CN219390439U - Be applied to automatic dewatering system's of improved generation battery steel casing platform of unloading - Google Patents

Abstract

Be applied to automatic dewatering system's of improved generation battery steel casing platform of unloading, including unloading the support body, install on unloading the support body and be used for accepting the manipulator take out the workstation of unloading of a plurality of dehydration bucket from the hydroextractor, be located unloading station one side and carry out the row material conveyer belt of feed for the stoving conveyer belt and with the synchronous upset of a plurality of dehydration bucket on the workstation of unloading empty to row material conveyer belt on and have the turning device of pin subassembly, this turning device is including installing the swing frame and the upset motor that drive swing frame overturns and empty on unloading the support body lateral wall. This platform structural design ideal of unloading can empty the in-process of unloading to synchronous empting of a plurality of dehydration buckets, empties the operation of unloading more steadily, and is efficient moreover. By adopting the design of the stop lever assembly, the bung holes of the plurality of dewatering barrels are simultaneously blocked by the stop lever assembly, the plurality of dewatering barrels are not easy to loose and fall off, and the synchronous dumping operation of the plurality of dewatering barrels can be met.

Description

Be applied to automatic dewatering system's of improved generation battery steel casing platform of unloading

Technical Field

The utility model relates to an improved automatic battery steel shell dehydration system, in particular to a discharge table applied to the improved automatic battery steel shell dehydration system.

Background

Barrel plating is classified into three types, namely horizontal barrel plating, inclined barrel plating and vibration plating, and taking horizontal barrel plating as an example, the existing horizontal barrel plating is also called barrel plating, which is a plating processing mode of placing a certain number of small parts (such as battery steel shells and the like) into a special barrel (a generally hexagonal prismatic rolling cage, the side wall of which is in a net shape) and depositing various metal or alloy plating layers on the surfaces of the parts in an indirect conductive mode in a rolling state so as to achieve the purposes of surface protection decoration and various functions.

After the battery steel shell is electroplated and cleaned, the battery steel shell is dehydrated. The traditional battery steel shell dehydration mode is that the battery steel shell in the roller is taken out manually and placed in the containing barrel with meshes, then the containing barrel is placed in the dehydrator, the rotating motor on the dehydrator drives the containing barrel to rotate for spin-drying, and the water on each battery steel shell in the containing barrel is ensured to be thrown out, so that the purpose of dehydrating the battery steel shell is achieved. The traditional battery steel shell dehydration mode has the defects of high labor intensity, unsatisfactory dehydration effect, influence on product quality, low dehydration efficiency, incapability of realizing continuous operation and difficulty in realizing a large-scale integrated production mode.

In order to solve the problem of the traditional battery steel shell dehydration mode, the applicant previously applies for Chinese patent names: an automatic dewatering system for battery steel cases (patent number: ZL202021853597.1, authorized bulletin day: 2021, month and year 06, and day 22) comprises a dewatering machine for dewatering and spin-drying the battery steel cases, an automatic feeding device for receiving the battery steel cases in rolling cages on electroplating production lines and feeding the dewatering machine, a discharging table for receiving the dewatered battery steel cases on the dewatering machine, a discharging conveyer belt for receiving the battery steel cases on the discharging table, and a manipulator for automatic feeding and connecting between the automatic feeding device, the dewatering machine and the discharging table. The prior unloading table has the defects that the structural design is not ideal enough, the lapping mode of the L-shaped baffle block on the outer edge of the barrel mouth of the dewatering barrel is not stable enough in the dumping and unloading process of the dewatering barrel, the dewatering barrel is easy to loosen, the efficiency is low, one baffle block can only be matched with one dewatering barrel, and one baffle block cannot meet the requirement of simultaneous dumping operation of a plurality of dewatering barrels.

Disclosure of Invention

The utility model provides a discharging table applied to an improved automatic battery steel shell dehydration system, and mainly aims to overcome the defects that a dehydration barrel is easy to loosen, the efficiency is low, one stop block can only be matched with one dehydration barrel, one stop block cannot meet simultaneous dumping operation of a plurality of dehydration barrels and the like in the dumping and discharging process of the dehydration barrel by the existing discharging table.

In order to solve the problems, the utility model adopts the following technical scheme:

be applied to automatic dewatering system's of improved generation battery steel casing platform of unloading, including unloading the support body, install on unloading the support body and be used for accepting the manipulator take out the workstation of unloading of a plurality of dehydration bucket from the hydroextractor, be located unloading station one side and carry out the row material conveyer belt of feed for the stoving conveyer belt and with the synchronous upset of a plurality of dehydration bucket on the workstation of unloading empty to row material conveyer belt on and have the turning device of pin subassembly, this turning device is including installing the swing frame and the upset motor that drive swing frame overturns and empty on unloading the support body lateral wall.

Further, the turnover device further comprises a blocking component for blocking the outer edges of the mouths of the plurality of dewatering buckets, the blocking component comprises a blocking cylinder and a blocking rod, the blocking cylinder is arranged on the top surface of the swinging frame, the blocking rod is connected with a piston rod of the blocking cylinder and is used for blocking the outer edges of the mouths of the plurality of dewatering buckets, and the blocking cylinder is arranged along the width direction of the swinging frame and is positioned on the side edges of the swinging frame; the blocking rod is arranged along the length direction of the swing frame and is positioned on the rear edge of the swing frame, and the blocking rod is pulled by the piston rod of the blocking cylinder so that the blocking rod moves forwards to be blocked on the outer edges of the bung holes of the plurality of dewatering barrels.

Further, the number of the blocking cylinders is two, the two blocking cylinders are respectively positioned on the left side edge and the right side edge of the swing frame, and the left end part and the right end part of the blocking rod are respectively connected with piston rods of the two blocking cylinders; the blocking assembly further comprises a guide strip arranged along the width direction of the swinging frame, and the guide strip is provided with a strip-shaped opening which is arranged along the length direction of the guide strip and used for blocking the rod to pass through.

Further, the number of the guide bars is plural, and the plural guide bars are sequentially arranged at intervals on the top surface of the swing frame in the width direction of the swing frame.

Further, the swing frame comprises a plurality of unit placing frames for placing a plurality of dewatering barrels, each unit placing frame is used for placing one dewatering barrel, each unit placing frame comprises a frame bottom on which the bottom of the dewatering barrel is placed and a plurality of limiting vertical rods which are arranged around the frame bottom in a surrounding manner and play a limiting role on the dewatering barrel, and one side wall of each limiting vertical rod can be abutted against the side wall of the dewatering barrel.

As can be seen from the above description of the structure of the present utility model, compared with the prior art, the present utility model has the following advantages: this platform structural design ideal of unloading can empty the in-process of unloading to synchronous empting of a plurality of dehydration buckets, empties the operation of unloading more steadily, and is efficient moreover. By adopting the design of the stop lever assembly, the bung holes of the plurality of dewatering barrels are simultaneously blocked by the stop lever assembly, the plurality of dewatering barrels are not easy to loose and fall off, and the synchronous dumping operation of the plurality of dewatering barrels can be met.

Drawings

Fig. 1 is a schematic diagram of the automatic dehydration system for the steel case of the battery.

Fig. 2 is a schematic diagram of an automatic feed device in the automatic dehydration system of the battery steel shell.

Fig. 3 is a schematic view of an automatic feeding device in the automatic dewatering system for the battery steel shell, wherein a loading trolley is in a state of being close to the lower part of a feeding hopper of a dewatering barrel.

Fig. 4 is a schematic diagram of the cooperation between the battery steel shell discharging hopper and the rolling cage in the automatic battery steel shell dewatering system, wherein the rolling cage is in a separated state.

Fig. 5 is a schematic diagram of the cooperation between the battery steel shell discharging hopper and the rolling cage in the automatic battery steel shell dewatering system, wherein the rolling cage is in a lap joint state.

Fig. 6 is a schematic diagram showing a side view direction of a battery steel shell discharging hopper in the automatic battery steel shell dehydration system.

Fig. 7 is a schematic view of a baffle device located at the bottom of a discharging hopper of a battery steel shell in the automatic battery steel shell dewatering system.

Fig. 8 is a schematic diagram of a top view of a manipulator in the present battery steel can automatic dehydration system.

Fig. 9 is a schematic diagram of the front view direction of the manipulator in the automatic battery steel shell dehydration system.

Fig. 10 is a schematic view of a mechanical head of a manipulator in a gantry in the automatic dehydration system for battery steel shells.

Fig. 11 is a schematic diagram of a side view of a dehydrator in the automatic battery steel can dehydration system.

Fig. 12 is a schematic view of a side view of a dehydrator in the automatic battery steel can dehydration system, wherein the container cover is in an opened state.

Fig. 13 is a schematic top view of a dehydrator in the present battery steel can automatic dehydration system, wherein the container cover is not shown.

Fig. 14 is a schematic view of a discharge table in the present battery steel can automatic dehydration system.

Fig. 15 is a schematic view of a discharge table in the present battery steel can automatic dehydration system, wherein the dehydration barrel is drawn.

Fig. 16 is a schematic view of a swing frame in the present battery steel can automatic dehydration system.

Detailed Description

Specific embodiments of the present utility model will be described below with reference to the accompanying drawings.

Reference is made to figure 1. An improved automatic dewatering system for battery steel shells comprises a plurality of dewatering machines 2 for carrying out dewatering and spin-drying operations on the battery steel shells, an automatic feeding device 1 for receiving the battery steel shells in a rolling cage 10 on an electroplating production line and feeding the plurality of dewatering machines 2, a discharging table 4 for receiving the dewatered battery steel shells on the plurality of dewatering machines 2, and a manipulator 3 for automatic feeding and connecting between the automatic feeding device 1, the plurality of dewatering machines 2 and the discharging table 4. The automatic dehydration system has high dehydration efficiency, can realize simultaneous dehydration operation of a plurality of dehydration barrels 6, has ideal handle control of some detail designs, for example, the manipulator 3 can simultaneously pick and place the plurality of dehydration barrels 6 each time, and has more stable operation and low failure rate; by adopting the design of the stop lever assembly 40, the mouths of the plurality of dewatering buckets 6 are simultaneously blocked by the stop lever assembly 40, the plurality of dewatering buckets 6 are not easy to loose and fall off, and the simultaneous dumping operation of the plurality of dewatering buckets 6 can be satisfied.

Reference is made to figures 1, 2, 6 and 7. The automatic feeding device 1 comprises a receiving groove body 12 with a dewatering barrel feeding station 11, a battery steel shell discharging hopper 13 arranged on one side of the receiving groove body 12 and positioned below a discharging station of a rolling cage 10 on an electroplating production line, a material loading trolley 14 movably arranged in the receiving groove body 12 and reciprocating between the battery steel shell discharging hopper 13 and the dewatering barrel feeding station 11, a discharging assembly 15 arranged on one side of the receiving groove body 12 and used for discharging the rolling cage 10, and a material blocking assembly 16 positioned at the bottom of the battery steel shell discharging hopper 13 and capable of blocking a discharging opening of the battery steel shell discharging hopper.

Reference is made to figures 1, 2 and 3. Two rails 121 which are arranged at intervals left and right and matched with rollers at the bottom of the carrying trolley 14 are arranged in the carrying groove body 12, one end of each rail 121 extends to the lower part of the battery steel shell blanking hopper 13, and the other end of each rail 121 extends to the dewatering barrel feeding station 11; the receiving tank body 12 is also internally provided with a central rack 122 which is arranged in parallel with the two rails, and the bottom of the material loading trolley 14 is provided with a central gear 141 which is in meshed connection with the central rack 122. By adopting the design that the central rack 122 is matched with the central gear 141, due to the meshing effect of the central rack 122 matched with the central gear 141, the material loading trolley 14 is more stable in the process of reciprocating between the battery steel shell blanking hopper 13 and the dewatering barrel feeding station 11, and the sliding problem is not easy to occur, particularly, when the battery steel shell blanking hopper 13 or the dewatering barrel feeding station 11 is directly under, the blanking operation and the blanking operation are more stable. Each dewatering drum 6 is a cylindrical drum with meshes on the side, and the mouth of the cylindrical drum is a circular mouth 60 with gradually reduced shape. One side of the receiving tank 12 is extended outwards with a leakage-proof baffle 17 for preventing the liquid from leaking out when the manipulator 3 lifts and transfers the plurality of dewatering tanks 6 into the dewatering machine 2.

Reference is made to figures 1, 2, 3 and 4. The battery steel shell discharging hopper 13 comprises a discharging hopper body 131, the top of the discharging hopper body 131 is an upper opening for receiving the battery steel shell in the upper rolling cage 10 of the electroplating production line, the bottom of the discharging hopper body 131 is composed of a plurality of unit discharging ports which are sequentially arranged, each unit discharging port vertically extends downwards to a leakage preventing cover 132 at the bung hole of each dewatering barrel, the outlet of each leakage preventing cover 132 is the discharging hole, and the bung hole of each dewatering barrel 6 on the carrying trolley 14 can be located under each leakage preventing cover 132. A blocking curtain 133 (such as a plastic blocking curtain) is arranged near the upper opening of the battery steel shell discharging hopper 13, one end of the blocking curtain 133 extends to the outer side edge of the battery steel shell discharging hopper 13, the other end of the blocking curtain extends to the upper section of a plurality of unit discharging outlets, and a gap cavity for liquid splashing is formed between the blocking curtain 133 and the inner wall of the battery steel shell discharging hopper 13.

Reference is made to figures 1, 4 and 5. The discharging assembly 15 comprises a discharging motor 151 and two supporting frames 152 respectively positioned at the left side and the right side of the battery steel shell discharging hopper 13; the output shaft of the discharging motor 151 is provided with a driving gear 152, and the top surfaces of the two supporting frames 152 are respectively provided with a clamping groove body 153 (in a V shape) which is symmetrically arranged; the rolling cage 10 comprises a rolling cage main body 101 with a side fluted disc 100 and a hanging assembly connected to the rolling cage main body 101, wherein the hanging assembly comprises a left side plate 102, a right side plate 103, a fixed shaft 104 and a rotating shaft 105 which are connected between the left side plate 102 and the right side plate 103, two side edges of the rolling cage main body 101 are respectively and rotatably connected between the left side plate 102 and the right side plate 103, and the tail end of the fixed shaft 104 can be lapped on the clamping groove body 153. The rotation shaft 105 is sleeved with a driven gear 106 in meshing connection with the driving gear 152 and a linkage gear 107 for driving the rolling cage main body 101 to rotate so as to perform discharging operation from a discharging opening on the rolling cage main body, and the linkage gear 107 is in meshing connection with the side fluted disc 100. The linkage gears 107 are provided in two, and the two linkage gears 107 are respectively located on the left and right sides of the rotation shaft 105. By adopting the design of the unloading assembly 15, automatic unloading operation is realized, the unloading is more rapid and convenient, the unloading efficiency is high, and various problems caused by manual unloading operation, such as time and labor waste, are greatly reduced.

Reference is made to fig. 6 and 7. The blocking assembly 16 comprises a blocking bottom plate 161 and a driving assembly for driving the blocking bottom plate 161 to block the discharging opening of the battery steel shell discharging hopper 13. The driving assembly comprises a sliding rail 162, a sliding block 163 connected to the sliding rail 162 and a driving cylinder 164 for driving the sliding block 163 to move on the sliding rail 162, wherein a connecting plate 165 is arranged on the sliding block 163, one side of the connecting plate 165 is fixedly connected to the top surface of one side of the shielding bottom plate 161, and the other side of the connecting plate is fixed to the sliding block 163. The front side of the shielding bottom plate 161 is provided with a bar-shaped groove 166 for preventing liquid from splashing and collecting and temporarily storing the splashed liquid. The driving assembly further includes a bar-shaped chute body 167 disposed front to rear and an auxiliary roller 168 installed in the bar-shaped chute body 167, the auxiliary roller 168 being connected to the top surface of the shielding bottom plate 161 through a roller shaft bracket 169. The number of the bar-shaped slide groove bodies 167 is two, and each bar-shaped slide groove body 167 is located between two leakage preventing covers 132.

Reference is made to figures 1, 8, 9 and 10. The manipulator 3 comprises a left base frame 31 and a right base frame 32 positioned at both sides of the plurality of dehydrators 2, a moving frame 33 installed on the left and right base frames 31, 32 and movable forward and backward at the top thereof, and a plurality of mechanical heads 30 fixedly connected to the moving frame 33 and vertically movable thereon; the moving frame 33 includes a horizontal moving frame 331 which can move forward and backward on top of the left and right base frames 31, 32, a door frame 332 which is installed on both left and right side walls of the horizontal moving frame 331, and a vertical moving frame 333 which can move vertically on the door frame 332 and has the plurality of mechanical heads 30. The number of the plurality of mechanical heads 30 is three. In addition, the number of the active components can be two or four or other suitable numbers. This manipulator 3 can get simultaneously at every turn and put a plurality of dehydration buckets 6, and manipulator 3's is efficient, and is because bilateral atress (i.e. door style of calligraphy) and operating frequency are little in the walking in-process moreover for the operation is more steady, and mechanical wear is little, and the fault rate is low, and is not fragile.

Reference is made to figures 1, 8, 9 and 10. The horizontal moving frame 331 includes a square frame and a first driving motor 334 mounted on the square frame, rollers 335 rolling back and forth on top of the left and right base frames 31, 32 are disposed at the bottom of the square frame, and the horizontal moving frame 331 drives the horizontal moving frame 331 to move back and forth on top of the left and right base frames 31, 32 through the first driving motor 334. The roller 335 is connected with a roller shaft, a gear assembly is sleeved on the roller shaft, and the output shaft of the first driving motor 334 drives the roller 335 to roll back and forth on the top of the left and right base frames 31 and 32 through the gear assembly.

Reference is made to figures 1, 8, 9 and 10. The inner wall of the door frame 332 is provided with left and right vertical rails 336, left and right sliding blocks 337 are respectively disposed on the left and right sides of the vertical moving frame 333, and the vertical moving frame 333 is connected with the door frame 332 by means of the left and right sliding blocks 337 respectively sliding up and down in the corresponding left and right vertical rails 336. The top of the door frame 332 is provided with a second driving motor 338, and the second driving motor 338 drives the left and right sliding blocks 337 to slide up and down in the left and right vertical rails 336 through a transmission assembly.

Reference is made to figures 1, 8, 9 and 10. The vertical moving frame 333 includes upper and lower horizontal rods 3331 and 3332, a left vertical rod 3333 and a right vertical rod 3334 connected between the upper and lower horizontal rods 3331 and 3332, and the left and right end portions of the upper horizontal rod 3331 are respectively provided with the left and right sliding blocks 337; the plurality of mechanical heads 30 are sequentially spaced apart along the length direction of the lower horizontal bar 3332, and the number of the plurality of mechanical heads 30 corresponds to the number of the plurality of dewatering tables of each dewatering machine 2 one by one.

Reference is made to fig. 8, 9 and 10. The mechanical head 30 comprises an upper disc body 302, a lower disc body 303 and a first connecting rod 304, wherein the upper disc body 302 and the lower disc body 303 are arranged on the lower horizontal rod 3332, the first connecting rod 304 is connected between the upper disc body 302 and the lower disc body 303, the upper disc body 302 is connected on the lower horizontal rod 3332 through a second connecting piece 305, three hanging hook pieces 306 which are arranged in a triangular mode are movably arranged at the bottom of the disc surface of the lower disc body 303, and the tops of the three hanging hook pieces 306 are arranged in a radial mode along the center of the lower disc body 303. A vertical cylinder 307 is further disposed between the upper and lower trays 302 and 303, a piston rod of the vertical cylinder 307 extends downward through a center of the lower tray 303, a shaft sleeve 308 is sleeved at an end of the piston rod, a side wall of each hook member 306 is connected with an inclined rod 309, one end of each inclined rod 309 is movably connected with a side wall of a corresponding hook member 306, the other end of each inclined rod 309 is connected to an outer side wall of the shaft sleeve 308, and the three hook members 306 realize loosening and grasping (i.e. opening or closing) actions on the bung hole 60 of the dewatering tub 6 through up-and-down movement of the piston rod of the vertical cylinder 307. The vertical air cylinder 307 is adopted to drive the plurality of hook pieces 306 to open and close, so that the dewatering barrel 6 is conveniently lifted and put down, the operation is stable, and the operation is convenient.

Reference is made to fig. 1, 11, 12 and 13. The dehydrator 2 comprises a dehydration frame 21 and a dehydration container 22 which is arranged on the dehydration frame 21 and can swing left and right, a plurality of dehydration turntables 23 used for placing a plurality of dehydration barrels 6 and dehydration motors 24 driving each dehydration turntable 23 to rotate at high speed are arranged in the dehydration container 22, the dehydration turntables 420 and the dehydration motors 421 form a rotating device, and each dehydration motor 24 is arranged at the bottom of the dehydration container 22. The number of the dehydrators 2 is four, the four dehydrators 2 are sequentially arranged to form a multi-stage dehydration line, and a plurality of dehydration barrels 6 on a plurality of dehydration turntables 23 in each dehydrator 2 can be simultaneously fetched and placed at a time by a manipulator 3. The dehydration container 42 comprises a container body, a container cover 25 covered on the top of the container body, and an uncovering cylinder 26 for driving the container cover 25 to open and close, wherein the bottom of the uncovering cylinder 26 is fixedly connected to the bottom of one side wall of the container body, and the end part of a piston rod of the uncovering cylinder 26 is connected to one side wall of the container cover 25. The number of the dewatering tables 23 is three, but may be two or four, or other suitable numbers.

Reference is made to figures 1, 14 and 15. The discharging table 4 comprises a discharging frame 41, a plurality of discharging stations 42 which are arranged on the discharging frame 41 and used for receiving the manipulator 3 to take out a plurality of dewatering buckets 6 from the dewatering machine 2, a discharging conveyor belt 5 which is positioned on one side of the plurality of discharging stations 42 and used for feeding the drying conveyor belt 7, and a turning device 43 which synchronously turns and pours the plurality of dewatering buckets 6 on the plurality of discharging stations 42 onto the discharging conveyor belt 5 and is provided with a stop lever assembly 40. This platform structural design ideal of unloading can empty the in-process of unloading to synchronous pouring of a plurality of dehydration bucket 6, adopts the design of pin subassembly 40, and the bung hole of a plurality of dehydration bucket 6 receives the blocking effect of pin subassembly 40 simultaneously, and dehydration bucket 6 is difficult for becoming flexible to drop, can satisfy a plurality of dehydration buckets and empty the operation simultaneously in step.

Reference is made to fig. 1, 14, 15 and 16. The turnover device 43 comprises a swinging frame 44 arranged on the plurality of unloading stations 42 and a turnover motor 45 for driving the swinging frame 44 to turn over and topple over, and the turnover motor 45 is arranged on one side wall of the unloading frame 41; the swinging frame 44 comprises a plurality of unit placing frames 440 for placing a plurality of dewatering barrels 6, wherein each unit placing frame 440 is internally provided with the unloading station 42, each unit placing frame 440 is used for placing one dewatering barrel 6, each unit placing frame 440 comprises a frame bottom on which the bottom of the dewatering barrel 6 is placed and a plurality of limiting vertical rods which are arranged around the frame bottom in a surrounding manner and play a limiting role on the dewatering barrel 6, and one side wall of each limiting vertical rod can be abutted against the side wall of the dewatering barrel 6.

Reference is made to fig. 14, 15 and 16. The turning device 43 further comprises a blocking assembly 40 for blocking the outer edges of the mouths of the plurality of dewatering barrels 6, the blocking assembly 40 comprises a blocking cylinder 400 positioned on the top surface of the swinging frame 44 and a blocking rod 401 connected with the piston rod of the blocking cylinder 400 and playing a role in blocking the outer edges of the mouths of the plurality of dewatering barrels 6, the blocking cylinder 400 is arranged along the width direction of the swinging frame 44 and positioned on the side edges of the swinging frame 44; the blocking lever 401 is disposed along the length direction of the swing frame 44 and is located on the rear edge of the swing frame 44, and the blocking lever 401 is pulled by the piston rod of the blocking cylinder 400 so that it moves forward to be blocked on the outer edges of the tub mouths of the plurality of dewatering tub 6.

Reference is made to fig. 14, 15 and 16. The number of the blocking cylinders 400 is two, the two blocking cylinders 400 are respectively positioned on the left side edge and the right side edge of the swing frame 44, and the left end and the right end of the blocking rod 401 are respectively connected with the piston rods of the two blocking cylinders 400; the blocking assembly 40 further comprises a guide bar 402 arranged along the width direction of the swing frame 44, the guide bar 402 being provided with a bar-shaped opening 403 arranged along the length direction thereof and through which the blocking bar 401 passes. The number of the guide bars 402 is plural, and the plural guide bars 402 are sequentially arranged at intervals on the top surface of the swing frame 44 in the width direction of the swing frame. The discharging conveyor belt 5 is positioned on one side edge of the discharging frame 41, the length direction of the discharging conveyor belt is consistent with the length direction of the discharging frame 41, and the drying conveyor belt 7 is positioned at the tail end of the discharging conveyor belt 5; the outer side edge of the discharging conveyer belt 5 is provided with a baffle plate 50 extending obliquely upwards. The discharge conveyor 7 is a mesh conveyor.

Reference is made to fig. 1, 2, 6, 7, 8, 9, 11, 13, 15 and 16. An improved automatic dehydration process for battery steel shells comprises the following steps of 1) automatically feeding, transferring battery steel shells in a rolling cage 10 on an electroplating production line into a plurality of dehydration barrels 6 on an automatic feeding device 1 for automatic feeding operation; the automatic feeding device 1 comprises a receiving groove body 12 with a dewatering barrel feeding station 11, a battery steel shell discharging hopper 13 arranged on one side of the receiving groove body 12 and positioned below a discharging station of a rolling cage 10 on an electroplating production line, a material loading trolley 14 movably arranged in the receiving groove body 12 and reciprocating between the battery steel shell discharging hopper 13 and the dewatering barrel feeding station 11, a discharging assembly 15 arranged on one side of the receiving groove body 12 and used for discharging the rolling cage 10, and a material blocking assembly 16 positioned at the bottom of the battery steel shell discharging hopper 13 and capable of blocking a discharging opening of the battery steel shell discharging hopper.

2) Automatic feeding, namely synchronously hanging a plurality of dewatering buckets into the corresponding dewatering machine 2 through a door-shaped manipulator 3 for automatic feeding operation; the robot 3 includes left and right base frames 31 and 32 at both sides of the plurality of dehydrators 2, a moving frame 33 mounted on the left and right base frames 31 and 32 and movable forward and backward at the top thereof, and a plurality of robot heads 30 fixedly coupled to the moving frame 33 and vertically movable thereon.

3) The dehydration operation, which adopts a rotating device on the dehydrator 2 to drive a plurality of dehydration barrels 6 on the dehydrator to rotate at high speed so as to dehydrate and spin-dry the battery steel shell; each of the dehydrators 2 comprises a dehydration frame 21 and a dehydration container 22 which is arranged on the dehydration frame 21 and can swing left and right, a plurality of dehydration turntables 23 for placing a plurality of dehydration barrels 6 and dehydration motors 24 for driving each dehydration turntable 23 to rotate at high speed are arranged in the dehydration container 22, the dehydration turntables 420 and the dehydration motors 421 form a rotating device, and each dehydration motor 24 is arranged at the bottom of the dehydration container 22.

4) Automatic discharge and drying, the dewatering barrel 6 is taken out from the dewatering machine 2 through the door-shaped mechanical arm 3 and transferred to a plurality of discharging stations 42 of the discharging table 4, the plurality of dewatering barrels 6 on the plurality of discharging stations 42 are synchronously turned and poured onto the discharging conveyor belt 5 through a turning device 43 on the discharging table 4, and then the battery steel shell can be conveyed to the drying conveyor belt 7 along the discharging conveyor belt 5 for subsequent drying operation. The discharging table 4 comprises a discharging frame 41, a plurality of discharging stations 42 which are arranged on the discharging frame 41 and used for receiving the manipulator 3 to take out a plurality of dewatering buckets 6 from the dewatering machine 2, a discharging conveyor belt 5 which is positioned on one side of the plurality of discharging stations 42 and used for feeding the drying conveyor belt 7, and a turning device 43 which synchronously turns and pours the plurality of dewatering buckets 6 on the plurality of discharging stations 42 onto the discharging conveyor belt 5 and is provided with a stop lever assembly 40.

The foregoing is merely illustrative of specific embodiments of the present utility model, but the design concept of the present utility model is not limited thereto, and any insubstantial modification of the present utility model by using the design concept shall fall within the scope of the present utility model.

Claims (5)

1. Be applied to automatic dewatering system's of improved generation battery steel casing platform of unloading, its characterized in that: the automatic overturning device comprises a discharging frame body, a discharging station, a discharging conveying belt and an overturning device, wherein the discharging station is arranged on the discharging frame body and used for taking out a plurality of dewatering buckets from a dehydrator by a bearing manipulator, the discharging conveying belt is positioned on one side of the discharging station and used for feeding a drying conveying belt, the overturning device synchronously overturns and dumps the dewatering buckets on the discharging station onto the discharging conveying belt and is provided with a stop lever assembly, the overturning device comprises a swinging frame arranged on the discharging station and an overturning motor for driving the swinging frame to overturn and dump, and the overturning motor is arranged on one side wall of the discharging frame body.

2. The discharge station for an improved automatic battery steel can dewatering system of claim 1, wherein: the overturning device further comprises a blocking component for blocking the outer edges of the bung holes of the plurality of dewatering buckets, the blocking component comprises a blocking cylinder and a blocking rod, the blocking cylinder is arranged on the top surface of the swinging frame, the blocking rod is connected with a piston rod of the blocking cylinder and is used for blocking the outer edges of the bung holes of the plurality of dewatering buckets, and the blocking cylinder is arranged along the width direction of the swinging frame and is positioned on the side edges of the swinging frame; the blocking rod is arranged along the length direction of the swing frame and is positioned on the rear edge of the swing frame, and the blocking rod is pulled by the piston rod of the blocking cylinder so that the blocking rod moves forwards to be blocked on the outer edges of the bung holes of the plurality of dewatering barrels.

3. A discharge station for an improved automatic battery steel casing dehydration system as claimed in claim 2, wherein: the number of the blocking cylinders is two, the two blocking cylinders are respectively positioned on the left side edge and the right side edge of the swing frame, and the left end part and the right end part of the blocking rod are respectively connected with piston rods of the two blocking cylinders; the blocking assembly further comprises a guide strip arranged along the width direction of the swinging frame, and the guide strip is provided with a strip-shaped opening which is arranged along the length direction of the guide strip and used for blocking the rod to pass through.

4. A discharge station for an improved automatic battery steel casing dehydration system as set forth in claim 3 wherein: the number of the guide bars is plural, and the plural guide bars are sequentially arranged on the top surface of the swing frame at intervals in the width direction of the swing frame.

5. The discharge station for an improved automatic battery steel can dewatering system of claim 1, wherein: the swing frame is including being used for placing a plurality of units of a plurality of dewatering barrels and putting the frame, and every unit is put the frame and is used for putting a dewatering barrel, and every unit is put the frame bottom and is enclosed to establish all around and play a plurality of spacing montant of limiting function to this dewatering barrel including a dewatering barrel bottom is arranged in on it to every spacing montant lateral wall can conflict on the lateral wall of this dewatering barrel.