CN220836028U - Pulping device for producing plant milk powder - Google Patents

Abstract

The utility model relates to the technical field of pulping equipment, and provides a pulping device for producing plant milk powder, which comprises a processing box, wherein a feeding mechanism for feeding soybean is arranged in the processing box, the feeding mechanism comprises a storage cavity and a grinding cavity which are arranged in the processing box, a feeding port for communication is arranged between the storage cavity and the grinding cavity, a grinding component for grinding soybean is arranged in the grinding cavity, a lifting block is slidably arranged at the lowest part of the storage cavity, and a traction rope is fixedly arranged at the upper part of the lifting block. According to the soybean feeding device, the effect of automatically feeding soybean into the grinding cavity is achieved through the arrangement of the feeding mechanism, so that the operating frequency of workers is reduced, the labor intensity of the workers is reduced, the pulp grinding rate of equipment is improved, and the baffle plate can automatically block the storage cavity after moving up the lifting block through the arrangement of the baffle plate, the abutting spring and other elements, so that soybean is prevented from falling below the lifting block and affecting the next feeding of the soybean.

Description

Pulping device for producing plant milk powder

Technical Field

The utility model relates to the technical field of pulping equipment, in particular to a pulping device for producing plant milk powder.

Background

The plant milk powder is a milk product produced by taking plant fruits as raw materials, wherein the soymilk is a common one in the plant milk powder, soybean needs to be ground in the production process, the soybean needs to be soaked before grinding due to the harder texture of the soybean, and the soybean is put into a grinding device for processing after the soybean is soaked, but the conventional equipment is inconvenient to realize automatic soybean feeding, and the soybean needs to be fed manually frequently in the processing process of the soybean, so that the feeding mode can increase the labor intensity of workers, further reduce the feeding speed of the soybean and be unfavorable for improving the processing efficiency of the soybean. In view of this, we propose a plant milk powder production is with fiberizing device.

Disclosure of utility model

The utility model aims to solve the defect of low soybean treatment efficiency of the traditional pulping device for producing plant milk powder.

In order to achieve the above purpose, the present utility model adopts the following technical scheme:

The pulping device for producing the plant milk powder comprises a processing box, wherein a feeding mechanism for feeding soybean is arranged in the processing box;

The feeding mechanism comprises a storage cavity and a grinding cavity which are arranged in a processing box, a feeding port used for being communicated is arranged between the storage cavity and the grinding cavity, a grinding component used for grinding soybeans is arranged in the grinding cavity, a lifting block is slidably arranged at the lowest position of the storage cavity, a traction rope is fixedly arranged on the upper portion of the lifting block, a traction block fixedly connected with the traction rope is slidably arranged in the processing box, and a driving component used for controlling the traction block and the grinding component to move is arranged in the processing box.

Preferably, a baffle is slidably arranged in the storage cavity, a collision rod which is mutually collided with the lifting block is fixedly arranged at the bottom of the baffle, and a collision spring fixedly connected with the processing box is fixedly arranged at the bottom of the baffle.

Preferably, the grinding assembly comprises a grinding block arranged in a grinding cavity, a screen plate is fixedly arranged in the grinding cavity and below the grinding block, a liquid outlet cavity is formed in the inner cavity of the processing box and below the grinding cavity, a filter plate is obliquely arranged between the grinding cavity and the liquid outlet cavity, and a water supplementing assembly is arranged on the inner wall of the grinding cavity.

Preferably, the water supplementing assembly comprises a water supplementing cavity formed in the inner wall of the grinding cavity, a water supplementing hole for communication is formed between the water supplementing cavity and the grinding cavity, and a water supplementing flange communicated with the water supplementing cavity is arranged outside the processing box.

Preferably, the drive assembly includes the driving motor of fixed mounting in processing case upper portion, the driving motor output runs through processing case and installs the drive lead screw, drive lead screw one end rotate install with the drive base of processing case rigid coupling, drive lead screw outside thread bush is equipped with the sliding sleeve, the outside annular array of sliding sleeve has four spacing sliders, drive base inside rotates and installs the drive sleeve, drive sleeve inside offered with spacing slider sliding fit's drive recess, drive base upper portion is equipped with the spacing spout with spacing slider mutual slip, drive sleeve bottom elasticity articulates there is the pawl, pawl one side meshing has the ratchet with drive base rigid coupling, sliding sleeve upper portion fixed mounting has drive gear one, drive gear one-to-one side meshing has drive gear two, drive gear two lower parts coaxial fixed with rotates the sleeve, rotate the sleeve outside and install one end and slide sleeve articulated connecting piece, drive gear two upper portions rotate and install the transmission sleeve, transmission sleeve outside fixed mounting has the transfer line, traction block one side be equipped with the drive bar looks block and mutually block C, drive gear two and two side-to-side meshing have the ratchet, drive sleeve and two side joint grinding sleeve and the grinding sleeve.

Compared with the prior art, the utility model has the beneficial effects that:

1. According to the soybean feeding device, the effect of automatically feeding soybean into the grinding cavity is achieved through the arrangement of the feeding mechanism, so that the operating frequency of workers is reduced, the labor intensity of the workers is reduced, the pulp grinding rate of equipment is improved, and the baffle plate can automatically block the storage cavity after moving up the lifting block through the arrangement of the baffle plate, the abutting spring and other elements, so that soybean is prevented from falling below the lifting block and affecting the next feeding of the soybean.

2. According to the utility model, through the arrangement of the water supplementing assembly, the soybean powder ground by the soybean can be mixed with the clean water to form soybean milk, so that the product is convenient to discharge.

Drawings

FIG. 1 is a schematic perspective view of the present utility model;

FIG. 2 is a cross-sectional view of the present utility model;

FIG. 3 is an enlarged schematic view of the area A in FIG. 2;

FIG. 4 is a schematic diagram of a driving assembly according to the present utility model;

Fig. 5 is an enlarged view of the area B in fig. 4.

In the figure: 1. a processing box; 2. a feeding mechanism; 21. a storage cavity; 22. a lifting block; 23. a traction rope; 24. a delivery port; 25. a traction block; 26. a grinding chamber; 27. a drive assembly; 271. a driving motor; 272. driving a screw rod; 273. a driving base; 274. limiting sliding grooves; 275. a drive sleeve; 276. a driving groove; 277. a pawl; 278. a ratchet wheel; 279. a sliding sleeve; 2710. a limit sliding block; 2711. a first driving gear; 2712. rotating the sleeve; 2713. a connecting piece; 2714. a transmission sleeve; 2715. a transmission rod; 2716. a limit slide bar; 2717. a second driving gear; 28. a grinding assembly; 281. grinding the blocks; 282. a sieve plate; 283. a filter plate; 284. a liquid outlet cavity; 29. a water replenishing assembly; 291. a water supplementing cavity; 292. a water supplementing hole; 210. a touch-up rod; 211. a baffle; 212. against the spring.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

Example 1

Referring to fig. 1-5, a pulping device for producing plant milk powder comprises a processing box 1, wherein a feeding mechanism 2 for feeding soybean is arranged in the processing box 1, and when the device is used, the soybean is fed into the processing box 1 through the feeding mechanism 2 for processing.

The feeding mechanism 2 comprises a storage cavity 21 and a grinding cavity 26 which are arranged in the processing box 1, a feeding port 24 which is used for being communicated is arranged between the storage cavity 21 and the grinding cavity 26, a grinding component 28 which is used for grinding soybeans is arranged in the grinding cavity 26, a lifting block 22 is slidably arranged at the lowest part of the storage cavity 21, a traction rope 23 is fixedly arranged at the upper part of the lifting block 22, a traction block 25 fixedly connected with the traction rope 23 is slidably arranged in the processing box 1, a driving component 27 which is used for controlling the traction block 25 and the grinding component 28 to move is arranged in the processing box 1, soybeans entering the processing box 1 can firstly enter the storage cavity 21 for storage, as shown in figure 1, a connecting flange which is communicated with the storage cavity 21 is arranged outside the processing box 1, clear water can be injected into the storage cavity 21 through the connecting flange for soaking the soybeans when the device is used, as can be seen from figure 2, the storage cavity 21 is obliquely arranged, so the soybean in the storage cavity 21 can slide to the lowest position of the storage cavity 21, namely the lifting block 22 under the action of self gravity, then the traction block 25 can be controlled to ascend through the driving component 27, and as the traction rope 23 is connected between the traction block 25 and the lifting block 22 in a transmission way, the traction block 25 can drive the lifting block 22 to synchronously ascend until the soybean on the lifting block 22 slides into the grinding cavity 26 from the throwing opening 24, at the moment, the grinding component 28 can be controlled to grind the soybean through the driving component 27, after grinding is finished, the slurry flows out from the liquid outlet flange shown in figure 1, then the lifting block 22 can repeat the operation under the action of the driving component 27, and the soybean is thrown into the grinding cavity 26, thereby achieving the effect of automatic throwing, reducing the operating frequency of staff and the labor intensity of the staff, the refining rate of the apparatus is improved.

The baffle 211 is slidably mounted in the storage cavity 21, the bottom of the baffle 211 is fixedly provided with the abutting rod 210 which is mutually abutted against the lifting block 22, the bottom of the baffle 211 is fixedly provided with the abutting spring 212 fixedly connected with the processing box 1, as shown in fig. 3, the abutting rod 210 is positioned below the lifting block 22, so that in a conventional state, the lifting block 22 can retract the baffle 211 to the inside of the processing box 1 through extruding the abutting rod 210, when the lifting block 22 ascends to throw soybean, the baffle 211 ascends to block the storage cavity 21 under the action of the abutting spring 212, and therefore soybean is prevented from falling below the lifting block 22, and the next feeding of the lifting block 22 is prevented from being influenced.

The grinding component 28 comprises a grinding block 281 arranged in the grinding cavity 26, a screen plate 282 is fixedly arranged in the grinding cavity 26 and below the grinding block 281, a liquid outlet cavity 284 is arranged in the inner cavity of the processing box 1 and below the grinding cavity 26, a filter plate 283 is obliquely arranged between the grinding cavity 26 and the liquid outlet cavity 284, a water supplementing component 29 is arranged on the inner wall of the grinding cavity 26, after soybean enters the grinding cavity 26, the grinding block 281 can be controlled to rotate through the driving component 27, so that the effect of grinding the soybean is achieved by utilizing friction between the grinding block 281 and the inner wall of the grinding cavity 26 and the soybean, clear water can be injected into the grinding cavity 26 through the water supplementing component 29 during the grinding process, soybean powder is flushed out of the screen plate 282 and falls onto the filter plate 283, the soybean powder mixed with the clear water can become the soybean milk and passes through the filter plate 283 to enter the liquid outlet cavity 284 due to the fact that the filter plate 283 is obliquely arranged, and soybean residues with larger particle size can slide to the lowest position of the filter plate 283 to wait for collection, and thus the soybean pulp processing is finished.

The moisturizing subassembly 29 is including seting up the moisturizing chamber 291 on grinding chamber 26 inner wall, be equipped with the moisturizing hole 292 that is used for the intercommunication between moisturizing chamber 291 and the grinding chamber 26, processing case 1 outside is equipped with the moisturizing flange with moisturizing chamber 291 intercommunication, when moisturizing subassembly 29 used, alright supply water to moisturizing chamber 291 through moisturizing flange, the clear water that gets into in the moisturizing chamber 291 just can flow into grinding chamber 26 from moisturizing hole 292, as shown in fig. 2, moisturizing hole 292 annular array is on grinding chamber 26 inner wall, so the clear water that flows out in moisturizing chamber 291 can carry out the omnidirectional washing to grinding chamber 26 inner wall, thereby the washing of follow-up equipment is convenient for.

Example two

Referring to fig. 1-5, the present embodiment is substantially the same as the first embodiment, and more preferably, the driving assembly 27 includes a driving motor 271 fixedly installed at the upper portion of the processing box 1, an output end of the driving motor 271 penetrates through the processing box 1 and is provided with a driving screw rod 272, one end of the driving screw rod 272 is rotatably provided with a driving base 273 fixedly connected with the processing box 1, a sliding sleeve 279 is sleeved on an external thread of the driving screw rod 272, four limit sliders 2710 are arranged on an external annular array of the sliding sleeve 279, a driving sleeve 275 is rotatably installed inside the driving base 273, a driving groove 276 slidingly matched with the limit sliders 2710 is formed inside the driving sleeve 275, a limit chute 274 mutually sliding with the limit sliders 2710 is formed at the upper portion of the driving base 273, a pawl 277 is elastically hinged at the bottom of the driving sleeve 275, a ratchet wheel 278 fixedly connected with the driving base 273 is meshed at one side of the pawl 277, a driving gear one 2711 is fixedly installed at the upper portion of the sliding sleeve 279, one side of a driving gear I2711 is meshed with a driving gear II 2717, the lower part of the driving gear II 2717 is coaxially fixed with a rotating sleeve 2712, a connecting piece 2713 with one end hinged with a sliding sleeve 279 is rotatably arranged outside the rotating sleeve 2712, a transmission sleeve 2714 is rotatably arranged on the upper part of the driving gear II 2717, a transmission rod 2715 is fixedly arranged outside the transmission sleeve 2714, one side of a traction block 25 is provided with a C-shaped frame which is mutually clamped with the transmission rod 2715, the middle parts of the driving gear II 2717, the transmission sleeve 2714 and the rotating sleeve 2712 are respectively sheathed with a limiting slide rod 2716 fixedly connected with a processing box 1 in a sliding manner, the bottom of the rotating sleeve 2712 is fixedly connected with a grinding block 281, when the device is used, the driving screw 272 can be controlled to rotate through a driving motor 271, and the sliding sleeve 279 is in threaded connection with the driving screw 272 so that the sliding sleeve 279 can be driven to move upwards when the driving screw 272 rotates, because the sliding sleeve 279 is connected with the rotating sleeve 2712 through the connecting piece 2713, when the sliding sleeve 279 moves, the rotating sleeve 2712 is driven to synchronously move through the connecting piece 2713, the rotating sleeve 2712 drives the transmission rod 2715 to move through the transmission sleeve 2714 arranged on the rotating sleeve 2712, the transmission rod 2715 is mutually clamped with the C-shaped frame on the traction block 25 to achieve the purpose of driving the traction block 25 to move up and down, after soybean is put into the grinding cavity 26, the driving motor 271 is reversed, the driving screw rod 272 drives the sliding sleeve 279 to descend until the limit sliding block 2710 on the sliding sleeve 279 is separated from the limit sliding groove 274 and enters the driving groove 276, at the moment, the driving screw rod 272 drives the sliding sleeve 279 and the driving sleeve 275 to rotate together in the driving base 273, and further the driving gear two 2717 is meshed with the driving gear two 2717 through the driving gear one 2711 to be coaxially fixed with the rotating sleeve 2712, so the rotating sleeve 2712 is driven to rotate together, the rotating sleeve 2712 drives the grinding block 281 to grind soybean in the grinding cavity 26 when rotating, after grinding, the driving motor 271 resumes to rotate positively, at this time, the pawl 277 at the bottom of the driving sleeve 275 is engaged with the ratchet 278 fixedly connected to the driving base 273 when rotating, so that the driving sleeve 275 and the sliding sleeve 279 do not rotate, and the sliding sleeve 279 slowly rises, and because the number of teeth of the ratchet 278 and the driving grooves 276 is four, and the limit sliding groove 274 is located right above one tooth of the ratchet 278, when the sliding sleeve 279 moves upwards, a limit sliding block 2710 must slide into the limit sliding groove 274, the above operation is repeated after the sliding sleeve 279 moves upwards, the effect of throwing soybean and grinding soybean is achieved, in addition, a controller electrically connected with the driving motor 271 is arranged in the processing box 1, the effect of controlling the driving motor 271 to rotate forward and backward at regular time can be achieved, and since the control mode of the present utility model is automatically controlled by the controller, and the control circuit of the controller can be implemented by simple programming by those skilled in the art, the supply of power is also well known in the art, and the present utility model is mainly used for protecting mechanical devices, the present utility model does not explain the control mode and circuit connection in detail.

Although embodiments of the present utility model have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made therein without departing from the principles and spirit of the utility model, the scope of which is defined in the appended claims and their equivalents.

Claims (6)

1. The utility model provides a plant milk powder production is with grinding device, includes processing case (1), its characterized in that: a feeding mechanism (2) for feeding soybean is arranged in the processing box (1);

The feeding mechanism (2) comprises a storage cavity (21) and a grinding cavity (26) which are arranged in a processing box (1), a feeding port (24) used for communication is arranged between the storage cavity (21) and the grinding cavity (26), a grinding component (28) used for grinding soybeans is arranged in the grinding cavity (26), a lifting block (22) is slidably arranged at the lowest part of the storage cavity (21), a traction rope (23) is fixedly arranged on the upper part of the lifting block (22), a traction block (25) fixedly connected with the traction rope (23) is slidably arranged in the processing box (1), and a driving component (27) used for controlling the movement of the traction block (25) and the grinding component (28) is arranged in the processing box (1).

2. A milk milling device for producing plant milk powder according to claim 1, characterized in that: the material storage cavity (21) is internally provided with a baffle plate (211) in a sliding mode, the bottom of the baffle plate (211) is fixedly provided with a collision rod (210) which is mutually collided with the lifting block (22), and the bottom of the baffle plate (211) is fixedly provided with a collision spring (212) fixedly connected with the processing box (1).

3. A milk milling device for producing plant milk powder according to claim 1, characterized in that: the grinding assembly (28) comprises a grinding block (281) arranged in a grinding cavity (26), a screen plate (282) is fixedly arranged in the grinding cavity (26) and located below the grinding block (281), a liquid outlet cavity (284) is formed in the inner cavity of the processing box (1) and located below the grinding cavity (26), a filter plate (283) is obliquely arranged between the grinding cavity (26) and the liquid outlet cavity (284), and a water supplementing assembly (29) is arranged on the inner wall of the grinding cavity (26).

4. A milk milling device for producing a plant milk powder according to claim 3, characterized in that: the water supplementing assembly (29) comprises a water supplementing cavity (291) formed in the inner wall of the grinding cavity (26), water supplementing holes (292) used for communicating are formed between the water supplementing cavity (291) and the grinding cavity (26), and a water supplementing flange communicated with the water supplementing cavity (291) is arranged outside the processing box (1).

5. A milk milling device for producing a plant milk powder according to claim 3, characterized in that: the driving assembly (27) comprises a driving motor (271) fixedly mounted on the upper portion of the processing box (1), an output end of the driving motor (271) penetrates through the processing box (1) and is provided with a driving screw rod (272), one end of the driving screw rod (272) is rotatably provided with a driving base (273) fixedly connected with the processing box (1), an external thread bush of the driving screw rod (272) is provided with a sliding sleeve (279), the sliding sleeve (279) is externally provided with four limit sliders (2710), the driving base (273) is rotatably provided with a driving sleeve (275) in an internal mode, a driving groove (276) which is in sliding fit with the limit sliders (2710) is formed in the driving sleeve (275), a limit chute (274) which slides mutually is formed in the upper portion of the driving base (273), a pawl (277) is elastically hinged to the bottom of the driving sleeve (275), and one side of the pawl (277) is meshed with a ratchet wheel (278) fixedly connected with the driving base (273).

6. The plant milk powder production pulping device of claim 5, wherein: the novel grinding device is characterized in that a first driving gear (2711) is fixedly arranged on the upper portion of the sliding sleeve (279), a second driving gear (2717) is meshed with one side of the first driving gear (2711), a rotating sleeve (2712) is coaxially fixed on the lower portion of the second driving gear (2717), a connecting piece (2713) with one end hinged to the sliding sleeve (279) is rotatably arranged on the outer portion of the rotating sleeve (2712), a transmission sleeve (2714) is rotatably arranged on the upper portion of the second driving gear (2717), a transmission rod (2715) is fixedly arranged on the outer portion of the transmission sleeve (2714), a C-shaped frame which is mutually clamped with the transmission rod (2715) is arranged on one side of the traction block (25), limiting sliding rods (2716) fixedly connected with the processing box (1) are sleeved on the middle portions of the second driving gear (2717), the transmission sleeve (2714) and the rotating sleeve (2712), and the bottom of the rotating sleeve (2712) is fixedly connected with the grinding block (281).