying belt and a pair of limiting frames, wherein the conveying belt is installed on the workbench; a rotating disc is arranged on the front side of the right part of the conveying belt; the arc surface of the rotating disc is uniformly provided with clamping grooves.

A main control dial box and a motor are fixedly arranged on the workbench; the motor is connected with an incomplete bevel gear, and the incomplete bevel gear is respectively meshed with a small bevel gear and a large bevel gear; a transmission assembly connected with the large bevel gear and the rotating disc is arranged between the large bevel gear and the rotating disc; the small bevel gear is connected with a connecting rod which is arranged on a main control dial box through a bearing, and a dial component is arranged in the main control dial box; the poking component is connected with a main poking rod.

The poking assembly comprises an incomplete straight gear arranged on the connecting rod, and the incomplete straight gear is respectively engaged with an upper gear and a lower gear; the upper gear and the lower gear are respectively and correspondingly provided with an upper lug and a lower lug at the large-surface eccentric positions.

The main control is dialled case upper end and is opened there is the through-hole, it still includes the transfer line that links to each other with main driving lever to stir the subassembly, and the transfer line welding has last floating block, it has the last cooperation groove of upper convex block slip and articulated installation to open on the floating block.

The transfer line lower part is opened there is the square groove, and the vertical sliding fit in square groove has the square bar, and the welding of square bar lower extreme has the round roller of dialling the incasement at the master control through the bearing frame, it has the circular arc groove to open on the arc surface of round roller, and circular arc groove sliding fit has the slide bar, and the slide bar is connected with lower floating block, it has the lower cooperation groove of lower protruding slip and articulated installation to open on the lower floating block.

A guide rail for vertically and slidably mounting the lower floating block is mounted in the main control dial box, and the upper gear and the lower gear are both connected with an auxiliary shaft mounted in the main control dial box through a bearing seat; and a spring connected with the upper floating block and the top of the inner side of the main control shifting box is arranged between the upper floating block and the top of the inner side of the main control shifting box. The elastic force of the spring has a supporting function on the upper floating block.

The transmission assembly comprises a central shaft connected with the rotating disc, a first bevel gear is mounted on the central shaft, and a second bevel gear is meshed with the first bevel gear; the second bevel gear is connected with a left shaft; the left shaft is provided with a left belt wheel, the left belt wheel is connected with a transmission belt, the transmission belt is connected with a right belt wheel, and the right belt wheel is connected with a right shaft connected with a large bevel gear.

The center shaft, the left shaft and the right shaft are all installed on the workbench through bearings.

In the invention, a conveying groove with an L-shaped track is formed between a pair of limiting frames. The cross sections of the square rod and the square groove are both square. The position of the front and back extending track part of the transport groove is matched with the position of a card groove positioned at the rearmost side.

The invention has the beneficial effects that:

the automatic stirring and feeding device has high automation degree, and can accurately and stably stir and feed a single filling bottle into the corresponding clamping groove in each rotation stop period of the rotating disc on the basis of controlling the rotating disc to rotate intermittently, so that the effect of conveniently controlling the filling bottle to feed the filling bottle to the rotating disc is achieved.

Drawings

The invention is further illustrated with reference to the following figures and examples.

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

FIG. 2 is a top view of the present invention;

FIG. 3 is a front view of the master batch box and the batch assembly;

fig. 4 is a structural view of a filling bottle.

In the figure: 1. a work table; 2. a conveyor belt; 3. a limiting frame; 4. rotating the disc; 5. a master control dialing box; 6. a motor; 7. an incomplete bevel gear; 8. a bevel pinion gear; 9. a large bevel gear; 10. a main deflector rod; 11. an incomplete spur gear; 12. an upper gear; 13. a lower gear; 14. an upper floating block; 15. a lower floating block; 16. a guide rail; 17. a counter shaft; 18. a connecting rod; 19. a square bar; 20. a round roller; 21. a slide bar; 22. a spring; 23. a central shaft; 24. a first bevel gear; 25. a second bevel gear; 26. a left shaft; 27. a left pulley; 28. a transmission belt; 29. a right pulley; 30. a right shaft; 31. and a transmission rod.

Detailed Description

In order to make those skilled in the art better understand the technical solution of the present invention, the present invention will be described more clearly and more completely with reference to the drawings in the following embodiments, and it is understood that the described embodiments are only a part of the present invention, rather than all of the present invention, and based on the embodiments, other embodiments obtained by those skilled in the art without inventive exercise are within the protection scope of the present invention.

As shown in fig. 1 to 3, the pushing and rotating controller applied to the filling processing line includes a workbench 1, a conveyor belt 2 mounted on the workbench, and a pair of limiting frames 3; a rotating disk 4 is arranged on the front side of the right part of the conveying belt 2; the arc surface of the rotating disc 4 is uniformly provided with clamping grooves 4 a.

A main control dial box 5 and a motor 6 are fixedly arranged on the workbench 1; the motor 6 is connected with an incomplete bevel gear 7, and the incomplete bevel gear 7 is respectively meshed with a small bevel gear 8 and a large bevel gear 9; a transmission assembly connected with the large bevel gear 9 and the rotating disc 4 is arranged between the large bevel gear and the rotating disc; the small bevel gear 8 is connected with a connecting rod 18 which is arranged on the main control dial box 5 through a bearing, and a dial component is arranged in the main control dial box 5; the toggle assembly is connected with a main toggle lever 10.

The toggle assembly comprises an incomplete straight gear 11 arranged on a connecting rod 18, and the incomplete straight gear 11 is respectively engaged and matched with an upper gear 12 and a lower gear 13; the upper gear 12 and the lower gear 13 are respectively provided with an upper lug 12a and a lower lug 13a at the large-surface eccentric position.

The upper end of the main control shifting box 5 is provided with a through hole, the shifting assembly further comprises a transmission rod 31 connected with the main shifting rod 10, an upper floating block 14 is welded on the transmission rod 31, and an upper matching groove 14a which is used for sliding and hinged installation of an upper convex block 12a is formed in the upper floating block 14.

The utility model discloses a case, including transfer line 31, square groove 31a, square bar 19 lower extreme welding has the round roller 20 of dialling the case 5 at the main control through the bearing frame installation, it has circular arc groove 20a to open on the arc surface of round roller 20, and circular arc groove 20a sliding fit has slide bar 21, and slide bar 21 is connected with lower floating block 15, it has lower cooperation groove 15a that slides and the articulated installation of lug 13a down to open on the floating block 15 down.

A guide rail 16 for vertically and slidably mounting a lower floating block 15 is mounted in the main control shifting box 5, and the upper gear 12 and the lower gear 13 are both connected with an auxiliary shaft 17 mounted in the main control shifting box 5 through bearing seats; a spring 22 connected with the upper floating block 14 and the top of the inner side of the main control dial box 5 is arranged between the upper floating block and the main control dial box. The spring 22 has a supporting function on the upper floating block 14.

The transmission assembly comprises a central shaft 23 connected with the rotating disc 4, a first bevel gear 24 is mounted on the central shaft 23, and a second bevel gear 25 is meshed with the first bevel gear 24; the second bevel gear 25 is connected with a left shaft 26; the left shaft 26 is provided with a left belt wheel 27, the left belt wheel 27 is connected with a transmission belt 28, the transmission belt 28 is connected with a right belt wheel 29, and the right belt wheel 29 is connected with a right shaft 30 connected with the large bevel gear 9.

The central shaft 23, the left shaft 26 and the right shaft 30 are all mounted on the workbench 1 through bearings.

In the invention, a conveying groove with an L-shaped track is formed between a pair of limiting frames 3. The square bar 19 and the square groove 31a are both square in cross section. The position of the track portion extending forward and backward of the transport trough is matched to the position of one card slot 4a located at the rearmost side.

During the use, will place the filling bottle as shown in fig. 4 on conveyer belt 2 to make the bottleneck department block of filling bottle in the region between the conveyer trough that two spacing framves 3 formed, carry the filling bottle from left to right through conveyer belt 2.

Meanwhile, the motor 6 drives the incomplete bevel gear 7 to rotate at a constant speed, and the incomplete bevel gear 7 is driven to be in alternate meshing transmission with the small bevel gear 8 and the large bevel gear 9 respectively.

When the incomplete bevel gear 7 is in meshed transmission with the small bevel gear 8, the small bevel gear 8 and the incomplete spur gear 11 can rotate twice at a constant speed, and the incomplete spur gear 11 can be alternately meshed with the upper gear 12 and the lower gear 13 twice, so that the following four steps can be performed:

in the first step, when the incomplete straight gear 11 and the lower gear 13 are engaged for transmission for the first time, the lower gear 13 rotates 180 degrees, the lower floating block 15 and the slide rod 21 both vertically slide upwards to promote the circular roller 20 to rotate anticlockwise, the transmission rod 31 and the main deflector rod 10 can rotate anticlockwise by a rated angle along with the circular roller 20, and the main deflector rod 10 can move the filling bottle positioned at the rightmost side in the conveying trough forwards through the front-back extending track of the conveying trough, so that the neck part of the filling bottle is pushed forwards to be clamped in the corresponding clamping groove 4 a.

In the second step, when the incomplete spur gear 11 is meshed with the upper gear 12 for the first time, the upper gear 12 rotates 180 degrees, and the upper floating block 14, the transmission rod 31 and the main shift lever 10 can all ascend.

Thirdly, when the incomplete straight gear 11 and the lower gear 13 are in secondary meshing transmission, the lower gear 13 rotates 180 degrees, the lower floating block 15 and the sliding rod 21 vertically slide downwards to enable the round roller 20 to rotate clockwise, and the transmission rod 31 and the main deflector rod 10 can rotate clockwise along with the round roller 20 by a rated angle, so that the main deflector rod 10 can be driven to cross over the rightmost filling bottle in the conveying tank.

Fourthly, when the incomplete straight gear 11 and the upper gear 12 are meshed for transmission for the second time, the upper gear 12 rotates 180 degrees, the upper floating block 14, the transmission rod 31 and the main driving lever 10 can descend, and the main driving lever 10 is reset.

The filling bottle at the rightmost side in the conveying trough can be stirred into the corresponding clamping groove 4a in the four steps.

When incomplete bevel gear 7 and big bevel gear 9 meshing transmission, under drive belt 28 and bevel gear transmission effect, whole rotary disk 4 can rotate a rated angle, namely makes an empty draw-in groove 4a rotate to the position and the front and back extension orbit part position of conveyer trough corresponding, conveniently continues to stir the material loading to the filling bottle.

The foregoing shows and describes the general principles, essential features, and advantages of the invention. It will be understood by those skilled in the art that the present invention is not limited to the embodiments described above, which are merely illustrative of the principles of the invention, but that various changes and modifications may be made without departing from the spirit and scope of the invention, which fall within the scope of the invention as claimed. The scope of the invention is defined by the appended claims and equivalents thereof.

Claims (4)

1. The pushing rotary controller applied to the filling processing line comprises a workbench (1), a conveying belt (2) arranged on the workbench and a pair of limiting frames (3); a rotating disc (4) is arranged on the front side of the right part of the conveying belt (2); clamping grooves (4a) are uniformly distributed on the arc surface of the rotating disc (4);

the method is characterized in that:

a main control dial box (5) and a motor (6) are fixedly arranged on the workbench (1); the motor (6) is connected with an incomplete bevel gear (7), and the incomplete bevel gear (7) is respectively meshed with a small bevel gear (8) and a large bevel gear (9); a transmission assembly connected with the large bevel gear (9) and the rotating disc (4) is arranged between the large bevel gear and the rotating disc; the small bevel gear (8) is connected with a connecting rod (18) which is arranged on the main control dial box (5) through a bearing, and a dial component is arranged in the main control dial box (5); the shifting assembly is connected with a main shifting lever (10);

the poking assembly comprises an incomplete straight gear (11) arranged on a connecting rod (18), and the incomplete straight gear (11) is respectively engaged with an upper gear (12) and a lower gear (13); the upper gear (12) and the lower gear (13) are respectively and correspondingly provided with an upper lug (12a) and a lower lug (13a) at large-surface eccentric positions;

the upper end of the main control shifting box (5) is provided with a through hole, the shifting assembly further comprises a transmission rod (31) connected with the main shifting rod (10), an upper floating block (14) is welded on the transmission rod (31), and an upper matching groove (14a) which is used for sliding and hinging the upper convex block (12a) is formed in the upper floating block (14);

a square groove (31a) is formed in the lower portion of the transmission rod (31), a square rod (19) is vertically matched with the square groove (31a) in a sliding mode, a round roller (20) installed in the main control shifting box (5) through a bearing seat is welded at the lower end of the square rod (19), an arc groove (20a) is formed in the arc surface of the round roller (20), a sliding rod (21) is matched with the arc groove (20a) in a sliding mode, the sliding rod (21) is connected with a lower floating block (15), and a lower matching groove (15a) which enables a lower protruding block (13a) to slide and is installed in a hinged mode is formed in the lower floating block (15);

an L-shaped track conveying groove is formed between the pair of limiting frames (3); the cross sections of the square rod (19) and the square groove (31a) are square; the position of the track part extending back and forth of the transport trough is matched with the position of a clamping groove (4a) positioned at the rearmost side.

2. The push rotation controller applied to the filling processing line according to claim 1, wherein: a guide rail (16) for vertically and slidably mounting a lower floating block (15) is arranged in the main control shifting box (5), and the upper gear (12) and the lower gear (13) are both connected with an auxiliary shaft (17) which is arranged in the main control shifting box (5) through a bearing seat; a spring (22) connected with the upper floating block (14) and the top of the inner side of the main control dial box (5) is arranged between the upper floating block and the main control dial box.

3. The push rotation controller applied to the filling processing line according to claim 2, wherein: the transmission assembly comprises a central shaft (23) connected with the rotating disc (4), a first bevel gear (24) is mounted on the central shaft (23), and a second bevel gear (25) is meshed with the first bevel gear (24); the second bevel gear (25) is connected with a left shaft (26); the left shaft (26) is provided with a left belt wheel (27), the left belt wheel (27) is connected with a transmission belt (28), the transmission belt (28) is connected with a right belt wheel (29), and the right belt wheel (29) is connected with a right shaft (30) connected with the large bevel gear (9).

4. The push rotation controller applied to the filling processing line according to claim 3, wherein: the central shaft (23), the left shaft (26) and the right shaft (30) are all mounted on the workbench (1) through bearings.

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