CN210446802U - Automatic separation device for separating yolk from egg white - Google Patents

Abstract

The utility model relates to a food processing equipment field especially indicates an autosegregation device for separating yolk and egg white, including the frame with be located the roating seat of rotation on the frame. A plurality of separating mechanisms are fixed on the ring surface of the rotating seat, and each separating mechanism comprises an egg white box, an egg yolk box, a connecting frame and a supporting rod. The link connect in the roating seat, the side of yolk box below has the space, the branch lower extreme rotates to be connected in the link upper end, and the yolk box is fixed in the branch upper end, egg white box rotates to be connected in the link lower extreme to egg white box is located under the yolk box, and one side that egg white box corresponds branch still is equipped with the dog. The egg yolk egg white separator is characterized in that a bearing strip is fixed on the machine base, an inclined plane which inclines upwards is arranged at the position of the bearing strip before egg yolk and egg white are poured, a rack is fixed at one end in the rotary base of the machine base, the rack is consistent with the moving path of the support rod, and the length of one end, close to the machine base, of the support rod extends to be capable of contacting the rack.

Description

Automatic separation device for separating yolk from egg white

Technical Field

The utility model relates to a food processing equipment field especially indicates an automatic separation device for separating yolk and egg white.

Background

When the cake is made, eggs are the main raw materials, the cakes made of egg white and yolk have different tastes, and the egg white and the yolk are separated when the cakes with different tastes are made. The separation work of yolk and albumen of fresh eggs in the existing food processing technology is a very labor-consuming process, and most of the separation work needs manual operation. Particularly, the most common yellow-clearing separator at present is a spoon-shaped separator used in a pastry shop, and has the characteristics of simplicity, convenience and low price, but the operation is uninterrupted by manpower, so that the working intensity is high, and the efficiency is low.

Disclosure of Invention

The utility model provides an automatic separation device for separating yolk and egg white to overcome the problem that the existing yolk and egg white separation equipment is inefficient.

The utility model adopts the following technical scheme: a autosegregation device for separating yolk and egg white, including frame and roating seat, the roating seat is located rotation on the frame, its characterized in that: a plurality of separating mechanisms are fixed on the ring surface of the rotary seat, each separating mechanism comprises an egg white box, a yolk box, a connecting frame and a supporting rod, the connecting frame is connected to the rotary seat, a gap is formed in the side surface below the yolk box, the lower end of the supporting rod is rotatably connected to the upper end of the connecting frame, the yolk box is fixed at the upper end of the supporting rod, the egg white box is rotatably connected to the lower end of the connecting frame, the egg white box is located right below the yolk box, and a stop block is further arranged on one side of the egg white box, corresponding; the egg white box is characterized in that a bearing strip is fixed on the machine base, the bearing strip is consistent with the moving path of the egg white box, an inclined plane which inclines upwards is arranged at the position of the bearing strip before egg yolk and egg white are poured, a rack is fixed at one end in the machine base rotating seat, the rack is consistent with the moving path of the support rod, and the length of the support rod, close to one end in the machine base, extends to be capable of contacting the rack.

As a further improvement, an egg white groove is formed in the machine base, and the bearing strip is located between the egg white groove and the position where the egg yolk and the egg white are poured.

As a further improvement, the machine base is provided with a yolk slot behind the egg white slot along the rotation direction of the rotary base, and the rack is positioned from the position of pouring the yolk and the egg white to the position of the front of the yolk slot.

As a further improvement, the bottom of the yolk box is an egg supporting groove with a concave circular structure, and a circle of penetrating gap is arranged on the yolk box on the egg supporting groove.

From the above description of the structure of the present invention, compared with the prior art, the present invention has the following advantages: the utility model discloses a separating mechanism when rotating under the drive of roating seat, when the egg white box removed the position on the bearing strip, egg white box upswing drove yolk box upswing simultaneously, and egg white box and yolk box are horizontal migration's state this moment, can pour yolk and egg white into in egg white box. And in this process, the vibrating arm contact at the branch end of fixed yolk box is in the rack, and the vibrating arm moves on the flank of tooth of rack and consequently forms the vibration to transmit the vibration to yolk box, be that yolk box will hold in the palm the egg white of egg inslot and shake off to from the space that holds in the palm egg groove upper edge through the mode of vibration on the egg white box, thereby yolk is located yolk box, and egg white is located egg white box, thereby reaches automatic effect that reaches separation yolk and egg white, compares artificial operation mode, and this mode has realized that automatic separation is more high-efficient.

Drawings

Fig. 1 is a schematic perspective view of the conveyor of the present invention with a shell breaking mechanism.

Fig. 2 is a schematic perspective view of the utility model after hiding each separation structure.

Fig. 3 is a perspective view of the back view of the breaking mechanism connected to the right above the separating mechanism.

Fig. 4 is a schematic perspective view of the contact process between the first guide sleeve and the first guide plate of the shell breaking mechanism.

Fig. 5 is a side view schematically illustrating a process of contacting the first guide sleeve and the first guide plate of the shell breaking mechanism.

Fig. 6 is a schematic perspective view of the contact process between the roller of the shell breaking mechanism and the second guide plate.

Fig. 7 is a schematic front view of the contact process between the roller of the shell breaking mechanism and the second guide plate.

Fig. 8 is a schematic front view of the egg after being cracked by the cracking mechanism.

Fig. 9 is a schematic perspective view of the separating mechanism of the present invention.

Fig. 10 is a schematic side view of the separating mechanism of the present invention.

Fig. 11 is a schematic perspective view of the revolving bed of the present invention connecting a plurality of shell breaking mechanisms and separating mechanisms.

Fig. 12 is an enlarged view of direction a in fig. 10.

Fig. 13 is an enlarged view in the direction B of fig. 10.

Fig. 14 is a perspective view from another side of fig. 10.

Fig. 15 is an enlarged view of the direction C in fig. 10.

Fig. 16 is an enlarged view in the direction D of fig. 10.

Fig. 17 is an enlarged view of direction E in fig. 10.

Detailed Description

The following describes embodiments of the present invention with reference to the drawings.

As shown in fig. 14 and 16, the automatic separation device for separating yolk from egg white comprises a base 6 and a rotary base 2, wherein the rotary base 2 is fixed with a plurality of separation mechanisms 4, the rotary base 2 is positioned on the base 6 for rotation, a rotary column is fixedly connected to the bottom of the rotary base 22, a bearing seat is fixed in the base 6, the rotary column is fixed in the bearing seat, a motor is fixed in the base 6, and the motor drives the rotary column to rotate in a chain transmission mode, so that rotation of the rotary base 2 on the base 6 can be realized.

As shown in fig. 1, 14 and 15, the base 6 is further provided with an egg white groove 7 and a yolk groove 8 in sequence behind the conveyor 3 along the rotation direction of the rotary base 2, the bottom surfaces of the egg white groove 7 and the yolk groove 8 are both inclined downward, and the lower ends of the egg white groove 7 and the yolk groove 8 are both provided with through holes, so that egg white collected in the egg white groove 7 and yolk collected in the yolk groove 8 can fall to a box body placed below the through holes for collection. Each separating mechanism 5 can be connected with a device for breaking shells and pouring out yolk and egg white, so that the yolk and the egg white directly fall on the separating mechanism 5, and the separating mechanism 5 is convenient for separating the yolk from the egg white. Specifically, the device for breaking the shell and pouring out the yolk and the egg white can be the shell breaking mechanisms 4 as shown in fig. 3 to 8, each shell breaking mechanism 4 is also fixed on the rotary base 2 and is right above the separation mechanism 5, so that the shell breaking mechanisms 4 and the separation mechanisms 5 are in one-to-one correspondence from top to bottom to form a group, and the rotation of the rotary base 2 can drive each shell breaking mechanism 4 and each separation mechanism 5 to revolve relative to the axis of the base 1.

In addition, as shown in fig. 14 and 16, the present invention can also be connected with a conveyer belt 3 for conveying eggs 1, the output end of the conveyer 3 faces the frame 6, and the conveyer 3 can be a roller conveyer driven by a chain 32. Furthermore, the ring surface of each roller 31 of the conveyor 3 is provided with a concave groove 311, eggs are placed on the conveyor 3 one by one, each egg 1 can be respectively positioned in the grooves 311 between two adjacent rollers 31 and conveyed orderly, and the eggs 1 are placed between the two rollers 31 in the conveying process, so that the eggs 1 can be prevented from rolling on the conveyor 3 arbitrarily, and the eggs 1 are prevented from being broken due to collision in the conveying process. In addition, the eggs 1 are placed in the grooves 311 of the two adjacent rollers 31, so that the eggs 1 are positioned, and the eggs 1 can accurately fall onto the shell breaking mechanism 4 by setting the running speed of the conveyor 3 and the corresponding rotating speed of the rotating base 2 when being conveyed out of the conveyor 3.

As shown in fig. 9 and 10, the separating mechanism 5 includes an egg white box 52, an egg yolk box 54, a connecting frame 51 and a support rod 53, the connecting frame 51 is fixed to the rotary base 2 and located below the breaking mechanism 4, a fixing ring 21 formed by surrounding pipe fittings is fixed below the specific rotary base 22, and the connecting frame 51 is fixed to the fixing ring 21 through a structure of inserting bolts. The bottom of the yolk box 54 is an egg supporting groove 541 with a concave circular structure, a circle of penetrating gap 542 is arranged on the egg supporting groove 541 of the yolk box 54, the width of the gap 542 is smaller than the thickness of the normal yolk after being flatly placed, and the yolk is prevented from shaking off along with the vibration of the yolk box. After the two egg receiving plates 44 of the shell breaking mechanism 4 are separated, the yolk and the albumen can fall down into the yolk box 54 and are positioned in the egg supporting groove 541. The support rod 53 is in an inverted T-shaped structure, the lower end of the support rod 53 is rotatably connected to the upper end of the connecting frame 51, the yolk box 54 is fixed to the upper end of the support rod 53, the egg white box 52 is rotatably connected to the lower end of the connecting frame 51, and the egg white box 52 is located right below the yolk box 54. The egg white box 52 is further provided with a raised stopper 521 at a side corresponding to the supporting rod 53. When the egg white box 52 swings upwards, the support rod 53 is jacked up by the stop block 52, so that the egg yolk box 54 is driven by the support rod 53 to swing upwards.

As shown in fig. 11, 12, 14 and 15, the support 6 is fixed with a support strip 55 at a position between the conveyor 3 and the albumen trough 7, the support strip 55 is consistent with the moving path of the albumen box 52, and the support strip 55 is provided with an upward inclined surface at a position before the yolk and the albumen are poured (i.e. at an end close to the conveyor 3). When the egg white box 52 moves to the position of the bearing strip 55, the egg white box 52 moves upwards along the inclined plane of the bearing strip 55 at one end of the conveyor 3, so that the egg white box 52 swings upwards to a position above the bearing strip 55, and moves horizontally along the upper surface of the bearing strip 55 under the bearing of the bearing strip 55, and the egg white box 52 swings upwards and simultaneously drives the egg yolk box 54 to swing upwards in the process. Until the egg white box is moved on the egg white groove 7 (i.e. after being separated from the supporting strip 55), the egg white box 52 is turned downwards due to no support at the bottom, so that the egg white on the egg white box 52 falls into the egg white groove 7.

As shown in fig. 2, 14 and 15, a rack 56 is fixed inside the frame 6 at a position before the conveyor 3 reaches the yolk slot 8, the rack 56 can be a rack used for meshing with a gear in the prior art, the rack 56 is consistent with the moving path of the support rod 53, the length of one end of the support rod 53 near the inside of the frame 6 is provided with a vibrating rod 531 which extends to be capable of contacting the rack 56, and after the albumen box 52 swings upwards to be positioned on the bearing strip 55 and the support rod 53 and the yolk box 54 swing upwards, the vibrating rod 531 contacts the rack 56. At this time, the vibration bar 531 moves on the tooth surface of the rack 56 as the support bar 53 and the yolk case 54 move, and is sequentially inserted into the respective tooth grooves of the rack 56 during the movement, thereby generating vibration, and transmitting the vibration to the yolk case 54. When the egg supporting groove 541 of the egg yolk box 54 contains the egg yolk and the egg white, in the process of vibration of the egg yolk box 54, the egg white in the egg supporting groove 541 is shaken off from the gap 542 on the upper edge of the egg supporting groove 541 onto the egg white box 52 in a vibration mode, so that the effect of separating the egg yolk from the egg white is achieved. After the egg white box 522 is separated from the supporting strip 55 and swings downwards, the supporting rod 53 loses the support of the stop block 521, and meanwhile, the vibrating rod 531 does not turn downwards rapidly under the action of resistance contacted with the rack 56 when moving, but gradually turns downwards along with the movement, and when moving to the yolk slot 8 (namely, being separated from the rack 56), the yolk box 54 loses the resistance and turns downwards completely, so that the yolk falls into the yolk slot 8.

As shown in fig. 3 to 8, the shell breaking mechanism 4 includes a fixed frame 41, a swing rod 43, a pressing block 45, a moving shaft 42, a connecting rod 46, a shell breaking knife 410 and an egg bearing plate 44. The fixing frame 41 is fixed on the side surface above the rotating base 2 in a manner of bolt penetration. The swing rod 43 is rotatably connected to both sides of the bottom of the fixing frame 41, the bottom of the fixing frame 41 is provided with an inward concave groove, one end of the swing rod 43 penetrates into the groove, and a pin 414 penetrates through the swing shaft 43 outside the fixing frame 41, so that the swing shaft 43 rotates relative to the fixing frame 41. The number of the egg bearing plates 44 is two, the two egg bearing plates 44 are respectively fixedly connected to the two swing rods 43 through welding rod bodies, and the egg bearing plates 44 are connected with the swing rods 43 to form an angle close to the vertical direction, so that the two egg bearing plates 44 swing relative to the side edge of the fixing frame 41. The egg bearing plates 44 are flat plates and are bent into a C-shaped structure, and the openings of the C-shaped structures are upward, so that the two egg bearing plates 44 can support the eggs 1 conveniently. The shell breaking knife 410 is fixed on the fixing frame 41, the cutting edge of the shell breaking knife 410 is positioned between the two egg bearing plates 44 and extends to the egg bearing plates 44, and the shell breaking knife 410 is close to one side of one of the egg bearing plates 44. The pressing block 45 is positioned above the egg bearing plate 44 and is rotationally connected with the fixed frame 41, so that the pressing block 45 is positioned above the egg bearing plate 44 and swings up and down relative to the egg bearing plate 44. The pressing block 45 is a metal part with a certain weight, and the bottom surface of the pressing block 45 is provided with an inwards concave cambered surface by which the egg 1 can be wrapped. After the pressing block 45 swings downwards, the egg 1 placed on the egg bearing plate 44 can be pressed downwards by the weight of the pressing block, so that the egg 1 is pressed to the shell breaking knife 410, and the bottom surface of the egg 1 is cut by the shell breaking knife 410 to form a crack.

As shown in fig. 2, 11 and 13, a guide rod 413 is fixed above the output end of the conveyor 3, both ends of the guide rod 413 are bent and inclined downwards relative to both sides of the conveyor 3, and a second guide sleeve 49 is rotatably connected to one end surface of the pressing block 45 away from the rotary base 2, preferably, the guide sleeve 49 is of a rotatable structure. When the shell breaking mechanism is driven by the 4 rotating base 2 to rotate to the conveyor 3, the second guide sleeve 49 moves upwards along the guide rod 413 in an inclined mode, when the shell breaking mechanism moves to the conveying plane position of the conveyor 3, the second guide sleeve 49 moves on the guide rod 413 under the driving of the rotating base 2, at the moment, the press block 45 is lifted upwards along with the second guide sleeve 49 along with the guide rod 413 in an inclined mode, in this way, an open state is formed between the press block 45 and the egg bearing plates 44, and eggs 1 conveyed by the conveyor 3 can directly fall onto the two egg bearing plates 44 of the shell breaking mechanism 4. Then, the shell breaking mechanism 4 continues to move, the second guide sleeve 49 moves downwards along the inclination of the guide rod 413 until the second guide sleeve is separated from the guide rod 413, at the moment, the pressing block 45 swings downwards along with the second guide sleeve 49 along the inclination of the guide rod 413 to press the egg 1 on the egg bearing plate 44, so that the pressing block 45 presses the egg 1 downwards to be cut by the shell breaking knife 410, and a crack is automatically formed at the bottom of the eggshell.

As shown in fig. 3 to 8, the fixing frame 41 is provided with a vertical through hole, and the moving shaft 42 is inserted into the through hole, so that the moving shaft 42 can move up and down relative to the fixing frame 41. The two swing rods 43 are rotatably connected with connecting rods 46, the specific connecting rod 46 can be connected to a pin shaft 414 connecting the swing rod 43 and the fixed frame 41, the other end of the connecting rod 46 opposite to the swing rod 43 is rotatably connected with the lower end of the moving shaft 42, when the moving shaft 422 moves upwards, the connecting rod 46 can be pulled to swing upwards by taking the pin shaft 414 as an axis, so that the swing rod 43 is driven to swing towards the center of the fixed frame 41, the moving shaft 42 moves upwards to drive the two egg bearing plates 44 to swing towards the fixed frame 41, and the closing is realized, so that a complete egg 1 can be supported. When the moving shaft 42 moves downward, the connecting rod 46 can be pulled to swing downward around the pin 414 as an axis, so as to drive the swing rod 43 to swing to incline toward the outer side of the fixed frame 41, thereby realizing that the moving shaft 42 moves downward to drive the two egg supporting plates 44 to swing to incline toward the outer side of the fixed frame 41, and realizing separation. When the two egg bearing plates 44 are closed and bear an egg 1, the pressing block 45 swings downwards to enable the eggshell of the egg 1 to be pressed downwards to be cut and split by the shell breaking knife 410 to form a crack, at the moment, the upper half part of the eggshell is wrapped by the pressing plate 45, the two egg bearing plates 44 are driven to be separated by pushing the moving shaft 42 to move downwards, the lower end of the cut eggshell can be made to form two halves along the crack and be separated towards the two ends of the fixing frame 41, therefore, the yolk and the egg white drop downwards to the separating mechanism 5, and the eggshell can be clamped between the two egg bearing plates 44 and the pressing block 45 by the downward pressing force of the pressing block 45, so that the eggshell cannot drop.

As shown in fig. 4 to 8 and 11, a first guide plate 411 and a second guide plate 412 are sequentially fixed to the machine base 1 on both sides of the conveyor 3 along the rotation direction of the rotary base 2, and the first guide plate 411 and the second guide plate 412 are both located above the rotary base 2. The first guide plate 411 is provided with an inclined surface inclined upward along the rotation direction of the rotary base 2, and the second guide plate 412 is provided with an inclined surface inclined downward along the rotation direction of the rotary base 2. A roller 48 is fixed on the top of the moving shaft 42, the roller 48 may be a bearing, and the roller 48 may move along the inclined surface of the second guide plate 412. A first guide sleeve 47 is rotatably connected to one end of the moving shaft 42 facing the conveyor 3, and preferably, the first guide sleeve 47 is of a rotatable structure, and the first guide sleeve 47 can move along the inclined surface in the first guide plate 411. When the shell breaking mechanism 4 moves the first guide plate 411 under the driving of the rotary seat 2, the first guide sleeve 47 gradually moves upwards along the inclined plane of the first guide plate 411 while moving, so as to drive the moving shaft 42 to move upwards, thereby realizing that the moving shaft 42 moves upwards to drive the two egg bearing plates 44 to swing towards the fixed frame 41, and realizing automatic closing. Subsequently, when the shell breaking mechanism 4 is driven by the rotary base 2 to continue to move to the second guide plate 412, the roller 48 gradually moves downward along the inclined surface of the second guide plate 412 while moving, so as to drive the moving shaft 42 to move downward, thereby realizing that the moving shaft 42 moves downward to drive the two egg bearing plates 44 to swing outward of the fixed frame 41, and realizing automatic separation.

In addition, as shown in fig. 4, 7 and 8, the fixing frame 41 is connected to the torsion springs 415 at positions connecting the two connecting rods 46, specifically, the torsion springs 415 can be sleeved on the pin 414 connecting the swing rod 43 and the fixing frame 41, one ends of the two torsion springs 415 are fixed to the fixing frame 41, the other ends of the two torsion springs 415 are respectively and fixedly connected to the adjacent connecting rods 46, and the connection mode can be that the ends of the torsion springs 415 are inserted into the configuration holes shown in fig. 4. The structure of the torsion spring 415 enables the link 46 to keep the action force of the upward swing by the action force of the elastic reset of the torsion spring 415 under the condition that the link 46 does not have the action force of the external force after the link 46 swings downwards. When the moving shaft 42 moves downward to drive the two connecting rods 46 to swing downward to separate the two egg bearing plates 44, the two connecting rods 46 are in a horizontal state on the same straight line, and at this time, the elastic force of the torsion spring 415 cannot drive the connecting rods 46 to swing upward. Therefore, after the moving shaft 42 moves downwards to drive the two egg supporting plates 44 to separate, the two egg supporting plates 44 can be kept in a separated state all the time until the egg supporting plates move to the position of the first guide plate 411, and the moving shaft 42 is driven by the first guide plate 411 to move upwards so that the two egg supporting plates 44 can be closed. The two egg receiving plates 44 are kept in a separated state, which facilitates the complete falling of the yolk and the albumen and the separation of the eggshell.

As shown in fig. 14 and 17, the housing 6 is further connected with an egg shell slot 9, and the egg shell slot 9 is used for collecting egg shells. The receiving plate 91 is connected to the notch of the eggshell groove 9, the downward inclined end of the receiving plate 91 is connected to the notch of the eggshell groove 9, and the receiving plate 91 is right below the upward inclined end of the guide rod 413 along the rotation direction of the rotary seat 2. When the eggshell is clamped on the shell breaking mechanism 4 and moves to the position where the guide rod 413 inclines upwards (namely the position of the eggshell groove) under the driving of the rotary seat 2, the second guide sleeve 49 connected to the press block 45 ascends along the guide rod 413 to drive the press block 45 to ascend upwards, and as the two egg bearing plates 44 swing to incline when the eggshell is separated, the eggshell inevitably falls to the bearing plate 91 of the eggshell groove 9 along the egg bearing plates after being out of the limit of the press block 45, and slides into the eggshell groove 9 along the bearing plate 91, so that the recovery of one eggshell can be completed.

The utility model discloses connect conveyer 3 and shell breaking mechanism 4 back to a set of shell breaking mechanism 4 and separating mechanism 5 are the example, and concrete work flow is as follows:

s1, the shell breaking mechanism 4 and the separating mechanism 5 are driven by the rotating base 2 to rotate to the position close to the output end of the conveyor 3, and at the moment, the second guide sleeve 49 of the shell breaking mechanism 4 moves upwards to the guide rod 413 along one end of the guide rod 413 in an inclined manner, so that an open state is formed between the pressing block 45 and the egg bearing plate 44;

s2, when the shell breaking mechanism 4 and the separating mechanism 5 are driven by the rotating base 2 to move to the first guide plate 411, the first guide sleeve 47 gradually moves upwards along the inclined plane of the first guide plate 411 while moving, so as to drive the moving shaft 42 to move upwards, so that the moving shaft 42 moves upwards to drive the two egg bearing plates 44 to swing towards the fixed frame 41, so as to realize closing, and the conveyor 3 conveys the eggs 1 to the two closed egg bearing plates 44 falling on the shell breaking mechanism 4;

s3, the rotating base 2 continues to drive the shell breaking mechanism 4 and the separating mechanism 5 to move, so that the second guide sleeve 49 of the shell breaking mechanism 4 moves obliquely downwards along the other end of the guide rod 413 until the second guide sleeve is separated from the guide rod 413, and at the moment, the press block 45 swings downwards along with the second guide sleeve 49 obliquely downwards along the guide rod 413 until the press block presses the egg 1 on the egg bearing plate 44, so that the press block 45 presses the egg 1 downwards to be cut by the shell breaking knife 410 to form a gap;

s4, when the egg white box 52 of the separating mechanism 5 moves to the position of the bearing strip 55, the egg white box 52 moves upwards along the inclined plane of the bearing strip 55 at one end of the conveyor 3 to move parallel to the upper surface of the bearing strip 55, in the process, the egg white box 52 swings upwards and drives the yolk box 54 to swing upwards, and the yolk box 54 and the egg white box 52 are both in a horizontal state with upward openings;

s5, the breaking mechanism 4 and the separating mechanism 5 are driven by the rotary base 2 to move continuously, when moving to the second guiding plate 412, the roller 48 on the moving shaft 42 moves while gradually moving downwards along the inclined plane of the second guiding plate 412, so as to drive the moving shaft 42 to move downwards, thereby realizing that the moving shaft 422 moves downwards to drive the two egg bearing plates 44 to swing outwards the fixed frame 41, so as to realize separation, through the separation of the two egg bearing plates 44, the eggshell can be broken into two half eggshells along the crack, and the yolk and the egg white in the eggshell both drop onto the yolk box 54 of the separating mechanism 5;

s6, the shell breaking mechanism 4 and the separating mechanism 5 are driven by the rotating seat 2 to move continuously, when the shell breaking mechanism moves to the rack 56, the vibrating rod 531 of the supporting rod 53 contacts and moves along the rack 56, and the vibrating rod 53 is sequentially embedded into each tooth socket of the rack 56 in the process, so that vibration is formed, the vibration is transmitted to the yolk box 54, and the egg white in the egg supporting groove 541 is shaken off from the gap on the upper edge of the egg supporting groove 54 to the egg white box 52 in a vibration mode;

s7, the shell breaking mechanism 4 and the separating mechanism 5 are driven by the rotating seat 2 to move continuously until the egg white box 52 is separated from the bearing strip 55 (i.e. the egg white box 52 is positioned on the egg white groove 7), and the egg white box 522 is turned down because no support is arranged at the bottom, so that the egg white on the egg white box 52 falls into the egg white groove 7;

s8, the shell breaking mechanism 4 and the separating mechanism 5 continue to move under the drive of the rotating seat 2, after the egg white box 52 is separated from the bearing strip 55 and swings downwards in s7, the supporting rod 53 loses the bearing of the stop block 521, and simultaneously the vibrating rod 531 moves, under the action of resistance in contact with the rack 56, gradually turns downwards along with the movement, completely turns downwards when moving to the yolk slot 8, so that the yolk falls into the yolk slot 8, and the separation of the egg white and the yolk is completed;

s9, the breaking mechanism 4 and the separating mechanism 5 are driven by the rotary base 2 to move continuously, when the breaking mechanism moves to the position of the egg shell groove 9 (i.e. the guide rod 413 inclines upwards), the second guide sleeve 49 rises along the guide rod 413 to drive the press block 45 to lift upwards, so that the egg shell loses the limit and falls on the receiving plate 91 of the egg shell groove 9, and slides into the egg shell groove 9 along the receiving plate 91, thus completing the working process of completely separating the egg white, the egg yolk and the egg shell of an egg, and then the breaking mechanism 4 and the separating mechanism 5 are driven by the rotary base 2 to move continuously to the first guide plate 411, and the step of s2 is repeated, thereby forming a continuous circulation automatic working process.

The above-mentioned be the utility model discloses a concrete implementation way, nevertheless the utility model discloses a design concept is not limited to this, and the ordinary use of this design is right the utility model discloses carry out immaterial change, all should belong to the act of infringement the protection scope of the utility model.

Claims (4)

1. A autosegregation device for separating yolk and egg white, including frame and roating seat, the roating seat is located rotation on the frame, its characterized in that: a plurality of separating mechanisms are fixed on the ring surface of the rotary seat, each separating mechanism comprises an egg white box, a yolk box, a connecting frame and a supporting rod, the connecting frame is connected to the rotary seat, a gap is formed in the side surface below the yolk box, the lower end of the supporting rod is rotatably connected to the upper end of the connecting frame, the yolk box is fixed at the upper end of the supporting rod, the egg white box is rotatably connected to the lower end of the connecting frame, the egg white box is located right below the yolk box, and a stop block is further arranged on one side of the egg white box, corresponding; the egg white box is characterized in that a bearing strip is fixed on the machine base, the bearing strip is consistent with the moving path of the egg white box, an inclined plane which inclines upwards is arranged at the position of the bearing strip before egg yolk and egg white are poured, a rack is fixed at one end in the machine base, the rack is consistent with the moving path of the support rod, and the length of the support rod, close to one end in the machine base, extends to be capable of contacting the rack.

2. An automatic separating apparatus for separating yolk and albumen as claimed in claim 1, wherein: the egg white machine is characterized in that an egg white groove is formed in the machine base, and the bearing strip is located between the egg white groove and the position where the egg yolk and the egg white are poured.

3. An automatic separating apparatus for separating yolk and albumen as claimed in claim 2, wherein: the machine base is provided with a yolk groove behind the egg white groove along the rotating direction of the rotating base, and the rack is positioned at the position where the yolk and the egg white are poured to the position before the yolk groove.

4. An automatic separating apparatus for separating yolk and albumen as claimed in claim 1, wherein: the bottom of the yolk box is an egg supporting groove with a concave circular structure, and the yolk box is provided with a circle of through gaps on the egg supporting groove.

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