CN111280194A - Flour dough equivalent segmentation auxiliary assembly - Google Patents

Abstract

The invention relates to auxiliary equipment, in particular to flour dough equivalent segmentation auxiliary equipment. The technical problem is how to design an equivalent dividing auxiliary device which can divide flour dough into equal parts, so that the manufactured baked wheat cakes are consistent in parts, the selling is not influenced, and vegetable oil can be sprayed to avoid the flour dough from being stuck. The utility model provides an auxiliary assembly is cut apart to flour dough equivalent, includes the bottom plate, the rigid coupling of bottom plate one side symmetry formula has the mounting bracket, the quantity of backup pad is two at least. According to the invention, the servo motor is started, so that the conveying belt can rotate forwards, the quantitative hopper rotates backwards to enable the material receiving groove to rotate upwards, the material pushing plate presses flour dough into the quantitative hopper, the quantitative hopper conveys the flour dough with the same quantity onto the conveying belt, and the conveying belt conveys the flour dough onto the opening plate, so that the flour dough can be divided into the same quantity, the problem that the quantity is inconsistent when baked cakes are made is avoided, and the sale is not influenced.

Description

Flour dough equivalent segmentation auxiliary assembly

Technical Field

The invention relates to auxiliary equipment, in particular to flour dough equivalent segmentation auxiliary equipment.

Background

Flour is a powder ground from wheat. According to the content of protein in the flour, the flour can be divided into high gluten flour, medium gluten flour, low gluten flour and non-gluten flour. Flour (wheat flour) is staple food in most areas in the north of China, food made of the flour is various in variety, various in pattern and different in flavor, flour dough is required to be processed and made into baked cakes in the process of making the baked cakes, and the flour dough is required to be divided because a large number of flour dough are made, so that the baked cakes are convenient to make.

The existing cutting device, for example, chinese patent with patent publication No. CN209152130U discloses a dough cutting device, which is characterized in that: the cutting device comprises a transmission shaft, a transmission belt and a cutter, wherein the transmission shaft is connected with the transmission belt, the transmission shaft is provided with a crankshaft, the cutter is installed in a sliding rail, the moving direction of the sliding rail is perpendicular to the transmission belt, and the crankshaft is connected with the cutter through a connecting rod. The invention has the beneficial effects that: the dough moves under the drive belt drives, and the transmission shaft rotates along with the drive belt, and bent axle, connecting rod and cutter constitute slider-crank mechanism, and the transmission shaft drives the bent axle and rotates, is that the cutter reciprocates along the slide rail along the drive belt, and the cutter cuts the dough on the drive belt, and above-mentioned patent exists following not enoughly: the flour dough can not be equally divided, so that the sesame seed cake is easily inconsistent in weight after being made, the selling is influenced, and the vegetable oil is not sprayed to avoid the flour dough from being stuck and inconvenient to take out.

Therefore, an auxiliary device for dividing the flour dough into equal parts is particularly needed, so that the manufactured baked wheat cakes are consistent in quantity, the selling is not affected, and vegetable oil can be sprayed to avoid the flour dough from being stuck, so that the problems in the prior art are solved.

Disclosure of Invention

In order to overcome the defects that the flour dough can not be equally divided, the quantity of the baked wheat cake is easily inconsistent after the baked wheat cake is made, the baking cake is sold under the influence, and the vegetable oil is not sprayed to avoid the flour dough from being stuck and inconvenient to take out, the technical problem to be solved is as follows: the utility model provides a can cut apart the equal volume of flour dough for the sesame seed cake volume of making is unanimous, does not influence and sells, and can also spout the equal volume of dividing apart auxiliary assembly of flour dough that vegetable oil avoided the flour dough to stick.

The technical scheme of the invention is as follows: an equal-quantity dividing auxiliary device for flour dough, comprising: the quantitative frame is arranged between one sides of the two support plates far away from the bottom plate; the placing frame is arranged on one side of the outside of the quantitative frame far away from the bottom plate, and the material pushing plate capable of extruding the flour dough is placed in the placing frame in a sliding mode; the one-way valve pipe is arranged on one side in the quantitative frame facing the bottom plate, one end of the one-way valve pipe penetrates through the quantitative frame, and the oil inlet pipe is connected to the end part of the one-way valve pipe positioned outside the quantitative frame and communicated with the end part; the conveying device is arranged between the two mounting racks and one side of the bottom plate and is used for conveying the equivalent flour dough; and the quantitative discharging device is arranged between the placing frame and the quantitative frame, is fixedly connected with the conveying device and the material pushing plate, and is used for dividing the flour dough into equal quantities.

Further, the conveying device comprises: the conveying belt is wound between the two driving rollers, and one of the driving rollers is connected with the quantitative discharging device; the servo motor is arranged at the edge of one side of the bottom plate, and an output shaft of the servo motor is fixedly connected with the end part of the transmission roller at the same side; the opening plate is installed between the inner sides of the two mounting frames, matched with the conveying belt and used for collecting the flour dough.

Further, the quantitative discharging device comprises: the first fixing seat is arranged on one side of the outer side of the quantitative frame far away from the oil inlet pipe, and a first driving assembly is connected between one side of the first fixing seat and the end part, close to the opening plate, of the driving roller far away from the servo motor; the rotating disc is arranged at the end part of the shaft of the first driving assembly far away from the first fixed seat, and the pushing rod is arranged at the position of the circle center of one side of the rotating disc far away from the first driving assembly; the third fixing seat is mounted on one side of the outer side of the placing frame far away from the bottom plate and the first driving assembly, and the rotating rod is rotatably connected to one part of the third fixing seat far away from the placing frame in a penetrating mode; the first gear is arranged at one end of the rotating rod; the pushing frame is arranged on one side of the material pushing plate far away from the bottom plate and is L-shaped, the sliding rail is vertically arranged on one side in the pushing frame towards the bottom plate, and the sliding strip is slidably arranged on the sliding rail; the ratchet bar is arranged on one side of the sliding bar far away from the sliding rail, one side of the ratchet bar far away from the placing frame is fixedly connected with a first rack, and the first rack is meshed with the first gear; the ratchet is rotatably arranged on one side of the third fixed seat close to the sliding rail and is meshed with the ratchet strip, and the torsion spring is connected to the joint of the ratchet and the third fixed seat; the limiting rod is arranged on one side of the third fixing seat close to the ratchet and is in contact fit with the ratchet; the second fixed seat is arranged on one side outside the quantitative frame on the same side with the first driving assembly, the rotating shaft is rotatably connected to one part of the second fixed seat far away from the quantitative frame in a penetrating manner, and a second driving assembly is connected between the end part of the second fixed seat far away from the first driving assembly and the end part of the rotating rod far away from the first gear; the driving shaft is rotatably connected between the middle parts of the quantitative frames in a penetrating manner, and a three-groove frame is fixedly connected to the end part of the driving shaft close to the rotating disc and matched with the push rod; the number of the first bevel gears is at least two, one of the first bevel gears is arranged at one part of the driving shaft close to the quantitative frame and the rotating rod, the other one of the first bevel gears is arranged at the end part of the rotating shaft facing the first driving component, and the two first bevel gears are meshed with each other; and the quantitative hopper is arranged on the driving shaft positioned in the quantitative frame and is used for dividing the flour dough into equal amounts.

Further, the method also comprises the following steps: the third driving assembly is arranged between one sides of the two driving rollers close to the servo motor, the number of the tooth blocks is at least six, and the tooth blocks are arranged on a belt of the third driving assembly; the third gear is rotatably arranged on one side of the support plate close to the third driving assembly and far away from the servo motor and is matched with the tooth block; the bearing seat is arranged on one side of the supporting plate close to the third gear, the transmission shaft is rotatably connected in the bearing seat in a penetrating manner, and a second gear is fixedly connected to the end part of the transmission shaft far away from the servo motor; the number of the second bevel gears is at least two, one of the second bevel gears is arranged at the end part of the transmission shaft far away from the second gear, the other one of the second bevel gears is arranged at the end part of the third gear far away from the support plate, and the two second bevel gears are meshed; the guide strip is arranged on the supporting plate close to the first driving assembly and close to the third driving assembly; the number of the guide sleeves is at least two, the guide sleeves are sleeved on the guide strip in a sliding mode, and the second rack is arranged between one sides of the two guide sleeves facing the servo motor and meshed with the second gear; the first compression spring is sleeved on the guide strip, one end of the first compression spring is fixedly connected with one side of the guide sleeve far away from the first driving assembly, and the other end of the first compression spring is fixedly connected with the end part of the guide strip far away from the first driving assembly; the connecting rod is arranged on one side of the second rack far away from the second gear and the transmission roller; the wedge-shaped plate is slidably placed on one side of the bottom plate close to the opening plate and the mounting frame, and one side of the wedge-shaped plate is fixedly connected with the tail end of the connecting rod; the number of the guide rails is at least two, the guide rails are symmetrically arranged in the middle of one side of the bottom plate close to the wedge-shaped plate, the transverse plate is placed on the inner side of the guide rails in a sliding mode, and the second compression spring is connected between one side of the transverse plate facing the bottom plate and one side of the bottom plate facing the opening plate; the number of the printing plates is at least nine, the printing plates are fixedly connected between the transverse plates at the two sides at intervals and matched with the opening plate; and the cambered plate is arranged between one sides of the two transverse plates close to the wedge-shaped plate and towards the bottom plate, and is in contact fit with the inclined surface of the wedge-shaped plate.

Further, the method also comprises the following steps: the hollow frame is arranged on one side outside the placing frame close to the oil inlet pipe, one side of the hollow frame is connected and communicated with the tail end of the oil inlet pipe, and the infusion pipe is connected to one side of the hollow frame far away from the bottom plate and communicated with the inside of the hollow frame; the baffle plate is arranged in the hollow frame in a sliding mode and used for blocking a feeding hole of an oil inlet pipe, and the third compression spring is connected between one side of the baffle plate facing the bottom plate and the inner side of the hollow frame; the vertical plate is arranged on one side of the bottom plate close to the servo motor, and two lead frames are fixedly connected to one side of the vertical plate facing the supporting plate; a fourth gear rotatably connected to the side close to the bottom plate and facing the mounting rack and engaged with the tooth block; and the winding roller is arranged at one part of the fourth gear close to the vertical plate, the pull wire is wound on the winding roller, and the tail end of the pull wire penetrates through the lead frame and then penetrates through the hollow frame to be fixedly connected with one side of the stop block facing the bottom plate.

Further, the method also comprises the following steps: the guide frame is symmetrically arranged on one side of the opening plate far away from the bottom plate and is parallel to the guide strip; and the oil brushing roller is placed between the guide frames on the two sides in a sliding manner.

The invention has the following advantages:

1. through starting servo motor, can be so that the conveyer belt corotation, make the constant head box reversal simultaneously make to connect the silo reversal to the top, the scraping wings then impresses the flour dough in the constant head box, the constant head box carries equivalent flour dough to the conveyer belt on, the conveyer belt then carries the flour dough to the opening board on, so can make the flour dough cut apart into equivalent, weight is inconsistent when avoiding the sesame seed cake preparation, does not influence and sells.

2. Plant oil is sprayed into the quantitative hopper through the check valve pipe, and the flour dough is contacted with the plant oil, so that the flour dough can be prevented from being stuck and being difficult to drop.

3. Through the effect of the printing plate, the equal amount of flour dough can be further marked in an equal amount, so that the flour dough can be conveniently used by a subsequent operator.

Drawings

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

Fig. 2 is a schematic perspective view of a second embodiment of the present invention.

Fig. 3 is a schematic diagram of a partially separated three-dimensional structure according to the present invention.

FIG. 4 is a schematic view of a first partial body structure according to the present invention.

Fig. 5 is an enlarged schematic view of the structure of the present invention a.

FIG. 6 is a schematic view of a second partial body structure according to the present invention.

In the reference symbols: 1. a bottom plate, 2, a mounting frame, 3, a conveying device, 301, a driving roller, 302, a conveying belt, 303, a servo motor, 304, an opening plate, 4, a supporting plate, 5, a quantitative frame, 6, a placing frame, 7, a quantitative discharging device, 701, a driving shaft, 702, a quantitative hopper, 703, a first bevel gear, 704, a three-groove rack, 705, a first fixed seat, 706, a first driving component, 707, a rotating disk, 708, a pushing rod, 709, a second fixed seat, 7010, a third fixed seat, 7011, a second driving component, 7012, a first gear, 7013, a sliding rail, 7014, a sliding bar, 7015, a ratchet bar, 7016, a first rack, 7017, a pushing rack, 7018, a ratchet, a torsion spring, 7020, a limiting rod, 7021, a rotating shaft, 7022, a rotating rod, 8, a material pushing plate, 9, an oil inlet pipe, 10, a one-way valve pipe, 11, a guide bar, 12, a guide sleeve, 7014, a second spring, 13, a first compression spring, 15. the automatic winding device comprises a bearing seat, 16. a transmission shaft, 17. a second gear, 18. a second bevel gear, 19. a third gear, 20. a third driving assembly, 21. a gear block, 22. a connecting rod, 23. a wedge-shaped plate, 24. a guide rail, 25. a transverse plate, 26. a printing plate, 27. a second compression spring, 28. a cambered plate, 29. a vertical plate, 30. a winding roller, 31. a fourth gear, 32. a lead frame, 33. a pull wire, 34. a hollow frame, 35. a third compression spring, 36. a stop block, 37. a liquid conveying pipe, 38. a guide frame and 39. an oil brushing roller.

Detailed Description

The following further describes the technical solution with reference to specific embodiments, and it should be noted that: the words upper, lower, left, right, and the like used herein to indicate orientation are merely for the location of the illustrated structure in the corresponding figures. The serial numbers of the parts are themselves numbered herein, for example: first, second, etc. are used solely to distinguish one from another as to objects described herein, and do not have any sequential or technical meaning. The application states that: the connection and coupling, unless otherwise indicated, include both direct and indirect connections (couplings).

Example 1

Referring to fig. 1-4, an equivalent dividing auxiliary device for flour dough comprises a bottom plate 1, a mounting frame 2, a conveying device 3, a supporting plate 4, a quantitative frame 5, a placing frame 6, a quantitative discharging device 7, a material pushing plate 8, an oil inlet pipe 9 and a one-way valve pipe 10, wherein the mounting frame 2 is fixedly connected to the front side and the rear side of the top of the bottom plate 1, the conveying device 3 is arranged between the top ends of the mounting frame 2, the supporting plate 4 is fixedly connected to the middle of the top of the mounting frame 2, the quantitative frame 5 is fixedly connected between the top of the supporting plate 4, the placing frame 6 is fixedly connected to the top of the quantitative frame 5, the material pushing plate 8 is slidably arranged in the placing frame 6, the quantitative discharging device 7 is arranged between the top of the material pushing plate 8 and the outer side of the placing frame 6 and the quantitative frame 5, the quantitative discharging device 7 is matched with the quantitative frame 5, the quantitative discharging, the front end of the one-way valve pipe 10 penetrates through the quantitative frame 5 to be connected with an oil inlet pipe 9, and the oil inlet pipe 9 is communicated with the inside of the one-way valve pipe 10.

Conveyor 3 is including driving roller 301, conveyer belt 302, servo motor 303 and opening plate 304, between the 2 upper portion left sides of front and back both sides mounting bracket and between the right side all the rotary type be connected with driving roller 301, around there being conveyer belt 302 between the left and right sides driving roller 301, right side driving roller 301 rear end is connected with ration discharging device 7, fixedly connected with can be to the opening plate 304 of face powder collection between the 2 medial surface right sides of front and back both sides mounting bracket, servo motor 303 is installed through bolted connection's mode to the front portion in 1 top left side of bottom plate, servo motor 303's output shaft passes through shaft coupling and the 301 front end fixed connection of left side driving roller.

The quantitative discharging device 7 comprises a driving shaft 701, a quantitative hopper 702, a first bevel gear 703, a three-groove rack 704, a first fixed seat 705, a first driving component 706, a rotating disk 707, a pushing rod 708, a second fixed seat 709, a third fixed seat 7010, a second driving component 7011, a first gear 7012, a sliding rail 7013, a sliding bar 7014, a ratchet bar 7015, a first rack 7016, a pushing rack 7017, a ratchet 7018, a torsion spring 7019, a limiting rod 7020, a rotating shaft 7021 and a rotating rod 7022, wherein the driving shaft 701 is rotatably connected between the middle parts of the front side and the rear side of the quantitative frame 5, the quantitative hopper 702 is fixedly connected to the front part of the driving shaft 701 and is positioned in the quantitative frame 5 to be matched with the quantitative hopper 702, the three-groove rack 704 is fixedly connected to the rear part of the right side outside the quantitative frame 5, the first fixed seat 705 is fixedly connected to the middle part of the rear part of the right side, the first driving component 706 is, a rotating disk 707 is fixedly connected to the rear end of a shaft on the first driving component 706, a pushing rod 708 is fixedly connected to the center of the circle of the rear side of the rotating disk 707, the rotating disk 707 and the pushing rod 708 are both matched with the three-slot rack 704, a second fixing seat 709 is fixedly connected to the middle part of the left side of the outer rear side of the quantitative frame 5, a rotating shaft 7021 is rotatably connected to the rear part of the second fixing seat 709, first bevel gears 703 are fixedly connected to the right end of the rotating shaft 7021 and the rear part of the driving shaft 701, the two first bevel gears 703 are engaged, a third fixing seat 7010 is fixedly connected to the left side of the upper part of the outer rear side of the placing frame 6, a rotating rod 7022 is rotatably connected to the rear part of the third fixing seat 7010, a second driving component 7011 is arranged between the left end of the rotating rod 7022 and the left end of the rotating shaft 7021, a first gear 7012 is fixedly connected, a sliding bar 7014 is arranged on the sliding rail 7013 in a sliding manner, a ratchet bar 7015 is fixedly connected to the right side of the sliding bar 7014, a first rack 7016 is fixedly connected to the rear side of the ratchet bar 7015, the first rack 7016 is engaged with a first gear 7012, a ratchet 7018 is rotatably connected to the front portion of the right side of the third fixing seat 7010, the ratchet 7018 is engaged with the ratchet bar 7015, a torsion spring 7019 is arranged at the joint of the ratchet 7018 and the third fixing seat 7010, a limiting rod 7020 capable of limiting the ratchet 7018 is mounted on the upper portion of the front side of the right side of the third fixing seat 7010, and the limiting rod 7020 is in contact with the ratchet 7018.

Initially, a proper amount of fermented flour dough is placed in the placing frame 6, firstly, an operator connects vegetable oil outside the oil inlet pipe 9, the vegetable oil is discharged into the oil inlet pipe 9, the vegetable oil in the oil inlet pipe 9 is discharged into the one-way valve pipe 10, the vegetable oil in the one-way valve pipe 10 is sprayed on the quantitative discharging device 7, when a proper amount of vegetable oil is arranged on the quantitative discharging device 7, the vegetable oil is stopped being discharged into the oil inlet pipe 9, the conveying device 3 is started, the conveying device 3 operates to drive the quantitative discharging device 7 to operate, the quantitative discharging device 7 intermittently drives the material pushing plate 8 to move downwards, the material pushing plate 8 moves downwards to extrude the flour dough, the flour dough is further pressed into the quantitative discharging device 7, the quantitative discharging device 7 conveys the same amount of flour dough onto the conveying device 3, the conveying device 3 operates to convey the flour dough to the right side, the operator can take down the flour dough for subsequent treatment, repeating the steps to divide the flour dough into equal amount. After the flour dough is cut, the conveying device 3 is closed, and the quantitative discharging device 7 is pulled to drive the material pushing plate 8 to move upwards for resetting.

When a proper amount of vegetable oil is sprayed on the quantitative discharging device 7, the servo motor 303 is started to rotate forwards, the servo motor 303 rotates forwards to drive the left driving roller 301 to rotate forwards, the left driving roller 301 rotates forwards to drive the conveying belt 302 to rotate forwards through the right driving roller 301, the right driving roller 301 also drives the quantitative discharging device 7 to operate, the quantitative discharging device 7 operates to intermittently drive the material pushing plate 8 to move downwards, then the flour dough with the same amount is pressed into the quantitative discharging device 7, the quantitative discharging device 7 conveys the flour dough to the conveyer belt 302, the conveyer belt 302 rotates forwards to drive the flour dough to move rightwards, when the flour dough moves rightwards to the maximum stroke, the dough drops onto the opening plate 304, the operator can take the dough off the opening plate 304 for use, this is repeated, and every time the same amount of dough is fed onto the conveyor belt 302 by the constant-volume-feeder 7, the conveyor belt 302 feeds the dough onto the opening plate 304. When the dough is divided, the servo motor 303 is turned off and the conveyor belt 302 stops rotating forward.

When the one-way valve pipe 10 sprays vegetable oil, the vegetable oil is sprayed in the quantitative hopper 702, and further when the servo motor 303 is started, the right-side driving roller 301 rotates forward to drive the first driving component 706 to rotate forward, the first driving component 706 rotates forward to drive the rotating disc 707 to rotate forward, the rotating disc 707 rotates forward to drive the push rod 708 to rotate forward, when the push rod 708 rotates forward to contact with the three-groove frame 704, the push rod 708 drives the three-groove frame 704 to rotate backward, the three-groove frame 704 rotates backward to drive the driving shaft 701 to rotate backward, the driving shaft 701 rotates backward to drive the quantitative hopper 702 to rotate backward, one of the material receiving grooves rotates backward to the upper side by the reverse rotation of the quantitative hopper 702, meanwhile, the driving shaft 701 rotates backward to drive the front-side first bevel gear 703 to rotate backward, the front-side first bevel gear rotates backward to drive the rear-side first bevel gear 703 to rotate backward to drive the rotating shaft 7021 to rotate backward, the rotating shaft 7021 rotates backward to drive, the rotating rod 7022 rotates reversely to drive the first gear 7012 to rotate reversely, the first gear 7012 rotates reversely to drive the first rack 7016 to move downwards, the first rack 7016 moves downwards to drive the ratchet bar 7015 to move downwards, the ratchet bar 7015 moves downwards to slide on the ratchet 7018, the ratchet bar 7015 also drives the pushing frame 7017 to move downwards, the pushing frame 7017 moves downwards to drive the pushing plate 8 to move downwards, the pushing plate 8 moves downwards to press the flour dough into the receiving groove of the quantitative hopper 702, when the pushing rod 708 rotates forwards continuously to separate from the three groove frames 704, the quantitative hopper 702 stops rotating backwards, the pushing plate 8 also stops moving downwards, when the pushing rod 708 rotates forwards continuously to contact with the three groove frames 704, the pushing rod 708 rotates reversely to drive the three groove frames 704 to rotate backwards, the quantitative hopper 702 rotates the flour dough reversely, and simultaneously the next receiving groove rotates upwards, and the same amount of flour dough can be continuously pressed into the quantitative hopper 702, when the flour dough on the quantitative hopper 702 rotates backwards to the lower side, the dough drops onto the conveyor belt 302, and the conveyor belt 302 transports the dough onto the aperture plate 304. When the flour dough is divided into equal amounts, the servo motor 303 is turned off, the quantitative hopper 702 stops reversing, and the pushing frame 7017 stops driving the material pushing plate 8 to move downwards. After the flour dough is cut, the ratchet 7018 is pulled to swing forwards, the torsion spring 7019 is stretched, the ratchet 7018 swings forwards to be separated from the ratchet bar 7015, the ratchet bar 7015 can be pulled to move upwards, the pushing frame 7017 drives the material pushing plate 8 to move upwards to reset, the ratchet 7018 is loosened, and the ratchet 7018 swings backwards to reset and is meshed with the ratchet bar 7015 under the action of the torsion spring 7019. Thus, the dough mass can be divided into equal amounts for subsequent use.

Example 2

Referring to fig. 1, 3, 5 and 6, the present embodiment mainly differs from embodiment 1 in that the present embodiment further includes a guide bar 11, a guide sleeve 12, a second rack 13, a first compression spring 14, a bearing seat 15, a transmission shaft 16, a second gear 17, a second bevel gear 18, a third gear 19, a third driving assembly 20, a toothed block 21, a connecting rod 22, a wedge plate 23, a guide rail 24, a horizontal plate 25, a printing plate 26, a second compression spring 27 and an arc plate 28, the lower portion of the right side surface of the rear support plate 4 is fixedly connected with the guide bar 11, the guide bar 11 is slidably provided with two guide sleeves 12, the second rack 13 is fixedly connected between the left side surfaces of the two guide sleeves 12, the first compression spring 14 is wound between the front side surface of the front guide sleeve 12 and the front end of the guide bar 11, the connecting rod 22 is fixedly connected to the bottom front side of the second rack 13, the right portion of the top front side of the bottom plate 1 is slidably provided with the wedge plate 23, the lower part of the front side of a wedge-shaped plate 23 is fixedly connected with the tail end of a connecting rod 22, the middle of the right side of the top of a bottom plate 1 is symmetrically and fixedly connected with a guide rail 24, the guide rail 24 is provided with a transverse plate 25 in a sliding way, the inner side surfaces of the transverse plates 25 at the left side and the right side are fixedly connected with a printing plate 26 matched with an opening plate 304 at intervals, an arc plate 28 matched with the wedge-shaped plate 23 is fixedly connected between the front sides of the bottom of the transverse plates 25 at the left side and the right side of the top of the bottom plate 1, the arc plate 28 is contacted with the inclined surface of the wedge-shaped plate 23, the middle of the bottom of the transverse plate 25 is connected with a second compression spring 27 between the middle of the bottom of the top of the bottom plate 1, the lower part of the right side of the front side of a front side supporting plate 4 is, the two second bevel gears 18 are meshed, the right end of the transmission shaft 16 is fixedly connected with a second gear 17, the second gear 17 is positioned above the second rack 13 and meshed with the second gear, a third driving component 20 is arranged between the front portions of the left and right side transmission rollers 301, six tooth blocks 21 are fixedly connected to a belt of the third driving component 20, and the tooth blocks 21 are matched with the third gear 19.

When the servo motor 303 is started, the driving roller 301 further drives the third driving component 20 to rotate forwardly, the third driving component 20 drives the tooth block 21 to rotate forwardly, when the tooth block 21 rotates forwardly and meshes with the third gear 19, the tooth block 21 drives the third gear 19 to rotate reversely, the third gear 19 rotates reversely and drives the rear-side second bevel gear 18 to rotate reversely, the rear-side second bevel gear 18 rotates reversely and drives the front-side second bevel gear 18 to rotate reversely, the front-side second bevel gear 18 rotates reversely and drives the transmission shaft 16 to rotate reversely, the transmission shaft 16 rotates reversely and drives the second gear 17 to rotate reversely and drives the second gear 17 to move backwards, the second gear 13 moves backwards and drives the guide sleeve 12 to move backwards, the first compression spring 14 stretches, the second gear 13 moves backwards and drives the wedge plate 23 to move backwards through the connecting rod 22, the wedge plate 23 moves backwards and drives the cambered plate 28 to move upwards, the cambered plate 28 moves upwards and drives the transverse plate 25 to move upwards, the second compression spring 27 is stretched, the transverse plate 25 moves upwards to drive the printing plate 26 to move upwards, the printing plate 26 moves upwards to penetrate through the opening plate 304 to be contacted with the flour dough, the printing plate 26 marks on the flour dough, when the tooth block 21 continues to rotate forwards and is separated from the third gear 19, the guide sleeve 12 moves forwards to drive the second rack 13 to move forwards under the action of the first compression spring 14, the second rack 13 moves forwards to drive the wedge-shaped plate 23 to move forwards through the connecting rod 22 to reset, and the transverse plate 25 drives the printing plate 26 to move downwards to reset under the action of the second compression spring 27, so that an operator can take down the flour dough and cut the flour dough into equal amount according to the marks. In this manner, the platen 26 is moved upward to mark the dough each time the dough drops onto the aperture plate 304. Therefore, the flour dough can be further marked in an equal amount so as to facilitate subsequent use.

Example 3

Referring to fig. 1, 3, 5 and 6, the present embodiment is different from embodiment 1 and embodiment 2 mainly in that the present embodiment further includes a vertical plate 29, a winding roller 30, a fourth gear 31, a lead frame 32, a pulling wire 33, a hollow frame 34, a third compression spring 35, a stopper 36 and a transfusion tube 37, the hollow frame 34 is fixedly connected to the front side of the lower portion of the outer right side surface of the placement frame 6, the upper portion of the left side of the hollow frame 34 is connected and communicated with the tail end of the oil inlet tube 9, the stopper 36 capable of blocking the inlet port of the oil inlet tube 9 is slidably arranged in the hollow frame 34, the third compression spring 35 is connected between the bottom of the stopper 36 and the inner bottom of the hollow frame 34, the transfusion tube 37 is connected to the middle of the top of the hollow frame 34, the transfusion tube 37 is communicated with the hollow frame 34, the vertical plate 29 is fixedly connected to the left portion of the front side of the top of the bottom plate 1, the lower portion of the rear side of the vertical plate 29 is rotatably connected with a fourth gear 31, the fourth gear 31 is matched with the tooth block 21, the front portion of the fourth gear 31 is connected with a winding roller 30, a pull wire 33 is wound on the winding roller 30, and the tail end of the pull wire 33 penetrates through two lead frames 32 and then penetrates through the middle of the bottom of the hollow frame 34 to be fixedly connected with the bottom of the stop block 36.

The cleaning device also comprises a guide frame 38 and an oil brushing roller 39, the guide frame 38 is fixedly connected to the left side and the right side of the top of the opening plate 304, and the oil brushing roller 39 is arranged between the guide frames 38 on the left side and the right side in a sliding mode.

Firstly, an operator connects vegetable oil to the infusion tube 37 externally, then discharges the vegetable oil into the infusion tube 37, discharges the vegetable oil in the infusion tube 37 into the hollow frame 34, when the tooth block 21 continues to rotate forwards and is meshed with the fourth gear 31, the tooth block 21 drives the fourth gear 31 to rotate backwards, the fourth gear 31 rotates backwards and drives the winding roller 30 to rotate backwards, the winding roller 30 rotates backwards and winds up the pull wire 33, the pull wire 33 winds up and drives the stop block 36 to move downwards, the third compression spring 35 compresses, the stop block 36 moves downwards and does not block a feed inlet of the oil inlet pipe 9, the vegetable oil in the hollow frame 34 is discharged into the oil inlet pipe 9 and is further sprayed into the quantitative hopper 702 through the check valve pipe 10, and the flour dough is prevented from being stuck on the quantitative hopper 702 and is difficult to drop. When the tooth block 21 is separated from the fourth gear 31, the stopper 36 moves upward to reset to block the feed inlet of the oil inlet pipe 9 due to the action of the third compression spring 35, the vegetable oil stops being sprayed, and the stopper 36 also drives the pull wire 33 to move upward, thereby driving the winding roller 30 to rotate forward and reset. So, need not operating personnel and control the blowout to vegetable oil, convenient and fast.

Firstly, an operator can paint a proper amount of vegetable oil on the oil brushing roller 39, then pulls the oil brushing roller 39 to move forwards, the oil brushing roller 39 moves forwards to paint the vegetable oil on the opening plate 304, when the oil brushing roller 39 moves forwards to the maximum stroke, the oil brushing roller 39 can be pulled to move backwards to reset, and then when the flour dough falls onto the opening plate 304, the flour dough is contacted with the vegetable oil. Thus, the flour dough can be prevented from being stuck on the opening plate 304 and being inconvenient to take down.

The above description is only for the specific embodiments of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art can easily conceive of the changes or substitutions within the technical scope of the present invention, and all the changes or substitutions should be covered within the scope of the present invention. Therefore, the protection scope of the present invention shall be subject to the protection scope of the claims.

Claims (6)

1. The utility model provides a flour dough equivalent segmentation auxiliary assembly which characterized in that, including:

the quantitative measuring device comprises a bottom plate (1), wherein mounting frames (2) are symmetrically and fixedly connected to one side of the bottom plate (1), at least two supporting plates (4) are arranged on one side of the mounting frame (2) far away from the bottom plate (1), and a quantitative frame (5) is arranged between one sides of the two supporting plates (4) far away from the bottom plate (1);

the placing frame (6), the placing frame (6) is installed on one side of the outer side of the quantitative frame (5) far away from the bottom plate (1), and the material pushing plate (8) capable of extruding the flour dough is placed in the placing frame (6) in a sliding mode;

the check valve pipe (10) is arranged on one side in the quantitative frame (5) facing the bottom plate (1), one end of the check valve pipe (10) penetrates through the quantitative frame (5), and the oil inlet pipe (9) is connected to the end part of the check valve pipe (10) located outside the quantitative frame (5) and communicated with the end part;

the conveying device (3) is arranged between the two mounting frames (2) and one side of the bottom plate (1) and is used for conveying equivalent flour dough;

and the quantitative discharging device (7) is arranged between the placing frame (6) and the quantitative frame (5), is fixedly connected with the conveying device (3) and the material pushing plate (8), and is used for dividing the flour dough into equal quantities.

2. An apparatus as claimed in claim 1, wherein the conveying means (3) comprises:

the transmission rollers (301) are symmetrically and rotatably connected between one sides of the two mounting frames (2) far away from the bottom plate (1), the conveying belt (302) is wound between the two transmission rollers (301), and one of the transmission rollers (301) is connected with the quantitative discharging device (7);

the servo motor (303), the said servo motor (303) is mounted to the edge position of one side of said bottom plate (1), its output shaft and said drive roller (301) end of the same side are fixedly connected;

an opening plate (304), said opening plate (304) being mounted between the inner sides of said two mounting frames (2), which cooperates with said conveyor belt (302) for the collection of the dough.

3. An apparatus as claimed in claim 2, wherein the means (7) for quantitatively discharging comprises:

the first fixing seat (705) is installed on one side of the outer side of the quantitative frame (5) far away from the oil inlet pipe (9), and a first driving assembly (706) is connected between one side of the first fixing seat (705) and the end part, close to the opening plate (304), of the driving roller (301) far away from the servo motor (303);

the rotating disc (707) is mounted at the shaft end part of the first driving assembly (706) far away from the first fixed seat (705), and the pushing rod (708) is mounted at the circle center position of one side of the rotating disc (707) far away from the first driving assembly (706);

the third fixing seat (7010) is installed on one side of the outer side of the placing frame (6) far away from the bottom plate (1) and the first driving assembly (706), and the rotating rod (7022) is rotatably connected to one part of the third fixing seat (7010) far away from the placing frame (6) in a penetrating mode;

a first gear (7012), the first gear (7012) being mounted to one end of the rotating bar (7022);

the pushing frame (7017) is installed on one side of the material pushing plate (8) far away from the bottom plate (1) and is L-shaped, the sliding rail (7013) is vertically installed on one side in the pushing frame (7017) facing the bottom plate (1), and the sliding strip (7014) is placed on the sliding rail (7013) in a sliding mode;

the ratchet bar (7015) is mounted on one side of the sliding bar (7014) far away from the sliding rail (7013), one side of the ratchet bar (7015) far away from the placing frame (6) is fixedly connected with a first rack (7016), and the first rack (7016) is meshed with the first gear (7012);

the ratchet (7018) is rotatably arranged on one side of a third fixed seat (7010) close to the sliding rail (7013) and is meshed with the ratchet bar (7015), and the torsion spring (7019) is connected to the joint of the ratchet (7018) and the third fixed seat (7010);

the limiting rod (7020) is mounted on one side of the third fixing seat (7010) close to the ratchet (7018) and is in contact fit with the ratchet (7018);

the second fixing seat (709) is arranged on one side of the outer side of the quantitative frame (5) on the same side with the first driving component (706), the rotating shaft (7021) is rotatably connected to one part of the second fixing seat (709) far away from the quantitative frame (5), and a second driving component (7011) is connected between the end part of the second fixing seat far away from the first driving component (706) and the end part of the rotating rod (7022) far away from the first gear (7012);

the driving shaft (701) is rotatably connected between the middle parts of the quantitative frames (5) in a penetrating mode, a three-groove frame (704) is fixedly connected to the end part, close to the rotating disc (707), of the driving shaft (701), and the three-groove frame (704) is matched with the pushing rod (708);

the number of the first bevel gears (703) is at least two, one of the first bevel gears (703) is arranged at one part of the driving shaft (701) close to the quantitative frame (5) and the rotating rod (7022), the other one of the first bevel gears is arranged at the end part of the rotating shaft (7021) facing the first driving component (706), and the two first bevel gears (703) are meshed;

a quantitative hopper (702), wherein the quantitative hopper (702) is arranged on the driving shaft (701) positioned in the quantitative frame (5) and is used for dividing the flour dough into equal amount.

4. An apparatus as defined in claim 3, further comprising:

the third driving assembly (20), the third driving assembly (20) is installed between one sides of the two driving rollers (301) close to the servo motor (303), the number of the tooth blocks (21) is at least six, and the tooth blocks are installed on a belt of the third driving assembly (20);

a third gear (19), wherein the third gear (19) is rotatably arranged at one side of the support plate (4) close to the third driving component (20) and far away from the servo motor (303) and is matched with the tooth block (21);

the bearing seat (15) is installed on one side of the supporting plate (4) close to the third gear (19), the transmission shaft (16) is rotatably connected into the bearing seat (15) in a penetrating mode, and the end, far away from the servo motor (303), of the transmission shaft is fixedly connected with a second gear (17);

the number of the second bevel gears (18) is at least two, one of the second bevel gears is arranged at the end of the transmission shaft (16) far away from the second bevel gear (17), the other one of the second bevel gears is arranged at the end of the third bevel gear (19) far away from the support plate (4), and the two second bevel gears (18) are meshed;

a guide bar (11), said guide bar (11) being mounted on said support plate (4) proximate to the first drive assembly (706) proximate to said third drive assembly (20);

the number of the guide sleeves (12) is at least two, the guide sleeves (12) are slidably sleeved on the guide strip (11), and the second rack (13) is arranged between one sides of the two guide sleeves (12) facing the servo motor (303) and meshed with the second gear (17);

the first compression spring (14) is sleeved on the guide strip (11), one end of the first compression spring (14) is fixedly connected with one side of the guide sleeve (12) far away from the first driving assembly (706), and the other end of the first compression spring is fixedly connected with the end part of the guide strip (11) far away from the first driving assembly (706);

the connecting rod (22), the connecting rod (22) is installed on one side of the second rack (13) far away from the second gear (17) and the transmission roller (301);

the wedge-shaped plate (23) is slidably placed on one side of the bottom plate (1) close to the opening plate (304) and the mounting frame (2), and one side of the wedge-shaped plate (23) is fixedly connected with the tail end of the connecting rod (22);

the number of the guide rails (24) is at least two, the guide rails (24) are symmetrically arranged in the middle of one side of the bottom plate (1) close to the wedge-shaped plate (23), the transverse plate (25) is placed on the inner side of the guide rails (24) in a sliding mode, and the second compression spring (27) is connected between one side of the transverse plate (25) facing the bottom plate (1) and one side of the bottom plate (1) facing the opening plate (304);

the number of the printing plates (26) is at least nine, the printing plates (26) are fixedly connected between the two lateral transverse plates (25) at intervals and are matched with the opening plate (304);

the cambered plate (28) is arranged between one sides of two transverse plates (25) close to the wedge-shaped plate (23) and towards the bottom plate (1), and the cambered plate (28) is in contact fit with the inclined surface of the wedge-shaped plate (23).

5. An apparatus as defined in claim 4, further comprising:

the hollow frame (34) is arranged on one side of the outside of the placing frame (6) close to the oil inlet pipe (9), one side of the hollow frame (34) is connected and communicated with the tail end of the oil inlet pipe (9), and the infusion tube (37) is connected to one side of the hollow frame (34) far away from the bottom plate (1) and communicated with the inside of the hollow frame (34);

the stopper (36) is slidably placed in the hollow frame (34) and used for stopping a feeding hole of the oil inlet pipe (9), and the third compression spring (35) is connected between one side of the stopper (36) facing the bottom plate (1) and the inner side of the hollow frame (34);

the vertical plate (29) is mounted on one side of the bottom plate (1) close to the servo motor (303), and two lead frames (32) are fixedly connected to one side of the vertical plate (29) facing the supporting plate (4);

a fourth gear (31), wherein the fourth gear (31) is rotatably connected to the side close to the bottom plate (1) and facing the mounting frame (2) and is matched with the tooth block (21);

the winding roller (30), winding roller (30) install in be close to fourth gear (31) one portion of riser (29), draw line (33) are around on winding roller (30), and its tail end passes through lead frame (32) rethread hollow frame (34) with dog (36) one side fixed connection towards bottom plate (1).

6. An apparatus as defined in claim 5, further comprising:

the guide frame (38) is symmetrically arranged on one side of the opening plate (304) far away from the bottom plate (1) and is parallel to the guide strip (11);

and the oil brushing roller (39) is placed between the two side guide frames (38) in a sliding manner.

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