CN113994989A - Quantitative material injection device for moon-like crust production - Google Patents

Abstract

The invention relates to a material injection device, in particular to a quantitative material injection device for manufacturing moon bars. The invention provides a quantitative material injection device for manufacturing a moon-shaped crust, which can inject materials quantitatively during material injection, does not need to shake up manually, is simple to operate and can ensure the working efficiency. The invention provides a quantitative material injection device for manufacturing a moon-like crust, which comprises a base, an installation plate, a support frame, a hopper, a quantitative cylinder, a T-shaped material pipe, a connecting sleeve and the like. The flour paste is filled through the hopper, and after the flour paste is filled, the flour paste is injected into the die through the T-shaped material pipe, so that the effect of injecting the flour paste is achieved.

Description

Quantitative material injection device for moon-like crust production

Technical Field

The invention relates to a material injection device, in particular to a quantitative material injection device for manufacturing moon bars.

Background

The moon crisp is also called bean crisp, belongs to a guest snack and is a traditional food of Gannan province, and in the manufacturing process of the moon crisp, flour paste is generally required to be injected into a mold for material injection and then fried for manufacturing. At present, the mode of pouring into the face thick liquid into in the mould is usually ladled out with the face thick liquid by the manual work earlier with the ladle, pour the face thick liquid of ladling out into the mould again, artifical manual rocking mould afterwards, make the face thick liquid pave in the mould, thereby accomplish the notes material, above-mentioned mode is owing to be artifical ladling out the face thick liquid with the ladle when carrying out the notes material, the volume of annotating at every turn is not well controlled, the too much or too little condition of volume that leads to the notes material easily takes place, influence off-the-shelf quality easily, and when the notes material, still need the manual work to rock and shake evenly, operation process is comparatively loaded down with trivial details, work efficiency is lower.

Therefore, the quantitative material injection device for manufacturing the moon-shaped bars, which can inject materials quantitatively when injecting the materials, does not need to shake up manually, is simple to operate and can ensure the working efficiency, needs to be developed.

Disclosure of Invention

(1) Technical problem to be solved

In order to overcome the defects that the quantity of the materials is not well controlled during the material injection, the materials are shaken up manually during the material injection, the operation process is complicated, and the working efficiency is low, the invention aims to solve the technical problem of providing the quantitative material injection device for moon-stick manufacturing, which can quantitatively inject the materials during the material injection, does not need to shake up manually, is simple to operate, and can ensure the working efficiency.

(2) Technical scheme

In order to solve the technical problem, the invention provides a quantitative material injection device for manufacturing a moon-shaped bus, which comprises a base, a mounting plate, a supporting frame, a hopper, a quantifying cylinder, a T-shaped material pipe, baffle plates, a connecting sleeve and a limiting device, wherein the mounting plate is connected to one side of the top of the base, the supporting frame is connected to the upper portion of the mounting plate, the hopper is connected between the supporting frame and the mounting plate, the quantifying cylinder is connected to the lower portion of the hopper in a sliding mode and can rotate on the lower portion of the hopper, the connecting sleeve is rotatably connected to the lower portion of the quantifying cylinder, the T-shaped material pipe is connected to the bottom of the connecting sleeve, the baffle plates are connected to the inside of the connecting sleeve and the top of the quantifying cylinder, the two baffle plates can be communicated after rotating, and the limiting device is arranged between the mounting plate and the quantifying cylinder.

Preferably, the limiting device comprises a convex rod, a sliding sleeve, a limiting rod, a limiting spring, a clamping block and a stirring frame, the lower portion of one side of the mounting plate is connected with the convex rod, the sliding sleeve is connected onto the convex rod, the limiting rod is connected onto the sliding sleeve in a sliding mode, the limiting spring is sleeved on one side of the limiting rod, the two ends of the limiting spring are connected onto the sliding sleeve and the limiting rod respectively, one side, close to the limiting rod, of the quantitative cylinder is connected with the two clamping blocks, and the lower portion of the T-shaped material pipe is connected with the stirring frame.

Preferably, still including transmission, transmission is including guide cylinder, deflector roll, reset spring, ring rail and change, and mounting panel bottom one side is connected with the guide cylinder, and ration section of thick bamboo top both sides all are connected with the deflector roll, and the deflector roll can slide on the guide cylinder, and hopper outside sub-unit connection has ring rail, and the ring rail internal rotation formula is connected with the change, is connected with two reset spring between change bottom and the ration section of thick bamboo top, and two reset spring set up for the symmetry.

Preferably, the automatic feeding device further comprises a resetting device, the resetting device comprises a sliding frame, a fixed sliding frame, a sliding clamping shaft, a torsion spring, a sliding wheel, a driving wheel and a driving belt, the sliding frame is connected to the convex rod, the sliding frame is connected with the fixed sliding frame in a sliding mode, the sliding frame is connected with the sliding clamping shaft in a rotating mode, the fixed sliding frame can slide on the sliding clamping shaft, the torsion spring is sleeved on the upper portion of the sliding clamping shaft, two ends of the torsion spring are connected to the sliding clamping shaft and the sliding frame respectively, the sliding clamping shaft is connected with the sliding wheel in a sliding mode, the sliding wheel can rotate on the fixed sliding frame, the driving wheel is connected to the upper portion of the T-shaped material pipe, the driving wheel can rotate on the fixed sliding frame, and the driving belt is wound between the driving wheel and the sliding wheel.

Preferably, still including receiving device, receiving device is including underframe, cassette, powerful spring, baffle and take-up pan, and base top both sides all are connected with the underframe, and the gliding style is connected with the cassette on the underframe, is connected with powerful spring between cassette and the underframe, and the base top is connected with the baffle, and the joint has the take-up pan between the cassette of both sides, and the take-up pan is for dismantling the setting.

Preferably, still including drive arrangement, drive arrangement is including gear motor, first gear, the band gear, second gear and third gear, mounting panel one side mid-mounting has gear motor, be connected with first gear on gear motor's the output shaft, the projecting bar lower part is three band gear that the triangle-shaped distributes, three equal rotary type of band gear is connected in the projecting bar lower part, around having the band gear between the three band gear, be connected with the second gear on the band gear of being close to first gear, the mounting panel is worn out to the second gear and first gear engagement, slip card axle sub-unit connection has the third gear, the band gear cooperates with the third gear.

Preferably, still including covering device, covering device is including connecting axle, apron and handle, and hopper outer both sides upper portion all is connected with the connecting axle, and the rotation type is connected with the apron on the connecting axle, and the apron top is connected with the handle.

Preferably, still including connecting device, connecting device is including the pin, the arc pole, the arc spring, the reel, act as go-between, the leading wheel, stay cord and connecting rod, mounting panel upper portion both sides all are connected with the pin, the sliding type is connected with the arc pole on the pin, the cover has the arc spring on the arc pole, arc spring both ends are connected respectively in the arc pole outside and the pin outside, arc pole one end is connected at the apron top, the apron both sides all are connected with the reel, the reel rotates on the connecting axle, around acting as go-between on the reel, be connected with the connecting rod between acting as go-between on two reels of homonymy, the leading wheel is all installed to base top both sides, the connecting rod middle part is connected with the stay cord, the stay cord is walked around the leading wheel and is connected with the cassette.

(3) The invention has the beneficial effects that:

1. dress the face thick liquid through the hopper, after adorning the face thick liquid, will fill in the mould with the face thick liquid through T shape material pipe to the realization is to the face thick liquid effect of annotating the material, and annotate the material in-process, the face thick liquid can be stored in a quantitative section of thick bamboo earlier, and the face thick liquid that pours into in the mould also is the face thick liquid of a quantitative section of thick bamboo inside, carries out the ration through a quantitative section of thick bamboo to the face thick liquid, thereby realizes the effect of a ration notes material.

2. In the process of injecting the materials, as the discharge ends of the T-shaped material pipes are more and can rotate, the flour slurry can be uniformly paved in the die in the process of injecting the materials without manual shaking.

3. The quantitative barrel is limited by the limiting device, so that the quantitative barrel is prevented from moving together in the moving process of the T-shaped material pipe to influence the material injection.

4. The movement and the reset of the quantitative cylinder are assisted through the matching operation of the driving device, the transmission device and the reset device, and the movement and the reset of the quantitative cylinder do not need to be operated manually, so that the manual operation is more convenient in operation.

5. Through the contact of receiving device to the face thick liquid that overflows carelessly, avoid the face thick liquid to spill over, it is comparatively troublesome to clear up, also can lead to the waste of face thick liquid.

6. The hopper is covered by the matching operation of the covering device and the connecting device, so that the influence on food safety caused by the contact of dust entering the hopper and flour slurry inside the hopper is avoided.

Drawings

Fig. 1 is a schematic perspective view of the present invention.

Fig. 2 is a partial perspective view of the present invention.

Fig. 3 is an exploded view of a portion of the components of the present invention.

Fig. 4 is a schematic perspective view of the spacing device of the present invention.

Fig. 5 is an enlarged view of the invention at a.

Fig. 6 is a schematic perspective view of the transmission device of the present invention.

Fig. 7 is an exploded view of a component of the transmission of the present invention.

Fig. 8 is a schematic perspective view of the repositioning device of the present invention.

Fig. 9 is an exploded view of a portion of the reset device of the present invention.

Fig. 10 is a schematic perspective view of the receiving device of the present invention.

Fig. 11 is a schematic perspective view of a driving device according to the present invention.

Fig. 12 is a schematic perspective view of the covering device of the present invention.

Fig. 13 is a schematic perspective view of the connecting device of the present invention.

Fig. 14 is an enlarged view of the invention at B.

FIG. 15 is an enlarged view of the invention at C.

The labels in the figures are: 1-base, 2-mounting plate, 3-supporting frame, 4-hopper, 5-quantitative cylinder, 6-T-shaped material pipe, 7-striker plate, 8-connecting sleeve, 9-limiting device, 91-convex rod, 92-sliding sleeve, 93-limiting rod, 94-limiting spring, 95-fixture block, 96-stirring frame, 10-transmission device, 11-guiding cylinder, 12-guiding roller, 13-return spring, 14-annular guide rail, 15-rotating ring, 20-return device, 21-sliding frame, 22-fixed sliding frame, 23-sliding fixture shaft, 24-torsion spring, 25-sliding wheel, 26-driving belt, 27-driving wheel, 30-receiving device, 31-bottom frame, 32-clamping seat, 33-strong spring, 34-baffle, 35-take-up, 40-drive, 41-gear motor, 42-first gear, 43-toothed pulley, 44-toothed belt, 45-second gear, 46-third gear, 50-cover, 51-connecting shaft, 52-cover, 53-handle, 60-connecting device, 61-stop bar, 62-arc bar, 63-arc spring, 64-reel, 65-pull, 66-guide wheel, 67-pull rope, 68-connecting rod.

Detailed Description

The invention is further described below with reference to the figures and examples.

Example 1

A quantitative material injection device for manufacturing a moon-like crust is disclosed, as shown in figures 1-5, and comprises a base 1, a mounting plate 2, a support frame 3, a hopper 4, a quantitative cylinder 5, a T-shaped material pipe 6, a material baffle plate 7, a connecting sleeve 8 and a limiting device 9, wherein the mounting plate 2 is connected with the rear side of the top of the base 1, the support frame 3 is connected with the upper part of the front side of the mounting plate 2, the hopper 4 is connected between the support frame 3 and the front side of the mounting plate 2, the hopper 4 is used for containing flour slurry, the quantitative cylinder 5 is connected with the lower part of the hopper 4 in a sliding manner, the bottom of the quantitative cylinder 5 is of a material outlet end structure, the quantitative cylinder 5 can rotate at the lower part of the hopper 4, the connecting sleeve 8 is rotatably connected with the lower part of the quantitative cylinder 5, the T-shaped material pipe 6 is connected with the bottom of the connecting sleeve 8, 5 material outlet pipes are uniformly arranged at the bottom of the T-shaped material pipe 6, the material baffle plates 7 are connected with the connecting sleeve 8 and the top of the quantitative cylinder 5, the two material baffle plates 7 can communicate after rotating, a limiting device 9 is arranged between the mounting plate 2 and the quantifying cylinder 5, and the limiting device 9 is used for limiting the quantifying cylinder 5.

Stop device 9 is including nose bar 91, sliding sleeve 92, restriction lever 93, spacing spring 94, fixture block 95 and stirring frame 96, 2 front side sub-unit connections on the mounting panel have nose bar 91, nose bar 91 front side is connected with sliding sleeve 92, sliding connection has restriction lever 93 on the sliding sleeve 92, restriction lever 93 rear side cover has spacing spring 94, spacing spring 94 both ends are connected respectively on sliding sleeve 92 and restriction lever 93, 5 rear sides of quantitative section of thick bamboo are connected with two fixture blocks 95, restriction lever 93 can carry out spacingly through fixture block 95 to quantitative section of thick bamboo 5, 6 sub-unit connections on the T shape material pipe have stirring frame 96.

Firstly, a user can add flour slurry into the hopper 4, the flour slurry in the hopper 4 slowly flows into the quantitative cylinder 5, at the moment, because the two material blocking plates 7 can block the discharge end of the quantitative cylinder 5, the flour slurry in the quantitative cylinder 5 cannot flow into the T-shaped material pipe 6, the user can place a mold below the T-shaped material pipe 6, then the stirring frame 96 is pulled to drive the T-shaped material pipe 6 to rotate, the T-shaped material pipe 6 rotates to drive the connecting sleeve 8 to rotate along the lower part of the quantitative cylinder 5, at the moment, the limiting rod 93 and the clamping block 95 can limit the quantitative cylinder 5 to prevent the quantitative cylinder 5 from rotating along with the connecting sleeve 8, the connecting sleeve 8 rotates to drive the material blocking plates 7 on the connecting sleeve 8 to rotate to be communicated with the material blocking plates 7 at the bottom of the quantitative cylinder 5, at the moment, the flour slurry in the quantitative cylinder 5 can flow into the T-shaped material pipe 6 through the two material blocking plates 7, the flour slurry in the T-shaped material pipe 6 flows on the die, the flour slurry is viscous and has a slow flow rate, the quantitative cylinder 5 can be pulled to move upwards, the flour slurry in the quantitative cylinder 5 is extruded by the hopper 4 when the quantitative cylinder 5 moves upwards, so that the flour slurry in the quantitative cylinder 5 is more quickly pressed into the T-shaped material pipe 6 and then is added on the die through the T-shaped material pipe 6, the flour slurry in the quantitative cylinder 5 can be more uniformly injected on the die when the flour slurry is injected due to a plurality of discharging pipes of the T-shaped material pipe 6, the die does not need to be shaken manually to shake uniformly, when the quantitative cylinder 5 moves upwards to the limit, the flour slurry in the quantitative cylinder 5 also flows out completely, the flour slurry in the hopper 4 cannot quickly flow into the quantitative cylinder 5 due to the viscous flour slurry, so that the effect of quantitative material injection is realized, the quantitative cylinder 5 can be pulled to move downwards to reset, and the T-shaped material pipe 6 and the connecting sleeve 8 are driven to reset by pulling the shifting frame 96, so, just so, can annotate the material to annotate the material in-process, can quantitative annotate the material, still more even notes material need not the manual work and shakes evenly, makes artifical convenience more when the operation.

Example 2

On the basis of embodiment 1, as shown in fig. 1, fig. 6, fig. 7, fig. 8 and fig. 9, the quantitative measuring device further comprises a transmission device 10, the transmission device 10 is used for assisting the quantitative cylinder 5 to move, the transmission device 10 comprises a guide cylinder 11, a guide roller 12, a return spring 13, an annular guide rail 14 and a rotary ring 15, the guide cylinder 11 is connected to the front side of the bottom of the mounting plate 2, the guide roller 12 is connected to the left side and the right side of the top of the quantitative cylinder 5, the guide roller 12 can slide on the guide cylinder 11, the guide cylinder 11 can drive the guide roller 12 to move, the annular guide rail 14 is connected to the lower portion of the outer side of the hopper 4, the rotary ring 15 is rotatably connected to the annular guide rail 14, two return springs 13 are connected between the bottom of the rotary ring 15 and the top of the quantitative cylinder 5, and the two return springs 13 are symmetrically arranged in the front and back direction.

When the connecting sleeve 8 rotates to the limit along the lower part of the quantifying cylinder 5, the stirring frame 96 is continuously pulled to drive the T-shaped material pipe 6 to rotate, at the moment, the T-shaped material pipe 6 rotates to drive the quantifying cylinder 5 to rotate together through the connecting sleeve 8, the quantifying cylinder 5 drives the fixture block 95 to rotate when rotating, the fixture block 95 extrudes the limiting rod 93 to move backwards when rotating, the limiting spring 94 is stretched, when the fixture block 95 rotates to be separated from the limiting rod 93, the limiting rod 93 resets under the action of the limiting spring 94, the quantifying cylinder 5 also drives the guide roller 12 to rotate when rotating, the guide roller 12 moves upwards along the guide cylinder 11 when rotating, the return spring 13 is compressed, the guide roller 12 drives the return spring 13 to rotate along the annular guide rail 14 through the rotating ring 15 when rotating, the quantifying cylinder 5 moves upwards when moving upwards, after the quantifying cylinder 5 moves upwards to the limit, the stirring frame 96 is loosened, and the quantifying cylinder 5 moves downwards to reset under the action of the return spring 13, quantitative section of thick bamboo 5 can be through guide cylinder 11 and deflector roll 12 antiport to the normal position when the rebound resets, quantitative section of thick bamboo 5 drives fixture block 95 antiport together when antiport, after fixture block 95 antiport to contact with restriction lever 93, fixture block 95 continues the antiport extrusion restriction lever 93 and moves backward, spacing spring 94 is stretched once more, when fixture block 95 antiport to no longer contact with restriction lever 93, restriction lever 93 resets and blocks fixture block 95 under spacing spring 94's effect, at this moment quantitative section of thick bamboo 5 also antiport to the normal position, it can to drive T shape material pipe 6 to reset by artifical pulling toggle frame 96 afterwards, so, artifical only need operate T shape material pipe 6 to rotate can, make the manual work more convenient when the operation.

The device also comprises a resetting device 20, the resetting device 20 is used for assisting the resetting of the quantitative cylinder 5 and the T-shaped material pipe 6, the resetting device 20 comprises a sliding frame 21, a fixed sliding frame 22 and a sliding clamping shaft 23, the device comprises a torsion spring 24, a sliding wheel 25, a transmission wheel 27 and a transmission belt 26, wherein the front side of a convex rod 91 is connected with a sliding frame 21, the sliding frame 21 is connected with a fixed sliding frame 22 in a sliding mode, the front side of the sliding frame 21 is connected with a sliding clamping shaft 23 in a rotating mode, the fixed sliding frame 22 can slide on the sliding clamping shaft 23, the torsion spring 24 is sleeved on the upper portion of the sliding clamping shaft 23, two ends of the torsion spring 24 are respectively connected to the sliding clamping shaft 23 and the sliding frame 21, the sliding wheel 25 is connected on the sliding clamping shaft 23 in a sliding mode, the sliding wheel 25 can rotate on the fixed sliding frame 22, the transmission wheel 27 is connected to the upper portion of a T-shaped material pipe 6, the transmission wheel 27 can rotate on the fixed sliding frame 22, and the transmission belt 26 is wound between the transmission wheel 27 and the sliding wheel 25.

The T-shaped material pipe 6 drives the driving wheel 27 to rotate when rotating, the driving wheel 27 drives the sliding wheel 25 to rotate through the driving belt 26, the sliding wheel 25 drives the sliding clamping shaft 23 to rotate, the torsion spring 24 is compressed, the T-shaped material pipe 6 can drive the driving wheel 27 and the fixed sliding frame 22 to move up and down when moving up and down, the fixed sliding frame 22 drives the sliding wheel 25 to move up and down when moving up and down, so that the sliding wheel 25 can be matched with the movement of the driving wheel 27, when the T-shaped material pipe 6 needs to be reset, the poking frame 96 is directly loosened, the sliding clamping shaft 23 rotates reversely under the action of the torsion spring 24, the sliding clamping shaft 23 rotates reversely to drive the sliding wheel 25 to rotate reversely, the sliding wheel 25 rotates reversely through the driving belt 26 to drive the driving wheel 27 to rotate reversely, the driving wheel 27 drives the T-shaped material pipe 6 to rotate reversely when rotating reversely, and when the torsion spring 24 returns to a normal state, the T-shaped material pipe 6 and the dosing barrel 5 rotate reversely to a normal position, therefore, the T-shaped material pipe 6 does not need to be manually operated to reset, and manpower is effectively saved.

Example 3

On the basis of embodiment 2, as shown in fig. 1, fig. 10, fig. 11, fig. 12, fig. 13, fig. 14 and fig. 15, the receiving device 30 is further included, the receiving device 30 is used for collecting excess materials generated in the material injecting process, the receiving device 30 includes a bottom frame 31, a clamping seat 32, a strong spring 33, a baffle 34 and a receiving tray 35, the bottom frame 31 is connected to the left and right sides of the top of the base 1, the clamping seat 32 is connected to the bottom frame 31 in a sliding manner, the strong spring 33 is connected between the clamping seat 32 and the bottom frame 31, the baffle 34 is connected to the rear side of the top of the base 1, the receiving tray 35 is clamped between the clamping seats 32 on the two sides, the receiving tray 35 is used for collecting excess materials generated in the material injecting process, the baffle 34 can block the receiving tray 35, the receiving tray 35 is located below the T-shaped material pipe 6, and the receiving tray 35 is detachably disposed.

Initially, strong spring 33 is tensile state, in the process of annotating the material, if the clout spills over, the clout that spills over can flow to on the take-up pan 35, collect through take-up pan 35, after the clout is filled up on take-up pan 35, can take out take-up pan 35, take out the back, both sides cassette 32 is close to each other under strong spring 33's effect, when the take-up pan 35 will be placed once more to needs, pulling both sides cassette 32 and keeping away from each other, strong spring 33 is stretched once more, put into take-up pan 35 afterwards, put well the back, loosen cassette 32, both sides cassette 32 is close to each other and blocks take-up pan 35 under strong spring 33's effect, baffle 34 can block take-up pan 35, so, just can collect the clout that annotates the material in-process production, the emergence of the extravagant condition has been avoided.

Still including drive arrangement 40, drive arrangement 40 is used for driving T shape material pipe 6 and operates, drive arrangement 40 is including gear motor 41, first gear 42, toothed belt wheel 43, rack belt 44, second gear 45 and third gear 46, mounting panel 2 rear side mid-mounting has gear motor 41, gear motor 41 is used for providing drive power, be connected with first gear 42 on gear motor 41's the output shaft, three toothed belt wheel 43 is distributed to the cam 91 lower part for the triangle-shaped, three equal rotary type of toothed belt wheel 43 is connected in the cam 91 lower part, it has toothed belt 44 to wind between three toothed belt wheel 43, be connected with second gear 45 on the toothed belt wheel 43 near first gear 42, second gear 45 wears out mounting panel 2 and meshes with first gear 42, slip card axle 23 sub-unit connection has third gear 46, rack belt 44 and third gear 46 cooperate.

The speed reducing motor 41 is started to drive the first gear 42 to rotate, the first gear 42 drives the second gear 45 to rotate, the second gear 45 drives the rack belt 44 to rotate through the gear belt wheel 43, after the rack belt 44 rotates to be meshed with the third gear 46, the rack belt 44 continues to rotate to drive the third gear 46 to rotate, the third gear 46 rotates to drive the sliding clamping shaft 23 to rotate, the torsion spring 24 is compressed, the sliding clamping shaft 23 rotates to drive the sliding wheel 25 to rotate, the sliding wheel 25 rotates to drive the T-shaped material pipe 6 to rotate through the transmission belt 26 and the transmission wheel 27, when the rack belt 44 rotates to be disengaged with the third gear 46, the sliding clamping shaft 23 rotates reversely under the action of the torsion spring 24, the sliding clamping shaft 23 rotates reversely to drive the sliding wheel 25 to rotate reversely, the sliding wheel 25 rotates reversely to drive the T-shaped material pipe 6 to rotate reversely through the transmission belt 26 and the transmission wheel 27, and therefore, the T-shaped material pipe 6 does not need to be rotated manually, the manpower is effectively saved, and when the material is not required to be injected, the speed reducing motor 41 is turned off.

Still including covering device 50, covering device 50 is used for blocking hopper 4, and covering device 50 is including connecting axle 51, apron 52 and handle 53, and hopper 4 outer left and right sides upper portion all is connected with connecting axle 51, and the rotation type is connected with apron 52 on the connecting axle 51, and apron 52 can block hopper 4 top, and the apron 52 top is connected with handle 53.

When needing to add the face thick liquid, pulling handle 53 opens apron 52, can add the face thick liquid afterwards, adds the face thick liquid back, loosens handle 53, and apron 52 resets and blocks hopper 4 under the effect of gravity, so, just can block hopper 4, avoids having the dust to get into in the hopper 4, influences food safety.

Also comprises a connecting device 60, the connecting device 60 is used for assisting the covering device 50 to operate, the connecting device 60 comprises a stop lever 61, an arc-shaped lever 62, an arc-shaped spring 63 and a reel 64, act as go-between 65, leading wheel 66, stay cord 67 and connecting rod 68, the mounting panel 2 upper portion left and right sides all is connected with pin 61, the sliding type is connected with arc pole 62 on pin 61, the cover has arc spring 63 on arc pole 62, the arc spring 63 both ends are connected respectively in the arc pole 62 outside and the pin 61 outside, 62 one end of arc pole is connected at the apron 52 top, both sides all are connected with reel 64 around the apron 52, reel 64 rotates on connecting axle 51, around acting as go-between 65 on reel 64, be connected with connecting rod 68 between the acting as go-between 65 on two reels 64 of homonymy, leading wheel 66 is all installed to the base 1 top left and right sides, connecting rod 68 middle part is connected with stay cord 67, stay cord 67 is walked around leading wheel 66 and is connected with cassette 32.

After the take-up disc 35 is taken out, the two side clamping seats 32 are close to each other under the action of the strong spring 33, when the two side clamping seats 32 are close to each other, the connecting rod 68 can be pulled by the pull rope 67 to move downwards, the connecting rod 68 pulls the pull wire 65 to move downwards when moving downwards, the pull wire 65 drives the winding wheel 64 to rotate when moving downwards, the winding wheel 64 opens the cover plate 52 when rotating, the cover plate 52 can drive the arc-shaped rod 62 to move when opening, the arc-shaped spring 63 is stretched, the flour slurry can be added at this time, or the flour slurry in the receiving tray 35 can be poured into the hopper 4 and then, then the clamping seats 32 at the two sides are pulled to be away from each other and put into the material receiving tray 35, the pulling rope 67 is loosened after the clamping seats 32 at the two sides are away from each other, at this time, the cover plate 52 is reset under the action of the arc-shaped spring 63, so that the cover plate 52 can be automatically opened and closed, and the manual operation is more convenient.

The above examples are merely representative of preferred embodiments of the present invention, and the description thereof is more specific and detailed, but not to be construed as limiting the scope of the present invention. It should be noted that, for those skilled in the art, various changes, modifications and substitutions can be made without departing from the spirit of the present invention, and these are all within the scope of the present invention. Therefore, the protection scope of the present patent shall be subject to the appended claims.

Claims (8)

1. A quantitative material injection device for manufacturing a moon-shaped bus is characterized by comprising a base (1), a mounting plate (2), a support frame (3), a hopper (4), a quantifying cylinder (5), a T-shaped material pipe (6), a material baffle plate (7), a connecting sleeve (8) and a limiting device (9), wherein one side of the top of the base (1) is connected with the mounting plate (2), the upper part of the mounting plate (2) is connected with the support frame (3), the hopper (4) is connected between the support frame (3) and the mounting plate (2), the lower part of the hopper (4) is connected with the quantifying cylinder (5) in a sliding manner, the quantifying cylinder (5) can rotate at the lower part of the hopper (4), the lower part of the quantifying cylinder (5) is connected with the connecting sleeve (8) in a rotating manner, the T-shaped material pipe (6) is connected at the bottom of the connecting sleeve (8), the material baffle plate (7) is connected in the connecting sleeve (8) and at the top of the quantifying cylinder (5), and the two material baffle plates (7) can communicate with each other after rotating, a limiting device (9) is arranged between the mounting plate (2) and the quantitative cylinder (5).

2. The quantitative material injection device for manufacturing the moon-shaped crust as claimed in claim 1, wherein the limiting device (9) comprises a convex rod (91), a sliding sleeve (92), a limiting rod (93), a limiting spring (94), a fixture block (95) and a stirring frame (96), the convex rod (91) is connected to the lower portion of one side of the mounting plate (2), the sliding sleeve (92) is connected to the convex rod (91), the limiting rod (93) is slidably connected to the sliding sleeve (92), the limiting spring (94) is sleeved on one side of the limiting rod (93), two ends of the limiting spring (94) are respectively connected to the sliding sleeve (92) and the limiting rod (93), two fixture blocks (95) are connected to one side, close to the limiting rod (93), of the quantitative cylinder (5), and the stirring frame (96) is connected to the lower portion of the T-shaped material pipe (6).

3. The quantitative material injection device for manufacturing the moon bars as claimed in claim 2, further comprising a transmission device (10), wherein the transmission device (10) comprises a guide cylinder (11), a guide roller (12), a return spring (13), a circular guide rail (14) and a rotary ring (15), one side of the bottom of the mounting plate (2) is connected with the guide cylinder (11), the two sides of the top of the quantifying cylinder (5) are connected with the guide roller (12), the guide roller (12) can slide on the guide cylinder (11), the lower part of the outer side of the hopper (4) is connected with the circular guide rail (14), the circular guide rail (14) is connected with the rotary ring (15) in a rotating mode, two return springs (13) are connected between the bottom of the rotary ring (15) and the top of the quantifying cylinder (5), and the two return springs (13) are symmetrically arranged.

4. The quantitative filling device for manufacturing the moon-shaped crust according to claim 3, further comprising a reset device (20), wherein the reset device (20) comprises a sliding frame (21), a fixed sliding frame (22), a sliding clamping shaft (23), a torsion spring (24), a sliding wheel (25), a driving wheel (27) and a driving belt (26), the sliding frame (21) is connected to the protruding rod (91), the fixed sliding frame (22) is connected to the sliding frame (21) in a sliding manner, the sliding clamping shaft (23) is connected to the sliding frame (21) in a rotating manner, the fixed sliding frame (22) can slide on the sliding clamping shaft (23), the torsion spring (24) is sleeved on the upper portion of the sliding clamping shaft (23), two ends of the torsion spring (24) are respectively connected to the sliding clamping shaft (23) and the sliding frame (21), the sliding wheel (25) is connected to the sliding clamping shaft (23) in a sliding manner, and the sliding wheel (25) can rotate on the fixed sliding frame (22), the upper part of the T-shaped material pipe (6) is connected with a driving wheel (27), the driving wheel (27) can rotate on the fixed sliding frame (22), and a driving belt (26) is wound between the driving wheel (27) and the sliding wheel (25).

5. The quantitative material injection device for manufacturing moon bars according to claim 4, characterized by further comprising a material receiving device (30), wherein the material receiving device (30) comprises a bottom frame (31), a clamping seat (32), a strong spring (33), a baffle (34) and a material receiving disc (35), the bottom frame (31) is connected to both sides of the top of the base (1), the clamping seat (32) is slidably connected to the bottom frame (31), the strong spring (33) is connected between the clamping seat (32) and the bottom frame (31), the baffle (34) is connected to the top of the base (1), the material receiving disc (35) is clamped between the clamping seats (32) on both sides, and the material receiving disc (35) is detachably arranged.

6. The quantitative filling device for manufacturing the moon bars according to claim 5, characterized by further comprising a driving device (40), wherein the driving device (40) comprises a speed reducing motor (41), a first gear (42), toothed belt wheels (43), a rack belt (44), a second gear (45) and a third gear (46), the speed reducing motor (41) is installed in the middle of one side of the mounting plate (2), the first gear (42) is connected to an output shaft of the speed reducing motor (41), three toothed belt wheels (43) are distributed on the lower portion of the convex rod (91) in a triangular shape, the three toothed belt wheels (43) are rotatably connected to the lower portion of the convex rod (91), the toothed belt belts (44) are wound among the three toothed belt wheels (43), the second gear (45) is connected to the toothed belt wheel (43) close to the first gear (42), and the second gear (45) penetrates through the mounting plate (2) to be meshed with the first gear (42), the lower part of the sliding clamping shaft (23) is connected with a third gear (46), and the rack belt (44) is matched with the third gear (46).

7. The quantitative material injection device for manufacturing the moon-shaped bars as claimed in claim 6, further comprising a covering device (50), wherein the covering device (50) comprises a connecting shaft (51), a cover plate (52) and a handle (53), the upper parts of the two outer sides of the hopper (4) are connected with the connecting shaft (51), the cover plate (52) is rotatably connected on the connecting shaft (51), and the top of the cover plate (52) is connected with the handle (53).

8. The quantitative material injection device for moon bar production according to claim 7, further comprising a connecting device (60), wherein the connecting device (60) comprises a stop lever (61), an arc lever (62), an arc spring (63), a reel (64), a pull wire (65), a guide wheel (66), a pull rope (67) and a connecting rod (68), the stop lever (61) is connected to both sides of the upper portion of the mounting plate (2), the arc lever (62) is slidably connected to the stop lever (61), the arc lever (62) is sleeved with the arc spring (63), both ends of the arc spring (63) are respectively connected to the outer side of the arc lever (62) and the outer side of the stop lever (61), one end of the arc lever (62) is connected to the top of the cover plate (52), the reel (64) is connected to both sides of the cover plate (52), the reel (64) rotates on the connecting shaft (51), the pull wire (65) is wound on the reel (64), connecting rods (68) are connected between the pull wires (65) on the two reels (64) on the same side, guide wheels (66) are installed on two sides of the top of the base (1), a pull rope (67) is connected to the middle of each connecting rod (68), and the pull rope (67) is connected with the clamping seat (32) by bypassing the guide wheels (66).

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