CN221081118U - Stator core stacking equipment - Google Patents

Abstract

The utility model provides stacking equipment for stator cores, and belongs to the technical field of stator cores. This kind of stator core fold equipment, including the transport table, the inside of transport table is equipped with the recess, and the internally mounted of recess has the conveyer belt, the inside of a pair of second support column all is equipped with first spout, and screw and guide bar are installed respectively to the inside of a pair of first spout, the outside of screw all slidable mounting has the slide, and one side of a pair of slide is connected with the mounting panel, the top of mounting panel is equipped with fixture, and fixture includes a pair of clamping bar, the collecting box is installed to one side of transport table, and the inside of collecting box is equipped with the collecting vat, the internally mounted of collecting vat has the installation pole, and the outside of installation pole is equipped with fixed establishment, fixed establishment includes a plurality of clamp splice, through being equipped with fixture, be convenient for carry out the centre gripping to the iron core, cooperation fixed establishment stacks the iron core of equidimension.

Description

Stator core stacking equipment

Technical Field

The utility model relates to the technical field of stator cores, in particular to a stacking device of a stator core.

Background

The rotating part of the motor is called a rotor, the stator is not rotated, and the rotor or the stator of the motor is generally formed by stacking a plurality of iron core punching sheets and then processing the iron core punching sheets in a punching mode, so that the iron core punching sheets are required to be stacked and aligned in the production and processing process of the rotor or the stator of the motor.

The position of the positioning rod in the iron core stacking equipment is relatively fixed, and the positioning rod cannot be adjusted according to different rotor punching sheets, namely, the positioning rod cannot be suitable for the use of more rotor punching sheets with different models and sizes, so that the universality of the equipment is not high enough, different stacking devices are required to be added by manufacturers for producing stators or rotors with different models, and the production cost is increased.

Disclosure of utility model

In order to overcome the defects, the utility model provides a stator core stacking device.

The utility model is realized in the following way:

The utility model provides a stator core's folding equipment, includes the transport table, the inside of transport table is equipped with the recess, just the internally mounted of recess has the conveyer belt, first support column is all installed to the bottom both sides of transport table, just the bottom of transport table is keeping away from one side of first support column and is installed a pair of second support column, a pair of the inside of second support column all is equipped with first spout, and a pair of lead screw and guide bar are installed respectively to the inside of first spout, the outside of lead screw all slidable mounting has the slide, and a pair of one side of slide is connected with the mounting panel, the top of mounting panel is equipped with fixture, just fixture includes a pair of clamping lever, the collecting box is installed to one side of transport table, just the inside of collecting box is equipped with the collecting tank, the internally mounted of collecting tank has the installation pole, just the outside of installation pole is equipped with fixed establishment, fixed establishment includes a plurality of clamp splice.

Further, one of them the internally mounted of first spout has first motor, just the output and the lead screw transmission of first motor are connected, first fixed case is installed at the top of mounting panel, just the second motor is installed to one side of first fixed case.

The beneficial effect of adopting above-mentioned further scheme is, through installing the lead screw, can drive the mounting panel and rise and descend, be convenient for carry out the centre gripping and place the iron core.

Further, the output end transmission of second motor is connected with first pivot, just the one end of first pivot runs through first fixed case to install drive bevel gear, the internally mounted of first fixed case has the second pivot, just driven bevel gear is installed to the bottom of second pivot, drive bevel gear and driven bevel gear intermeshing.

Further, one end of the second rotating shaft penetrates through the first fixed box and is connected with a connecting block, the top of the connecting block is connected with the second fixed box, a moving groove is formed in the second fixed box, and an air cylinder is mounted on one side of the second fixed box.

The beneficial effect of adopting above-mentioned further scheme is, through installing the cylinder, can drive the piston piece and lengthen or shorten to adjust the distance between a pair of clamp rod.

Further, the output end of the cylinder penetrates through the second fixed box and is connected with a piston block, a sliding rod is arranged in the moving groove, a limiting rod is arranged on one side of the sliding rod, a pair of clamping rods are slidably arranged outside the sliding rod and the limiting rod, a pair of springs are arranged outside the sliding rod, and one ends of the springs are connected with the clamping rods.

The beneficial effect of adopting above-mentioned further scheme is, through installing a pair of clamp lever, can carry out the centre gripping to the iron core, then place in the outside of installation pole, carry out the stack and collect.

Further, a plurality of second sliding grooves are formed in the mounting rod at equal intervals, connecting plates are mounted in the second sliding grooves, and one side of each connecting plate penetrates through each second sliding groove and is connected with the clamping blocks.

The beneficial effect of adopting above-mentioned further scheme is, through installing a plurality of clamp splice, can carry out the dress of folding to the iron core.

Further, the inside of installation pole is inserted and is equipped with first dwang, just the outside of first dwang is equipped with first gear in the one end cover of installation pole, just the inside equidistance of first gear is equipped with a plurality of mounting grooves, a plurality of equal slidable mounting in inside of mounting groove has the connecting rod, and a plurality of the connecting rod all with connecting plate interconnect.

The beneficial effect of adopting above-mentioned further scheme is, through installing the connecting plate, can drive the clamp splice and lengthen or shorten to adjust the diameter of installation pole.

Further, a second rotating rod is inserted at one side of the mounting rod, a second gear is sleeved outside the second rotating rod, and the first gear and the second gear are meshed with each other.

Further, the fixed plate is installed to top one side of transport table, just a pair of telescopic link is installed to one side of fixed plate, a pair of the output of telescopic link is connected with the guide plate, just the guide plate is laminated with the conveyer belt each other.

The beneficial effect of adopting above-mentioned further scheme is, through installing a pair of telescopic link, can adjust the position of guide plate to carry out spacingly to the iron core in the transportation of iron core.

The beneficial effects of the utility model are as follows: according to the stacking equipment for the stator iron core, which is obtained through the design, when the iron core is stacked, the iron core is conveyed through the conveying belt, in the conveying process, the pair of telescopic rods can be started, the position of the guide plate is adjusted, so that the iron core is limited in the conveying process of the iron core, then the air cylinder is started, the air cylinder drives the piston block to move, when the air cylinder moves between the pair of clamping rods, the pair of clamping rods are pushed to two sides, the pair of clamping rods move on the sliding rod, the pair of clamping rods are supported through the limiting rods, the pair of clamping rods clamp the iron core, then the second motor is started, the second motor drives the first rotary shaft and the driving bevel gear to rotate, the driven bevel gear and the second rotary shaft rotate, the connecting block and the second fixed box rotate by 180 degrees, the air cylinder is started, the air cylinder drives the piston block to move forwards, the pair of clamping rods move to two sides, the pair of clamping rods are separated from the iron core, the iron core is sleeved on the outer side of the iron core, the pair of clamping rods rotate outside the iron core, the diameter of the iron core is reduced, and the diameter of the connecting rod is not adjusted, and the diameter of the connecting rods is reduced when the iron core is installed inside the connecting rods or the connecting rods are not rotated, and the diameter of the connecting rods are not rotated.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present utility model, the drawings that are needed to be practical in the embodiments will be briefly described below, it being understood that the following drawings only illustrate some examples of the present utility model and therefore should not be considered as limiting the scope, and that other related drawings can be obtained according to these drawings without the inventive effort of a person skilled in the art.

Fig. 1 is a schematic perspective view of a stacking apparatus for stator cores according to the present utility model;

Fig. 2 is a schematic perspective view of a mounting rod of a stacking apparatus for a stator core according to the present utility model;

fig. 3 is a schematic perspective view of a clamping rod of a stacking apparatus for stator cores according to the present utility model;

Fig. 4 is a schematic top view of a mounting rod of a stacking apparatus for stator cores according to the present utility model;

Fig. 5 is an enlarged schematic view of the structure a in fig. 1.

In the figure: 1001. a transport table; 1002. a groove; 1003. a conveyor belt; 1004. a first support column; 1005. a second support column; 1006. a fixing plate; 1007. a telescopic rod; 1008. a deflector; 2001. a first chute; 2002. a first motor; 2003. a screw rod; 2004. a slide plate; 2005. a mounting plate; 2006. a first fixed box; 2007. a second motor; 2008. a first rotating shaft; 2009. a drive bevel gear; 2010. a driven bevel gear; 2011. a second rotating shaft; 2012. a connecting block; 2013. a second fixed box; 2014. a cylinder; 2015. a moving groove; 2016. a piston block; 2017. a slide bar; 2018. a limit rod; 2019. a spring; 2020. a clamping rod; 3001. a mounting rod; 3002. a second chute; 3003. a connecting plate; 3004. clamping blocks; 3005. a first gear; 3006. a mounting groove; 3007. a connecting rod; 3008. a first rotating lever; 3009. a second gear; 3010. a second rotating lever; 3011. a collection box; 3012. a collection tank.

Detailed Description

For the purpose of making the objects, technical solutions and advantages of the embodiments of the present utility model more apparent, the technical solutions of the embodiments of the present utility model will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present utility model, and it is apparent that the described embodiments are some embodiments of the present utility model, but not all embodiments. All other embodiments, based on the embodiments of the utility model, which are apparent to those of ordinary skill in the art without inventive faculty, are intended to be within the scope of the utility model.

Thus, the following detailed description of the embodiments of the utility model, as presented in the figures, is not intended to limit the scope of the utility model, as claimed, but is merely representative of selected embodiments of the utility model. All other embodiments, based on the embodiments of the utility model, which are apparent to those of ordinary skill in the art without inventive faculty, are intended to be within the scope of the utility model.

An embodiment of a stator core stacking apparatus of the present utility model

The utility model provides the following technical scheme: as referring to fig. 1, 3 and 5, the conveyor table 1001 comprises a conveyor table 1001, wherein a groove 1002 is arranged in the conveyor table 1001, a conveyor belt 1003 is arranged in the groove 1002, first support columns 1004 are arranged on two sides of the bottom of the conveyor table 1001, a pair of second support columns 1005 are arranged on one side, far away from the first support columns 1004, of the bottom of the conveyor table 1001, first sliding grooves 2001 are arranged in the second support columns 1005, a lead screw 2003 and a guide rod are respectively arranged in the first sliding grooves 2001, the outside of the screw 2003 is slidably provided with sliding plates 2004, one side of each pair of sliding plates 2004 is connected with a mounting plate 2005, the top of each mounting plate 2005 is provided with a clamping mechanism, each clamping mechanism comprises a pair of clamping bars 2020, a collecting box 3011 is arranged on one side of the transport table 1001, a collecting groove 3012 is arranged in the collecting box 3011, a mounting rod 3001 is arranged in the collecting groove 3012, a fixing mechanism is arranged outside the mounting rod 3001, each fixing mechanism comprises a plurality of clamping blocks 3004, a first motor 2002 is arranged in one first sliding groove 2001, the output end of the first motor 2002 is in transmission connection with a screw rod 2003, a first fixing box 2006 is arranged at the top of the mounting plate 2005, a second motor 2007 is arranged at one side of the first fixing box 2006, the output end of the second motor 2007 is in transmission connection with a first rotating shaft 2008, one end of the first rotating shaft 2008 penetrates through the first fixing box 2006 and is provided with a driving bevel gear 2009, a second rotating shaft 2011 is arranged in the first fixing box 2006, the bottom end of the second rotating shaft 2011 is provided with a driven bevel gear 2010, the driving bevel gear 2009 and the driven bevel gear 2010 are meshed with each other, one end of the second rotating shaft 2011 penetrates through the first fixed box 2006 and is connected with a connecting block 2012, the top of the connecting block 2012 is connected with a second fixed box 2013, a moving groove 2015 is arranged in the second fixed box 2013, a cylinder 2014 is arranged on one side of the second fixed box 2013, an output end of the cylinder 2014 penetrates through the second fixed box 2013 and is connected with a piston block 2016, a sliding rod 2017 is arranged in the moving groove 2015, a limiting rod 2018 is arranged on one side of the sliding rod 2017, a pair of clamping rods 2020 are slidably arranged outside the sliding rod 2017 and the limiting rod 2018, and the outside of slide bar 2017 is installed a pair of spring 2019, and a pair of spring 2019's one end all with a pair of clamp rod 2020 interconnect, through installing lead screw 2003, can drive mounting panel 2005 and rise and descend, be convenient for carry out centre gripping and place the iron core, through installing cylinder 2014, can drive piston piece 2016 and lengthen or shorten to adjust the distance between a pair of clamp rod 2020, through installing a pair of clamp rod 2020, can carry out the centre gripping to the iron core, then place the outside at mounting bar 3001, stack dress and collection.

Embodiment two of a stator core stacking device of the utility model

Referring to fig. 2 and 4, a plurality of second sliding grooves 3002 are equidistantly arranged in the mounting rod 3001, a connecting plate 3003 is installed in each of the plurality of second sliding grooves 3002, one side of the connecting plate 3003 penetrates through the second sliding groove 3002 and is connected with a plurality of clamping blocks 3004, a first rotating rod 3008 is inserted in the mounting rod 3001, a first gear 3005 is sleeved on one end of the mounting rod 3001 at the outer portion of the first rotating rod 3008, a plurality of mounting grooves 3006 are equidistantly arranged in the first gear 3005, connecting rods 3007 are slidably installed in each of the plurality of mounting grooves 3006, the plurality of connecting rods 3007 are connected with the connecting plate 3003, a second rotating rod 3010 is inserted in one side of the mounting rod 3001, and the outside cover of second dwang 3010 is equipped with second gear 3009, first gear 3005 and second gear 3009 intermesh, fixed plate 1006 is installed to top one side of transport table 1001, just a pair of telescopic link 1007 is installed to one side of fixed plate 1006, a pair of the output of telescopic link 1007 is connected with guide plate 1008, just guide plate 1008 and conveyer belt 1003 laminating each other, can stack the iron core through installing a plurality of clamp splice 3004, can drive clamp splice 3004 through installing connecting plate 3003 to adjust the diameter of installation pole 3001, can adjust the position of guide plate 1008 through installing a pair of telescopic link 1007, thereby carry out spacingly to the iron core in the transportation of iron core.

Specifically, the working principle of the stacking equipment of the stator core is as follows: when the iron cores are stacked, the iron cores are conveyed through the conveying belt 1003, in the conveying process, a pair of telescopic rods 1007 can be started to adjust the positions of the guide plates 1008, so that the iron cores are limited in the conveying process of the iron cores, when the iron cores are conveyed to one end of the conveying belt 1003, then the air cylinders 2014 are started to drive the piston blocks 2016 to move, when the iron cores are conveyed between the pair of clamping rods 2020, the pair of clamping rods 2020 are pushed to two sides to move on the sliding rods 2017, the pair of clamping rods 2020 are supported through the limiting rods 2018, the pair of clamping rods 2020 clamp the iron cores, then the second motor 2007 is started to drive the first rotary shaft 2008 and the driving bevel gear 2009 to rotate, so that the driven bevel gear 2010 and the second rotary shaft 2011 drive the connecting blocks 2012 and the second fixing boxes 2013 to rotate, when the first motor 2002 is started to rotate the collection box 3011 by 180 degrees, the first motor 2002 drives the screw 2003 to rotate, the mounting plate 2005 is driven to move downwards, then the cylinder 2014 is started, the cylinder 2014 drives the piston blocks 2016 to move forwards, the pair of clamping bars 2020 move to two sides, the pair of clamping bars 2020 are separated from the iron cores, then the iron cores are sleeved outside the clamping blocks 3004 to stack and collect the iron cores, when the iron cores with different sizes are transported, the second rotating rod 3010 is rotated, the second rotating rod 3010 drives the second gear 3009 to rotate, the first gear 3005 is driven to rotate, the connecting rods 3007 move in the mounting grooves 3006, the connecting rods 3003 are driven to move in the second sliding grooves 3002, the clamping blocks 3004 are stretched or shortened, the diameters of the mounting rods 3001 are convenient to adjust, and fixing and collecting iron cores with different diameters.

It should be noted that, specific model specifications of the telescopic rod 1007, the first motor 2002, the second motor 2007 and the air cylinder 2014 of the stacked apparatus of the stator core need to be determined by selecting a model according to actual specifications of the apparatus, and a specific model selection calculation method adopts the prior art in the art, so detailed descriptions thereof are omitted.

The power supply of the stacked apparatus of stator cores, the telescopic rod 1007, the first motor 2002, the second motor 2007, and the cylinder 2014, and the principle thereof will be apparent to those skilled in the art, and will not be described in detail herein.

The above description is only of the preferred embodiments of the present utility model and is not intended to limit the present utility model, and various modifications and variations may be made to the present utility model by those skilled in the art. Any modification, equivalent replacement, improvement, etc. made within the spirit and principle of the present utility model should be included in the protection scope of the present utility model.

Claims (9)

1. A stator core stacking apparatus is characterized by comprising a transport table (1001),

The inside of transport table (1001) is equipped with recess (1002), just internally mounted of recess (1002) has conveyer belt (1003), first support column (1004) are all installed to the bottom both sides of transport table (1001), just the bottom of transport table (1001) is installed in one side of keeping away from first support column (1004) a pair of second support column (1005), a pair of the inside of second support column (1005) all is equipped with first spout (2001), and a pair of lead screw (2003) and guide bar are installed respectively to the inside of first spout (2001), the outside of lead screw (2003) all slidable mounting has slide (2004), and a pair of one side of slide (2004) is connected with mounting panel (2005), the top of mounting panel (2004) is equipped with fixture, just fixture includes a pair of clamp bar (2020), collecting box (3011) are installed to one side of transport table (1001), just the inside of collecting box (3011) is equipped with collecting tank (3012), internally mounted of collecting tank (3012) has lead screw (2003) and guide bar, the outside of lead screw (2003) all slidable mounting has slide (2004), and a pair of slide (2004) one side is connected with mounting panel (2005), the top is equipped with fixture (2005).

2. The stator core stacking apparatus according to claim 1, wherein a first motor (2002) is installed inside one of the first sliding grooves (2001), an output end of the first motor (2002) is in driving connection with a screw (2003), a first fixing box (2006) is installed at a top of the mounting plate (2005), and a second motor (2007) is installed at one side of the first fixing box (2006).

3. The stator core stacking apparatus according to claim 2, wherein an output end of the second motor (2007) is drivingly connected with a first rotating shaft (2008), one end of the first rotating shaft (2008) penetrates through a first fixed box (2006) and is provided with a drive bevel gear (2009), a second rotating shaft (2011) is installed inside the first fixed box (2006), a driven bevel gear (2010) is installed at a bottom end of the second rotating shaft (2011), and the drive bevel gear (2009) and the driven bevel gear (2010) are meshed with each other.

4. A stacking device for stator cores according to claim 3, characterized in that one end of the second rotating shaft (2011) penetrates through the first fixed box (2006) and is connected with a connecting block (2012), the top of the connecting block (2012) is connected with a second fixed box (2013), a moving groove (2015) is arranged inside the second fixed box (2013), and a cylinder (2014) is mounted on one side of the second fixed box (2013).

5. The stator core stacking apparatus according to claim 4, wherein an output end of the cylinder (2014) penetrates through the second fixed box (2013) and is connected with a piston block (2016), a slide bar (2017) is installed inside the moving groove (2015), a limit bar (2018) is installed on one side of the slide bar (2017), a pair of clamping bars (2020) are slidably installed outside the slide bar (2017) and the limit bar (2018), a pair of springs (2019) are installed outside the slide bar (2017), and one ends of the pair of springs (2019) are connected with the pair of clamping bars (2020).

6. The stator core stacking apparatus according to claim 1, wherein a plurality of second sliding grooves (3002) are provided at equal intervals in the interior of the mounting rod (3001), and connecting plates (3003) are mounted in the interior of the plurality of second sliding grooves (3002), and one side of each connecting plate (3003) penetrates through each second sliding groove (3002) and is connected with each of the plurality of clamping blocks (3004).

7. The stator core stacking device according to claim 1, wherein a first rotating rod (3008) is inserted into the mounting rod (3001), a first gear (3005) is sleeved on one end of the mounting rod (3001) on the outer portion of the first rotating rod (3008), a plurality of mounting grooves (3006) are formed in the first gear (3005) at equal intervals, connecting rods (3007) are slidably mounted in the mounting grooves (3006), and the connecting rods (3007) are connected with the connecting plates (3003).

8. The stator core stacking apparatus according to claim 7, wherein a second rotating rod (3010) is inserted at one side of the mounting rod (3001), a second gear (3009) is sleeved outside the second rotating rod (3010), and the first gear (3005) and the second gear (3009) are meshed with each other.

9. The stator core stacking apparatus according to claim 1, wherein a fixing plate (1006) is installed on a top side of the transportation table (1001), and a pair of telescopic rods (1007) are installed on one side of the fixing plate (1006), and a guide plate (1008) is connected to an output end of the pair of telescopic rods (1007), and the guide plate (1008) and the conveyor belt (1003) are attached to each other.