CN111406767A

CN111406767A - Automatic dough cutting mechanism in bread making process

Info

Publication number: CN111406767A
Application number: CN202010393356.1A
Authority: CN
Inventors: 任义军
Original assignee: Dan Xiang Food Technology Co ltd
Current assignee: Dan Xiang Food Technology Co ltd
Priority date: 2020-05-11
Filing date: 2020-05-11
Publication date: 2020-07-14
Anticipated expiration: 2040-05-11
Also published as: CN111406767B

Abstract

The invention relates to the technical field of dough cutting, in particular to an automatic dough cutting mechanism in the bread making process, which comprises a cross bar, a rotating rod, blades, lifting devices, a control rod, vertical plates and a control pipe, wherein the rotating rod is distributed on one side of the cross bar in parallel, the rotating rod is fixedly connected with a plurality of uniformly distributed blades, the cross bar is connected with a plurality of uniformly distributed lifting devices, the blades and the lifting devices are alternately distributed, the control rod is distributed on one side of the rotating rod, which is far away from the cross bar, in parallel, the cross bar, the rotating rod and the control rod are arranged between the two vertical plates, and the control pipe is arranged on one side of the vertical plates. The problem of excessive deformation of massive dough is avoided, and the function is stable and strong.

Description

Automatic dough cutting mechanism in bread making process

Technical Field

The invention relates to the technical field of dough slicing, in particular to an automatic dough slicing mechanism in a bread making process.

Background

Ordinary dough processing stripping and slicing device among the prior art simple structure, the function is single, can not be fine satisfy the high quality cutting demand in the dough stripping and slicing, and high-accuracy cutting machine, the structure is complicated, and the maintenance is loaded down with trivial details difficult, and ordinary workshop uses such machine very uneconomic.

If the dough processing and cutting device can be invented, the dough processing and cutting device has stable and powerful functions, can solve the problem by realizing high-quality dough cutting work, and provides an automatic dough cutting mechanism in the bread making process.

Disclosure of Invention

The invention aims to provide an automatic dough slicing mechanism in a bread making process, so as to solve the problems in the background technology.

In order to achieve the purpose, the invention provides the following technical scheme: an automatic dough slicing mechanism in a bread making process comprises a cross rod, a rotating rod, blades, lifting devices, control rods, vertical plates and control tubes, wherein the rotating rod is distributed on one side of the cross rod in parallel, the rotating rod is fixedly connected with a plurality of uniformly distributed blades, the cross rod is connected with a plurality of uniformly distributed lifting devices, the blades and the lifting devices are alternately distributed, the control rods are distributed on one side of the rotating rod, which is far away from the cross rod, in parallel, the cross rod, the rotating rod and the control rods are arranged between the two vertical plates, the control tubes are arranged on one sides of the vertical plates, a pressure column is fixedly connected with one end of the rotating rod, the control tubes are in a U-shaped tube shape with one end being blocked, the control tubes are provided with control devices, one ends of the control devices extend to the outer parts of the control tubes, the pressure columns are in contact with the control devices, the lifting devices comprise thin rods, supporting plates and gears, the waist positions of, the one end fixedly connected with gear of pin, the other end of pin runs through the horizontal pole, the cylinder chamber has been seted up on the control lever, is provided with advancing device in the cylinder chamber of control lever, and gear and advancing device transmission are connected, and advancing device one end extends to the control lever outside, set up branch pipe chamber and main pipe chamber on the control lever, the mixed main pipe chamber in branch pipe chamber one end is connected, and the other end in branch pipe chamber is connected with the cylinder chamber bottom surface on the control lever, and main pipe chamber one end extends to in the control pipe chamber, controlling means includes flexible post, bellows one, sealing ring, sealed ball and ventilative board, the one end fixedly connected with flexible post of bellows one, the other end fixedly connected with sealing ring of bellows one, the one end of keeping away from bellows one on the sealing ring is provided with ventilative board, is provided with the sealed ball between ventilative.

Preferably, the propulsion device comprises a corrugated pipe, a control block, a sliding column and a corrugated pipe II, one end of the sliding column is fixedly connected with the corrugated pipe II, the other end of the sliding column is in contact with the corrugated pipe, one side of the sliding column is fixedly connected with the control block, the corrugated pipe, the sliding column and the corrugated pipe II are movably sleeved in a cylindrical cavity of the control rod, the control block penetrates through a sliding hole formed in the control rod, part of the control block extends to the outside of the control rod, and the control block is in meshed connection with the gear.

Preferably, the telescopic column is movably sleeved in an inner cavity of the control tube, one end of the telescopic column extends to the outside of the control tube, the telescopic column is in contact with the pressure column, a plurality of uniformly distributed convex sliding blocks are arranged on a fixing ring on the side wall of the telescopic column, and the convex sliding blocks on the telescopic column partially extend into sliding grooves formed in the inner wall of the control tube.

Preferably, the sealing ring is a cylinder and the cylinder is fixed on the inner wall of the control tube, the side wall of the sealing ring is annularly provided with a plurality of L-shaped tube cavities which are uniformly distributed, the middle part of the bottom surface of one side of the sealing ring is provided with a spherical groove, and the sealing ring is matched with the spherical groove and the sealing ball.

Preferably, the ventilating plate is a circular plate, a plurality of through holes are uniformly distributed in the plate body, the ventilating plate is fixed on the inner wall of the control tube, one end of the control rod extends into the inner cavity of the control tube, and one end of the main tube cavity is communicated with the control rod.

Preferably, one end of the second corrugated pipe is fixedly connected with the bottom surface of the cylindrical cavity of the control rod, the other end of the second corrugated pipe is fixedly connected with the bottom surface of the sliding column, one end of the branch pipe cavity is communicated with the second corrugated pipe, the control block is provided with a plurality of clamping grooves which are uniformly distributed, and the clamping grooves on the control block are meshed with the gears.

Compared with the prior art, the invention has the beneficial effects that:

1. the structure design of the invention realizes the purpose that a plurality of blades are matched with each other to cut the columnar dough and a plurality of supporting plates lift the dough, and realizes the effect of stably cutting the columnar dough;

2. the device realizes the stable control of air current through the communicating design of bellows one, control tube and control lever, through exerting pressure in bellows one position, can control the slip of a plurality of control blocks, and then control gear rotates, realizes the effective control to lifting device.

Drawings

FIG. 1 is a schematic structural view of the present invention;

FIG. 2 is a view showing a position distribution of the thin bar;

FIG. 3 is a schematic structural diagram of a control device;

fig. 4 is a schematic structural view of the propulsion device.

In the figure: the device comprises a cross rod 1, a rotating rod 2, a blade 3, a lifting device 4, a control rod 5, a vertical plate 6, a control pipe 7, a pressure column 8, a control device 9, a thin rod 10, a supporting plate 11, a gear 12, a propelling device 13, a telescopic column 15, a first corrugated pipe 16, a sealing ring 17, a sealing ball 18, a ventilating plate 19, a spring 20, a control block 21, a sliding column 22, a second corrugated pipe 23, a branch pipe cavity 24 and a main pipe cavity 25.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments obtained by those skilled in the art without creative efforts based on the technical solutions of the present invention belong to the protection scope of the present invention.

Referring to fig. 1 to 4, the present invention provides a technical solution: an automatic dough slicing mechanism in a bread making process comprises a cross rod 1, rotating rods 2, blades 3, lifting devices 4, control rods 5, vertical plates 6 and control tubes 7, wherein the rotating rods 2 are distributed on one side of the cross rod 1 in parallel, the rotating rods 2 are fixedly connected with the blades 3 which are uniformly distributed, the cross rod 1 is connected with the lifting devices 4 which are uniformly distributed, the blades 3 and the lifting devices 4 are alternately distributed, the control rods 5 are distributed on one side of the rotating rods 2, which is far away from the cross rod 1, in parallel, the cross rod 1, the rotating rods 2 and the control rods 5 are arranged between the two vertical plates 6, one side of each vertical plate 6 is provided with the control tube 7, one end of each rotating rod 2 is fixedly connected with a pressure column 8, the control tube 7 is in a U-shaped tube shape with one end being blocked, the control device 9 is arranged on each control tube 7, one end of the control device 9 extends to the outside of the control tube 7, the lifting device 4 comprises a thin rod 10, a supporting plate 11 and a gear 12, the waist position of the thin rod 10 is fixedly connected with the supporting plate 11, one end of the thin rod 10 is fixedly connected with the gear 12, the other end of the thin rod 10 penetrates through the cross rod 1, a cylindrical cavity is formed in the control rod 5, a propulsion device 13 is arranged in the cylindrical cavity of the control rod 5, the gear 12 is in transmission connection with the propulsion device 13, one end of the propulsion device 13 extends out of the control rod 5, a branch pipe cavity 24 and a main pipe cavity 25 are formed in the control rod 5, one end of the branch pipe cavity 24 is connected with the main pipe cavity 25 in a mixing mode, the other end of the branch pipe cavity 24 is connected with the bottom surface of the cylindrical cavity in the control rod 5, one end of the main pipe cavity 25 extends into the inner cavity of the control pipe 7, the control device 9 comprises a telescopic column 15, a first corrugated pipe 16, a sealing ring 17, a sealing ball 18 and, one end of the sealing ring 17 far away from the first bellows 16 is provided with a ventilation plate 19, a sealing ball 18 is arranged between the ventilation plate 19 and the sealing ring 17, refer to fig. 2, the bellows 20 penetrates through a through hole formed in the cross rod 1, a cylindrical clamping ring is fixedly sleeved on the bellows 20, the clamping ring is arranged in a disc cavity formed in the cross rod 1 in a matching manner, so that the cross rod 1 supports the thin rod 10, the thin rod 10 can rotate freely, the supporting plate 11 is arc-shaped plate-shaped, the rotating rod 2 is driven to rotate by a driving mechanism in the prior art, refer to fig. 1, the rotating rod 2 rotates anticlockwise to drive the blade 3, columnar dough is placed on the supporting plate 11, the columnar dough is supported by the supporting plates 11 and is cut off by the blades 3, the rotating rod 2 is driven to rotate reversely after cutting, and the blade 3 restores to the initial position.

The propelling device 13 comprises a corrugated pipe 20, a control block 21, a sliding column 22 and a corrugated pipe two 23, wherein one end of the sliding column 22 is fixedly connected with the corrugated pipe two 23, the other end of the sliding column 22 is contacted with the corrugated pipe 20, one side of the sliding column 22 is fixedly connected with the control block 21, the corrugated pipe 20, the sliding column 22 and the corrugated pipe two 23 are movably sleeved in a cylindrical cavity of the control rod 5, the control block 21 penetrates through a sliding hole formed in the control rod 5, part of the control block 21 extends to the outside of the control rod 5, and the control block 21 is in meshed connection with the gear 12.

Flexible post 15 activity cup joints in the inner chamber of control tube 7, and the one end of flexible post 15 extends to control tube 7 outside, and flexible post 15 and pressure column 8 contact are fixed the ring and are equipped with a plurality of evenly distributed's salient slider on the lateral wall of flexible post 15, and the salient slider part on the flexible post 15 extends to in the spout of seting up on the control tube 7 inner wall.

The sealing ring 17 is in a cylindrical shape, the cylinder body is fixed on the inner wall of the control tube 7, a plurality of L-shaped tube cavities which are uniformly distributed are annularly arranged on the side wall of the sealing ring 17, a spherical groove is formed in the middle of the bottom surface of one side of the sealing ring 17, and the sealing ring 17 is matched with the spherical groove and the sealing ball 18.

The shape of the air permeable plate 19 is a circular plate, a plurality of through holes which are uniformly distributed are formed in the plate body, the air permeable plate 19 is fixed on the inner wall of the control tube 7, one end of the control rod 5 extends into the inner cavity of the control tube 7, and one end of the main tube cavity 25 is communicated with the control rod 5.

One end of the second corrugated pipe 23 is fixedly connected with the bottom surface of the cylindrical cavity of the control rod 5, the other end of the second corrugated pipe 23 is fixedly connected with the bottom surface of the sliding column 22, one end of the branch pipe cavity 24 is communicated with the second corrugated pipe 23, a plurality of clamping grooves which are uniformly distributed are formed in the control block 21, and the clamping grooves in the control block 21 are meshed with the gear 12.

The working principle is that the rotating rod 2 rotates to drive the blade 3, the blade 3 cuts cylindrical dough, in the process, the rotating rod 2 drives the pressure column 8, the pressure column 8 rotates to press the telescopic column 15, the telescopic column 15 is pushed into the control tube 7 to press the first bellows 16 to deform and contract, gas in the first bellows 16 is squeezed out, the gas flows through the control tube 7 to the main tube cavity 25 and then diffuses through a plurality of branch tube cavities 24, the gas flows into the second bellows 23 to expand and deform the second bellows 23, the air pressure pushes up the sliding column 22, the sliding column 22 moves to drive the control block 21, further the gear 12 controls the gear 12 to rotate, the gear 12 drives the supporting plates 11 to rotate, the supporting plates 11 are matched with each other to transversely support the cylindrical dough, the dough is stably supported by the supporting plates 11 when the blade 3 rotates to cut the dough, the blade 3 rapidly penetrates through a gap between the two supporting plates 11 to achieve stable cutting, then the blade 3 rotates to recover to an initial position, the supporting plates 11 cannot directly complete reverse rotation, the supporting plates 11 can slowly rotate to a vertical state, the problem that the dough directly falls down to cause the problem that the gas flow of the air flow of the sealing ring 18 and the air flow which can only slowly recover the sealing ball, and the distance between the supporting plates 18 which causes the sealing ring 17 to cause the sealing of the sealing ball collection platform to slowly recover the sealing ring 17, and the sealing ring.

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

Claims

1. The utility model provides an automatic stripping and slicing machine of dough in bread process of making constructs, includes horizontal pole (1), bull stick (2), blade (3), lifting device (4), control lever (5), riser (6) and control tube (7), its characterized in that: the device is characterized in that rotating rods (2) are distributed on one side of a cross rod (1) in parallel, a plurality of blades (3) which are uniformly distributed are fixedly connected onto the rotating rods (2), a plurality of lifting devices (4) which are uniformly distributed are connected onto the cross rod (1), the blades (3) and the lifting devices (4) are alternately distributed, control rods (5) are distributed on one side of each rotating rod (2) far away from the cross rod (1) in parallel, the cross rod (1), the rotating rods (2) and the control rods (5) are arranged between two vertical plates (6), a control tube (7) is arranged on one side of each vertical plate (6), a pressure column (8) is fixedly connected onto the end part of one end of each rotating rod (2), the control tube (7) is in a U-shaped tube shape with one end blocked, a control device (9) is arranged on the control tube (7), one end of the control device (9) extends to the outside of the control tube (7), and the pressure column (, the lifting device (4) comprises a thin rod (10), a supporting plate (11) and a gear (12), the supporting plate (11) is fixedly connected to the waist position of the thin rod (10), the gear (12) is fixedly connected to one end of the thin rod (10), the other end of the thin rod (10) penetrates through the cross rod (1), a cylindrical cavity is formed in the control rod (5), a pushing device (13) is arranged in the cylindrical cavity of the control rod (5), the gear (12) is in transmission connection with the pushing device (13), one end of the pushing device (13) extends to the outside of the control rod (5), a branch pipe cavity (24) and a main pipe cavity (25) are formed in the control rod (5), one end of the branch pipe cavity (24) is connected with the main pipe cavity (25), the other end of the branch pipe cavity (24) is connected with the bottom surface of the cylindrical cavity on the control rod (5), one end of the main pipe cavity (25) extends into the inner cavity of the control, the control device (9) comprises a telescopic column (15), a first corrugated pipe (16), a sealing ring (17), a sealing ball (18) and a ventilation plate (19), wherein the telescopic column (15) is fixedly connected to one end of the first corrugated pipe (16), the sealing ring (17) is fixedly connected to the other end of the first corrugated pipe (16), the ventilation plate (19) is arranged at one end, far away from the first corrugated pipe (16), of the sealing ring (17), and the sealing ball (18) is arranged between the ventilation plate (19) and the sealing ring (17).

2. The automatic dough slicing mechanism for bread making process as claimed in claim 1, wherein: advancing device (13) are including bellows (20), control block (21), traveller (22) and bellows two (23), traveller (22) one end fixedly connected with bellows two (23), and the other end contact of traveller (22) has bellows (20), one side fixedly connected with control block (21) of traveller (22), bellows (20), traveller (22) and bellows two (23) activity cup joint in the cylinder chamber of control lever (5), and control block (21) run through the slide opening of seting up on control lever (5), and control block (21) part extends to control lever (5) outside, and control block (21) and gear (12) meshing are connected.

3. The automatic dough slicing mechanism for bread making process as claimed in claim 1, wherein: flexible post (15) activity cup joints in the inner chamber of control tube (7), and the one end of flexible post (15) extends to control tube (7) outside, and flexible post (15) and pressure column (8) contact, and solid fixed ring is equipped with a plurality of evenly distributed's protrusion slider on the lateral wall of flexible post (15), and the protrusion slider part on flexible post (15) extends to in the spout of seting up on control tube (7) inner wall.

4. The automatic dough slicing mechanism in the bread making process according to claim 1, characterized in that the sealing ring (17) is cylindrical and the barrel is fixed on the inner wall of the control tube (7), the side wall of the sealing ring (17) is annularly provided with a plurality of L-shaped tube cavities which are uniformly distributed, the middle part of the bottom surface of one side of the sealing ring (17) is provided with a spherical groove, and the sealing ring (17) is matched with the spherical groove and the sealing ball (18).

5. The automatic dough slicing mechanism for bread making process as claimed in claim 1, wherein: the ventilation plate (19) is in a circular plate shape, a plurality of through holes which are uniformly distributed are formed in the plate body, the ventilation plate (19) is fixed on the inner wall of the control tube (7), one end of the control rod (5) extends into the inner cavity of the control tube (7), and one end of the main tube cavity (25) is communicated with the control rod (5).

6. The automatic dough slicing mechanism for bread making process as claimed in claim 2, wherein: one end of the second corrugated pipe (23) is fixedly connected with the bottom surface of the cylindrical cavity of the control rod (5), the other end of the second corrugated pipe (23) is fixedly connected with the bottom surface of the sliding column (22), one end of the branch pipe cavity (24) is communicated with the second corrugated pipe (23), the control block (21) is provided with a plurality of clamping grooves which are uniformly distributed, and the clamping grooves on the control block (21) are meshed with the gear (12).