WO2013165073A1 - Dregs supply device for use in baking - Google Patents

Abstract

The dregs supply device for use in baking according to the present invention comprises: a dregs supply nozzle detachably coupled to a dregs supply pipe receiving dregs, and discharging the dregs to one side; and a fastening bracket detachably coupled to the dregs supply nozzle and mounted on a base block. The dregs supply device according to the present invention has the advantages of being able to: use a dregs supply pipe and various fixing brackets together due to the ability to replace only the dregs supply nozzle according to the type of rack; and adjust the height of the dregs supply nozzle within a certain range so as to minimize the falling distance of the dregs and prevent dregs-cutting means from interfering with the dregs or other elements during the transfer of racks.

Description

Bakery Sediment Feeder

The present invention relates to a baker's sediment feeder, and more particularly, to a baker's sediment feeder, which can be replaced with a sediment supply nozzle and is configured to stably supply sediment.

In general, the walnut pastry baking machine is installed on the main body of the dough supply unit for supplying the dough, the sediment supply unit for supplying the sediment and the additive supply unit for supplying additives such as walnut kernels. The dough supply unit is provided with a kneading container for storing the dough and the dough supply pipe for providing the dough, the sediment supply unit is provided with a sediment container for storing the sediment and a sediment supply tube for providing the sediment, the additive supply unit and the additive container for storing the additives; An additive supply pipe for providing an additive is provided. After attaching a plurality of molds on the line on which the dough supply pipe, the sediment supply pipe and the additive supply pipe are arranged, the dough, sediment and grains are quantitatively supplied by repeating the movement and stopping of the plurality of molds by using a moving means. When the mold is heated and heated by heating means, when it is properly cooked, the mold is placed on the take-out means and automatically pulled out to take out the ripe contents.Then, the mold is placed in the initial position and the contents are reloaded. A series of cycles are performed continuously and repeatedly.

In addition, the mold injecting the contents for firing the walnut cookies, the upper mold and the lower mold is covered so as to overlap each other up and down, one side is hinged, the handle on one side of the upper mold to easily open and close the upper mold Protrudes.

On the other hand, the dough is generally provided in a thin state so that the flow is easy to quantitatively supply to the mold, sediment is provided in a solid state with a very low fluidity, there is a difficulty in quantitative supply to the mold. In order to solve such a problem, a sediment cutting means of a baker that cuts the sediment discharged through a sediment supply pipe by a predetermined amount and supplies it to a mold has been proposed by the applicant of the present invention. At this time, the conventional bakery is configured to be replaced with a mold suitable for the type of bread to be manufactured so as to manufacture a variety of breads such as walnut cookies, maple bread, grass bread, dough supply unit and conventional bakery Regardless of the type, the end height of the sediment supply pipe for supplying the sediment is fixed, so that the dough supply pipe, sediment supply pipe, and additive supply pipe so that the various supply pipes do not interfere with the mold even when a high mold is mounted. It is located at a sufficiently high point.

In this way, if each supply pipe is installed high, when the dough is first supplied to the mold in a state where the mold is mounted with a low height and then sediment is supplied thereafter, the dough is splashed in all directions by the falling sediment, and the sediment is correctly positioned. There may be a problem that the supply is biased to one side without being seated in. Of course, if the sediment supply nozzle is replaced with a different type or the fixed height of the sediment supply nozzle is changed according to the type of the mold to be mounted, the position where the sediment is cut can be adjusted to the form, but the sediment supply nozzle is to be replaced or changed. If you do not have the disadvantage that you need to install a different component for fixing the sediment supply pipe. In addition, when the fixed height of the sediment supply pipe is changed, the sediment cutting means also needs to be changed, so there is a problem that subsequent work due to mold replacement becomes very complicated.

In addition, the sediment cutting means and the mold should be located very close to minimize the distance to drop after the sediment is cut.In this way, when the sediment cutting means and the mold are very close, the sediment cut by the sediment cutting means does not fall down. As it remains at the cutting position, there is a risk that the sediment cut during the transfer of the mold may interfere with the sediment cutting means.

The present invention has been proposed to solve the above problems, it is possible to replace only the sediment supply nozzle according to the type of mold, the mounting height of the sediment supply nozzle can be adjusted within a certain range, minimizing the dropping distance of the sediment It is also an object of the present invention to provide a sediment feeder which is configured such that the sediment cutting means does not interfere with sediment or other components during mold transfer.

Sediment supply apparatus according to the present invention for achieving the above object, the base block; A sediment supply nozzle coupled to the sediment supply pipe for providing sediment and detachable to discharge sediment to one side; The fastening bracket is coupled to the base block, the sediment supply nozzle is mounted in a removable structure.

The fastening bracket includes a fastening plate into which the sediment supply nozzle is inserted in a vertical direction, a fixing means for fixing the sediment supply nozzle to the fastening plate, and a fastening bar for coupling the fastening plate to the base block.

The sediment supply nozzle has a male screw thread formed on an outer circumferential surface thereof, and the fixing means is screwed to the male screw thread and applied to a pair of fastening nuts which are in close contact with the top and bottom surfaces of the fastening plate, respectively.

The sediment supply pipe is made of a flexible pipe that can be bent by the user's force.

It further comprises a cutting means for cutting the sediment discharged through the sediment supply nozzle.

The cutting means includes a first cutting frame having a first cutting wire arranged in a direction crossing the sediment supply direction in the longitudinal direction, and a second cutting wire arranged in a direction crossing the sediment supply direction in the longitudinal direction. And a second cutting mold, wherein the first cutting wire and the second cutting wire are in contact with or adjacent to each other below the sediment supply nozzle to cut the sediment discharged through the sediment supply nozzle. At least one of the second cutting machine is configured with a reciprocating structure.

The first cutting wire and the second cutting wire are arranged to be parallel to each other at the same height.

And elevating means for elevating the base block periodically.

The lifting means is configured to raise and lower the base block after the cutting means cuts the sediment discharged through the sediment supply nozzle and returns to the original state.

The elevating means maintains the base block in a raised state while the mold located below the sediment supply nozzle is transported laterally by a conveying rail.

And a driving means for driving the cutting means by the rotational force of the cutting drive shaft, wherein the lifting means is coupled to the lifting driving shaft for interlocking with the cutting driving shaft and the lifting driving shaft, and the base block according to a rotation angle. It includes an elevating cam for elevating.

The driving means is coupled to the driving drive shaft for rotation and rotating around the rotating shaft, and configured to maintain a state in which one side is in contact with the outer peripheral surface of the drive cam according to the rotation angle of the drive cam A rotating link to be rotated, a restoring member to apply an elastic force to the rotating link in a direction in which one side of the rotating link is in close contact with the outer circumferential surface of the driving cam, and the other side of the rotating link to rotate when the rotating link is rotated. And a reciprocating link for transporting the first cutting frame such that the first cutting wire is close to and away from the second cutting wire.

Three or more links are connected in series so as to be rotatable, and longitudinal interruptions are rotatably coupled to the base block, and both sides of the longitudinal direction are rotatably coupled to the first cutting frame and the second cutting frame. It further includes a connecting link for transferring the second cutting frame in the opposite direction when the transfer in one direction.

The inner side of the sediment supply nozzle is provided with a distribution bar across the sediment discharge flow path.

The sediment discharge flow path of the sediment supply nozzle is inclined to become narrower toward the end.

A step is formed at the end of the sediment discharge flow path of the sediment supply nozzle.

The sediment supply device according to the present invention can replace only the sediment supply nozzle according to the type of mold, so that the sediment supply pipe and various fixing brackets can be used in common, and the height of the sediment supply nozzle can be adjusted within a predetermined range. While minimizing the fall distance of the mold, the sediment cutting means can prevent the phenomenon of interference with the sediment or other components during mold transfer.

1 is a perspective view of a baker equipped with a sediment supply device according to the present invention.

2 and 3 are side and partial perspective views of the sediment supply apparatus according to the present invention.

Figure 4 is a perspective view of the cutting means included in the sediment supply apparatus according to the present invention.

5 and 6 are a side view and an exploded perspective view showing the mounting structure of the sediment supply nozzle included in the sediment supply apparatus according to the present invention.

7 to 9 is an operation state diagram of the sediment supply apparatus according to the present invention.

10 is a bottom perspective view of the sediment supply nozzle included in the sediment supply apparatus according to the present invention.

11 is a cross-sectional view of a second embodiment of a sediment supply nozzle included in the sediment supply apparatus according to the present invention.

Hereinafter, an embodiment of a sediment supply device according to the present invention with reference to the accompanying drawings will be described in detail.

1 is a perspective view of a baker equipped with a sediment supply device according to the present invention.

The sediment supply apparatus 10 according to the present invention is a device installed in a bakery that manufactures walnut cookies, racing bread, grass bread, etc., and is configured to inject sediment into the inner space of the mold 20 to be heated. At this time, the baking machine is provided with a transfer rail 30 for transferring the mold 20, a dough supply device 40 for supplying flour dough, and an additive supply device 50 for injecting additives other than sediment such as walnut kernels. do.

The sediment supply apparatus 10 forms a sediment container 100 for storing sediment and a sediment pressurizing means 200 for discharging the sediment stored in the sediment container 100 to the outside of the sediment container 100. 20) is provided with a sediment supply pipe 300 for providing to the side, the dough supply device 40 is a dough container 42 and the dough container for storing the dough and the dough dough stored in the dough container 42 to the mold 20 side It is provided with a dough supply pipe (not shown) for providing, the additive supply device 50 is an additive container for storing the additive and the additive for providing the additive stored in the additive container 52 to the mold 20 side A supply pipe 54 is provided. At this time, the mold 20, the conveying rail 30, the dough feeder 40, the additive feeder 50 is applied to the same as the conventional baking machine bar details will be omitted, and the sediment feeder below (10) will be mainly described.

2 and 3 are a side view and a partial perspective view of a sediment supply device 10 according to the present invention, Figure 4 is a perspective view of the cutting means 600 included in the sediment supply device 10 according to the present invention, Figure 5 6 is a side view and an exploded perspective view showing a mounting structure of the sediment supply nozzle 400 included in the sediment supply device 10 according to the present invention.

Sediment supply device 10 according to the present invention, sediment supply pipe 300 and sediment supply nozzle 400 for discharging the sediment to the mold 20 side, and sediment supply nozzle 400 fixed to the base block (B) Fastening bracket 500 for cutting, cutting means 600 for cutting the sediment discharged through the sediment supply nozzle 400 by a predetermined amount, driving means 700 for driving the cutting means 600, It comprises a lifting means 800 for lifting the base block (B).

The cutting means 600 is a component for equalizing the size and shape of the sediment supplied to the mold 20 by cutting the sediment discharged through the lower end of the sediment supply nozzle 400 in the horizontal direction, Figure 3 and As shown in FIG. 4, a first cutting mold having a first cutting wire 612 arranged in a direction in which the longitudinal direction intersects with the sediment supply direction (up and down in this embodiment) (horizontal direction in this embodiment). And a second cutting frame 620 having a second cutting wire 622 arranged in a direction in which the longitudinal direction intersects with the sediment supply direction. The sediment supply nozzle 400 is mounted to discharge the sediment S between the first cutting wire 612 and the second cutting wire 622 as shown in FIG. 5, and has a predetermined amount from the sediment supply nozzle 400. When the sediment S is discharged, the first cutting mold 610 and the second cutting mold 620 are transferred so that the first cutting wire 612 and the second cutting wire 622 are close to each other, so that the sediment supply nozzle ( The sediment S discharged downward from the 400 is cut by the first cutting wire 612 and the second cutting wire 622 to fall down.

In this case, the first cutting wire 612 and the second cutting wire 622 may be close until the contact with each other, it may be configured to only close until the distance between each other is less than the set value. In addition, in the present embodiment, the structure in which both the first cutting mold 610 and the second cutting mold 620 are transported, but if the sediment (S) can be cut only the first cutting wire 612 and the second Only one of the cutting wires 622 may be configured to be transferred. However, when only one of the first cutting wire 612 and the second cutting wire 622 is transferred, since the sediment (S) is pushed to one side during the cutting process, the supply position may be changed, as shown in the present embodiment As described above, it is preferable that both the first cutting wire 612 and the second cutting wire 622 are configured to be transferred.

In addition, the first cutting wire 612 and the second cutting wire 622 are parallel to each other at the same height so that the sediment (S) can be cut clean, that is, the cutting surface of the sediment (S) to form a single plane. Is preferably arranged to

Meanwhile, the driving means 700 for driving the cutting means 600 is a first extension bar included in the first cutting frame 610 (more specifically, the first cutting frame 610) by a rotation force provided from the outside. 614) and the second cutting mold 620 (more specifically, the second extension bar 624 included in the second cutting mold 620). That is, the cutting means 600 has a flat cam structure coupled to the cutting drive shaft 710 is rotated by the power supplied from the outside and the drive cam 720 is formed with a recess groove 722 on the outer peripheral surface, Rotating link 730 that can be rotated around the rotating shaft 732 mounted in the longitudinal interruption and rolling roller 734 provided on one side (lower side in this embodiment) rolls on the outer circumferential surface of the drive cam 720; And a restoring member 760 for applying an elastic force to the pivoting link 730 in a direction in which one side of the pivoting link 730 is in close contact with the outer circumferential surface of the driving cam 720 (clockwise in this embodiment), and the pivoting link. The first cutting wire 612 is coupled to the second cutting wire 622 when one side of the rotation link 730 is inserted into the recess groove 722 is coupled to the other side (upper side in the present embodiment) of the 730. It includes a reciprocating link 740 for transporting the first cutting mold 610 to be close.

In addition, the suspension is coupled to the base block B so that the second cutting frame 620 may be transferred in the opposite direction when the first cutting frame 610 is transferred in one direction, and both sides of the longitudinal direction of the first cutting frame 610 may be rotated. Connecting link hinged to the cutting frame 610 and the second cutting frame 620 to transfer the transfer force applied to the first cutting frame 610 in the opposite direction to the second cutting frame 620 ( 750 may be further included. In this case, when the connection link 750 has a single bar structure, the first cutting frame 610 and the second cutting frame 620 do not reciprocate in a horizontal direction and move up and down, the connection link 750. The three or more links are connected in series so as to be rotatable, but both sides of the length direction are preferably coupled to the first cutting frame 610 and the second cutting frame 620 in a rotatable structure. Operation of the cutting means 600 and the transfer means will be described in detail with reference to FIGS. 7 to 9.

On the other hand, the conventional sediment supply device is a sediment bucket, sediment supply pipe and sediment supply nozzle is integrally combined, it is configured to maintain a constant height of the sediment supply nozzle according to the type of bread to be manufactured. Therefore, when manufacturing different types of bread having a difference in height, there is a problem in that the replacement cost and time are very high because the entire sediment feeder must be replaced. In particular, when the sediment container is replaced, the sediment filled in the existing sediment container must be transferred to a new sediment container. In this way, the transfer of the sediment takes a lot of time, and in the process of transporting the sediment, dust or foreign matter There is a problem of being very unsanitary because it can be mixed in sediment. In addition, in order to be able to manufacture a variety of bread, there is a problem in that the total price of the bakery machine must be purchased because the sediment supply device for each bread type must be purchased.

The sediment supply device 10 according to the present invention is a sediment supply coupled to the discharge end of the sediment supply pipe 300 (an opposite end of the side connected to the sediment container 100) so as to solve the above problems. The nozzle 400 is fixed to the base block (B), the sediment supply nozzle 400 is characterized in that it comprises a fastening bracket 500 is mounted in a removable structure. When the sediment supply nozzle 400 for supplying the sediment to the mold 20 side is combined with the sediment supply pipe 300 and the fastening bracket 500 as described above, the mold 20 may be replaced with another standard. When only the sediment supply nozzle 400 is replaced and installed in the size that fits the replaced mold 20, and the sediment supply pipe 300 and the fastening bracket 500 can be used in common, the work process for replacing the mold 20 is very This has the advantage of simplicity.

For example, when the thickness of the bread to be manufactured is increased so that the height of the dough supplied to the mold 20 increases, the lower end of the sediment supply nozzle 400 should be adjusted upward so as not to contact the dough. If the thickness of the bread to be manufactured is low because the thickness of the dough to be supplied to the mold 20 is low, the lower end of the sediment supply nozzle 400 should be adjusted downward so as to be as close as possible to the dough. Accordingly, when the height of the mold 20 to be replaced is high, the sediment supply nozzle 400 having a short length is mounted, and when the height of the mold 20 to be replaced is low, the sediment supply nozzle 400 is long. , Other components except the sediment supply nozzle 400 of the sediment supply device 10 can be used in common.

In addition, even in the case where the thickness of the bread to be manufactured is the same or to increase or decrease the amount of sediment supplied, the sediment supply apparatus according to the present invention controls the sediment supply amount by replacing only the sediment supply nozzle 400. Since it can be used, there is an advantage that the use of the bread maker becomes very simple. In addition, although the sediment supply nozzle 400 is conventionally fixed directly on the mold 20, it has been difficult to clean the mold 20, but the sediment supply device 10 according to the present invention removes the sediment supply nozzle 400. By doing so, there is an advantage that the mold 20 can be more easily washed.

Meanwhile, the sediment supply nozzle 400 and the fastening bracket 500 may be combined in any structure as long as they are detachable, but the sediment supply nozzle 400 may be stably fixed in a state of being coupled to the fastening bracket 500. It is preferable to be configured to be. That is, the fastening bracket 500 includes a fastening plate 510 having a through hole 512 formed therein so that the sediment supply nozzle 400 can be penetrated in the up and down direction, and the interruption portion is positioned in the through hole 512. It may include a fixing means 520 for fixing the sediment supply nozzle 400 to the fastening plate 510, and a fastening bar 530 for coupling the fastening plate 510 to the base block (B). The fastening plate 510 is seated so as to span the pair of fastening bar 530, the coupling bolt 532 protruding upward from the upper surface of the fastening bar 530 is penetrated and fastened to the coupling bolt 532 It is fixedly coupled to the fastening bar 530 by a coupling nut 534.

At this time, the sediment supply nozzle 400 is a male thread 410 is formed on the outer circumferential surface, the fixing means 520 is a female thread threaded to the male thread 410 of the sediment supply nozzle 400 is formed on the inner peripheral surface fastening plate It may be applied to a pair of fastening nuts which are in close contact with the top and bottom surfaces of the 510, respectively. In this way, if a thread is formed on the outer circumferential surface of the sediment supply nozzle 400 and the fixing means 520 is applied with a pair of fastening nuts, the position where the sediment supply nozzle 400 is coupled to the fastening plate 510 is upward and downward. Since it can be adjusted with, there is an advantage that the portion where the sediment is cut can be adjusted more accurately. For example, when the sediment supply nozzle 400 is fastened to the fastening bracket 500, the lower end of the sediment supply nozzle 400 is the first cutting wire 612 due to the accumulation of manufacturing tolerances and assembly tolerances of the respective parts. And a lower point than the second cutting wire 622, in which case the first cutting wire 612 and the second cutting wire 622 may interfere with the sediment supply nozzle 400 to cut the sediment. There will be no. At this time, if the sediment supply nozzle 400 is configured to be coupled to the fastening plate 510 by a pair of fastening nuts as shown in the present embodiment, the sediment supply nozzles by rotating the pair of fastening nuts in one direction ( Since the coupling height of 400 may be adjusted, the first cutting wire 612 and the second cutting wire 622 may be prevented from interfering with the sediment supply nozzle 400. On the contrary, even when the sediment supply nozzle 400 is excessively coupled to the upper side, the coupling height of the sediment supply nozzle 400 can be appropriately lowered.

When the sediment supply nozzle 400 of various types, such as the sediment supply device 10 according to the present invention, is configured to be replaced, the sediment supply pipe 300 is coupled according to the type of the sediment supply nozzle 400 to be mounted. The position of the point (in this embodiment, the top of the sediment supply nozzle 400) can be changed. Therefore, the sediment supply pipe 300 is preferably made of a flexible pipe that can be bent by the user's force so that even if any sediment supply nozzle 400 is mounted, it can be connected to the sediment supply nozzle (400).

Hereinafter, an operation example of the sediment supply device 10 according to the present invention with reference to the accompanying drawings will be described in detail.

7 to 9 are operational state diagrams of the sediment supply device 10 according to the present invention.

In the state shown in FIG. 2, the cutting drive shaft 710 rotates in the clockwise direction so that the recessed roller 734 is positioned on one side (lower side in this embodiment) of the recessed groove 722. When facing the direction, as shown in Figure 7, the rolling roller 734 is introduced into the recess groove 722, the rotation link 730 is rotated in the clockwise direction, the other side of the rotation link 730 (this embodiment In the example, the reciprocating link 740 and the first cutting frame 610 connected to the upper side are transferred in the right direction, and the second cutting frame 620 connected to the first cutting frame 610 by the connecting link 750 is It is conveyed in a direction opposite to the first cutting mold 610, that is, the left direction.

As such, when the first cutting mold 610 is transferred in the right direction and the second cutting mold 620 is moved in the left direction, the first cutting wire 612 and the second cutting wire 622 are transported to be close to each other. The sediment discharged from the supply nozzle 400 is cut. At this time, the first cutting frame 610 and the second cutting frame 620 of the first cutting frame 610 and the second cutting frame 620 so that the reciprocating only in the horizontal direction without swinging up and down A guide member 770 may be provided to guide the conveying direction. The guide member 770 extends toward the pivot link 730 of the first cutting mold 610 and the second cutting mold 620, that is, the first extension bar 614 and the second extension bar 624. It includes a first guide member 772 and a second guide member 774 coupled to the base block (B) to be arranged in the longitudinal direction of (see Figure 3), the first extension bar 614 and the second extension bar By contacting the upper and lower surfaces of the 624 serves to prevent the vertical movement of the first extension bar 614 and the second extension bar 624. At this time, the first guide member 772 and the second guide member 774 are provided with a roller in a portion in contact with the first extension bar 614 and the second extension bar 624, the first extension bar 614 and the first It is preferred that the two extension bars 624 are configured to minimize the frictional forces generated when reciprocating. As described above, the guide member 770 for guiding the conveying direction of the member conveyed by the external force in any one direction is already applied to various structures in various fields, and a detailed description thereof will be omitted.

When the driving cam 720 is further rotated in the state shown in FIG. 7 and the rolling roller 734 of the pivoting link 730 is out of the recessed groove 722 as shown in FIG. 8, the pivoting link 730. Is rotated counterclockwise, so the reciprocating link 740 pushes the first cutting frame 610 to the left direction and the connecting bar pushes the second cutting frame 620 to the right direction, and the first cutting wire 612. The second cutting wires 622 are separated from each other, that is, return to the state shown in FIG. In this way, after cutting the sediment supplied through the sediment supply nozzle 400 to provide the mold 20, the transfer rail 30 transfers the mold 20 so that sediment may be provided to another mold 20. In the state in which the first cutting mold 610 and the second cutting mold 620 are very close to the mold 20 as in the present embodiment, the mold 20 is first in the process of transferring the mold 20. There is a fear that the cutting mold 610 or the second cutting mold 620 may be interfered with. In addition, even when the gap between the sediment provided to the mold 20 and the sediment supply nozzle 400 is very narrow, the sediment provided to the mold 20 during the transfer of the mold 20 interferes with the sediment supply nozzle 400 to sediment the sediment. There is a fear that the position of is out of the normal state.

Therefore, in the sediment supply device 10 according to the present invention, the sediment supply nozzle 400, the first cutting frame 610, the second cutting frame 620, etc., while the conveying rail 30 conveys the mold 20. It is configured to include a lifting means 800 for elevating the sediment supply nozzle 400, the first cutting mold 610 and the second cutting mold 620 so as to be spaced away from the mold 20.

The lifting means 800 is connected to the driving shaft 710 for cutting by a power transmission chain, etc., the driving shaft 810 for interlocking with the driving shaft 710 for cutting, and the driving shaft for lifting 810 and the outer peripheral surface It comprises a lifting cam 820 in contact with the bottom of the base block (B) to raise and lower the base block (B) according to the rotation angle.

At this time, when the lifting means 800 lifts the base frame while the cutting means 600 cuts the sediment, not only the sediment cutting may be normally performed, but the cut sediment falls to the mold 20. There is a fear that the position of the sediment will be out of the normal position due to the long distance. Accordingly, the elevating means 800 is the base block (B) after the cutting means (600) cuts the sediment discharged through the sediment supply nozzle 400 and returns to its original state, that is, after the state shown in FIG. To raise and lower.

When the driving cam 720 is further rotated in the state shown in FIG. 8 so that the long axis end of the elevating cam 820 contacts the bottom of the base block B, the base block B and the as shown in FIG. The sediment supply nozzle 400, the fastening bracket 500, the first cutting frame 610, and the second cutting frame 620 coupled thereto are raised. As shown in FIG. 9, the transfer rail 30 has a mold 20 while the sediment supply nozzle 400, the fastening bracket 500, the first cutting frame 610, and the second cutting frame 620 are raised. By transporting, it is possible to prevent the phenomenon that the mold 20 and the sediments contained therein interfere with other components. At this time, the shape of the lifting cam 820 is produced in various ways depending on the rise distance and the holding time of the sediment supply nozzle 400, the fastening bracket 500, the first cutting frame 610, the second cutting frame 620. Can be.

10 is a bottom perspective view of a sediment supply nozzle 400 included in the sediment supply apparatus 10 according to the present invention, and FIG. 11 is a sediment supply nozzle 400 included in the sediment supply apparatus 10 according to the present invention. It is sectional drawing of 2 Example.

Distribution bar 420 across the sediment discharge flow path inside the sediment supply nozzle 400 as shown in Figure 10 so that the sediment discharged through the sediment supply nozzle 400 is not discharged in large quantities at one time. It may be provided. When the distribution bar 420 is provided inside the sediment supply nozzle 400 as described above, since the sediment inside the sediment supply nozzle 400 is first contacted with the distribution bar 420 and then discharged to the outside, at a time It is possible to prevent the discharge of a large amount of sediment. In addition, when the distribution bar 420 is arranged radially around the vertical center axis of the sediment supply nozzle 400, there is an advantage that the sediment in the sediment supply nozzle 400 can be evenly distributed in each direction and discharged. In this embodiment, only the case where the distribution bar 420 is arranged in a '+' shape, but the arrangement of the distribution bar 420 may be variously changed.

On the other hand, sediment supply nozzle 400 included in the present invention, sediment supply nozzle 400 as shown in Figure 11 so as to more reliably prevent the phenomenon discharged as a large amount of sediment at once poured out The sediment discharge channel of the structure may be configured to be inclined so as to become narrower toward the end, that is, the sediment discharge channel may be configured to have a slope on the inside. When the sediment discharge passage of the sediment supply nozzle 400 is formed to be inclined to become narrow toward the end, the sediment inside the sediment supply nozzle 400 is compressed toward the discharge end to lower the fluidity, so that the sediment is discharged as if the sediment is poured. You can prevent it.

In addition, a step 430 may be further provided at the end of the sediment discharge flow path of the sediment supply nozzle 400. When the step 430 is formed at the end of the sediment discharge flow path, the sediment is caught by the step 430 at the direct point so that the sediment is discharged to the outside of the sediment supply nozzle 400 so that the phenomenon of discharge as the sediment is poured more effectively. do. The shape and size of the step 430 may be variously changed according to various conditions such as the characteristics of sediment and the amount of sediment supply.

As mentioned above, although this invention was demonstrated in detail using the preferable embodiment, the scope of the present invention is not limited to a specific embodiment, Comprising: It should be interpreted by the attached Claim. In addition, those skilled in the art should understand that many modifications and variations are possible without departing from the scope of the present invention.

The present invention can be used in confectionery equipment, baking equipment and the like.

Claims (16)

1. Baseblocks;

   A sediment supply nozzle coupled to the sediment supply pipe for providing sediment and detachable to discharge sediment to one side;

   A coupling bracket coupled to the base block and mounted in a structure in which the sediment supply nozzle is detachable;

   Sediment supply device comprising a.
2. The method of claim 1,

   The fastening bracket is,

   Sediment supply apparatus comprising a fastening plate into which the sediment supply nozzle is inserted in the vertical direction, a fixing means for fixing the sediment supply nozzle to the fastening plate, and a fastening bar for coupling the fastening plate to the base block. .
3. The method of claim 2,

   The sediment supply nozzle is formed with a male thread on the outer peripheral surface,

   The fixing means is a sediment supply device, characterized in that a pair of fastening nuts screwed to the male screw thread is in close contact with the top and bottom surfaces of the fastening plate, respectively.
4. The method of claim 1,

   The sediment supply pipe is a sediment supply device, characterized in that the flexible pipe that can be bent by the user's force.
5. The method of claim 1,

   Sediment supply device further comprises a cutting means for cutting the sediment discharged through the sediment supply nozzle.
6. The method of claim 5,

   The cutting means includes a first cutting frame having a first cutting wire arranged in a direction crossing the sediment supply direction in the longitudinal direction, and a second cutting wire arranged in a direction crossing the sediment supply direction in the longitudinal direction. And a second cutting mold, wherein the first cutting wire and the second cutting wire are in contact with or adjacent to each other below the sediment supply nozzle to cut the sediment discharged through the sediment supply nozzle. And sediment supply device characterized in that at least one of the second cutting machine is configured in a reciprocating structure.
7. The method of claim 6,

   The first cutting wire and the second cutting wire, sediment supply device, characterized in that arranged to be parallel to each other at the same height.
8. The method of claim 5,

   Sediment supply device further comprises a lifting means for periodically lifting the base block.
9. The method of claim 8,

   The lifting means is a sediment supply device, characterized in that the cutting means is configured to raise and lower the base block after cutting the sediment discharged through the sediment supply nozzle and returned to its original state.
10. The method of claim 9,

    The lifting means,

    Sediment supply device characterized in that to maintain the base block is raised while the mold located below the sediment supply nozzle is transported laterally by a transfer rail.
11. The method of claim 8,

    Further comprising a driving means for driving the cutting means by the rotational force of the drive shaft for cutting,

    The lifting means, sediment supply device comprising a lifting drive shaft for interlocking with the cutting drive shaft and the lifting cam coupled to the lifting drive shaft for lifting the base block according to the rotation angle.
12. The method of claim 11,

    The cutting means includes a first cutting frame having a first cutting wire arranged in a direction crossing the sediment supply direction in the longitudinal direction, and a second cutting wire arranged in a direction crossing the sediment supply direction in the longitudinal direction. Including a second cutting machine to make,

    The driving means is coupled to the driving drive shaft for rotation and rotating around the rotating shaft, and configured to maintain a state in which one side is in contact with the outer peripheral surface of the drive cam according to the rotation angle of the drive cam A rotating link to be rotated, a restoring member to apply an elastic force to the rotating link in a direction in which one side of the rotating link is in close contact with the outer circumferential surface of the driving cam, and the other side of the rotating link to rotate when the rotating link is rotated. Sediment supply device comprising a reciprocating link for transporting the first cutting wire so that the first cutting wire is closer to the second cutting wire and away.
13. The method of claim 12,

    The drive means,

    Three or more links are connected in series so as to be rotatable, and longitudinal interruptions are rotatably coupled to the base block, and both sides of the longitudinal direction are rotatably coupled to the first cutting frame and the second cutting frame. Sediment supply device further comprises a connecting link for transferring the second cutting machine in the opposite direction when the transfer in one direction.
14. The method according to any one of claims 1 to 13,

    Sediment supply device characterized in that the inner side of the sediment supply nozzle is provided with a distribution bar across the sediment discharge passage.
15. The method according to any one of claims 1 to 13,

    The sediment discharge channel of the sediment supply nozzle is formed inclined so as to be narrowed toward the end.
16. The method according to any one of claims 1 to 13,

    Sediment supply device, characterized in that the stepped end of the sediment discharge flow path of the sediment supply nozzle.

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