KR102574688B1 - Pizza dough making system - Google Patents

Abstract

The present invention relates to a pizza dough manufacturing system implemented so that the entire manufacturing process of pizza dough can be implemented using one system, comprising: a dough manufacturing unit for preparing dough by stirring while adding water to raw materials for manufacturing pizza dough; A transfer unit for measuring and transferring the dough prepared in the dough production unit in a certain amount; a forming roller unit that receives the dough transferred through the transfer unit and shapes it into a pizza dough; and a packaging unit individually packaging the pizza dough formed by the forming roller unit.

Description

Pizza dough manufacturing system {PIZZA DOUGH MAKING SYSTEM}

The present invention relates to a pizza dough manufacturing system, and more particularly, to a pizza dough manufacturing system implemented so that the entire manufacturing process of pizza dough can be implemented using one system.

Pizza dough refers to flour dough, which is a raw material for making pizza, and as patent documents related to a method for manufacturing such pizza dough, the documents presented below may be presented as examples.

Conventionally, in order to manufacture pizza dough, it was necessary to divide the dough raw material, which is a dough containing yeast, into a spherical shape by rolling it round) with a scraper, a knife blade, etc. Since physical damage occurs to raw dough materials, intermediate fermentation is required to restore such physical damage, and accordingly, the divided dough raw material lumps have to be rounded to form spheres, and then frozen and distributed.

On the other hand, the above-mentioned background art is technical information that the inventor possessed for derivation of the present invention or acquired in the process of derivation of the present invention, and cannot necessarily be said to be known art disclosed to the general public prior to filing the present invention. .

Korean Patent Publication No. 10-2021-0012117 Korean Patent Registration No. 10-1875003

One aspect of the present invention provides a pizza dough manufacturing system implemented so that the entire pizza dough manufacturing process, such as kneading, measuring, forming, and packaging, can be implemented using one system.

The technical problem of the present invention is not limited to the technical problem mentioned above, and other technical problems not mentioned will be clearly understood by those skilled in the art from the following description.

A pizza dough manufacturing system according to an embodiment of the present invention includes a dough making unit for preparing dough by stirring while adding water to raw materials for making pizza dough; A transfer unit for measuring and transferring the dough prepared in the dough production unit in a certain amount; a forming roller unit that receives the dough transferred through the transfer unit and shapes it into a pizza dough; and a packaging unit individually packaging the pizza dough formed by the forming roller unit.

In one embodiment, the shaping roller unit, the shaping main body is formed with a central through-hole in the central portion in the vertical direction; a rotation drive coupled to an upper portion of the molding body to generate rotational force; a rotational molding unit coupled to a lower side of the rotational driving unit to form pizza dough; A forming plate formed in a flat form so that the dough transported through the transfer unit can be seated; And a plate lifting unit installed below the forming plate to support the forming plate and elevating the forming plate so that the dough seated on the upper side of the forming plate can come into contact with the rotational forming unit. can

In one embodiment, the plate elevating unit is formed in the form of a square flat plate to form a through hole in the vertical direction at each corner and is installed on the lower side of the molding plate support plate; a support case formed in a cylindrical shape with a closed lower side and installed on each lower side of each through-hole of the support plate; a plate support elastic part installed for each support case and on which the molding plate is seated on an upper side exposed to an upper side of the support case; a flat plate support having an upper side coupled to the lower surface of the support plate and a lower side coupled to the molding body, a rack gear formed in the vertical direction, and capable of extending and contracting in the vertical direction; And a pinion gear engaged with the rack gear is coupled to one side and a handle is provided to the other side, so that when the handle is lowered downward with the pinion gear as a rotation center, the flat plate support rises and when raised upward, the flat plate support is lowered. An elevating lever; may be included.

In one embodiment, the plate support elastic portion is formed in the form of a square flat plate to support the lower side of the molding plate first support plate; A first side bending frame that is bent downward from one side of the first support plate, one side surface forming a vertical surface, and the other side surface forming a first upper inclined surface such that the other side surface is inclined in one direction from the upper side to the lower side; It forms a symmetrical structure in the left and right directions with the first side bending frame, and is bent downward from the other side of the first support plate, and the other side surface forms a vertical surface, and as one side goes from the upper side to the lower side, the other side is different. A second side bending frame forming a second upper inclined surface to be inclined in one direction; a second support plate formed in a square flat plate shape, spaced downward from the first support plate, and seated on an inner bottom surface of the support case; The upper part is connected to the lower side of the first support plate to slide in the left and right directions, and the lower part is connected to the upper side of the second support plate to slide in the left and right directions, so that the first support plate and the second support plate are connected to each other. It is supported between the support plates, and a first lower inclined surface is formed such that one side is inclined in the other direction so as to face the first upper inclined surface from the lower side to the upper side, and the first lower inclined surface is formed between the first supporting plate and the second supporting plate. a first side support frame in which the first lower inclined surface is pushed and moved in another direction by the first upper inclined surface as the distance decreases; And forming a symmetrical structure in the left and right direction with the first side support frame, the upper part is connected to the lower side of the first support plate to slide in the left and right directions, and the lower part is installed on the upper side of the second support plate in the left and right direction The second lower inclined surface is installed to be slidably connected to support between the first supporting plate and the second supporting plate, and the other side is inclined in one direction so as to face the second upper inclined surface from the lower side to the upper side. And a second side support frame in which the second lower inclined surface is pushed and moved in one direction by the second upper inclined surface as the distance between the first supporting plate and the second supporting plate decreases. can

In one embodiment, the first side support frame is connected to an upper sliding groove extending in the left and right directions along the upper side of the second support plate so that a lower portion can slide in the left and right directions, and is installed on one side of the first side support frame. 1 a support frame body on which a lower slope is formed; The upper side is bent in the other direction and connected to the lower sliding groove extending in the left and right directions along the lower side of the first support plate so as to be slid in the left and right directions, and the lower portion extending in the vertical direction is the support frame. An upper body support that is inserted and installed into an upper support groove formed on an upper portion of the body; at least one first spring installed along the lower side of the upper support groove to support the lower side of the upper body support; At least one second spring installed along the other side of the upper sliding groove to support the other lower side of the support frame body; at least one third spring installed along the other side of the lower sliding groove to support the other upper side of the upper body support; a first leg gear formed in a vertical direction along the first upper inclined surface; a second leg gear formed in a vertical direction along the first lower inclined surface; and interlockingly installed between the first leggear and the second leggear, and rotating along the first leggear and the second leggear as the first side-bending frame moves in the vertical direction, the support It may include; at least one gap support gear for moving the frame body in the forward and backward directions.

In one embodiment, the first side bending frame is formed by bending downward from one side of the first support plate, one side forming a vertical surface, and the other side forming the first leg gear. A bending frame body made of an upper inclined surface; a vertical support bar extending in a vertical direction, installed above the second support plate, and having an upper portion inserted into a lower support groove formed in a lower portion of the bending frame body; and a vertical buffer spring installed on the upper side of the lower support groove to support the upper side of the collection support bar.

In one embodiment, the gap support gear may include a gear body engaged and connected between the first leg gear and the second leg gear; A first sliding guide groove formed in a disk shape, rotatably connected to the front end of the gear body, and extending vertically along the first leg gear to prevent separation of the gear body, and the first a first guide wheel seated in a second sliding guide groove extending vertically along the second leg gear while facing the sliding guide groove; And formed in a disk shape and rotatably connected to the rear end of the gear body, spaced apart from the rear end from the first sliding guide groove to prevent separation of the gear body, and vertically along the first leg gear. A second guide wheel seated in a third sliding guide groove that extends and a fourth sliding guide groove that faces the third sliding guide groove and extends vertically along the second leg gear.

According to one aspect of the present invention described above, the entire process of manufacturing pizza dough, such as kneading, weighing, molding, and packaging, is implemented using one system, uniformity of pizza dough can be obtained, and labor costs can be reduced, resulting in a product It can provide the effect of increasing the price competitiveness of

Effects of the present invention are not limited to the effects mentioned above, and various effects may be included within a range apparent to those skilled in the art from the contents to be described below.

1 is a diagram showing a schematic configuration of a pizza dough manufacturing system according to an embodiment of the present invention.
FIG. 2 is a view showing a forming roller portion of FIG. 1 .
3 and 4 are views showing the plate lifting part of FIG. 2 .
FIG. 5 is a diagram explaining a method of supporting a molded plate by the plate elevating unit of FIG. 3 .
6 to 8 are views showing an embodiment of the plate supporting elastic part of FIG. 3 .

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The detailed description of the present invention which follows refers to the accompanying drawings which illustrate, by way of illustration, specific embodiments in which the present invention may be practiced. These embodiments are described in sufficient detail to enable one skilled in the art to practice the present invention. It should be understood that the various embodiments of the present invention are different from each other but are not necessarily mutually exclusive. For example, specific shapes, structures, and characteristics described herein may be implemented in another embodiment without departing from the spirit and scope of the invention in connection with one embodiment. Additionally, it should be understood that the location or arrangement of individual components within each disclosed embodiment may be changed without departing from the spirit and scope of the invention. Accordingly, the detailed description set forth below is not to be taken in a limiting sense, and the scope of the present invention, if properly described, is limited only by the appended claims, along with all equivalents as claimed by those claims. Like reference numbers in the drawings indicate the same or similar function throughout the various aspects.

Hereinafter, preferred embodiments of the present invention will be described in more detail with reference to the drawings.

1 is a diagram showing a schematic configuration of a pizza dough manufacturing system according to an embodiment of the present invention.

Referring to FIG. 1 , a pizza dough manufacturing system 10 according to an embodiment of the present invention includes a dough making unit 100, a conveying unit 200, a forming roller unit 300, and a packaging unit 400. .

The dough making unit 100 prepares the dough (P) by adding water to the raw material for making pizza dough and stirring it, and then transfers the stirred dough (P) to the conveying unit (200).

The transfer unit 200 measures the dough P prepared in the dough production unit 100 in a certain amount (eg, 100 g to 500 g, etc.), and then separates the weighed and separated dough lumps in turn, forming the roller unit 300. ) is transferred to

The forming roller unit 300 receives the dough P transported through the transfer unit 200, shapes it into a pizza dough shape, and delivers the formed pizza dough to the packaging unit 400.

The packaging unit 400 individually wraps the pizza dough formed by the forming roller unit 300 .

The pizza dough manufacturing system 10 according to an embodiment of the present invention having the configuration described above includes the dough making unit 100, the conveying unit 200, the forming roller unit 300, and the packaging unit 400, respectively. It may be provided with a conveyor system (not shown in the drawing for convenience of description) for conveying dough or the like between intervals, or a worker may manually deliver it.

The pizza dough manufacturing system 10 according to an embodiment of the present invention having the configuration described above implements the entire manufacturing process of pizza dough, such as kneading, measuring, molding, and packaging, by using one system, and pizza dough uniformity can be obtained, and labor costs can be reduced, which can provide an effect of increasing the price competitiveness of the product.

FIG. 2 is a view showing a forming roller portion of FIG. 1 .

Referring to FIG. 2 , the shaping roller unit 300 includes a shaping body 310 , a rotary driving unit 320 , a rotation shaping unit 330 , a shaping plate 340 and a plate lifting unit 350 .

In the molding body 310, a pedestal 311 having a circular through hole 312 in the center is formed in the central portion in the vertical direction, a rotation driving unit 320 and a rotational molding unit 330 are installed on the upper side, and the pedestal ( A molding plate 340 is installed in the lower space of 311).

The rotational drive unit 320 is engaged and connected to the top of the rotational molding unit 330 from the top of the molding body 310 to generate rotational force, and rotates the rotational molding unit 330 using the generated rotational force.

The rotational molding unit 330 is coupled to the lower side of the rotational driving unit 320 and molds pizza dough using the dough P exposed upward through the through hole 312 of the pedestal 311 .

In one embodiment, the rotational molding unit 330 includes a rotational plate 331 installed on the upper side of the molding body 310 and rotated by the driving force of the rotational drive unit 320, one lower side of the rotational plate 331 and the other side. A roller rotating unit 332 installed on one side, and formed in a triangular cone shape, connected to the front end of each roller rotating unit 332, and driven to rotate by the roller rotating unit 332, the dough seated on the molding plate 340 It may be made of a cone-shaped push rod 333 that spreads the dough (P) while rotating in close contact with (P).

The molding plate 340 is formed in a flat plate shape so that the dough P transferred through the transfer unit 200 can be seated, and is seated on the upper side of the plate lifting unit 350.

The plate lifting unit 350 is installed on the lower side of the forming plate 340 to support the forming plate 340, and the dough P seated on the upper side of the forming plate 340 is rotated in the forming unit 330. The forming plate 340 is moved up and down so that it can come into contact with it.

The forming roller unit 300 having the configuration as described above can form pizza dough using an automated pizza dough forming machine instead of human hands, and can shorten the time required for pizza dough forming work, Regardless of the skill level of the machine, it is always possible to mold pizza dough in a certain shape.

3 and 4 are views showing the plate lifting part of FIG. 2 .

3 and 4, the plate elevation part 350 includes a support plate 351, a support case 352, a support elastic part 353, a plate support 354, and an elevating lever 355. do.

The support plate 351 is formed in the shape of a square plate having through holes 3511 in the vertical direction so that the support elastic parts 353 can be inserted at each corner thereof, and is installed below the forming plate 340 .

The support case 352 is formed in a cylindrical shape with a closed lower side and is installed on each lower side of each through hole of the support plate 351 .

The plate support elastic part 353 is installed for each support case 352 , and the molding plate 340 is seated on the upper side exposed to the upper side of the support case 352 .

The plate support 354 has an upper side coupled to the lower surface of the support plate 351 and a lower side coupled to the molding body 310, and a rack gear (not shown in the drawing for convenience of description) is formed in the vertical direction, It is possible to expand and contract in the vertical direction according to the driving of the lowering lever 355 .

The elevating/lowering lever 355 has a pinion gear (not shown in the drawing for convenience of explanation) coupled to a rack gear on one side and a handle on the other side, and when the handle is lowered downward with the pinning gear as the center of rotation, the flat plate When the support 354 rises and is raised upward, the flat plate support 354 descends.

The plate elevating unit 350 having the configuration as described above can not only perform the vertical driving of the lifting or lowering of the forming plate 340 on which the dough P is seated, but also as shown in FIG. Corresponding to the degree of shaping of the dough P by the cone-shaped rolling pins 333-1 and 333-2, the forming plate 340 can be adjusted using elastic force, that is, when the thickness of the dough P is thick. As shown in (a) of FIG. 5, the forming plate 340 is pressed downward in correspondence with the thickness of the dough (P), but as the dough (P) is gradually spread, (b), ( As shown in c), as the molding plate 340 is gradually lifted by the elastic force of the plate support elastic part 353, the adhesion of the dough P by the cone-shaped pushers 333-1 and 333-2 is always It can be made with a constant force so that the molding of the dough (P) can be made more uniformly.

6 to 8 are views showing an embodiment of the plate supporting elastic part of FIG. 3 .

6 to 8, the plate support elastic part 500 according to an embodiment includes a first support plate 510, a first side bending frame 520, a second side bending frame 530, 2 includes a support plate 540, a first side support frame 550 and a second side support frame 560.

The first support plate 510 is formed in the form of a square flat plate to support the lower side of the molding plate 340, the first side bending frame 520 is formed on one side, and the second side bending frame 530 is formed on the other side. ) is formed, and is supported by being spaced upward from the second support plate 540 by the first side support frame 550 and the second side support frame 560.

The first side bending frame 520 is bent from one side of the first support plate 510 to the lower side, and one side surface forms a vertical surface, and the other side surface is inclined in one direction from the upper side to the lower side. 1 upper inclined surface 520a is formed, and the first upper inclined surface 520a is supported by the first lower inclined surface 550a of the first side support frame 550 and moves in the vertical direction, so that the first side support frame 550 slides in the left and right directions.

Here, the second side bending frame 530 forms a left-right symmetrical structure with the first side bending frame 520 to be described later, and the bending frame body 521 of the first side bending frame 520 to be described later, vertical Configurations such as the support bar 522 and the vertical buffer spring 523 can be equally applied, and the description thereof will be omitted to avoid duplication of description.

In one embodiment, the first side bending frame 520 includes a bending frame body 521, a vertical support bar 522 and a vertical buffer spring 523.

The bending frame body 521 is bent downward from one side of the first support plate 510, one side surface forms a vertical surface, and the other side surface is a first upper inclined surface on which the first leg gear 556 is formed (520a), the lower side is supported by the vertical support bar (522).

The vertical support bar 522 extends in the vertical direction and is installed on the upper side of the second support plate 540, and the upper part is inserted into the lower support groove 521a formed in the lower part of the bent frame body 521. The upper side is supported by the vertical buffer spring 523.

The vertical buffer spring 523 is installed on the upper side of the lower support groove and supports the upper side of the vertical support bar 522 using elastic force to buffer vertical vibration or shock generated in the bending frame body 521. give.

The second side bending frame 530 forms a symmetrical structure in the left and right direction with the first side bending frame 520, and is bent downward from the other side of the first support plate 510, but the other side is a vertical plane. A second upper inclined surface 530a is formed so that one side surface is inclined in the other direction from the upper side to the lower side, and the second upper inclined surface 530a is the second lower part of the second side support frame 560. It is supported by the inclined surface 560a and slides the second side support frame 560 in the left and right directions as it moves up and down.

The second support plate 540 is formed in a square flat plate shape, is spaced downward from the first support plate 510 and is seated on the inner bottom surface of the support case 352, and the first side support frame 550 on the upper side. ) and the second side support frame 560 are connected and installed to enable sliding movement in the left and right directions, respectively.

The first side support frame 550 forms a symmetrical structure in the left and right directions with the second side support frame 560, and the upper part is connected to the lower side of the first support plate 510 so as to slide in the left and right directions, and is installed. , The lower part is connected to the upper side of the second support plate 540 so as to slide in the left and right directions, and supports between the first support plate 510 and the second support plate 540, and one side moves from the lower side to the upper side. The first lower inclined surface 550a is formed so as to be inclined in one direction to face the first upper inclined surface 520a gradually, and as the distance between the first support plate 510 and the second support plate 540 decreases, The first lower inclined surface 550a is pushed and moved in one direction by the first upper inclined surface 520a.

Here, the second side support frame 560 forms a left-right symmetrical structure with the first side support frame 550 to be described later, and includes a support frame body 551, an upper body support 552, and a first spring to be described later. Components such as 553, second spring 554, third spring 555, first leg gear 556, second leg gear 557, and at least one spacing support gear 558 are the same As applicable, the description will be omitted to avoid duplication of description.

In one embodiment, the first side support frame 550 includes a support frame body 551, an upper body support 552, a first spring 553, a second spring 554, a third spring 555, A first leg gear 556, a second leg gear 557, and at least one spacing support gear 558 may be included.

The support frame body 551 is connected to and installed so that the lower part can slide in the left and right directions in the upper sliding groove 541 extending in the left and right directions along the upper side of the second support plate 540, and the first support frame body 551 is installed on one side. A lower inclined surface 550a is formed.

In one embodiment, the support frame body 551 is a sliding formed extending along one side and the other side of the upper sliding groove 541 on one side and the other side of the lower part in order to prevent the upper sliding groove 541 from moving away. It is inserted into the groove (not shown in the drawing for convenience of explanation) to form a sliding protrusion (K2) for sliding movement.

The upper body support 552 is connected to the lower sliding groove 511 extending in the left and right direction along the lower side of the first support plate 510 by bending the upper side in a different direction so as to be slid in the left and right directions. , The lower part extending in the vertical direction is inserted into the upper support groove 5511 formed on the upper part of the support frame body 551 and supported by the first spring 553.

In one embodiment, the upper body support 552 is a sliding formed extending along one side and the other side of the lower sliding groove 511 on one side and the other side of the lower side in order to prevent the lower sliding groove 511 from moving away. It is inserted into the groove (not shown in the drawing for convenience of explanation) to form a sliding protrusion (K1) for sliding movement.

At least one first spring 553 is installed along the lower side of the upper support groove 5511 to support the lower side of the upper body support 552 and vibrate in the vertical direction transmitted through the upper body support 552 or shock absorber, etc.

At least one second spring 554 is installed along the other side of the upper sliding groove 541 to support the other lower side of the support frame body 551 .

At least one third spring 555 is installed along the other side of the lower sliding groove 511 to support the other upper side of the upper body support 552 .

That is, the second spring 554 and the third spring 555 bring the support frame body 551 and the upper body support 552 into close contact in one direction, that is, in the direction of the second upper inclined surface 530a, by using elastic force. As a result, the first side bending frame 520 overcomes the external force pressed from the upper side to prevent the lowering, as well as to absorb vibration or shock in the vertical direction transmitted through the first side bending frame 520. .

The first leg gear 556 is installed to face the second leg gear 557 with the gap support gear 558 therebetween, and is formed in the vertical direction along the first upper inclined surface 520a to form a gap support gear ( 558) is interlocked and connected.

The second leg gear 557 is installed to face the first leg gear 556 with the gap support gear 558 therebetween, and is formed in the vertical direction along the first lower inclined surface 550a to form a gap support gear ( 558) is interlocked and connected.

The gap support gear 558 is engaged and connected between the first leg gear 556 and the second leg gear 557, and as the first side bending frame 520 moves in the vertical direction, the first leg gear ( 556) and the second leg gear 557 while rotating and moving the support frame body 551 forward and backward.

In one embodiment, the gap support gear 558 may include a gear body 5581 , a first guide wheel 5582 and a second guide wheel 5583 .

The gear body 5581 is engaged and connected between the first leg gear 556 and the second leg gear 557, the first guide wheel 5582 is connected to the front end, and the second guide wheel ( 5583) is connected and installed.

The first guide wheel 5582 is formed in the shape of a disc and is rotatably connected to the front end of the gear body 5581, and along the first leg gear 556 to prevent the gear body 5581 from leaving. In the first sliding guide groove (L1) extending in the vertical direction and the second sliding guide groove (L1) extending in the vertical direction along the second leg gear 557 while facing the first sliding guide groove (L1) settle in

The second guide wheel 5583 is formed in the shape of a disc and is rotatably connected to the rear end of the gear body 5581, and is rotatably installed from the first sliding guide groove L1 to prevent the gear body 5581 from being separated. A third sliding guide groove (L3) spaced apart from the rear end and extending in the vertical direction along the first leg gear 556 and a vertical direction along the second leg gear 557 while facing the third sliding guide groove (L3) It is seated in the fourth sliding guide groove (L4) formed extending to.

That is, the gap support gear 558 moves the support frame body 551 while rotating between the first leg gear 556 and the second leg gear 557 as the bending frame body 521 descends, or As the support frame body 551 is brought into close contact with each of the springs 554 and 555 in one direction, the bending frame body 521 may be moved up and down.

The second side support frame 560 forms a symmetrical structure with the first side support frame 550 in the left-right direction, and the upper part is connected to the lower side of the first support plate 510 so as to slide in the left-right direction, and is installed. , The lower part is connected to the upper side of the second support plate 540 so as to slide in the left and right directions, and supports between the first support plate 510 and the second support plate 540, and the other side faces from the lower side to the upper side. A second lower inclined surface 560a is formed so as to be inclined in one direction to face the second upper inclined surface 530a toward The second lower inclined surface 560a is pushed and moved in one direction by the second upper inclined surface 530a.

The plate supporting elastic part 500 according to an embodiment having the configuration described above moves the forming plate 340 up and down by using the elastic force, thereby lifting the molded plate 340 by the cone pushers 333-1 and 333-2. The adhesion of the dough (P) is always made with a constant force so that the molding of the dough (P) can be made more uniformly.

The above-described embodiments are for illustrative purposes, and those skilled in the art to which the above-described embodiments belong can easily transform into other specific forms without changing the technical spirit or essential features of the above-described embodiments. You will understand. Therefore, it should be understood that the above-described embodiments are illustrative in all respects and not restrictive. For example, each component described as a single type may be implemented in a distributed manner, and similarly, components described as distributed may be implemented in a combined form.

The scope to be protected through this specification is indicated by the following claims rather than the detailed description above, and should be construed to include all changes or modifications derived from the meaning and scope of the claims and equivalent concepts thereof. .

10: pizza dough manufacturing system
100: dough manufacturing unit
200: transfer unit
300: forming roller unit
400: packaging unit

Claims (5)

A dough making unit for preparing dough by stirring while adding water to raw materials for making pizza dough;
A transfer unit for measuring and transferring the dough prepared in the dough production unit in a certain amount;
a forming roller unit that receives the dough transferred through the transfer unit and shapes it into a pizza dough; and
A packaging unit for individually packaging the pizza dough formed by the forming roller unit,
The forming roller part,
A molded body formed with a pedestal having a circular center in a central portion in a vertical direction;
a rotation drive coupled to an upper portion of the molding body to generate rotational force;
a rotational molding unit coupled to a lower side of the rotational driving unit to form pizza dough;
A forming plate formed in a flat shape so that the dough transported through the transfer unit can be seated; and
A plate lifting unit installed on the lower side of the forming plate to support the forming plate and elevating the forming plate so that the dough seated on the upper side of the forming plate can come into contact with the rotational forming unit;
The plate lifting part,
a support plate formed in the form of a square plate having vertical through-holes at each corner thereof and installed below the molding plate;
a support case formed in a cylindrical shape with a closed lower side and installed on each lower side of each through-hole of the support plate;
a plate support elastic part installed for each support case and on which the molding plate is seated on an upper side exposed to an upper side of the support case;
a flat plate support having an upper side coupled to the lower surface of the support plate and a lower side coupled to the molding body, a rack gear formed in the vertical direction, and capable of extending and contracting in the vertical direction; and
A pinion gear engaged with the rack gear is coupled to one side and a handle is provided to the other side, so that when the handle is lowered downward with the pinion gear as a rotation center, the flat plate support rises, and when raised upward, the flat plate support moves down. Lever; including,
The plate supporting elastic part,
A first support plate formed in a square flat plate shape to support the lower side of the molding plate;
A first side bending frame that is bent downward from one side of the first support plate, one side surface forming a vertical surface, and the other side surface forming a first upper inclined surface such that the other side surface is inclined in one direction from the upper side to the lower side;
It forms a symmetrical structure in the left and right directions with the first side bending frame, and is bent downward from the other side of the first support plate, and the other side surface forms a vertical surface, and as one side goes from the upper side to the lower side, the other side is different. a second side bending frame forming a second upper inclined surface to be inclined in one direction;
a second support plate formed in a square flat plate shape, spaced downward from the first support plate, and seated on an inner bottom surface of the support case;
The upper part is connected to the lower side of the first support plate to slide in the left and right directions, and the lower part is connected to the upper side of the second support plate to slide in the left and right directions, so that the first support plate and the second support plate are connected to each other. It is supported between the support plates, and a first lower inclined surface is formed such that one side is inclined in the other direction so as to face the first upper inclined surface from the lower side to the upper side, and the first lower inclined surface is formed between the first supporting plate and the second supporting plate. a first side support frame in which the first lower inclined surface is pushed and moved in another direction by the first upper inclined surface as the distance decreases; and
It forms a symmetrical structure with the first side support frame in the left-right direction, and the upper part is connected to the lower side of the first support plate to slide in the left-right direction, and the lower part is installed on the upper side of the second support plate in the left-right direction. The second lower inclined surface is installed to be slidably connected to support between the first supporting plate and the second supporting plate, and the other lower inclined surface is inclined in one direction so as to face the second upper inclined surface from the lower side to the upper side. And a second side support frame in which the second lower inclined surface is pushed and moved in one direction by the second upper inclined surface as the distance between the first supporting plate and the second supporting plate decreases. Pizza dough making system.
delete delete delete The method of claim 1, wherein the first side support frame,
a support frame body connected to an upper sliding groove extending left and right along an upper side of the second support plate so that a lower portion thereof can slide in a left and right direction, and having the first lower inclined surface formed on one side thereof;
The upper side is bent in the other direction and connected to the lower sliding groove extending in the left and right directions along the lower side of the first support plate so as to be slid in the left and right directions, and the lower portion extending in the vertical direction is the support frame. An upper body support that is inserted and installed into an upper support groove formed on an upper portion of the body;
at least one first spring installed along the lower side of the upper support groove to support the lower side of the upper body support;
At least one second spring installed along the other side of the upper sliding groove to support the other lower side of the support frame body;
at least one third spring installed along the other side of the lower sliding groove to support the other upper side of the upper body support;
a first leg gear formed in a vertical direction along the first upper inclined surface;
a second leg gear formed in a vertical direction along the first lower inclined surface; and
It is engaged and connected between the first leg gear and the second leg gear, and rotates along the first leg gear and the second leg gear as the first side bending frame moves in the vertical direction, and the support frame A pizza dough manufacturing system comprising: at least one gap support gear for moving the body in the forward and backward directions.