JPH0776048B2 - Bread confectionery dough storage device - Google Patents

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a device for adjusting a feeding interval of bread confectionery dough, and more specifically, it transfers bread confectionery dough discharged from a rounding machine and sequentially conveyed by conveyor means. The present invention relates to a technique for reliably storing one bucket in each bucket in synchronization with the movement of each bucket.

[0002]

2. Description of the Related Art As is well known, in the baking and confectionery process, there is a step of supplying the dough divided by a divider to a rounding machine and storing the dough rounded by the rounding machine in each tray of a proofer. Exists. For details of this process, after the dough is divided into a predetermined size by the divider and continuously fed to the rounding machine, the dough discharged from the rounding machine is conveyed by the conveyor, and the distribution blade is rotating. At the same time as storing the fabrics one by one in each of the fabric storage recesses (waterwheel-shaped), the fabrics previously stored in the distribution blades are sequentially dropped and stored one by one in the multiple feeder bucket during transfer. After that, when the feeder bucket containing the dough is further transferred to a predetermined position, a predetermined number of the dough is dropped from the feeder bucket onto the tray of the proofer and stored. On the other hand, the proofer is for fermenting the dough after shaping in an intermediate manner, and an overhead proofer that is one of the proofers is a so-called skein, but the processing capacity of this proofer is the processing of a dividing machine. Ideally, it is equal to ability. In other words, if the dividing machine divides, for example, 3600 doughs per hour, the proofer should ideally be able to process approximately 3600 doughs per hour. Also, other mechanical devices that further perform post-processes on the fabric discharged from the proofer can have a processing capacity of about 3600 pieces per hour, in other words, a dividing machine, a proofer,
It is possible to make all the processing capabilities of the other mechanical devices the same or substantially the same, and it is possible to improve the compatibility of these respective mechanical devices.

[0003]

However, since the shaping processing by the above-mentioned rounding machine is intended to automatically round the soft cloth, the processing operation and the required processing time are not uniform. Therefore, the time intervals of the doughs sequentially and continuously discharged from the rounding machine vary. If these discharged fabrics stick to each other due to stagnation, etc., they will be defective products called double balls, so the conveyors connected directly downstream of the rounding machine prevent the fabrics from stagnation. It is indispensable to be constantly driven as much as possible. Therefore, the dough continuously discharged from the rounding machine is conveyed with an irregular pitch. Nevertheless, the feeder bucket is transported at a constant speed that is set in advance to correspond to the throughput of the proofer, and the distribution blade is also rotating at a constant speed. When the dough is fed from the dough to the dispensing blade, two doughs drop simultaneously in one dough storage recess of the dispensing vane, causing so-called double balls, which is a defective product, or the dough of the dispensing vane. Not only the so-called tooth missing state is caused due to frequent emptying of the storage recess, but also the following problems are caused. That is, when the dough reaches the downstream end of the conveyor, the distribution vanes do not have to be in any rotation angle position. Must be able to properly receive the dough at the downstream end of the conveyor. If it is not in such a state, the cloth collides with the convex portion (blade portion) of the distribution blade and is deformed or scratched, which causes an increase in defective products. However, in the past, the distribution blade and the feeder bucket moved at a constant speed in spite of variations in the time interval pitch of the dough reaching the downstream end of the conveyor, so the above-mentioned problems frequently occur. However, in order to avoid this, the operator has to constantly watch the falling timing and pitch of the material at the downstream end of the conveyor and make appropriate corrections, which complicates the troublesome and complicated work. Further, as a result of a large amount of defective products as described above, the dough that has been divided into a predetermined number in the dividing machine is drastically reduced in number by passing through the rounding machine, the distribution blades, and the feeder bucket. This has caused a problem that the dough collection efficiency is extremely deteriorated. Furthermore, in the proofer,
Since it is necessary to move the tray in which the dough is arranged in a toothless state, the capacity of the proofer must be set larger than the capacity corresponding to the actual number of doughs, and that capacity is wasted. This leads to a decrease in economic efficiency and, for example, the processing capacity of the divider is 360
If the number is 0, the processing capacity of the proofer must be set to, for example, about 4000 pieces per unit time, and the processing capacity of the dividing machine, the proofer, and other mechanical devices in the subsequent process can be made uniform. However, the compatibility was deteriorated.

The present invention has been made in view of the above circumstances. Even when the dough is not regularly discharged from the rounding machine at a constant cycle, the dough is fed from the conveyor to the distribution blades or the feeder bucket. Optimally controls the linking operation between the feeding side and the receiving side to reduce the occurrence of defective products as much as possible, thereby improving the collection efficiency of the dough sent from the divider in the proofer. The technical problem is to make the processing capacity of the dividing machine, the proofer, and the mechanical device in the subsequent process uniform.

[0005]

DISCLOSURE OF THE INVENTION The device for distributing and storing bread confectionery dough according to the present invention, which has been made to achieve the above technical problems, has the following features. In other words, a product that conveys the pastry dough discharged from the rounding machine
And a plurality of material storage recesses formed on the outer periphery.
And is rotatably held around its central axis and
The raw confectionery dough sent from the conveyor means
Distribution blades temporarily stored in the ground storage recess, and the distribution blades
Bread confectionery dough dropped from the dough storage recess of
Bread cake with multiple buckets that store and transfer individual pieces
In the device for distributing and storing child dough, the conveyor means is used.
In addition to dividing into multiple pieces in the transport direction,
At least one component located downstream of the
With a control conveyor that can control the drive and stop of the beer means
Meanwhile, the rotation speed of the distribution blade and the multiple bucket
Of the distribution vane and the rotation speed of the distribution vane.
With a rotation angle sensor that detects the rotation angle position,
Distributor blade cloth based on the signal from the rotation angle sensor
It is determined whether the storage recess is at a predetermined position and this determination
Control the drive and stop of the control conveyor based on the result
It is provided with a control means. Control in this case
As a concrete measure, it rotates integrally with the distribution blade.
It has a rotating plate and a plurality of slits are formed on the rotating plate.
And distribute the number and forming angle position of these slits
Corresponds to the number of blade material storage recesses and formation angle position
Then, the photoelectric conversion is performed with the slit formation portion of the rotary plate sandwiched therebetween.
A switch is installed to control the signal from this photoelectric switch.
It is preferable to input to the means.

[0006]

According to the above means, the bread confectionery dough continuously discharged from the rounding machine is conveyed by the conveyor means. During this conveyance, the bread confectionery dough is sequentially transferred to the plurality of conveyor means. Go. Then, at the time when the dough is conveyed to a predetermined position on the downstream side of the dough conveyance route, one piece of bread confectionery is transferred onto the control conveyor.
When the first bread confectionery dough is waiting in the
The dough storage recess of one of the distribution blades is the bread confectionery dough of the above
Whether it is in a rotating position that can reliably receive
When it is determined that the rotation position is as requested
Then, the control means drives the control conveyor to drive the one pan.
Send out the confectionery dough. This makes this one bread candy
The dough is stored in the dough storing recess of one of the distribution blades,
After this, when the distribution vanes rotate by a predetermined angle
Then, is the dough of the first confectionery item a concave part of the dough storage?
, One of the multiple buckets in transit
It is dropped and stored. In this case, the rotation speed of the distribution blade
Since it is synchronized with the transfer speed of multiple buckets,
The buckets of the multiple buckets can be
The dough will surely be filled with the bread confectionery dough.

[0007]

In this case, as a means for detecting whether or not the rotation angle position of the distribution blade is at the required position, the distribution blade is a rotating plate having slits corresponding to a plurality of material storage concave portions of the distribution blade. If the photoelectric switch is arranged so as to be integrally rotated with the photoelectric switch, the control means can accurately control the control conveyor based on the signal from the photoelectric switch.

[0009]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of a bread and cake dough distributing and storing apparatus according to the present invention will be described below with reference to the drawings. First, the overall configuration of the device according to the present invention will be described with reference to FIGS. 2 and 3. The device 1 is a bread confectionery dough continuously fed from a divider (not shown) (hereinafter, simply referred to as dough). .) For rounding and shaping, the conveyor means 10 for receiving the material A discharged from the machine 2A and conveying it toward the downstream side, and the material A dropped from the downstream end of the conveyor means 10.
A proofer that sequentially stores the distribution blades 52 that are temporarily stored and the material A that drops from the distribution blades 52.
Feeder bucket 53 consisting of multiple buckets that transfer up to 60
... with 53. The conveyor means 10 is connected to the rounding machine 2A and is continuously driven at a constant speed. The first conveyor 11 has a long transportation distance, and the second conveyor 11 has a short transportation distance to transfer the dough from the downstream end of the first conveyor 11. Conveyor 12 and a third conveyor having a short transport distance on which the material is transferred from the downstream end of the second conveyor 12.
A conveyor 13; a fourth conveyor 14 arranged orthogonally to the third conveyor 13 to transfer the dough from its downstream end; and a distribution conveyor 15 to transfer the dough from the downstream end of the fourth conveyor 14. It is divided into 2nd, 3rd,
The fourth conveyors 12, 13, 14 are control conveyors that can be controlled to be driven and stopped. In addition, in this embodiment, as shown in the figure, in addition to the rounding machine 2A, other rounding machine
The rounding machine 2B is also equipped with the conveyor means 10 and the distribution blades 52 in the same manner as described above.

As shown in FIG. 1, the fourth conveyor 14 located on the most downstream side among the control conveyors is driven by a fourth drive motor 24 via a winding transmission member (timing belt, V-belt or chain, etc.) 26. The fourth conveyor 14 and the distribution blades 52 are configured to be driven and stopped by the control means 35 including a sequence control circuit and a microcomputer. The distribution conveyor 15 interposed between the two is constantly driven at a constant speed. The distribution blade 52,
52a having a plurality of material storage recesses 52a formed at predetermined angular intervals on the outer periphery thereof, and being driven to rotate at a constant speed in the arrow X direction around the rotary shaft 51, the distribution conveyor 15
The dough dropped from is temporarily stored in the dough storing recess 52a and then dropped into the feeder bucket 53. Further, a circular disc 56 with a slit serving as a rotary plate is integrally rotatably fixed to the rotary shaft 51 of the distribution blade 52, and the circular disc 56 with a slit is provided with a concave portion 52a for storing the dough of the distribution blade. 56a corresponding to 52a are formed, and the light projecting portion 57 is sandwiched by the circular plate 56 with slits.
A photoelectric switch consisting of a and the light receiving section 57b is installed. The signal from the light receiving section 57b is input to the control means 35. As shown in FIGS. 2 and 3, a large number of feeder buckets 53 are fixed to a chain (or belt) at equal intervals, and are arranged on both sides of the distribution blade 52 with a long distance. The chains are wound around the sprockets 54, 54 so that the feeder buckets 53 ... 53 are moved in the direction of arrow Y at a constant speed. And the distribution conveyor 15
The distribution blade 52 and the feeder bucket 53 are driven by a single distribution drive motor 55 in synchronization with each other (see FIG. 5). As shown in FIG. 1, a tension pulley 16 is provided at the upstream end of the distribution conveyor 15. The tension pulley 16 has a threaded rod 17
The position of the tension pulley 16 is variable by being held at the tip of the screw rod 17 and being screwed into the nut 18 attached to the base.

On the other hand, as shown in FIG. 4, the first conveyor 11, the second conveyor 12, and the third conveyor 13 have a first drive motor 21, a second drive motor 22, and a third drive motor mounted on a base. Each of them is independently driven by the drive motor 23, and these conveyors 11, 12 and 13 are arranged in series at the same height and in a straight line. And
In this embodiment, the length (conveyance distance) of the first conveyor 11 is about 1000 mm or more,
Length of second conveyor 12 and third conveyor 13 (conveyance distance)
Is about 100 to 300 mm (preferably 180 mm)
~ 250 mm). In addition, each of the conveyors 11,1
The tension pulleys 24, 24 are held in an appropriate tension state by the tension pulleys 24, 24.
Are variable in position along the long holes 25 ... 25 formed in the base side member. The reference numerals 26 ... 26 denote the drive motors.
A winding transmission member for transmitting the rotations of 21, 22, and 23 to each of the conveyors 11, 12, and 13. Further, as shown in FIG. 5, at a predetermined position of the first conveyor 11, a first fabric detection sensor for detecting whether or not the fabric A conveyed in the arrow direction has passed.
31 is provided, and similarly, the second conveyor 12 and the third conveyor 13 are also provided with the second fabric detection sensor 32 and the third fabric detection sensor 33. These sensors 31, 32, 33 are photoelectric sensors in this embodiment, but it is also possible to use mechanical sensors such as limit switches that detect the fabric weight, or other non-contact sensors. . Then, the signals from the first, second and third fabric detection sensors 31, 32 and 33 are input to the control means 35, and from the control means 35, the second and third drive motors 22, A control signal for controlling the driving and stopping of the signal is output to 23. Incidentally, the fourth conveyor
For 14 as well, a fourth fabric detection sensor 34 may be provided in the same manner as described above to detect the presence or absence of the fabric A on the fourth conveyor 14, but in this embodiment, as will be described below. All the other sensors can be controlled, and they are not provided because of the reduction in the number of parts.

Next, the operation of the above embodiment will be described. The dough A discharged from the rounding machine 2A is conveyed by the first, second and third conveyors 11, 12 and 13 to the fourth conveyor 14,
The fourth conveyor 14 is a photoelectric switch light receiving unit shown in FIG.
Until the ON signal is input to the control means 35 from 57b, it is in a stopped state. That is, the time T until the dough A passes from the fourth conveyor 14 on the distribution conveyor 15 to reach the distribution blades 52 is calculated in advance and the distribution blades are
The rotation speed R of 52 is also fixed, and the disk with slit
The number and forming locations of the slits 56a in 56 correspond to the number and forming locations of the dough storage recesses 52a in the distribution blade 52. Since the relative mounting angle position of the slitted disc 56 with respect to the distribution blade 52 is set in consideration of the time T and the rotation speed R, control is performed by issuing an ON signal from the photoelectric switch light receiving unit 57b. Means 35
When a drive signal is output from the fourth drive motor 24 to drive the fourth conveyor 14 to send out the dough A, the dough A reaches the downstream end inclined surface 15x of the distribution conveyor 15 shown in FIG. At this point, the lower blade tip 52x of the dough storage recess 52a of the distribution blade 52 is positioned slightly below the downstream end inclined surface 15x of the distribution conveyor 15, or there is no step between the two. Become. Therefore, the cloth A is accurately and smoothly stored in the cloth storage recess 52a without colliding with the blade portion of the distribution blade 52.

In this way, after the dough A is dropped from the distribution conveyor 15 into the dough storage recesses 52a ... 52a of the distribution vanes 52 in sequence and temporarily stored, the dough A is rotated every predetermined angle. A drops into the feeder bucket 53 one by one. In this case, since the transfer speed of the feeder bucket 53 and the rotation speed of the distribution blade 52 are surely synchronized with each other, the dough A dropping from the distribution blade 52 one after another is surely transferred to each moving feeder bucket 53. Is stored in. Also, FIG.
As shown in, the dough A is fed not only from the one rounding machine 2A but also from the other rounding machine 2B in the same manner as the feeder bucket 53 ... 53.
Due to the fact that the material A falls from one of the rounding machines 2B to the alternate feeder bucket 53, the other doughing machine 2B
From 2A, place the dough A in every other feeder bucket 53
Is configured to fall.

The feeder buckets 53 ... 53 in which the dough A is stored as described above are fed to the step of performing intermediate fermentation (so-called step of soaking) as follows. That is,
As shown in FIG. 2, in a proofer (overhead proofer) 60 that performs intermediate fermentation, a tray (tray bucket) 61 having a predetermined number of dough storage sections 61a ... 61a.
Are moving in a predetermined cycle in the direction of arrow Z, and the distribution blade 5
When the feeder buckets 53 ... 53 moving in the Y direction while sequentially storing the materials dropped from 2,52 reach the side of the tray 61 which is on standby with a predetermined number of materials stored, When a predetermined number of feeder buckets 53 ... 53 rotate 90 degrees (see Fig. 3), a predetermined number of dough is discharged and dropped from these feeder buckets 53 ... 53 all at once, and the dough chutes 62 ... 61 each dough storage section 61a
… Stored in 61a. And after this, the tray 61 shows the arrow Z.
By moving in the direction and circulating in the proofer 60, intermediate fermentation is performed. Further, the dough that has undergone the intermediate fermentation is sequentially fed to another mechanical device for performing a post-process. In this case, the processing capacity of the proofer 60, that is, the number of fabrics discharged from the proofer 60 per unit time and the processing capacity of other mechanical devices for the subsequent process are the same or substantially the same (within the allowable error range). Has been done.

By the way, the dough A continuously discharged from the rounding machine 2A is adjusted in the upstream portion of the conveyor means 10 so that the interval between the doughs is constant. This adjusting operation is as follows. To be executed. In the initial stage, the first conveyor 11 and the distribution conveyor 15 are continuously driven at a constant speed, and the second conveyor 12 and the third conveyor 13 are also driven at the same speed as the first conveyor 11. , Only the fourth conveyor 14 is stopped. As shown in FIG. 5, the fabric A discharged from the rounding machine 2A
Is first continuously conveyed by the first conveyor 11,
If the pitch between the doughs A at this time is the required value and is uniform, the first dough A is transferred from the first conveyor 11 to the second and third conveyors 12 and 13 without stopping in sequence. To the fourth conveyor 14 and the rotation angle position of the distribution blade 52 is an appropriate position, the photoelectric switch light receiving unit
When the ON signal is output from 57b to the control means 35, the fourth conveyor 14 is driven to distribute the material A to the distribution conveyor 15
Send to. The second and subsequent fabrics A ... A are also sequentially sent to the distribution conveyor 15.

On the other hand, when the pitch between the cloths A becomes short, the second cloth A reaches the third conveyor 13 while the first cloth A is waiting on the fourth conveyor 14. However, in this case, although the ON signal from the photoelectric switch light receiving portion 57b has not been input to the control means 35, the third cloth detection sensor 33 outputs a signal indicating the presence of the cloth A to the control means 35. As a result, the control means 35 stops the third drive motor 23 and the third conveyor
Wait for the second dough A on 13. Then, when the ON signal is issued from the photoelectric switch light receiving portion 57b, the control means 35 drives the fourth conveyor 14 for a predetermined time to send the first dough A to the distribution conveyor 15, and thereafter. 4 Conveyor 14 is stopped and further control means 35
Is the third signal after a predetermined time has elapsed since the ON signal was issued.
Drives the second dough A to the fourth conveyor by driving the conveyor 13.
Transfer to 14. The operation immediately after this will be described in detail. When the second dough A is delivered from the third conveyor 13 as described above, a signal indicating the absence of the dough A from the third dough detection sensor 33 is sent to the control means. 35, and the control means 35 receives this signal for a predetermined time (the fabric A is completely
(Time required to transfer to the conveyor 14) is determined by a timer or the like, and the result of this determination indicates that a predetermined time has elapsed, and the photoelectric switch light receiving unit 57b
Only when the ON signal is issued from the 4th conveyor 14
Is driven to feed the dough A to the distribution conveyor 15.

When the short pitch between the fabrics A continues to occur, when the second fabric A is waiting on the third conveyor 13, the third fabric A is the second fabric A.
Although it reaches the conveyor 12, in this case, even though the third fabric detection sensor 33 outputs a signal indicating the presence of the fabric A to the control means 35, the second fabric detection sensor 32 outputs the signal. Also outputs a signal indicating the presence of the cloth A to the control means 35, and as a result, the control means 35 stops the second drive motor 22 and the third cloth A on the second conveyor 12.
To wait. Then, after that, the third conveyor 13 is driven and a signal indicating the absence of the cloth A is output from the third cloth detection sensor 33 to the control means 35, whereby the control means 35.
Drives the second conveyor 12 to transfer the third fabric A to the driving third conveyor 13. Further, if the pitch between the fabrics A is still short, the fourth fabric A is downstream of the first conveyor 11 when the third fabric A is waiting on the second conveyor 12. In this case, the second fabric detection sensor 32 is reached.
The signal from the first fabric detection sensor 31 also indicates the presence of the fabric A, although the signal from indicates the presence of the fabric A, and as a result, the control means 35 issues an alarm or the like.
Therefore, when the worker hears this warning, the fourth cloth A is removed, so that the cloth A can be conveyed smoothly thereafter. The control means 35 also issues an alarm or the like when it detects that the two fabrics A, A are conveyed at an abnormally short pitch based on the signal from the first fabric detection sensor 11. Therefore, in this case as well, the operator can remove the material A that interferes with the operation, so that the material A can be carried smoothly thereafter.

On the other hand, as described above, the second and third conveyors 1
If the pitch between the fabrics A becomes longer than the above after the fabric A is kept waiting on the second and third fabrics 13, the second fabric A is transferred from the third conveyor 13 to the fourth conveyor 14. Is transferred and the third material A is transferred from the second conveyor 12 to the third conveyor 13, the fourth material A is not transferred from the first conveyor 11 to the second conveyor 12 immediately, and the third material A is transferred. Dough A from the third conveyor 13 to the fourth conveyor 14
The fourth dough A is sent to the first conveyor 11
When the dough A does not wait on the second conveyor 12 when the dough A comes to be delivered to the second conveyor 12, and when the pitch between the doughs A continues to be long, the first The material A that has reached the third conveyor 13 from the conveyor 11 through the second conveyor 12 is transferred to the fourth conveyor 14 without waiting, and the second conveyor 12 and the third conveyor 13
The dough A does not wait on the conveyor 13. Therefore, if the variation in the pitch between the cloths A is within the allowable range, the two cloths A and A do not overlap with each other from the fourth conveyor 14 to the distribution conveyor 15 and the tooth is in a missing state. The dough A is always sent out continuously at a constant cycle.

In the above embodiment, the second, third and fourth conveyors 12, 13, 14 are used as control conveyors in order to exert a great effect on the operation for keeping the conveyance interval pitch of the cloth A constant. It uses three conveyors of
The number of control conveyors is not particularly limited, and it is possible to further increase the effect of the pitch adjusting action by setting, for example, three or more. Is something you can do. Further, the distribution conveyor 15 in the above embodiment
Is not an indispensable constituent element, and the distribution conveyor 15 is abolished and the cloth A is directly fed from the fourth conveyor 14 to the distribution blades 52.
It is also possible to drop. Further, the above embodiment is
In order to make the space compact, the dough transport path from the rounding machine to the distribution blades is bent in the middle, but without doing this, the dough transport path should be straight or have a gentle slope. You may

[0020]

As described above, according to the apparatus for distributing and storing bread dough according to the present invention, the conveyor means for carrying the dough discharged from the rounding machine is a control conveyor capable of controlling its driving and stopping. , Drive and stop of this control conveyor, rotation of distribution vanes that rotate in synchronization with multiple buckets
Since the dough is controlled according to the angular position , the dough delivered from the downstream end of the conveyor means is accurately received, and the dough falls or is distributed in the gap between the multiple buckets. Problems such as collision with the blades of the blades are avoided, occurrence of defective products and the occurrence of missing teeth are reduced as much as possible, and the recovery efficiency of the dough processed by the divider in the proofer is improved. Not only this, it becomes possible to equalize the processing capacities of the dividing machine, the proofer, and the other mechanical devices in the post-process, and it is possible to improve the interchangeability of these machines.

[Brief description of drawings]

FIG. 1 is a side view of a main part showing a relationship among a control conveyor, distribution blades, and multiple buckets, which is a main part of the present invention.

FIG. 2 is a plan view showing the overall configuration of the present invention.

FIG. 3 is a front view showing the overall configuration of the present invention.

FIG. 4 is a schematic side view showing the configuration of a part of the conveyor means according to the present invention.

FIG. 5 is a schematic configuration diagram showing a control system according to the present invention.

[Explanation of symbols]

 1 Distributor storage device 2A Rounding machine 2B Rounding machine 11 Conveyor means (1st conveyor) 12 Control conveyor (2nd conveyor) 13 Control conveyor (3rd conveyor) 14 Control conveyor (4th conveyor) 35 Control means 52 Distributor blade 52a Dough Storage recess 53 Multiple bucket (feeder bucket) 56 Rotating plate 56a Slit 57a Photoelectric switch (light emitting part) 57b Photoelectric switch (light receiving part)

 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Tatsumi Hasegawa 2-747 Kashima, Yodogawa-ku, Osaka City, Osaka Prefecture, Fujisawa Co., Ltd. (56) References: Kaihei 3-89015 (JP, U) 54-12873 (JP, Y2)

Claims (2)

[Claims] 1. A bread confectionery dough discharged from a rounding machine
Conveyor means for carrying and a plurality of raw materials formed on the outer periphery.
Has a ground storage recess and is rotatable about its central axis
Confectionery held and conveyed from said conveyor means
A distribution vane for temporarily storing similar material in the material storage recess,
Bread confectionery dropped and delivered from the dough storage recess of the distribution blade
Has a multiple bucket that stores and transfers similar materials one by one
In the device for distributing and storing bread confectionery dough, when the conveyor means is divided into a plurality in the carrying direction.
Both are located downstream of the plurality of conveyor means
Controllable driving and stopping of at least one conveyor means
Rotation of the distribution vane while it is composed of an efficient control conveyor
The speed and the transfer speed of the multiple buckets are synchronized, and
A rotation angle sensor for detecting the rotation angle position of the distribution blade.
And a sensor based on the signal from the rotation angle sensor.
Based on whether or not the material storage recess of the distribution blade is in the specified position.
And the control conveyor based on this determination result.
A control means for controlling the driving and stopping of the
Distributing and storing device for bread dough. 2. A rotary plate that rotates integrally with the distribution blade is provided.
And a plurality of slits are formed on the rotary plate.
The number of slits and the forming angle position
Rotate according to the number of storage recesses and the formation angle position.
Optoelectronic switches are placed across the slit formation point on the plate.
And input the signal from this photoelectric switch to the control means.
The bread confectionery according to claim 1, characterized in that
Distributing and storing device for baby material.