CN110477429B - Bean dreg cake forming machine - Google Patents

Abstract

The invention discloses a bean dreg cake forming machine, and belongs to the technical field of food forming equipment. And the bean dregs are filled into the punching holes on the punching circular plate of the punching mechanism through the filling mechanism, the driving mechanism controls the punching column to punch the bean dregs in the punching holes, and the bean dregs are pressed onto the bottom plate to form bean dregs cakes. After the bean dreg cake is formed in one punching hole, the driving mechanism controls the punching column to be taken out, a driving plate in the grooved pulley mechanism is controlled to rotate, the driving plate drives a driven grooved pulley to rotate, the driven grooved pulley rotates 360 degrees/n, a rotating shaft coaxially fixed with the driven grooved pulley rotates by the same angle, the rotating shaft drives the punching circular plate to rotate by the same angle, the bean dreg cake in one punching hole of the punching circular plate is rotated to the falling groove of the bottom plate, the bean dreg cake falls from the falling groove to be collected, and then the next bean dreg cake is punched and formed. The bean dreg cake forming machine can continuously form bean dreg cakes, and can be used for preparing a large amount of bean dreg into food, so that resources are effectively saved.

Description

Bean dreg cake forming machine

Technical Field

The invention relates to the technical field of food forming equipment, in particular to a bean dreg cake forming machine.

Background

The bean dregs are byproducts of processing bean products such as bean curd, soy milk and the like, and a large amount of bean dregs are generated in the process of manufacturing the bean products such as bean curd, soy milk and the like. The bean dregs have high nutritive value as food, but because the bean dregs are not easy to be made into food, although part of the bean dregs can be cooked, most of the bean dregs are directly discarded or used as fuel, so that the waste of resources is caused.

Disclosure of Invention

The embodiment of the invention provides a bean dreg cake forming machine which can be used for preparing a large amount of bean dreg into food, so that resources are effectively saved. The technical scheme is as follows:

the embodiment of the invention provides a bean dreg cake forming machine which comprises a stamping mechanism, a bracket, a filling mechanism, a driving mechanism and a sheave mechanism,

the stamping mechanism comprises a stamping circular plate, a rotating shaft, a bottom plate and a stamping column, wherein the stamping circular plate is coaxially fixed at one end of the rotating shaft, the bottom plate is sleeved on the rotating shaft and fixedly connected with the bracket, one plate surface of the stamping circular plate is propped against one plate surface of the bottom plate, n stamping holes with equal distance are formed in the circumferential direction of the stamping circular plate, n is more than or equal to 3, n is an integer, the stamping column is used for stamping bean dregs in the stamping holes, a dropping groove is formed in the bottom plate and corresponds to one stamping hole in the n stamping holes,

the filling mechanism is used for filling bean dregs into the n punching holes,

the driving mechanism is used for controlling the stamping column to stamp, a driven sheave of the sheave mechanism is coaxially fixed at the other end of the rotating shaft, the radial groove number of the driven sheave is n, and the driving mechanism is also used for controlling a driving plate of the sheave mechanism to rotate.

Optionally, the driving mechanism comprises a power element, a first gear, a second gear, a connecting rod, a sliding plate, a first transmission shaft, a connecting shaft, a first bevel gear and a second bevel gear,

the power element is in transmission connection with the first gear, the first gear is meshed with the second gear, the end face of the second gear is hinged with one end of the connecting rod, the other end of the connecting rod is hinged with the sliding plate, the sliding plate is slidably connected on the bracket, the sliding direction of the sliding plate is parallel to the axial direction of the punching hole, the sliding plate is fixed with the punching column,

the second gear is coaxially connected with one end of the first transmission shaft, the other end of the first transmission shaft is coaxially connected with the first bevel gear, the first bevel gear is meshed with the second bevel gear, the second bevel gear is coaxially connected with the connecting shaft, and the connecting shaft is coaxially connected with the driving plate.

Optionally, the packing mechanism includes a packing section of thick bamboo, a packing shaft and a packing pole, a packing section of thick bamboo with support fixed connection, a packing section of thick bamboo is located on the punching press plectane, it has a filler hole to open on the packing section of thick bamboo, the filler hole with one of n punching press holes corresponds, the coaxial interpolation of one end of a packing shaft is in a packing section of thick bamboo, one end of a packing shaft with the packing pole is fixed, the length direction of packing pole is perpendicular to the axial of packing shaft, the other end of packing shaft with power component transmission is connected.

Optionally, the driving mechanism further includes a third bevel gear, a fourth bevel gear, a fifth bevel gear, a sixth bevel gear and a second transmission shaft, the output shaft of the power element is coaxially connected with the third bevel gear, the third bevel gear is meshed with the fourth bevel gear, the fourth bevel gear is coaxially connected with the second transmission shaft, one end of the second transmission shaft is coaxially connected with the first gear, the other end of the second transmission shaft is coaxially connected with the fifth bevel gear, the fifth bevel gear is meshed with the sixth bevel gear, and the sixth bevel gear is coaxially connected with the other end of the filler shaft.

Optionally, the stamping mechanism further comprises a connecting plate, wherein the connecting plate is fixed on the bracket and hinged with the other end of the rotating shaft.

Optionally, the support includes horizontal supporting frame, vertical supporting frame, a plurality of horizontal movable rod and a plurality of vertical movable rod, a plurality of horizontal movable rod slidable sets up on the horizontal supporting frame, a plurality of vertical movable rod slidable sets up on the vertical supporting frame, the bottom plate the packing section of thick bamboo is all fixed on the vertical movable rod, first transmission shaft sets up on the horizontal movable rod.

Optionally, the bracket further comprises a first fixed cylinder, the first fixed cylinder is fixed on the transverse moving rod, and the first transmission shaft is rotatably inserted into the first fixed cylinder.

Optionally, the driving mechanism further comprises two guide plates, the two guide plates are connected to the support in parallel, two sliding grooves corresponding to the two guide plates are arranged on the sliding plate, and the two sliding grooves are respectively sleeved on the two guide plates.

Optionally, the number of the punching holes is 4.

Optionally, the plane that the axis of two punching holes of diagonal angle is located on the punching circular plate is perpendicular the terminal surface of second gear, one punching hole in two punching holes corresponds the groove that drops, bean dreg cake make-up machine still includes the pushing post, the pushing post is connected on the slide, the pushing post with two punching holes of punching post corresponding diagonal angle respectively, the pushing post is used for promoting bean dreg cake and follows the groove that drops.

The technical scheme provided by the embodiment of the invention has the beneficial effects that: the bean dreg cake forming machine can fill bean dreg into the punching holes on the punching circular plate of the punching mechanism through the filling mechanism, then the driving mechanism controls the punching columns in the punching mechanism to punch the bean dreg in the punching holes, and the bean dreg is punched on the bottom plate to form the bean dreg cake. After the bean dreg cake is formed in one punching hole, the punching column can be controlled by the driving mechanism to be taken out, and then the driving plate in the grooved pulley mechanism is controlled by the driving mechanism to rotate, so that the driving plate drives the driven grooved pulley to rotate, and the driven grooved pulley rotates by 360 degrees/n. At the moment, the rotating shaft coaxially fixed with the driven grooved pulley rotates by the same angle, the rotating shaft drives the stamping circular plate to rotate by the same angle, so that the bean dreg cake in one stamping hole of the stamping circular plate is rotated to the falling groove of the bottom plate, the bean dreg cake loses the shielding of the bottom plate and falls from the falling groove to be collected, and then the next bean dreg cake is subjected to stamping forming. The bean dreg cake forming machine can continuously form bean dreg cakes, and can be used for preparing a large amount of bean dreg into food, so that resources are effectively saved.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings that are required to be used in the description of the embodiments will be briefly introduced,

fig. 1 is a schematic structural view of an okara cake forming machine provided by an embodiment of the invention;

fig. 2 is a side view of an okara cake forming machine provided in an embodiment of the present invention;

fig. 3 is a schematic view of a part of a driving mechanism according to an embodiment of the present invention.

Detailed Description

For the purpose of making the objects, technical solutions and advantages of the present invention more apparent, the embodiments of the present invention will be described in further detail with reference to the accompanying drawings.

Fig. 1 is a schematic structural diagram of an okara cake forming machine provided by the embodiment of the invention, and as shown in fig. 1, the okara cake forming machine comprises a stamping mechanism 1, a bracket 2, a filling mechanism 3, a driving mechanism 4 and a sheave mechanism 5.

The pressing mechanism 1 includes a pressing disk 101, a rotation shaft 102, a bottom plate 103, and a pressing column 104. The punching circular plate 101 is coaxially fixed at one end of the rotating shaft 102, the bottom plate 103 is sleeved on the rotating shaft 102, the bottom plate 103 is fixedly connected with the support 2, one plate surface of the punching circular plate 101 abuts against one plate surface of the bottom plate 103, n equidistant punching holes are formed in the circumferential direction of the punching circular plate 101, n is larger than or equal to 3, n is an integer, the punching column 104 is used for punching bean dregs in the punching holes 101a, the bottom plate 103 is provided with a dropping groove 103a, and the dropping groove 103a corresponds to one punching hole 101a of the n punching holes.

The filling mechanism 3 is used for filling bean dregs into the n punching holes.

The driving mechanism 4 is used for controlling the punching column 104 to punch, the driven sheave 501 of the sheave mechanism 5 is coaxially fixed at the other end of the rotating shaft 102, the radial groove number 501a of the driven sheave 501 is n, and the driving mechanism 4 is also used for controlling the driving plate 502 of the sheave mechanism 5 to rotate.

The bean dreg cake forming machine can fill bean dreg into the punching hole 101a on the punching circular plate 101 of the punching mechanism 1 through the filling mechanism 3, then the driving mechanism 4 controls the punching column 104 in the punching mechanism 1 to punch the bean dreg in the punching hole 101a, and the bean dreg is punched on the bottom plate 103 to form the bean dreg cake. After the bean dreg cake is formed in one punching hole 101a, the punching column 104 can be controlled by the driving mechanism 4 to be taken out, and then the driving plate 502 in the grooved pulley mechanism 5 is controlled by the driving mechanism 4 to rotate, the driving plate 502 drives the driven grooved pulley 501 to rotate, and the driven grooved pulley 501 rotates by 360 degrees/n. At this time, the rotation shaft 102 coaxially fixed with the driven sheave 501 rotates by the same angle, the rotation shaft 102 drives the punching circular plate 101 to rotate by the same angle, so that the bean dreg cake in one punching hole 101a of the punching circular plate 101 is rotated to the position of the falling groove 103a of the bottom plate 103, the bean dreg cake is lost to be blocked and falls from the falling groove 103a to be collected, and then the next punching forming of the bean dreg cake is performed. The bean dreg cake forming machine can continuously form bean dreg cakes, and can be used for preparing a large amount of bean dreg into food, so that resources are effectively saved.

In this structure, the punching column 104 and the sheave mechanism 5 are controlled by the driving mechanism 4, and the space occupied by the whole is small.

As shown in fig. 1, the stamping mechanism 1 may further include a connection plate 105, the connection plate 105 being fixed to the bracket 2, the connection plate 105 being hinged to the other end of the rotation shaft 102.

The addition of the connecting plate 105 can improve the stability of the rotating shaft 102 during operation, and keep the rotating shaft 102 in the vertical state.

Fig. 2 is a side view of an okara cake forming machine according to an embodiment of the present invention, fig. 3 is a schematic diagram of a part of a structure of a driving mechanism 4 according to an embodiment of the present invention, and, with reference to fig. 1 to 3, the driving mechanism 4 includes a power element 401, a first gear 402, a second gear 403, a connecting rod 404, a sliding plate 405, a first transmission shaft 406, a connecting shaft 407, a first bevel gear 408 and a second bevel gear (not shown in the drawings).

The power element 401 is in transmission connection with the first gear 402, the first gear 402 is meshed with the second gear 403, the end face of the second gear 403 is hinged with one end of the connecting rod 404, the other end of the connecting rod 404 is hinged with the sliding plate 405, the sliding plate 405 is slidably connected to the support 2, the sliding direction of the sliding plate 405 is parallel to the axial direction of the punching hole 101a, and the sliding plate 405 is fixed with the punching column 104.

The second gear 403 is coaxially connected to one end of the first transmission shaft 406, the other end of the first transmission shaft 406 is coaxially connected to the first bevel gear 408, the first bevel gear 408 is meshed with the second bevel gear, the second bevel gear is coaxially connected to the connection shaft 407, and the connection shaft 407 is coaxially connected to the drive plate 502.

In this structure, the first gear 402 can be driven by only one power element 401, the first gear 402 drives the second gear 403 to rotate, the second gear 403, the connecting rod 404 and the sliding plate 405 form a crank-connecting rod 404 mechanism, the punching column 104 on the sliding plate 405 moves back and forth along with the sliding plate 405 in the sliding direction of the sliding plate 405, and the punching of the bean dreg cake is completed once per round of the punching column 104. Meanwhile, the rotation of the second gear 403 drives the first transmission shaft 406 to rotate, the movement of the first transmission shaft 406 is converted into the rotation of the connecting shaft 407 through the first bevel gear 408 and the second bevel gear, and finally the driving dial 502 of the geneva mechanism 5 is driven to rotate, so that the power element 401 can simultaneously control the geneva mechanism 5 and the punching column 104. The structure is convenient and occupies small space. And when the second gear 403 rotates for one circle, the sliding plate 405 drives the punching column 104 to complete one punching motion, at this time, the sheave mechanism 5 can just rotate for 360 °/n, so that the bean dreg cake in one punching hole 101a rotates to the falling groove 103a to fall, and the other punching hole 101a can fill the stroke of the bean dreg. The time interval of two bean dreg cakes is short, and the forming efficiency of the bean dreg cakes is high.

In the embodiment of the invention, the number of the punching holes 101a in the punching disc and the number of the driven sheaves 501 in the sheave mechanism 5 can be 4, so that the structure is convenient to design, and the forming efficiency of the bean dreg cake is higher.

On the premise that the number of the punching holes 101a is 4, the planes of the axes of the two punching holes 101a on the opposite angles of the punching circular plate 101 are perpendicular to the end face of the second gear 403, one punching hole 101a of the two punching holes 101a corresponds to the drop slot 103a, the bean dreg cake forming machine may further include a pushing column 6, the pushing column 6 is connected to the sliding plate 405, the pushing column 6 and the punching column 104 correspond to the two punching holes 101a on opposite angles respectively, and the pushing column 6 is used for pushing the bean dreg cake to drop from the drop slot 103 a.

In this arrangement, the punching column 104 and the pushing column 6 are controlled by the sliding plate 405 at the same time, and when one bean dreg cake is formed, the bean dreg cake in the other punching hole 101a is pushed by the pushing column 6 to fall off, so that the bean dreg cake is easy to collect, and the bean dreg cake can be stably fallen down due to the arrangement of the pushing column 6, so that the damage of the bean dreg cake is reduced.

Referring to fig. 1 and 2, the packing mechanism 3 includes a packing cylinder 301, a packing shaft 302, and a packing rod 303. The packing cylinder 301 is fixedly connected with the support 2, the packing cylinder 301 is positioned on the stamping circular plate 101, a packing hole 301a is formed in the packing cylinder 301, the packing hole 301a corresponds to one stamping hole 101a in the n stamping holes, one end of the packing shaft 302 is coaxially inserted into the packing cylinder 301, one end of the packing shaft 302 is fixed with the packing rod 303, the length direction of the packing rod 303 is perpendicular to the axial direction of the packing shaft 302, and the other end of the packing shaft 302 is in transmission connection with the power element 401.

The power element 401 in the driving mechanism 4 can drive the filling shaft 302 to rotate at the same time when driving, the filling shaft 302 rotates to drive the connecting rod to rotate, and bean dregs in the filling cylinder 301 are pushed to fall into the punching hole 101a from the filling hole 301a when the connecting rod rotates, so that the filling of the bean dregs in the punching hole 101a is convenient to realize, and the occupied space is small.

The packing cylinder 301 and the bracket 2 may be connected and fixed by a rod structure.

Referring to fig. 2 and 3, the driving mechanism 4 further includes a third bevel gear 409, a fourth bevel gear 410, a fifth bevel gear 411, a sixth bevel gear 412, and a second transmission shaft 413. The output shaft of the power element 401 is coaxially connected with the third bevel gear 409, the third bevel gear 409 meshes with the fourth bevel gear 410, the fourth bevel gear 410 is coaxially connected with the second transmission shaft 413, one end of the second transmission shaft 413 is coaxially connected with the first gear 402, the other end of the second transmission shaft 413 is coaxially connected with the fifth bevel gear 411, the fifth bevel gear 411 meshes with the sixth bevel gear 412, and the sixth bevel gear 412 is coaxially connected with the other end of the filler shaft 302.

In this structure, the power element 401 drives the second transmission shaft 413 to rotate through the third bevel gear 409 and the fourth bevel gear 410, the second transmission shaft 413 rotates to drive the first gear 402 to rotate, and meanwhile, the power of the second transmission shaft 413 can be transmitted to the packing shaft 302 through the fifth bevel gear 411 and the sixth bevel gear 412, so as to realize control of the packing rod 303. The driving mechanism 4 with such an arrangement occupies very little space, reducing the space occupied by the machine.

As shown in fig. 1, the driving mechanism 4 may further include two guide plates 414, where the two guide plates 414 are connected to the support 2 in parallel, and two sliding grooves 405a corresponding to the two guide plates 414 are provided on the sliding plate 405, and the two sliding grooves 405a are respectively sleeved on the two guide plates 414.

The arrangement of the guide plate 414 and the chute 405a ensures stable operation and running of the slide plate 405 and the ram 104.

Referring to fig. 1 to 3, the stand 2 may include a lateral support frame 201, a longitudinal support frame 202, a plurality of lateral movement bars 203, and a plurality of longitudinal movement bars 204, the plurality of lateral movement bars 203 being slidably disposed on the lateral support frame 201, the plurality of longitudinal movement bars 204 being slidably disposed on the longitudinal support frame 202, the base plate 103 and the packing cylinder 301 being fixed on the longitudinal movement bars 204, and the first transmission shaft 406 and the second transmission shaft 413 being disposed on the lateral movement bars 203.

The bracket 2 adopts the structure, so that the space occupied by the bracket 2 can be reduced, and the positions of the transverse moving rod and the longitudinal moving rod 204 can be freely adjusted, so that the stamping mechanism 1, the driving mechanism 4 and other structures can be conveniently disassembled and assembled.

As shown in fig. 3, the bracket 2 may further include a first fixed cylinder 205 and a second fixed cylinder 206, where the first fixed cylinder 205 and the second fixed cylinder 206 are both fixed on the lateral moving rod 203, and a first transmission shaft 406 and a second transmission shaft 413 are respectively rotatably inserted into the first fixed cylinder 205 and the second fixed cylinder 206.

The first transmission shaft 406 and the second transmission shaft 413 are arranged on the bracket 2 through the first fixing cylinder 205 and the second fixing cylinder 206, so that the stability of the first transmission shaft 406 and the second transmission shaft 413 can be improved, and the working stability of the bean dreg cake forming machine can be improved.

Referring to fig. 2 and 3, the okara cake molding machine may further include a collecting mechanism 7, the collecting mechanism 7 being for collecting the okara cake dropped from the drop tank 103 a.

The collection mechanism 7 is added to avoid stacking of bean dreg cakes and ensure that the bean dreg cake forming machine stably pressurizes and forms the bean dreg cakes.

The collecting mechanism 7 may include a conveyor belt 701, a first conveying shaft 702, a second conveying shaft 703 and a motor 704, where the first conveying shaft 702 and the second conveying shaft 703 are arranged in parallel, the conveyor belt 701 is sleeved on the first conveying shaft 702 and the second conveying shaft 703 in a straight manner, an output shaft of the motor 704 is coaxially connected with the first transmission shaft 406, and the motor 704 is arranged on the transverse supporting frame 201.

The motor 704 is operated to drive the first conveying shaft 702 to rotate, and the first conveying shaft 702 drives the conveying belt to rotate under the action of friction force to convey the bean dreg cakes out of the bean dreg cake forming machine.

Optionally, the collecting mechanism 7 further includes two support rods 705, where the two support rods 705 are arranged side by side, one ends of the two support rods 705 are fixed on the transverse support frame 201, and the other ends of the two support rods 705 are detachably connected with the motor 704.

The foregoing description of the preferred embodiments of the invention is not intended to limit the invention to the precise form disclosed, and any such modifications, equivalents, and alternatives falling within the spirit and scope of the invention are intended to be included within the scope of the invention.

Claims (6)

1. The bean dreg cake forming machine is characterized by comprising a stamping mechanism (1), a bracket (2), a filling mechanism (3), a driving mechanism (4) and a sheave mechanism (5),

the stamping mechanism (1) comprises a stamping circular plate (101), a rotating shaft (102), a bottom plate (103), a stamping column (104) and a connecting plate (105), wherein the stamping circular plate (101) is coaxially fixed at one end of the rotating shaft (102), the bottom plate (103) is sleeved on the rotating shaft (102), the bottom plate (103) is fixedly connected with the support (2), one plate surface of the stamping circular plate (101) is propped against one plate surface of the bottom plate (103), n stamping holes with equal intervals are formed in the circumferential direction of the stamping circular plate (101), wherein n is equal to or more than 3, n is an integer, the stamping column (104) is used for stamping bean dregs in the stamping holes (101 a), a dropping groove (103 a) is formed in the bottom plate (103), the dropping groove (103 a) corresponds to one stamping hole (101 a) in the n stamping holes, the connecting plate (105) is fixed on the support (2), the connecting plate (105) is hinged with the other end of the rotating shaft (102),

the bracket (2) comprises a transverse supporting frame (201), a longitudinal supporting frame (202), a plurality of transverse moving rods (203) and a plurality of longitudinal moving rods (204), wherein the transverse moving rods (203) are slidably arranged on the transverse supporting frame (201), the longitudinal moving rods (204) are slidably arranged on the longitudinal supporting frame (202), the bottom plate (103) is fixed on the longitudinal moving rods (204),

the driving mechanism (4) is used for controlling the punching column (104) to punch, a driven grooved pulley (501) of the grooved pulley mechanism (5) is coaxially fixed at the other end of the rotating shaft (102), the radial groove number (501 a) of the driven grooved pulley (501) is n, the driving mechanism (4) is also used for controlling a driving plate (502) of the grooved pulley mechanism (5) to rotate, the driving mechanism (4) comprises a power element (401), a first gear (402), a second gear (403), a connecting rod (404), a sliding plate (405), a first transmission shaft (406), a connecting shaft (407), a first bevel gear (408) and a second bevel gear, the power element (401) is in transmission connection with the first gear (402), the first gear (402) is meshed with the second gear (403), the end face of the second gear (403) is hinged with one end of the connecting rod (404), the other end of the connecting rod (404) is hinged with the sliding plate (405), the sliding plate (405) is slidably connected with the bracket (2), the sliding plate (405) is connected with the first transmission shaft (101) in the axial direction of the first transmission shaft (406), the sliding plate (405) is connected with the first transmission shaft (101) in parallel to the axial direction of the punching column (406), the other end of the first transmission shaft (406) is coaxially connected with the first bevel gear (408), the first transmission shaft (406) is arranged on the transverse moving rod (203), the first bevel gear (408) is meshed with the second bevel gear, the second bevel gear is coaxially connected with the connecting shaft (407), the connecting shaft (407) is coaxially connected with the driving dial (502),

the packing mechanism (3) is used for packing bean dregs into the n punching holes, the packing mechanism (3) comprises a packing cylinder (301), a packing shaft (302) and a packing rod (303), the packing cylinder (301) is fixedly connected with the longitudinal moving rod (204), the packing cylinder (301) is located on the punching circular plate (101), a packing hole (301 a) is formed in the packing cylinder (301), the packing hole (301 a) corresponds to one punching hole (101 a) in the n punching holes, one end of the packing shaft (302) is coaxially inserted into the packing cylinder (301), one end of the packing shaft (302) is fixed with the packing rod (303), the length direction of the packing rod (303) is perpendicular to the axial direction of the packing shaft (302), and the other end of the packing shaft (302) is in transmission connection with the power element (401).

2. The okara cake molding machine according to claim 1, characterized in that the driving mechanism (4) further comprises a third bevel gear (409), a fourth bevel gear (410), a fifth bevel gear (411), a sixth bevel gear (412) and a second transmission shaft (413), an output shaft of the power element (401) is coaxially connected with the third bevel gear (409), the third bevel gear (409) is engaged with the fourth bevel gear (410), the fourth bevel gear (410) is coaxially connected with the second transmission shaft (413), one end of the second transmission shaft (413) is coaxially connected with the first gear (402), the other end of the second transmission shaft (413) is coaxially connected with the fifth bevel gear (411), the fifth bevel gear (411) is engaged with the sixth bevel gear (412), and the sixth bevel gear (412) is coaxially connected with the other end of the filler shaft (302).

3. The okara cake molding machine according to claim 1, characterized in that the bracket (2) further comprises a first fixed cylinder (205), the first fixed cylinder (205) is fixed on the transverse moving rod (203), and the first transmission shaft (406) is rotatably inserted in the first fixed cylinder (205).

4. The okara cake forming machine according to claim 2, characterized in that the driving mechanism (4) further comprises two guide plates (414), the two guide plates (414) are connected to the support (2) in parallel, two sliding grooves (405 a) corresponding to the two guide plates (414) are arranged on the sliding plate (405), and the two sliding grooves (405 a) are respectively sleeved on the two guide plates (414).

5. The okara cake molding machine of claim 2, characterized in that the number of the punching holes (101 a) is 4.

6. The okara cake molding machine according to claim 5, characterized in that the planes of the axes of two diagonal punching holes (101 a) on the punching circular plate (101) are perpendicular to the end face of the second gear (403), one punching hole (101 a) of the two punching holes (101 a) corresponds to the drop slot (103 a), the okara cake molding machine further comprises a pushing post (6), the pushing post (6) is connected to the sliding plate (405), the pushing post (6) and the punching post (104) correspond to the two punching holes (101 a) of the diagonal respectively, and the pushing post (6) is used for pushing the okara cake to drop from the drop slot (103 a).