CN111872701A

CN111872701A - Automatic cooling and gate removing production line of battery fixing support

Info

Publication number: CN111872701A
Application number: CN202010564834.0A
Authority: CN
Inventors: 史沸涛; 吴兵; 成晓辉; 刘佳; 汪志强
Original assignee: Wuhu Jinyi Machinery Co ltd
Current assignee: Anhui Changwei Intelligent Technology Co ltd
Priority date: 2020-06-19
Filing date: 2020-06-19
Publication date: 2020-11-03
Anticipated expiration: 2040-06-19
Also published as: CN114799349B; CN111872701B; CN114799349A

Abstract

The invention discloses an automatic cooling and de-gating production line of a battery fixing support, which relates to the field of automatic equipment and comprises a conveying belt, a conveying block, a clamping mechanism, a cooling mechanism, a cutting mechanism and an adsorption component.

Description

Automatic cooling and gate removing production line of battery fixing support

Technical Field

The invention belongs to the field of automation equipment, and particularly relates to an automatic cooling and de-gating production line for a battery fixing support.

Background

An iron fixed support produced by the department of China is molded by adopting a casting process, and in the rear-section machining procedure of the fixed support, the iron fixed support needs to be processed by cooling, sprue removal, drilling, tapping and the like.

The cooling mode that adopts at present is the forced air cooling, and the back needs the manual work to remove the runner with the help of the cutting machine and handles, and is inefficient, and intensity of labour is big, and the cutting precision of runner is difficult to master, and is great to the quality of product influence, so it is necessary to design an automatic equipment in order to realize the cooling of fixed bolster and the synchronous processing of removing the runner.

Disclosure of Invention

The invention aims to provide an automatic cooling and de-gating production line for a battery fixing support, which aims to overcome the defects caused in the prior art.

The utility model provides a battery fixed bolster's automatically cooling and runner production line that goes, includes conveyer belt, transport piece, clamping mechanism, cooling body, cutting mechanism and adsorption component, the transport piece can be dismantled and connect on the conveyer belt and can realize carrying forward with the help of the conveyer belt, clamping mechanism installs on the transport piece and is used for realizing the tight location of clamp to the fixed bolster, cooling body installs on the carriage of conveyer belt one side and is used for cooling the fixed bolster, cutting mechanism installs in the one side of carriage and can rotate 360 degrees under drive assembly's effect to realize the excision of runner, adsorption component is along with cutting mechanism synchronous motion and be used for adsorbing the runner after the cutting, shifts to row material station after that.

Preferably, the clamping mechanism comprises a base, a clamping block, two magnetic metal blocks and a first electromagnet, the base is mounted on the top surface of the conveying block, a containing groove is formed in the top surface of the base, the first electromagnet is mounted at the geometric center of the containing groove, the two magnetic metal blocks are connected into the containing groove in a sliding mode, the two magnetic metal blocks are located on two sides of the first electromagnet respectively, and the magnetic metal blocks are further connected with guide pillars which penetrate through the base and are connected to the clamping block.

Preferably, the cooling mechanism comprises an L-shaped plate and a cooling fan, the L-shaped plate is mounted on one side of the conveying frame, and the cooling fan is mounted on the top of the L-shaped plate and is located right above the conveying belt.

Preferably, the cutting mechanism comprises a motor base, a cutting motor, a transmission assembly and a cutting blade, wherein the output end of the cutting motor arranged on the motor base is connected to the cutting blade through the transmission assembly so as to realize the rotary motion of the cutting blade;

the driving assembly comprises a first stand column, a driven gear, an intermediate gear, a support, a rack and a connecting piece, wherein the support is arranged on one side of the conveying belt, the support and the L-shaped plate are respectively positioned on two sides of the conveying belt, one stand column is rotatably connected to the support, the upper end of the first stand column is fixedly connected with the motor base, the driven gear is arranged on the lower portion of the first stand column, the driven gear is meshed with the intermediate gear, the intermediate gear is rotatably connected to the support through a rotating shaft, and the rack is fixed to the conveying block through the connecting piece and is matched with the intermediate gear.

Preferably, the motor cabinet is fixed a position through stop gear after 360 degrees of rotation, and this stop gear includes stand two, layer board, sleeve, spring and ejector pin, and on the stand two was fixed in the support, the layer board was fixed in the top of stand two, and the sleeve is fixed in the top of layer board, and equal sliding connection of ejector pin and spring is in the sleeve and the spring is located the below of ejector pin, and the top of ejector pin is the sphere form and contacts with the bottom surface of motor cabinet all the time, and the bottom surface of motor cabinet still is equipped with one with ejector pin complex spacing groove.

Preferably, the adsorption component comprises a third upright post, a support plate and a second electromagnet, the third upright post is fixed on the top surface of the motor base and coaxial with the first upright post, the support plate is fixed on the top of the third upright post, and the second electromagnet is cylindrical and fixed at the other end of the support plate.

Preferably, transmission assembly includes the action wheel, follows driving wheel and conveyer belt, and the action wheel is connected to the output of cutting motor, and the action wheel passes through the conveyer belt and is connected from the driving wheel, follows the transmission shaft that driving wheel is connected to the cutting piece, and the transmission shaft passes through the bearing and rotates to be connected on the motor cabinet.

Preferably, a power supply and a controller are mounted on the supporting plate and the base, the power supply on the supporting plate is used for supplying power to the cutting motor and the electromagnet II, the controller on the supporting plate is used for controlling the operation of the cutting motor and the electromagnet, and the power supply and the controller on the base are respectively used for supplying power and controlling the electromagnet I.

The invention has the advantages that:

(1) the cooling and the sprue removing work of the fixed support can be simultaneously finished by one set of equipment, compared with the traditional manual treatment, the production efficiency is obviously improved, the cutting precision of the cutting mechanism is easy to control, and the influence on the quality of a product is small.

(2) The cutting mechanism and the adsorption component can periodically rotate under the action of the driving component, so that the cutting and the removal of the sprue are realized, the cut sprue is adsorbed and rotates to the discharging station along with the continuous conveying of the conveying block and is taken away manually or mechanically, the whole process is fast in rhythm, the efficiency is high, and errors are not easy to occur.

(3) The ejector pin among the stop gear can realize the location behind the rotatory a week of motor cabinet, avoids leading to the motor cabinet to rotate excessively because of inertia and influences the cutting next time.

Drawings

FIG. 1 is a schematic structural diagram of the present invention.

Fig. 2 is a front view of the present invention.

Fig. 3 is a top view of the present invention.

Fig. 4 is an exploded view of a portion of the clamping mechanism of the present invention.

Fig. 5 is a schematic structural view of the cutting mechanism of the present invention.

Fig. 6 is a schematic structural view of a motor base according to the present invention.

Fig. 7 is a schematic structural view of the limiting mechanism of the present invention.

Fig. 8 is a cross-sectional view of fig. 7.

Wherein, 1-a conveyer belt, 2-a conveyer frame, 3-a conveyer block, 4-a clamping mechanism, 41-a containing groove, 42-an electromagnet I, 43-a magnetic metal block, 44-a clamping block, 45-a guide post, 46-a base, 5-a cooling mechanism, 51-an L-shaped plate, 52-a cooling fan, 6-a cutting mechanism, 61-a motor base, 62-a cutting motor, 63-a transmission component, 631-a driving wheel, 632-a driven wheel, 633-a conveyer belt, 64-a cutting sheet, 7-a driving component, 71-an upright post I, 72-a driven gear, 73-an intermediate gear, 74-a support, 75-a rack, 76-a connecting component, 8-an adsorption component, 81-an upright post III, 82-a supporting plate, 83-electromagnet II, 9-limiting mechanism, 91-upright post II, 92-supporting plate, 93-sleeve, 94-spring, 95-ejector rod, 96-limiting groove, 10-power supply, 11-controller, 12-fixed support and 13-pouring gate.

Detailed Description

In order to make the technical means, the creation characteristics, the achievement purposes and the effects of the invention easy to understand, the invention is further described with the specific embodiments.

As shown in fig. 1 to 8, an automatic cooling and degating production line for battery fixing brackets comprises a conveyor belt 1, a conveyor block 3, a clamping mechanism 4, a cooling mechanism 5, a cutting mechanism 6 and an adsorption component 8, the conveyor blocks 3 are detachably connected to the conveyor belt 1 and can be conveyed forward by means of the conveyor belt 1, the clamping mechanism 4 is arranged on the conveying block 3 and is used for realizing clamping and positioning of the fixed bracket 12, the cooling mechanism 5 is installed on the conveying frame 2 at one side of the conveying belt 1 and used for cooling the fixed support 12, the cutting mechanism 6 is installed at one side of the conveying frame 2 and can rotate 360 degrees under the action of a driving assembly 7, so as to cut off the gate 13, the adsorption component 8 moves synchronously with the cutting mechanism 6 and is used for adsorbing the cut gate 13, and then the gate is transferred to a discharging station.

In this embodiment, the clamping mechanism 4 includes a base 46, a clamping block 44, a magnetic metal block 43, and a first electromagnet 42, wherein the base 46 is installed on the top surface of the conveying block 3, the top surface of the base 46 is provided with a receiving groove 41, the first electromagnet 42 is installed at the geometric center of the receiving groove 41, the magnetic metal block 43 is connected in the receiving groove 41 in a sliding manner by two pieces, the two magnetic metal blocks 43 are respectively located on two sides of the first electromagnet 42, the magnetic metal block 43 is further connected with a guide pillar 45, and the guide pillar 45 penetrates through the base 46 and is connected to the clamping block 44.

In the present embodiment, the cooling mechanism 5 includes an L-shaped plate 51 and a cooling fan 52, the L-shaped plate 51 is installed on one side of the conveying frame 2, and the cooling fan 52 is installed on the top of the L-shaped plate 51 and is located right above the conveying belt 1.

In this embodiment, the cutting mechanism 6 includes a motor base 61, a cutting motor 62, a transmission assembly 63 and a cutting blade 64, the cutting motor 62 is mounted on the motor base 61, and an output end of the cutting motor 62 is connected to the cutting blade 64 through the transmission assembly 63, so as to realize the rotation movement of the cutting blade 64;

the driving assembly 7 comprises a first upright post 71, a driven gear 72, an intermediate gear 73, a support 74, a rack 75 and a connecting piece 76, wherein the support 74 is arranged on one side of the conveyor belt 1, the support 74 and the L-shaped plate 51 are respectively positioned on two sides of the conveyor belt 1, the first upright post 71 is rotatably connected to the support 74 through a bearing, the upper end of the first upright post 71 is fixedly connected with the motor base 61, the driven gear 72 is arranged on the lower part of the first upright post 71, the intermediate gear 73 is meshed with the driven gear 72, the intermediate gear 73 is rotatably connected to the support 74 through a rotating shaft, and the rack 75 is fixed on the conveyor block 3 through the connecting piece 76 and is matched with the intermediate gear 73;

the adsorption component 8 comprises a third upright column 81, a support plate 82 and a second electromagnet 83, the third upright column 81 is fixed on the top surface of the motor base 61 and is coaxial with the first upright column 71, the support plate 82 is fixed on the top of the third upright column 81, and the second electromagnet 83 is cylindrical and is fixed at the other end of the support plate 82.

The cutting mechanism 6 and the adsorption component 8 in the invention can periodically rotate under the action of the driving component 7, on one hand, the cutting and removal of the sprue 13 are realized, on the other hand, the cut sprue 13 is adsorbed and rotates to a discharging station along with the continuous conveying of the conveying block 3, and the sprue 13 is taken away manually or mechanically, the whole process is fast in rhythm and high in efficiency, and errors are not easy to occur

In this embodiment, the motor base 61 is positioned by the limiting mechanism 9 after rotating 360 degrees, the limiting mechanism 9 includes a second upright post 91, a supporting plate 92, a sleeve 93, a spring 94 and a top rod 95, the second upright post 91 is fixed on the support 74, the supporting plate 92 is fixed on the top of the second upright post 91, the sleeve 93 is fixed on the top of the supporting plate 92, the top rod 95 and the spring 94 are both slidably connected in the sleeve 93, the spring 94 is located below the top rod 95, the top end of the top rod 95 is spherical and is always in contact with the bottom surface of the motor base 61, and the bottom surface of the motor base 61 is further provided with a limiting groove 96 matched with the top rod 95.

In this embodiment, the transmission assembly 63 includes a driving wheel 631, a driven wheel 632 and a transmission belt 633, the driving wheel 631 is connected to the output end of the cutting motor 62, the driving wheel 631 is connected to the driven wheel 632 through the transmission belt 633, the driven wheel 632 is connected to the transmission shaft of the cutting blade 64, and the transmission shaft is rotatably connected to the motor base 61 through a bearing.

In this embodiment, the power supply 10 and the controller 11 are mounted on the supporting plate 82 and the base 46, the power supply 10 on the supporting plate 82 is used for supplying power to the cutting motor 62 and the second electromagnet 83, the controller 11 on the supporting plate 82 is used for controlling the operation of the cutting motor 62 and the electromagnet, and the power supply 10 and the controller 11 on the base 46 are respectively used for supplying power to and controlling the first electromagnet 42. The power supply 10 is detachable so as to be replaced in time.

When the die-casting device is used, firstly, a mechanical arm places a fixed support 12 which is die-cast and molded on a clamping block 44, a controller 11 on a base 46 controls a first electromagnet 42 to be electrified, a magnetic metal block 43 is adsorbed, the clamping block 44 contracts to clamp and position the fixed support 12, then a conveying block 3 is conveyed forwards along with the movement of a conveying belt 1, a clamping mechanism 4 moves along with the movement of the clamping block, a rack 75 is in contact with an intermediate gear 73 and drives the intermediate gear 73 and a driven gear 72 to rotate, a cutting mechanism 6 and an adsorption component 8 rotate along with the rotation of the clamping block, the cutting mechanism 6 starts to cut the runner 13 after rotating to the position of the runner 13, meanwhile, a second electromagnet 83 is electrified to generate magnetic force, the runner 13 is adsorbed after being cut off and rotates to a discharging station along with the adsorption component 8, and then the runner 13 can be taken away by means of manpower. The cooling fan 52 is always in operation to cool the fixing bracket 12.

In the invention, after the motor base 61 rotates 360 degrees, the limiting groove 96 on the bottom surface of the motor base contacts with the top end of the ejector rod 95 and is positioned by means of the ejector rod 95. The conveying rhythm of the conveying belt 1 is step-by-step, that is, the conveying block 3 moves for a certain distance after moving once every certain time.

It will be appreciated by those skilled in the art that the invention may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. The embodiments disclosed above are therefore to be considered in all respects as illustrative and not restrictive. All changes which come within the scope of or equivalence to the invention are intended to be embraced therein.

Claims

1. The utility model provides a battery fixed bolster's automatically cooling and go runner production line, its characterized in that, includes conveyer belt (1), carries piece (3), clamping mechanism (4), cooling body (5), cutting mechanism (6) and adsorption component (8), carry piece (3) can dismantle to be connected on conveyer belt (1) and can realize carrying forward with the help of conveyer belt (1), clamping mechanism (4) are installed on carrying piece (3) and are used for realizing the tight location of clamp to fixed bolster (12), cooling body (5) are installed on conveyer frame (2) of conveyer belt (1) one side and are used for cooling fixed bolster (12), cutting mechanism (6) are installed in one side of conveyer frame (2) and can rotate 360 degrees under drive component (7)'s effect to realize the excision of runner (13), adsorption component (8) are along with cutting mechanism (6) synchronous motion and are used for inhaling runner (13) after the cutting and is used for And then transferred to a discharge station.

2. The automatic cooling and degating production line of a battery fixing bracket as claimed in claim 1, wherein: the clamping mechanism (4) comprises a base (46), a clamping block (44), a magnetic metal block (43) and a first electromagnet (42), wherein the base (46) is installed on the top surface of the conveying block (3), an accommodating groove (41) is formed in the top surface of the base (46), the first electromagnet (42) is installed in the geometric center of the accommodating groove (41), the magnetic metal blocks (43) are connected into the accommodating groove (41) in a sliding mode through two magnetic metal blocks, the two magnetic metal blocks (43) are located on two sides of the first electromagnet (42) respectively, the magnetic metal blocks (43) are further connected with guide pillars (45), and the guide pillars (45) penetrate through the base (46) and are connected to the clamping block (44).

3. The automatic cooling and degating production line of a battery fixing bracket as claimed in claim 2, wherein: the cooling mechanism (5) comprises an L-shaped plate (51) and a cooling fan (52), the L-shaped plate (51) is installed on one side of the conveying frame (2), and the cooling fan (52) is installed on the top of the L-shaped plate (51) and located right above the conveying belt (1).

4. The automatic cooling and degating production line of a battery fixing bracket as claimed in claim 3, wherein: the cutting mechanism (6) comprises a motor base (61), a cutting motor (62), a transmission assembly (63) and a cutting blade (64), wherein the cutting motor (62) is mounted at the output end of the cutting motor (62) on the motor base (61) and is connected to the cutting blade (64) through the transmission assembly (63) so as to realize the rotary motion of the cutting blade (64);

drive assembly (7) include stand (71), driven gear (72), intermediate gear (73), support (74), rack (75) and connecting piece (76), one side of conveyer belt (1) is located in support (74), and support (74) and L shaped plate (51) are located the both sides of conveyer belt (1) respectively, stand (71) rotate to be connected on support (74), the upper end and motor cabinet (61) fixed connection of stand (71), driven gear (72) are installed in the lower part of stand (71), and driven gear (72) meshing has intermediate gear (73), and intermediate gear (73) rotate through the pivot and connect on support (74), rack (75) are fixed in on transport block (3) through connecting piece (76) and cooperate with intermediate gear (73).

5. The automatic cooling and degating production line of a battery fixing bracket as claimed in claim 4, wherein: motor cabinet (61) is fixed a position through stop gear (9) after 360 degrees of rotation, this stop gear (9) are including stand two (91), layer board (92), sleeve (93), spring (94) and ejector pin (95), stand two (91) are fixed in on support (74), layer board (92) are fixed in the top of stand two (91), sleeve (93) are fixed in the top of layer board (92), ejector pin (95) and spring (94) equal sliding connection are in sleeve (93) and spring (94) are located the below of ejector pin (95), the top of ejector pin (95) is the sphere form and contacts with the bottom surface of motor cabinet (61) all the time, the bottom surface of motor cabinet (61) still is equipped with one and ejector pin (95) complex spacing groove (96).

6. The automatic cooling and degating production line of a battery fixing bracket as claimed in claim 5, wherein: adsorption component (8) are including three (81) on the stand, backup pad (82) and two (83) electromagnets, and three (81) on the stand are fixed in the top surface of motor cabinet (61) and coaxial with stand (71), backup pad (82) are fixed in the top of three (81) on the stand, and two (83) electromagnets are cylindrical and are fixed in the other end of backup pad (82).

7. The automatic cooling and degating production line of a battery fixing bracket as claimed in claim 4, wherein: the transmission assembly (63) comprises a driving wheel (631), a driven wheel (632) and a transmission belt (633), the driving wheel (631) is connected to the output end of the cutting motor (62), the driving wheel (631) is connected with the driven wheel (632) through the transmission belt (633), the driven wheel (632) is connected to a transmission shaft of the cutting blade (64), and the transmission shaft is connected to the motor base (61) through a bearing in a rotating mode.

8. The automatic cooling and degating production line of a battery fixing bracket as claimed in claim 4, wherein: all install power (10) and controller (11) on backup pad (82), base (46), power (10) on backup pad (82) are used for supplying power to cutting motor (62), electro-magnet two (83), and controller (11) on backup pad (82) are used for controlling the operation of cutting motor (62) and electro-magnet, and power (10) and controller (11) on base (46) are used for realizing the power supply and the control of electro-magnet (42) respectively.