CN213036699U - Stacking and bulk loading mechanism for breeding young silkworms - Google Patents

Abstract

The utility model discloses a stacking and bulk loading mechanism for breeding young silkworms, which comprises a stacking rack and a disc separating rack connected with one side of the stacking rack, wherein a pair of parallel and spaced disc separating conveyor belts are rotationally arranged in the disc separating rack, and a pair of parallel and spaced feeding conveyor belts are connected in the stacking rack through a lifting assembly; the tray dividing machine frame is internally provided with a material ejecting assembly positioned between the two tray dividing conveyor belts, the tray dividing machine frame is also provided with two material supporting assemblies which are arranged in opposite directions, and the two material supporting assemblies are positioned above two sides of a conveying line of the two tray dividing conveyor belts and move in opposite directions or away from each other; the lifting adjustment of the material ejecting component is matched with the opposite or separated movement of the two material supporting components to sequentially separate a plurality of silkworm trays in a silkworm tray stack on the two tray conveyer belts from bottom to top and then convey the silkworm trays away through the two tray conveyer belts; compared with the prior art, the utility model, realized automatic the transportation to the silkworm dish stack, improved work efficiency, the cost is reduced.

Description

Stacking and bulk loading mechanism for breeding young silkworms

Technical Field

The utility model relates to a sericulture equipment technical field, concretely relates to stack, the bulk mechanism of usefulness are bred to young silkworm.

Background

Silkworm is a completely metamorphotic insect and passes through four development stages which are completely different in morphology and physiology, such as eggs, larvae, pupae, imagoes and the like in life. The eggs are the stages of embryogenesis, development and formation of larvae, the larvae are the growth stages for taking in food nutrition, the pupae are the metamorphosis stages for transition from larvae to adults, and the adults are the reproduction stages for mating, oviposition and reproduction of offspring.

The silkworm shell formed in the silkworm pupating process has a certain medicinal value, and is widely applied to the traditional Chinese medicine, so that the silkworm breeding can obtain a higher economic value; at present, silkworm trays are generally used as a silkworm breeding container, when workers transfer a plurality of silkworm trays from one area to another area to feed each silkworm tray, the silkworm trays are overlapped together to form a silkworm tray stack and then are placed on a trolley, then the trolley is moved to transfer the silkworm trays to a required area, the silkworm trays are sequentially separated from the top down, and then the silkworm trays are fed; in order to facilitate the taking of the silkworm tray by the workers, the four included angles at the bottom of the silkworm tray are fixedly connected with supporting legs, and an insertion interval which is convenient for taking the silkworm tray is formed between every two adjacent supporting legs.

The above-mentioned transfer of a plurality of silkworm trays has the problems of low automation degree, low working efficiency and high labor cost.

SUMMERY OF THE UTILITY MODEL

To the not enough that exists among the prior art, the utility model aims to provide a stack, the bulk mechanism of usefulness are bred to young silkworm to solve among the prior art, there is the problem that degree of automation is low, work efficiency is low and the cost of labor is high at the in-process that shifts a plurality of silkworm dishes.

In order to achieve the above purpose, the utility model adopts the following technical scheme: a stacking and bulk loading mechanism for breeding young silkworms comprises a stacking rack and a disc separating rack connected with one side of the stacking rack, wherein a pair of parallel disc separating conveyor belts arranged at intervals are rotationally arranged in the disc separating rack, and a pair of parallel feeding conveyor belts arranged at intervals are connected in the stacking rack through a lifting assembly; the lifting assembly enables the two feeding conveyor belts to lift the silkworm tray stacks on the trolleys placed at the lower position in the stacking rack to the high position in the stacking rack, and the feeding conveyor belts are in staggered butt joint with the tray dividing conveyor belts after being lifted to the high position in the stacking rack;

the tray dividing machine frame is internally provided with a material ejecting assembly positioned between the two tray dividing conveyor belts, the tray dividing machine frame is also provided with two material supporting assemblies which are arranged in opposite directions, and the two material supporting assemblies are positioned above two sides of a conveying line of the two tray dividing conveyor belts and move in opposite directions or away from each other; the lifting adjustment of the material ejecting component is matched with the opposite or separated movement of the two material supporting components to sequentially separate a plurality of silkworm trays in a silkworm tray stack on the two tray conveyer belts from bottom to top and then convey the silkworm trays away through the two tray conveyer belts.

Compared with the prior art, the utility model discloses following beneficial effect has:

the stacking and bulk loading mechanism for breeding young silkworms pushes the cart into a low position in the stacking rack, the lifting component enables the two feeding conveyor belts to move the silkworm plate stacks placed on the cart from the low position to the high position in the stacking rack, and the two feeding conveyor belts are in staggered butt joint with the two branch conveyor belts; the two feeding conveyor belts and the two sub-disc conveyor belts run respectively, so that the silkworm tray stack is moved onto the two sub-disc conveyor belts from the two feeding conveyor belts, when the silkworm tray stack moves to the position above the ejection assembly, the ejection assembly runs to eject the silkworm tray stack upwards to a certain height, the two material supporting assemblies move oppositely, the lifting end parts of the two material supporting assemblies are inserted into the position below the penultimate silkworm tray at the bottom, so that the silkworm trays above the bottommost silkworm tray are supported and supported, and the ejection assembly descends to place the bottommost silkworm tray onto the two sub-disc conveyor belts to be transported away; the rear material ejecting component rises to a certain height again, the two material supporting components move away from each other, the supported silkworm trays are stacked and placed on the material ejecting component, the rear material ejecting component descends to a certain height, the two material supporting components move in opposite directions again, the supporting end parts of the two material supporting components are inserted below the penultimate silkworm tray at the bottom again, the silkworm trays above the bottommost silkworm tray are supported and supported, and the material ejecting component descends again to place the bottommost silkworm tray on the two branch tray conveying belts for carrying away; the liftout subassembly and two support material subassemblies are repeated above-mentioned motion then with a plurality of silkworm dishes one-to-one orderly place in the silkworm dish stack transport to required place on two minutes dish conveyer belts, realized automatic the transportation to silkworm dish stack, improved work efficiency, the cost is reduced.

Drawings

Fig. 1 is a schematic structural diagram of an embodiment of the present invention;

FIG. 2 is a first diagram illustrating a partial structure of FIG. 1;

FIG. 3 is an enlarged view of portion A of FIG. 2;

FIG. 4 is a schematic structural view of the ejector assembly of FIG. 2;

FIG. 5 is a second partial schematic view of the structure of FIG. 1;

fig. 6 is an enlarged view of a portion B in fig. 5.

Detailed Description

The present invention will be described in further detail with reference to the following embodiments:

reference numerals in the drawings of the specification include: the automatic silkworm rearing device comprises a stacking rack 1, a disc separating rack 2, a disc separating conveyor belt 3, a feeding conveyor belt 4, a pneumatic bracket shield 5, a linear guide rail supporting plate 6, a linear slide rail 7, a supporting roller 8, a lifting cylinder 9, a lifting cylinder panel 10, a lifting cylinder bottom plate 11, a linear shaft 12, a lifting side plate 13, a bottom lifting driven sprocket 14, a top lifting driven sprocket 15, a driving sprocket 16, a lifting chain 17, a lifting chain connecting piece 18, a supporting strip 181, a lower connecting plate 182, an upper connecting plate 183, a belt line motor bottom plate 19, a power seat cross support 20, a belt line power shaft 21 and a silkworm disc stack 22.

With reference to fig. 1, 2 and 5, an embodiment of the present invention provides a stacking and bulk loading mechanism for breeding young silkworms, which includes a stacking rack 1 and a separating tray rack 2 connected to one side of the stacking rack 1, wherein a pair of separating tray conveyor belts 3 arranged in parallel and at intervals are rotatably disposed in the separating tray rack 2, and a pair of feeding conveyor belts 4 arranged in parallel and at intervals are connected to the stacking rack 1 through a lifting assembly; the lifting assembly enables the two feeding conveyor belts 4 to lift silkworm tray stacks 22 placed on a cart at a low position in the stacking rack 1 to a high position in the stacking rack 1, and the feeding conveyor belts 4 are in staggered butt joint with the tray dividing conveyor belts 3 after being lifted to the high position in the stacking rack 1; the tray dividing machine frame 2 is internally provided with a material ejecting component positioned between the two tray conveyor belts 3, the tray dividing machine frame 2 is also provided with two material supporting components which are arranged in opposite directions, and the two material supporting components are positioned above two sides of a conveying line of the two tray conveyor belts 3 and move in opposite directions or in a separated direction; the lifting adjustment of the material ejecting component is matched with the opposite or separated movement of the two material supporting components to sequentially separate a plurality of silkworm trays in the silkworm tray stack 22 on the two tray conveyor belts 3 from bottom to top and then convey the silkworm trays away through the two tray conveyor belts 3.

Pushing the cart into a low position in the stacking rack 1, enabling the two feeding conveyor belts 4 to move silkworm tray stacks 22 placed on the cart from the low position in the stacking rack 1 to the high position through the lifting assembly, and enabling the two feeding conveyor belts 4 to be in staggered butt joint with the two branch conveyor belts 3; the two feeding conveyor belts 4 and the two branch disc conveyor belts 3 both operate, so that the silkworm disc stacks 22 are moved onto the two branch disc conveyor belts 3 from the two feeding conveyor belts 4, when the silkworm disc stacks 22 move to the upper part of the material ejecting assembly, the material ejecting assembly operates to eject the silkworm disc stacks 22 upwards to a certain height, the two material supporting assemblies move oppositely, the ejecting end parts of the two material supporting assemblies are inserted into the lower part of the penultimate silkworm disc at the bottom, so that the silkworm discs above the silkworm disc at the bottommost are all supported and supported, and the material ejecting assembly descends to place the silkworm disc at the bottommost onto the two branch disc conveyor belts 3 for transportation; then the material ejecting component rises to a certain height again, the two material supporting components move away from each other, the supported silkworm tray stack 22 is placed on the material ejecting component, the material ejecting component descends to a certain height, the two material supporting components move in opposite directions again, the supporting end parts of the two material supporting components are inserted below the penultimate silkworm tray at the bottom again, then the silkworm trays above the bottommost silkworm tray are supported and supported, and the material ejecting component descends again to place the bottommost silkworm tray on the two branch tray conveyor belts 3 for transportation; the above-mentioned movements of the material ejecting assembly and the two material supporting assemblies are repeated to place a plurality of silkworm trays in the silkworm tray stack 22 one by one in order on the two-tray conveyor belt 3 to be conveyed to a required place.

The adopted two pallet conveyor belts 3 are connected through a belt driving main shaft, and the belt driving main shaft is positioned at the lower position between the two pallet conveyor belts 3; the belt driving main shaft can be driven by a motor to rotate so as to enable the two tray conveyor belts 3 to run synchronously, and the two tray conveyor belts 3 can stably transport silkworm trays.

Combine fig. 2 and fig. 3, according to the utility model discloses an another embodiment, a stack, the bulk mechanism of usefulness are bred to young silkworm, still include to the structural optimization who holds in the palm the material subassembly, the same and symmetrical arrangement of two material subassembly structures that hold in the palm of adoption, every holds in the palm the material subassembly and all includes the fixed pneumatic bracket guard shield 5 that sets up in the pallet frame 2, and pneumatic bracket guard shield 5 is close to one side of two pallet conveyer belts 3 and is the opening, slides in the pneumatic bracket guard shield 5 and is provided with linear guide layer board 6, and linear guide layer board 6 in the two material subassemblies that hold in the palm carries out in opposite directions or slides apart from each other.

The linear guide rail supporting plate 6 is protected and supported by a pneumatic bracket shield 5, and the linear guide rail supporting plate 6 can be driven to move by an air cylinder; the two linear guide rail supporting plates 6 move oppositely to enable the supporting end parts of the two linear guide rail supporting plates 6 to be inserted into the insertion interval at the bottom of the silkworm tray, so that the silkworm tray can be supported, and the two material supporting assemblies move away from each other to support the silkworm tray and place the silkworm tray on the material ejecting assembly.

Wherein, the pneumatic bracket guard shield 5 internal fixation that adopts is provided with a pair of linear slide rail 7 of arranging perpendicularly with two minute dish conveyer belts 3's transfer chain direction, and the joint that all slides on every linear slide rail 7 has the linear bearing who links to each other with linear guide layer board 6 bottom is fixed, rotates on the minute dish frame 2 and is provided with a plurality of supporting rollers 8, and a plurality of supporting rollers 8 all slide with linear guide layer board 6 bottom that is close to minute dish conveyer belt 3 one side and offset.

The linear guide rail and the linear bearing are matched to further support the movement of the linear guide rail supporting plate 6, and meanwhile, the movement of the linear guide rail supporting plate 6 is guided; and the arrangement of a plurality of supporting rollers 8 is used for improving the supporting strength of the linear guide rail supporting plate 6 when the silkworm tray is supported.

With reference to fig. 2 and 4, according to another embodiment of the present invention, the stacking and bulk-loading mechanism for breeding young silkworms further comprises a structure optimization for an ejection assembly, the employed ejection assembly comprises a lifting cylinder 9 fixedly arranged on the tray dividing frame 2 and a lifting cylinder panel 10 connected to a piston rod at the top of the lifting cylinder 9, and the lifting cylinder panel 10 is positioned between the two tray dividing conveyor belts 3 for lifting; the lifting cylinder panel 10 is lifted and adjusted in the tray dividing rack 2 through the telescopic adjustment of the lifting cylinder 9, the lifting cylinder panel 10 jacks up the silkworm tray stacks 22 on the two tray conveying belts 3, so that the silkworm tray stacks 22 are lifted and adjusted along with the lifting cylinder panel 10, and a plurality of silkworm trays in the silkworm tray stacks 22 are separated from bottom to top in sequence by matching with the opposite or separated motion of the two linear guide rail supporting plates 6 and then are conveyed away through the two tray conveying belts 3.

In order to improve the stability and the moving accuracy of the lifting cylinder panel 10 in the lifting adjustment process, a lifting cylinder bottom plate 11 located below the lifting cylinder panel 10 is fixedly sleeved on the outer wall of the lifting cylinder 9, a plurality of linear shafts 12 connected with the lifting cylinder bottom plate 11 in a sliding mode are fixedly connected to the bottom surface of the lifting cylinder panel 10, the plurality of linear shafts 12 are circumferentially and uniformly distributed on the outer side of the lifting cylinder 9, and the moving direction of the plurality of linear shafts 12 is consistent with the extending and retracting direction of a piston rod of the lifting cylinder 9.

The stability of the lifting cylinder panel 10 in the lifting process is improved through the matching of the lifting cylinder bottom plate 11 and the plurality of linear shafts 12, and meanwhile, the lifting adjustment of the lifting cylinder panel 10 is guided through the movement of the plurality of linear shafts 12, so that the movement precision of the lifting cylinder panel 10 in the lifting process is improved.

Combine fig. 5 and fig. 6, according to the utility model discloses a another embodiment, a stack, the bulk mechanism that little silkworm breeding was used still include the configuration optimization to lifting unit, and the lifting unit of adoption is including fixed two chain formula elevation structure that set up in stack frame 1, and two chain formula elevation structure pass through the transmission of lift drive shaft and link to each other, and two chain formula elevation structure one-to-one fixed connection are in the side of keeping away from of two pay-off conveyer belts 4.

The driving shaft of the lifter can be driven by a motor to rotate so as to enable the two chain type lifting structures to synchronously move, thereby stably enabling the two feeding conveyor belts 4 to move between a low position and a high position in the stacking rack 1, and moving the silkworm tray stacks 22 on the cart to the high position in the stacking rack 1 and then conveying the silkworm tray stacks to the two branch conveyor belts 3.

Wherein, every chain formula elevation structure all includes and corresponds the lift curb plate 13 that pay-off conveyer belt 4 links to each other, rotate the bottom lift driven sprocket 14 that sets up in 1 bottom of stack frame, rotate the top lift driven sprocket 15 that sets up at 1 top of stack frame, fixed cover is established at the drive sprocket 16 of lift drive shaft one end, fixed connection is at lift chain connecting piece and the lift chain 17 on lift curb plate 13, the both ends of lift chain 17 all link to each other with lift chain connecting piece is fixed, the middle part tensioning winding in proper order of lift chain 17 is at bottom lift driven sprocket 14, drive sprocket 16 and top lift driven sprocket 15 are last.

The elevator driving shaft can be driven by a motor to rotate, the lifting chain 17 is driven to rotate through the matching of the bottom lifting driven chain wheel 14, the driving chain wheel 16 and the top lifting driven chain wheel 15, so that the lifting side plate 13 is adjusted in a lifting mode through the lifting chain connecting piece, and the feeding conveying belt 4 is fixed on the lifting side plate 13 and then synchronously lifted along with the lifting side plate 13.

Meanwhile, the adopted lifting chain connecting piece comprises a supporting bar 181 on the lifting side plate 13 and a lower connecting plate 182 connected to the side wall of the top of the supporting bar 181, the top surface of the lower connecting plate 182 is connected with an upper connecting plate 183 positioned above the lower connecting plate 182 through two parallel supporting plates arranged at intervals, an inclined strut is connected between the bottom of the lower connecting plate 182 and the supporting bar 181, and two ends of the lifting chain 17 are correspondingly connected with the lower connecting plate 182 and the upper connecting plate 183 one by one; come to correspond with the both ends of lifting chain 17 respectively through lower connecting plate 182 and upper junction plate 183 and link to each other to rationally carry out the overall arrangement to lifting chain 17, support bar 181 is as the basis that lower connecting plate 182 and upper junction plate 183 link to each other with lift curb plate 13, and the bracing strengthens lower connecting plate 182 and upper junction plate 183's connection stability.

As shown in fig. 5, according to the utility model discloses a stack, the mechanism of packing in bulk that little silkworm breeding was used, still include that the below position between two pay-off conveyer belts 4 is provided with belt line motor bottom plate 19, belt line motor bottom plate 19 top is provided with the power seat stull 20 of a plurality of parallel and interval arrangement, a plurality of power seat stulls 20 all connect between two pay-off conveyer belts 4, every power seat stull 20 all links to each other with belt line motor bottom plate 19 through a plurality of belt line power seat side pipes, the top of a plurality of power seat stulls 20 all is located the transfer surface below of two pay-off conveyer belts 4, and rotate on the belt line motor bottom plate 19 and be provided with the belt line power shaft 21 that links to each other with two pay-off conveyer belts 4, belt line power shaft 21 is used for driving two pay-off conveyer belts 4 synchronous motion.

A motor can be arranged on a belt line motor bottom plate 19, the motor is connected with a belt line power shaft 21 to enable the two feeding conveyor belts 4 to synchronously rotate, and the two feeding conveyor belts 4 are used for stably transporting silkworm trays; the belt line motor bottom plate 19 and the two feeding conveyor belts 4 are connected into a whole through the connection and the matching of the plurality of power seat cross braces 20 and the plurality of belt line power seat square tubes, so that the connection strength between the two feeding conveyor belts 4 is improved.

When the silkworm tray stacking machine works, a trolley is pushed into a feeding port in the stacking rack 1 and is positioned in an interval between the two feeding conveyor belts 4, the edge of the silkworm tray stack 22 is positioned right above the two feeding conveyor belts 4, and the silkworm tray stack 22 is positioned at a designed low position in the stacking rack 1; the lifting component operates to lift the two feeding conveyor belts 4 from a low position to a high position in the stacking rack 1, in the process, the two feeding conveyor belts 4 jack up the silkworm tray stack 22, and the silkworm tray stack 22 moves synchronously along with the two feeding conveyor belts 4; when the two feeding conveyor belts 4 move to be in staggered butt joint with the two branch disc conveyor belts 3, the two feeding conveyor belts 4 are connected with the first positions of the two branch disc conveyor belts 3, the conveying surfaces of the two feeding conveyor belts 4 and the conveying surfaces of the two branch disc conveyor belts 3 are positioned in the same horizontal plane, and at the moment, the silkworm tray stack 22 moves to the designed high position in the stacking rack 1; the two latter feeding conveyor belts 4 and the two sub-disc conveyor belts 3 run, and the silkworm disc stacks 22 are transferred from the two feeding conveyor belts 4 to the two sub-disc conveyor belts 3; when the silkworm tray stack 22 moves right above the material ejecting component, the material ejecting component operates, the silkworm tray stack 22 is ejected upwards to a certain height by the material ejecting component, the two material supporting components move oppositely, the ejecting end parts of the two material supporting components are inserted below the penultimate silkworm tray at the bottom, so that the silkworm trays above the bottommost silkworm tray are all supported, and the material ejecting component descends to place the bottommost silkworm tray on the two tray conveying belts 3 for transportation; then the material ejecting component rises to a certain height again, the two material supporting components move away from each other, the supported silkworm tray stack 22 is placed on the material ejecting component, the material ejecting component descends to a certain height, the two material supporting components move in opposite directions again, the supporting end parts of the two material supporting components are inserted below the penultimate silkworm tray at the bottom again, then the silkworm trays above the bottommost silkworm tray are supported and supported, and the material ejecting component descends again to place the bottommost silkworm tray on the two branch tray conveyor belts 3 for transportation; the material ejecting component and the two material supporting components repeat the movement, so that a plurality of silkworm trays in the silkworm tray stack 22 are orderly placed on the two tray conveyor belts 3 one by one and conveyed to a required place; the above processes are all controlled by the existing controller through programs, so that each structure moves orderly.

Finally, although the present invention has been described in detail with reference to the preferred embodiments, it should be understood by those skilled in the art that the present invention can be modified or replaced by other means without departing from the spirit and scope of the present invention, which should be construed as limited only by the appended claims.

Claims (10)

1. A stacking and bulk loading mechanism for breeding young silkworms is characterized by comprising a stacking rack and a disc separating rack connected with one side of the stacking rack, wherein a pair of parallel and spaced disc conveying belts are rotatably arranged in the disc separating rack, and a pair of parallel and spaced feeding conveying belts are connected in the stacking rack through a lifting assembly; the lifting assembly enables the two feeding conveyor belts to lift the silkworm tray stacks on the trolleys placed at the lower position in the stacking rack to the high position in the stacking rack, and the feeding conveyor belts are in staggered butt joint with the tray dividing conveyor belts after being lifted to the high position in the stacking rack;

the tray dividing machine frame is internally provided with a material ejecting assembly positioned between the two tray dividing conveyor belts, the tray dividing machine frame is also provided with two material supporting assemblies which are arranged in opposite directions, and the two material supporting assemblies are positioned above two sides of a conveying line of the two tray dividing conveyor belts and move in opposite directions or away from each other; the lifting adjustment of the material ejecting component is matched with the opposite or separated movement of the two material supporting components to sequentially separate a plurality of silkworm trays in a silkworm tray stack on the two tray conveyer belts from bottom to top and then convey the silkworm trays away through the two tray conveyer belts.

2. The stacking and bulk loading mechanism for young silkworm breeding according to claim 1, wherein: the two material supporting assemblies are identical in structure and are symmetrically arranged, each material supporting assembly comprises a pneumatic bracket shield fixedly arranged on the tray dividing rack, one side, close to the two tray dividing conveyor belts, of each pneumatic bracket shield is provided with an opening, linear guide rail supporting plates are slidably arranged in the pneumatic bracket shields, and the linear guide rail supporting plates in the two material supporting assemblies slide in opposite directions or in a separated mode.

3. The stacking and bulk loading mechanism for young silkworm breeding according to claim 2, characterized in that: the pneumatic bracket guard shield internal fixation is provided with a pair of linear slide rail of arranging perpendicularly with the transfer chain direction of two minutes set conveyer belts, and the joint that all slides on every linear slide rail has the linear bearing who links to each other with linear guide layer board bottom is fixed, rotates in the minute set frame and is provided with a plurality of supporting rollers, and a plurality of supporting rollers all slide with the bottom that linear guide layer board is close to minute set conveyer belt one side and offset.

4. The stacking and bulk loading mechanism for young silkworm breeding according to claim 1, wherein: the liftout subassembly is including fixed the lift cylinder that sets up in the depiler frame and connect the lift cylinder panel on the piston rod at lift cylinder top, and the lift cylinder panel is located and goes up and down between the bipartition dish conveyer belt.

5. The stacking and bulk loading mechanism for young silkworm breeding as claimed in claim 4, wherein: the fixed cover is equipped with the lift cylinder bottom plate that is located lift cylinder panel below on the lift cylinder outer wall, and lift cylinder panel bottom surface fixedly connected with a plurality of straight line axles that slide and link to each other with lift cylinder bottom plate, a plurality of straight line axle circumference equipartitions are in the outside of lift cylinder, and the moving direction of a plurality of straight line axles all is unanimous with the flexible direction of piston rod of lift cylinder.

6. A stacking, bulk-loading mechanism for young silkworm breeding as claimed in any one of claims 1 to 5, wherein: the lifting assembly comprises two chain type lifting structures fixedly arranged on the stacking rack, the two chain type lifting structures are connected through a driving shaft of the lifter in a transmission mode, and the two chain type lifting structures are fixedly connected to the opposite sides of the two feeding conveyor belts in a one-to-one correspondence mode.

7. The stacking and bulk loading mechanism for young silkworm breeding as claimed in claim 6, wherein: every chain formula elevation structure all includes the lift curb plate that links to each other with corresponding pay-off conveyer belt, rotates the bottom lift driven sprocket who sets up in stack frame bottom, rotates the top lift driven sprocket who sets up at the stacker frame top, fixed cover is established at the drive sprocket of lift drive shaft one end, fixed connection is at lift chain connecting piece and the lift chain on the lift curb plate, the both ends of lift chain all link to each other with the lift chain connecting piece is fixed, the middle part tensioning winding in proper order of lift chain is on bottom lift driven sprocket, drive sprocket and top lift driven sprocket.

8. The stacking and bulk loading mechanism for young silkworm breeding as claimed in claim 7, wherein: the lifting chain connecting piece comprises a supporting strip on the lifting side plate and a lower connecting plate connected to the top side wall of the supporting strip, the top surface of the lower connecting plate is connected with an upper connecting plate located above the lower connecting plate through two parallel supporting plates arranged at intervals, an inclined strut is connected between the bottom of the lower connecting plate and the supporting strip, and the two ends of the lifting chain are connected with the lower connecting plate and the upper connecting plate in a one-to-one correspondence manner.

9. The stacking and bulk loading mechanism for young silkworm breeding as claimed in claim 6, wherein: the utility model discloses a belt line motor, including two pay-off conveyer belts, below position between two pay-off conveyer belts is provided with belt line motor bottom plate, belt line motor bottom plate top is provided with the power seat stull of a plurality of parallel and interval arrangement, a plurality of power seat stulls are all connected between two pay-off conveyer belts, every power seat stull all links to each other with belt line motor bottom plate through a plurality of belt line power seat side pipes, the top of a plurality of power seat stulls all is located the transfer surface below of two pay-off conveyer belts, and rotate on the belt line motor bottom plate and be provided with the belt line power shaft that links to each other with two pay-off conveyer belts, belt line power shaft is used for driving two pay.

10. The stacking and bulk loading mechanism for young silkworm breeding according to claim 1, wherein: the two branch disc conveyor belts are connected through a belt driving main shaft, and the belt driving main shaft is located at the lower position between the two branch disc conveyor belts.

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