CN216438418U - Noodle strip folding structure and noodle strip folding equipment - Google Patents

Abstract

The utility model discloses a flour belt turning structure and flour belt turning equipment, wherein the flour belt turning structure comprises a conveyor belt, a book ware and supplementary climbing piece turn over, the conveyer belt is used for transmitting the face area, the face area includes that the width direction along the conveyer belt sets up side by side turns over a part and the face area tiling part of rolling over, it sets up in the top of conveyer belt to turn over the ware, the conveyer belt can move for turning over a ware, one side of the transmission direction of face area turns over the ware has set gradually spigot surface and a turnover face, the front end of spigot surface and the surface butt of conveyer belt, the spigot surface is used for the spigot surface area to turn over a part and removes to the turnover face on, it is used for the spigot surface area to turn over a part and turn over and fold on the face area tiling part, supplementary climbing piece is relative and the interval setting with the spigot surface, face area turns over a part and can pass between supplementary climbing piece and the spigot surface, supplementary climbing piece is used for with the face area to turn over the turnover part extrusion of direction near the spigot surface. The automatic turnover of the flour strip can be realized by the flour strip turnover structure, so that the labor is saved.

Description

Noodle strip folding structure and noodle strip folding equipment

Technical Field

The utility model relates to the technical field of food processing equipment, in particular to a flour belt folding structure and flour belt folding equipment.

Background

During the food processing, it is often necessary to roll the dough into a strip of dough, and then turn, divide and roll the strip of dough in order to further process the strip according to different food requirements.

When the flour belts on the transmission belt are turned, tools such as a flour belt turning device are usually used, the flour belt turning device is provided with a guide surface and a turning surface which are sequentially arranged along the transmission direction of the flour belts, the guide surface and the turning surface are both concave cambered surfaces, the guide surface and the turning surface of the flour belt turning device form a certain included angle with the horizontally tiled flour belts, the included angle between the guide surface and the horizontally tiled flour belts along the transmission direction of the flour belts is gradually reduced through an obtuse angle, the included angle between the turning surface and the horizontally tiled flour belts is an acute angle, and the turning part of the flour belts can move to the turning surface along the guide surface, so that the included angle between the turning part of the flour belts and the tiled part of the flour belts is gradually reduced until the turning part of the flour belts is folded from the turning surface to the tiled part of the flour belts under the action of gravity.

However, the noodle strip folding device usually only has a good folding effect on a noodle strip with a narrow width, and for a noodle strip with a thick thickness or a noodle strip with a wide width or a noodle strip which needs to be folded for many times, the noodle strip often slides off from the folding surface in the folding process of the noodle strip, so that the noodle strip cannot be turned over, the noodle strip needs to be lifted manually to assist in folding, and the labor cost is increased.

SUMMERY OF THE UTILITY MODEL

The embodiment of the application discloses a face area turns over a structure and a face area and turns over a equipment, can realize the automation of face area and turn over the book, has saved the manpower.

In order to achieve the above object, an embodiment of the present application discloses a flour ribbon folding structure, including:

the conveying belt is used for conveying flour belts, and each flour belt comprises a flour belt turning part and a flour belt tiling part which are arranged in parallel along the width direction of the conveying belt;

the conveying belt can move relative to the turner, a guide surface and a turning surface are sequentially arranged on one side of the turner along the conveying direction of the dough belt, the front end of the guide surface is abutted to the surface of the conveying belt on which the dough belt is placed, the guide surface is used for guiding the dough belt turning part to move to the turning surface, and the turning surface is used for guiding the dough belt turning part to be turned and folded on the dough belt laying part;

supplementary climbing piece, supplementary climbing piece with the guiding surface is relative and the interval sets up, face area turns over a part and can follow supplementary climbing piece with pass between the guiding surface, supplementary climbing piece be used for with face area turns over a part and is to being close to the direction extrusion of guiding surface.

In this embodiment, the dough belt is transported and moved by the conveyor belt, the turner is disposed above the conveyor belt, and the conveyor belt can move relative to the turner, so that the dough belt can move relative to the turner. The front end of the guide surface on the turnover device is abutted against the surface of the dough strip placed on the conveying belt, so that the turnover part of the dough strip can climb to the guide surface, and then the turnover part of the dough strip is guided to move to the turnover surface through the guide surface, and the turnover surface can enable the turnover part of the dough strip to be turned over and folded to the flat part of the dough strip, so that the dough strip is turned over. The auxiliary climbing piece and the guide surface are opposite and spaced, so that the dough strip turning part can penetrate through the auxiliary climbing piece and the guide surface, the climbing piece can extrude the dough strip turning part in the direction close to the guide surface, the dough strip turning part is in closer contact with the guide surface, and the dough strip turning part is not easy to fall off from the guide surface, so that the failure of turning the dough strip turning part due to falling of the dough strip turning part is avoided.

In a possible implementation manner of the first aspect, the auxiliary climbing part is a roller, an axial direction of the roller is perpendicular to a transmission direction of the surface belt, and a surface of the roller, which is used for extruding the turnover part of the surface belt, is parallel to the guide surface.

Therefore, compared with the auxiliary climbing piece with other special-shaped structures, the auxiliary climbing piece with the roller structure is simple in structure and easy to realize. And the axial direction of the roller is vertical to the transmission direction of the dough belt, and the surface of the roller for extruding the turnover part of the dough belt is parallel to the guide surface, so that the contact area between the roller and the turnover part of the dough belt can be increased, the contact area between the turnover part of the dough belt and the guide surface can be larger, and the guide surface can more easily guide the turnover part of the dough belt to the turnover surface.

In a possible implementation manner of the first aspect, the roller is a drum-shaped roller, and the diameter of the drum-shaped roller is gradually reduced from the middle to the two ends.

Therefore, the surface of the roller used for extruding the surface belt turnover part is parallel to the guide surface to the maximum extent, so that the waist drum-shaped roller can have a larger contact area with the surface belt turnover part, and the processing technology of the waist drum-shaped roller is mature and easy to realize.

In a possible implementation manner of the first aspect, the face area turnover structure further comprises a lifting piece, the lifting piece is opposite to the turnover face and is arranged at an interval, the face area turnover part can be taken from the lifting piece and penetrates through the turnover face, and the lifting piece is used for supporting the face area turnover part to be close to the direction bearing of the turnover face so as to prevent the face area turnover part from sliding off.

Therefore, the dough belt turning part can penetrate through the lifting piece and the turning face when moving to the turning face, the lifting piece can support the dough belt turning part in the direction of the turning face, and the dough belt turning part can be prevented from sliding along the turning face, so that the condition that the edge pressing occurs when the dough belt turning part is folded to the dough belt tiling part due to the fact that the dough belt turning part slides down is avoided, the turned dough belt is neat and attractive, and the turned dough belt can be conveniently subjected to subsequent operation.

In a possible implementation manner of the first aspect, a surface of the lifting piece, which is used for supporting the folded portion of the surface belt, is a first arc surface, the first arc surface protrudes toward the folded surface, and the folded surface is a concave arc surface.

Therefore, the smooth flatness of the surface of the folded part of the flour belt which is folded on the first cambered surface is not easily influenced, and the folded part of the flour belt can be neatly compacted when being folded on the flat part of the flour belt.

In a possible implementation manner of the first aspect, a distance between the first arc surface and the flat part of the surface belt is gradually reduced along the conveying direction of the surface belt.

Therefore, the surface belt turning part stacked on the first cambered surface can be gradually close to the surface belt tiling part in the transmission process until the surface belt turning part stacked on the first cambered surface moves out of the first cambered surface and is stacked on the surface belt tiling part, wrinkles of the surface belt turning part in the stacking process can be prevented, and the turning quality of the surface belt is improved.

In a possible implementation manner of the first aspect, the dough strip folding structure further includes a support frame, the conveyor belt is located on the support frame, and the conveyor belt is capable of moving relative to the support frame;

follow on the support frame the direction of transmission in face area has set gradually first installation pole and second installation pole, first installation pole with second installation pole all span in the top of conveyer belt, just first installation pole is close to the folded surface sets up, second installation pole is close to the spigot surface sets up, lift the piece with first installation pole is connected, supplementary climbing spare with the second installation pole is connected.

Because the support frame can be fixed for ground, and the conveyer belt can move on the support frame, consequently, the driving machine can drive the conveyer belt and move on the support frame to make the face area of placing on the conveyer belt conveyed. And because the first mounting rod and the second mounting rod are sequentially arranged on the support frame along the transmission direction of the surface belt, the lifting piece is fixedly connected with the first mounting rod, and the auxiliary climbing piece is fixedly connected with the second mounting rod, the lifting piece and the auxiliary climbing piece are fixedly arranged relative to the support frame, so that the lifting piece and the auxiliary climbing piece can not move along with the movement of the surface belt, the lifting piece and the auxiliary climbing piece do not need to be frequently adjusted, and the setting process of the lifting piece and the auxiliary climbing piece is simplified.

In a possible implementation manner of the first aspect, the lifting piece is connected with the first mounting rod in a sliding manner along the width direction of the conveyor belt, and the auxiliary climbing piece is connected with the second mounting rod in a sliding manner along the width direction of the conveyor belt.

From this, through lifting the piece and sliding along the width direction of conveyer belt on first installation pole, supplementary climbing piece slides along the width direction of conveyer belt on second installation pole, and adjustable lifting and supplementary climbing piece are for the position of conveyer belt to be applicable to turning over of different broad width area and turn over.

In a possible implementation manner of the first aspect, a first connecting assembly is slidably sleeved on the first mounting rod, a connecting end of the first connecting assembly is fixedly connected with the lifting piece, and an adjusting end of the first connecting assembly is slidably sleeved on the first mounting rod;

the sliding sleeve is equipped with second coupling assembling on the second installation pole, second coupling assembling's link with supplementary climbing piece fixed connection, second coupling assembling's regulation end sliding sleeve is located on the second installation pole.

Therefore, the lifting piece can slide along the extending direction of the first mounting rod, the auxiliary climbing piece can slide along the extending direction of the second mounting rod, the mounting position of the lifting piece relative to the first mounting rod can be changed, the mounting position of the auxiliary climbing piece relative to the second mounting rod can be changed, and then the positions of the lifting piece and the auxiliary climbing piece can be adjusted according to the width and the thickness of the surface belt, so that the structure is simple, and the realization is easy.

In a possible implementation manner of the first aspect, a first fastening piece is further arranged on the first mounting rod, a first threaded hole is formed in an adjusting end of the first connecting assembly, the first fastening piece is in threaded connection with the first threaded hole, and the first fastening piece can be abutted to the outer peripheral wall of the first mounting rod after penetrating through the first threaded hole;

still be provided with the second fastener on the second installation pole, second screw hole has been seted up to the regulation end of second coupling assembling, the second fastener with second screw hole threaded connection, the second fastener passes the second screw hole can with the periphery wall butt of second installation pole.

Therefore, the connecting structure between the first mounting rod and the first connecting component and between the second mounting rod and the second connecting component can be simplified.

In a possible implementation manner of the first aspect, the first connecting assembly includes a first connecting rod, a first connecting block, and a third fastening element, one end of the first connecting rod is fixedly connected to the lifting element, the other end of the first connecting rod is slidably disposed on the first connecting block along a vertical direction, a third threaded hole is formed in the first connecting block, the third fastening element is in threaded connection with the third threaded hole, the third fastening element penetrates through the third threaded hole and can abut against an outer peripheral wall of the first connecting rod, the first threaded hole is located on the first connecting block, and the first connecting block is further slidably sleeved on the first mounting rod;

the second connecting assembly comprises a second connecting rod, a second connecting block and a fourth fastener, one end of the second connecting rod is fixedly connected with the auxiliary climbing piece, the other end of the second connecting rod is along the transmission direction of the surface belt in a sliding and penetrating mode, a fourth threaded hole is formed in the second connecting block, the fourth fastener is in threaded connection with the fourth threaded hole, the fourth fastener penetrates through the fourth threaded hole and can be abutted to the outer peripheral wall of the second connecting rod, the second threaded hole is located in the second connecting block, and the second connecting block is further sleeved with the second mounting rod in a sliding mode.

Therefore, one end of the first connecting rod is fixedly connected with the lifting piece, the other end of the first connecting rod penetrates through the first connecting block in a sliding mode along the vertical direction, the first connecting rod can drive the lifting piece to move relative to the first connecting block along the vertical direction, the position of the lifting piece relative to the turnover face is adjusted, when a third fastener can penetrate through the third threaded hole to abut against the peripheral wall of the first connecting rod, the first connecting rod can be fixed relative to the first connecting block, the adjusted lifting piece is fixed relative to the first mounting rod, similarly, one end of the second connecting rod is fixedly connected with the auxiliary climbing piece, the other end of the second connecting rod penetrates through the second connecting block in a sliding mode along the transmission direction of the face belt, the second connecting rod can drive the auxiliary climbing piece to move relative to the second connecting block along the transmission direction of the face belt, and the position of the auxiliary climbing piece relative to the guide face is adjusted, when the fourth fastener can pass the periphery wall butt of fourth screw hole and second connecting rod, can make the second connecting rod fixed for the second connecting block to make the supplementary climbing piece after the adjustment fixed for the second installation pole, so, can make the position of lifting piece for the turnover face, and supplementary climbing piece is adjustable for the position of guide surface, thereby has improved the suitability of lifting piece and supplementary climbing piece.

In a second aspect, an embodiment of the present application discloses a dough strip folding apparatus, including the dough strip folding structure in the first aspect.

In the embodiment of the application, the noodle strip folding structure included in the noodle strip folding equipment can automatically fold the noodle strip with a narrow width, can automatically fold the noodle strip with a wide width, a thick noodle strip and the noodle strip needing to be folded for multiple times, is not easy to wrinkle or press edges, and has high folding quality. Therefore, when the noodle strip folding equipment comprises the noodle strip folding structure, the noodle strip folding equipment can automatically fold noodle strips which are narrow in width, wide in width, thick in thickness and need to be folded for many times, and the folding quality of the noodle strips is high.

Drawings

In order to more clearly illustrate the technical solutions in the embodiments of the present invention, the drawings needed to be used in the embodiments will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art that other drawings can be obtained according to these drawings without creative efforts.

Fig. 1 is a perspective view of a noodle folding structure provided in an embodiment of the present application;

FIG. 2 is an enlarged view of A in FIG. 1;

FIG. 3 is a perspective view of a construction of a turner provided in an embodiment of the present application;

fig. 4 is a perspective view of an auxiliary climbing member provided in an embodiment of the present application;

FIG. 5 is a perspective view of a lift provided by an embodiment of the present application;

FIG. 6 is a schematic cross-sectional view of one of the first connecting block and the second connecting block provided in the embodiments of the present application;

fig. 7 is a second schematic cross-sectional view of the first connecting block or the second connecting block according to the embodiment of the present application.

Description of the main reference numerals:

100-a surface with a turnover structure; 200-a flour band; 110-a conveyor belt; 120-a turner; 121-a guide surface; 122-a turnover surface; 130-auxiliary climbing members; 131-a roller; 140-a lift; 141-a first arc surface; 150-a support frame; 160-a first mounting bar; 161-a first connection assembly; 1611 — a first connection block; 1611 a-a first threaded hole; 1611 b-a third threaded hole; 1611c — a first lateral through hole; 1611 d-a first longitudinal through hole; 1612-a first fastener; 1613-a first connecting rod; 1614-a third fastener; 170-a second mounting bar; 171-a second connection assembly; 1711-a second connection block; 1711 a-a second threaded hole; 1711 b-a fourth threaded hole; 1711 c-a second lateral via; 1711 d-a second longitudinal through hole; 1712-a second fastener; 1713-a second connecting rod; 1714-fourth fastener.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

In the present invention, the terms "upper", "lower", "left", "right", "front", "rear", "top", "bottom", "inner", "outer", "center", "vertical", "horizontal", "lateral", "longitudinal", and the like indicate an orientation or positional relationship based on the orientation or positional relationship shown in the drawings. These terms are used primarily to better describe the utility model and its embodiments and are not intended to limit the indicated devices, elements or components to a particular orientation or to be constructed and operated in a particular orientation.

Moreover, some of the above terms may be used to indicate other meanings besides the orientation or positional relationship, for example, the term "on" may also be used to indicate some kind of attachment or connection relationship in some cases. The specific meanings of these terms in the present invention can be understood by those skilled in the art as appropriate.

Furthermore, the terms "mounted," "disposed," "provided," "connected," and "connected" are to be construed broadly. For example, it may be a fixed connection, a removable connection, or a unitary construction; can be a mechanical connection, or an electrical connection; may be directly connected, or indirectly connected through intervening media, or may be in internal communication between two devices, elements or components. The specific meanings of the above terms in the present invention can be understood by those of ordinary skill in the art according to specific situations.

Furthermore, the terms "first," "second," and the like, are used primarily to distinguish one device, element, or component from another (the specific nature and configuration may be the same or different), and are not used to indicate or imply the relative importance or number of the indicated devices, elements, or components. "plurality" means two or more unless otherwise specified.

During food processing, it is often necessary to stretch the dough into a strip of dough, and then turn, separate and roll the strip to further process the strip according to different food requirements.

When the flour belts on the transmission belt are turned over, tools such as a flour belt turning device are usually used, the flour belt turning device is provided with a guide surface and a turning surface which are sequentially arranged along the transmission direction of the flour belts, the guide surface and the turning surface are concave cambered surfaces, the guide surface and the turning surface of the flour belt turning device are both at a certain included angle with the horizontally tiled flour belts, the included angle between the guide surface of the transmission direction of the flour belts and the horizontally tiled flour belts is gradually reduced by an obtuse angle, and the included angle between the turning surface and the horizontally tiled flour belts is an acute angle. When the noodle band turning device is used, a noodle band is placed on an operation platform, such as a conveying belt and the like, the front end of the guide surface is abutted to the operation platform, the turning part of the noodle band is gradually reduced through an included angle between the guide surface and the tiled part of the noodle band until the turning part of the noodle band moves to the turning surface along the guide surface, the included angle between the turning part of the noodle band and the tiled part of the noodle band is an acute angle, then the turning part of the noodle band is overlaid on the tiled part of the noodle band under the action of gravity, so far, the noodle band finishes a turning action, and then the noodle band is continuously conveyed along the direction until the noodle band is turned over.

However, the noodle strip folding device usually only folds the noodle strips with a relatively narrow width to achieve a relatively good folding effect, and the noodle strips with a relatively thick thickness or the noodle strips with a relatively wide width or the noodle strips which need to be folded for many times often slide off from the guide surface in the process of folding the noodle strips, so that the noodle strips cannot be folded or need manual assistance; or the noodle belt is folded when being conveyed to the folding surface and also slides along the folding surface, at the moment, although the noodle belt can be folded, the condition of pressing the edge of the noodle belt can be caused, manual assistance is needed for folding, and the labor cost is increased.

In view of this, the utility model provides a noodle strip folding structure and noodle strip folding equipment, which can realize automatic folding of noodle strips and save labor.

The technical solutions of the present application will be described in detail below with reference to specific embodiments and accompanying drawings.

Example one

The embodiment of the present application provides a face area book structure, as shown in fig. 1-4, includes: a conveyor belt 110, a turner 120 and an auxiliary climbing member 130, the conveyor belt 110 is used for conveying a dough strip 200, the dough strip 200 includes a dough strip turning part and a dough strip tiling part which are arranged side by side along the width direction (i.e. the direction indicated by the arrow X in fig. 1) of the conveyor belt 110, the turner 120 is arranged above the conveyor belt 110, the conveyor belt 110 is movable relative to the turner 120, a guide surface 121 and a turning surface 122 are arranged in sequence along one side of the turner 120 in the conveying direction (i.e. the direction indicated by the arrow Y in fig. 1) of the dough strip 200, the front end of the guide surface 121 abuts against the surface of the conveyor belt 110 on which the dough strip 200 is placed, the guide surface 121 is used for guiding the dough strip turning part to move onto the turning surface 122, the turning surface 122 is used for guiding the dough strip turning part to turn and to be folded onto the dough strip tiling part, the auxiliary climbing member 130 is arranged opposite to and spaced from the guide surface 121, the dough strip turning part can pass between the auxiliary climbing member 130 and the guide surface 121, the auxiliary climbing member 130 serves to press the flap portion of the dough belt in a direction approaching the guide surface 121.

In the present embodiment, the dough strip 200 is moved by the conveyor belt 110, the turner 120 is disposed above the conveyor belt 110, and the conveyor belt 110 is movable relative to the turner 120, so that the dough strip 200 can be moved relative to the turner 120. The front end of the guide surface 121 of the turner 120 abuts against the surface of the conveyor belt 110 on which the dough strip 200 is placed, so that the dough strip turned part can climb onto the guide surface 121, and then the dough strip turned part is guided by the guide surface 121 to move onto the turning surface 122, and the turning surface 122 can turn and fold the dough strip turned part onto the dough strip tiled part, so that the dough strip 200 is turned over. The auxiliary climbing part 130 and the guide surface 121 are arranged oppositely and at intervals, so that the folded part of the dough strip can pass through the auxiliary climbing part 130 and the guide surface 121, and the climbing part can extrude the folded part of the dough strip in the direction close to the guide surface 121, the folded part of the dough strip and the guide surface 121 are in closer contact, the folded part of the dough strip is not easy to slip off from the guide surface 121, and the failure of folding the folded part of the dough strip due to the slipping of the folded part of the dough strip is avoided.

The auxiliary climbing member 130 may be implemented in various structures, such as a roller 131, or a pressing block, which is not limited herein. The following description will be made in detail by taking the auxiliary climbing member 130 as the roller 131 as an example.

As shown in fig. 2 and 4, when the auxiliary climbing member 130 is a roller 131, the axial direction of the roller 131 is perpendicular to the conveying direction Y of the noodle band 200, and the surface of the roller 131 for pressing the folded-back portion of the noodle band is parallel to the guide surface 121. Specifically, the side surface of the roller 131 may abut against the folded portion of the dough belt, and the surface of the roller 131 for pressing the folded portion of the dough belt is parallel to the guide surface 121, so that the contact area between the roller 131 and the folded portion of the dough belt may be increased, and a larger contact area between the folded portion of the dough belt and the guide surface 121 may be provided, so that the guide surface 121 may more easily guide the folded portion of the dough belt to the folded surface 122. In addition, the auxiliary climbing member 130 having the roller 131 structure is simpler in structure and easier to implement than the auxiliary climbing member 130 having another special-shaped structure.

Note that the axial direction of the roller 131 perpendicular to the conveying direction Y of the surface belt 200 means: the axial direction of the roller 131 is substantially perpendicular to the conveying direction of the dough belt 200 in the space, and the roller 131 and the folded portion of the dough belt may have a large contact area, which is not limited herein. The above-mentioned parallel of the surface of the roller 131 for pressing the folded portion of the dough strip with the guide surface 121 means that: the surface of the roller 131 for pressing the folded portion of the dough band is substantially parallel to the guide surface 121, and is not limited as long as the contact area between the folded portion of the dough band and the guide surface 121 can be increased.

In addition, the surface of the roller 131 for extruding the folded part of the surface belt is parallel to the guide surface 121, so that the condition that the surface of the folded part of the surface belt is not smooth after passing through the space between the roller 131 and the guide surface 121 can be prevented, and the subsequent process of the surface belt 200 is prevented from being influenced by the unsmooth surface of the folded part of the surface belt.

The roller 131 has various structural forms, such as a cylindrical roller 131, that is, the diameter of the roller 131 is uniform; the diameter of the drum-shaped roller 131 may be gradually reduced from the middle to both ends, so that the surface of the roller 131 for pressing the turned part of the dough strip is parallel to the guide surface 121 to the greatest extent, so that the drum-shaped roller 131 and the turned part of the dough strip have a larger contact area, and the drum-shaped roller 131 is mature in processing technology and easy to implement.

Further, the roller 131 may be a roller 131 capable of rotating on its own axis, so that the sliding frictional resistance between the roller 131 and the folded portion of the dough band becomes the rolling frictional resistance, and the folded portion of the dough band can be more easily passed between the roller 131 and the guide surface 121.

As shown in fig. 2, the dough strip folding structure 100 includes a lifting member 140 in addition to the conveyor 110, the folding member 120 and the auxiliary climbing member 130. The lifting piece 140 is opposite to the turnover face 122 and arranged at intervals, the turnover part of the flour belt can penetrate through the lifting piece 140 and the turnover face 122, and the lifting piece 140 is used for supporting the turnover part of the flour belt in the direction close to the turnover face 122 so as to prevent the turnover part of the flour belt from sliding off. Therefore, the dough belt turning part can pass through the lifting piece 140 and the turning face 122 when moving to the turning face 122, the lifting piece 140 can support the dough belt turning part in the direction of the turning face 122, and the dough belt turning part can be prevented from sliding along the turning face 122, so that the situation that the edge pressing occurs when the dough belt turning part is folded to the dough belt flat part due to the fact that the dough belt turning part slides down is avoided, the turned dough belt 200 is tidy and attractive, and the turned dough belt 200 can be conveniently subjected to subsequent operation.

Specifically, as shown in fig. 5, the surface of the lifting member 140 for supporting the folded portion of the belt is a first arc surface 141, the first arc surface 141 protrudes toward the folded surface 122, and the folded surface 122 is a concave arc surface. Therefore, the folded part of the flour strip, which forms an acute angle with the tiled part of the flour strip, can be firstly folded and fall on the first cambered surface 141 under the action of gravity, and the probability that the folded part of the flour strip slides along the folded surface 122 under the action of gravity is reduced. And because the face area 200 has fine ductility, the roughness on surface is easily influenced, consequently, when the face that is used for bearing face area turn-over part on lifting piece 140 is first cambered surface 141, can make the smooth roughness on the surface that the face area that the stack fell on first cambered surface 141 turned over the part be difficult for receiving the influence to can neatly compact when making face area turn-over part stack to fall on face area tiling.

In addition, one side of the first arc surface 141 close to the flat part of the dough strip may abut against the edge of the folded part of the dough strip close to the flat part of the dough strip, so as to further prevent the folded part of the dough strip from sliding down along the folding surface 122, thereby making the folding of the dough strip 200 more orderly.

When the dough strip turning part passes through the turning surface 122 and the lifting piece 140 to be turned, the edge part of the dough strip turning part, which is far away from the dough strip tiling part, can be firstly folded and fall onto the first arc surface 141 under the action of gravity, then along with the movement of the dough strip 200, the dough strip turning part folded and falling on the first arc surface 141 moves out of the first arc surface 141 and continues to be folded and fall under the action of gravity, and meanwhile, the dough strip turning part and other parts of the dough strip turning part are folded and fall onto the dough strip tiling part together, so that the phenomenon of pressing edges of the dough strip 200 after being turned can be prevented without manual assistance.

Further, as shown in fig. 5, the distance between the first arc face 141 and the patch flat portion in the conveying direction Y of the patch 200 gradually decreases. That is, the distance between the first arc surface 141 and the dough band tiled portion in the vertical direction gradually decreases in the transmission direction Y along the dough band 200, and thus, the dough band folded portion folded on the first arc surface 141 can be gradually brought close to the dough band tiled portion in the transmission process until the dough band folded portion folded on the first arc surface 141 moves out of the first arc surface 141 and is folded on the dough band tiled portion, and wrinkles of the dough band folded portion in the folding process can be prevented, thereby improving the folding quality of the dough band 200.

In some embodiments, as shown in fig. 1 and 2, the dough strip folding structure 100 further includes a support frame 150, the conveyor belt 110 is located on the support frame 150, and the conveyor belt 110 is capable of moving relative to the support frame 150; first installation rods 160 and second installation rods 170 are sequentially arranged on the support frame 150 along the transmission direction Y of the dough belt 200, the first installation rods 160 and the second installation rods 170 both span above the conveyor belt 110, the first installation rods 160 are arranged close to the turnover surface 122, the second installation rods 170 are arranged close to the guide surface 121, the lifting piece 140 is connected with the first installation rods 160, the auxiliary climbing piece 130 is connected with the second installation rods 170, and the turnover device 120 is fixed on the first installation rods 160.

Since the supporting frame 150 can be fixed relative to the ground and the conveyor belt 110 can move on the supporting frame 150, the driving machine can drive the conveyor belt 110 to move on the supporting frame 150, so that the flour belt 200 placed on the conveyor belt 110 is conveyed. Since the first mounting rod 160 and the second mounting rod 170 are sequentially arranged on the supporting frame 150 along the transmission direction Y of the surface belt 200, the lifting piece 140 is fixedly connected with the first mounting rod 160, and the auxiliary climbing piece 130 is fixedly connected with the second mounting rod 170, the lifting piece 140 and the auxiliary climbing piece 130 are fixedly arranged relative to the supporting frame 150, so that the lifting piece 140 and the auxiliary climbing piece 130 do not move along with the movement of the surface belt 200, and therefore frequent adjustment of the lifting piece 140 and the auxiliary climbing piece 130 is not required, and the arrangement process of the lifting piece 140 and the auxiliary climbing piece 130 is simplified.

The first mounting rod 160 is disposed close to the folding surface 122, and the second mounting rod 170 is disposed close to the guide surface 121, so that the interference between the lifting member 140 fixed to the first mounting rod 160 and the auxiliary climbing member 130 fixed to the second mounting rod 170 can be prevented, and the use of the surface belt folding structure 100 is not affected by the interference between the lifting member 140 and the auxiliary climbing member 130.

In actual production, different wheaten food products can be made on the different wide-width noodles 200, so that the noodle folding structure 100 can fold the different wide-width noodles 200, in some embodiments, the lifting member 140 is slidably connected with the first mounting rod 160 along the width direction X of the conveyor belt 110, and the auxiliary climbing member 130 is slidably connected with the second mounting rod 170 along the width direction X of the conveyor belt 110.

Therefore, the positions of the lifting member 140 and the auxiliary climbing member 130 relative to the conveyor belt 110 can be adjusted to be suitable for the folding of different wide belts 200 by sliding the lifting member 140 on the first mounting rod 160 in the width direction X of the conveyor belt 110 and sliding the auxiliary climbing member 130 on the second mounting rod 170 in the width direction X of the conveyor belt 110.

Specifically, the extending direction of the first mounting rod 160 and the second mounting rod 170 is perpendicular to the conveying direction of the conveyor belt 110, both ends of the first mounting rod 160 and both ends of the second mounting rod 170 are fixedly connected to the supporting frame 150, a first connecting assembly 161 is slidably sleeved on the first mounting rod 160, the connecting end of the first connecting assembly 161 is fixedly connected to the lifting member 140, and the adjusting end of the first connecting assembly 161 is slidably sleeved on the first mounting rod 160; the second mounting rod 170 is slidably sleeved with a second connecting assembly 171, the connecting end of the second connecting assembly 171 is fixedly connected with the auxiliary climbing member 130, and the adjusting end of the second connecting assembly 171 is slidably sleeved on the second mounting rod 170.

Because the adjusting end of the first connecting component 161 is slidably sleeved on the first mounting rod 160, the adjusting end of the second connecting component 171 is slidably sleeved on the second mounting rod 170, the first mounting rod 160 and the second mounting rod 170 are both fixedly arranged relative to the supporting frame 150, the first connecting component 161 is fixedly connected with the lifting piece 140, and the second connecting component 171 is fixedly connected with the auxiliary climbing piece 130, the lifting piece 140 can slide along the extending direction of the first mounting rod 160, the auxiliary climbing piece 130 can slide along the extending direction of the second mounting rod 170, so that the mounting position of the lifting piece 140 relative to the first mounting rod 160 can be changed, the mounting position of the auxiliary climbing piece 130 relative to the second mounting rod 170 can be changed, and the positions of the lifting piece 140 and the auxiliary climbing piece 130 can be adjusted according to the width and the thickness of the surface belt 200, the structure is simple, and the implementation is easy.

In some embodiments, as shown in fig. 2, 6 and 7, the first mounting rod 160 is further provided with a first fastening member 1612, the adjusting end of the first connecting assembly 161 is provided with a first threaded hole 1611a, the first fastening member 1612 is in threaded connection with the first threaded hole 1611a, and the first fastening member 1612 passes through the first threaded hole 1611a and can abut against the outer peripheral wall of the first mounting rod 160; the second mounting rod 170 is further provided with a second fastener 1712, the adjusting end of the second connecting assembly 171 is provided with a second threaded hole 1711a, the second fastener 1712 is in threaded connection with the second threaded hole 1711a, and the second fastener 1712 can be abutted against the outer peripheral wall of the second mounting rod 170 by passing through the second threaded hole 1711 a.

Accordingly, the first fastening member 1612 is inserted into the first screw hole 1611a to abut against the outer peripheral wall of the first mounting rod 160, so that the sliding friction between the inner wall of the first screw hole 1611a and the first mounting rod 160 is increased, and the first connecting member 161 is fixedly connected to the first mounting rod 160, and similarly, the second fastening member 1712 is inserted into the second screw hole 1711a to abut against the outer peripheral wall of the second mounting rod 170, so that the sliding friction between the inner wall of the second screw hole 1711a and the second mounting rod 170 is increased, so that the second connecting member 171 is fixedly connected to the second mounting rod 170, and the connection structure between the first mounting rod 160 and the first connecting member 161, and between the second mounting rod 170 and the second connecting member 171 is simplified. And screwing up first fastener 1612 can fix first coupling assembling 161 on first installation pole 160, unscrew first fastener 1612 can make first coupling assembling 161 slide on first installation pole 160, easy operation is convenient, and similarly, screwing up second fastener 1712 can fix second coupling assembling 171 on second installation pole 170, and unscrewing second fastener 1712 can make second coupling assembling 171 slide on second installation pole 170.

Specifically, as shown in fig. 2, the first connecting assembly 161 includes a first connecting rod 1613, a first connecting block 1611 and a third fastening member 1614, one end of the first connecting rod 1613 is fixedly connected to the lifting member 140, the other end of the first connecting rod 1613 is slidably disposed on the first connecting block 1611 along the vertical direction, a third threaded hole 1611b is formed in the first connecting block 1611, the third fastening member 1614 is in threaded connection with the third threaded hole 1611b, the third fastening member 1614 can be abutted against the outer peripheral wall of the first connecting rod 1613 by passing through the third threaded hole 1611b, the first threaded hole 1611a is located on the first connecting block 1611, and the first connecting block 1611 is further slidably sleeved on the first mounting rod 160; the second connecting assembly 171 includes a second connecting rod 1713, a second connecting block 1711 and a fourth fastener 1714, one end of the second connecting rod 1713 is fixedly connected with the auxiliary climbing member 130, the other end of the second connecting rod 1713 is slidably arranged on the second connecting block 1711 along the transmission direction Y of the surface belt 200, a fourth threaded hole 1711b is formed in the second connecting block 1711, the fourth fastener 1714 is in threaded connection with the fourth threaded hole 1711b, the fourth fastener 1714 penetrates through the fourth threaded hole 1711b and can be abutted against the outer peripheral wall of the second connecting rod 1713, the second threaded hole 1711a is located on the second connecting block 1711, and the second connecting block 1711 is further slidably sleeved on the second mounting rod 170.

Therefore, one end of the first connecting rod 1613 is fixedly connected with the lifting piece 140, the other end of the first connecting rod 1613 is slidably disposed through the first connecting block 1611 in the vertical direction, so that the first connecting rod 1613 can drive the lifting piece 140 to move relative to the first connecting block 1611 in the vertical direction, thereby adjusting the position of the lifting piece 140 relative to the folding surface 122, when the third fastening piece 1614 can pass through the third threaded hole 1611b to abut against the peripheral wall of the first connecting rod 1613, the first connecting rod 1613 can be fixed relative to the first connecting block 1611, thereby fixing the adjusted lifting piece 140 relative to the first mounting rod 160, and similarly, one end of the second connecting rod 1713 is fixedly connected with the auxiliary climbing piece 130, and the other end of the second connecting rod 1713 is slidably disposed through the second connecting block 1711 in the conveying direction Y of the surface belt 200, so that the second connecting rod 1713 can drive the auxiliary climbing piece 130 to move relative to the second connecting block 1711 in the conveying direction Y of the surface belt 200, therefore, the position of the auxiliary climbing member 130 relative to the guide surface 121 is adjusted, when the fourth fastening member 1714 can pass through the fourth threaded hole 1711b and abut against the peripheral wall of the second connecting rod 1713, the second connecting rod 1713 can be fixed relative to the second connecting block 1711, and the adjusted auxiliary climbing member 130 is fixed relative to the second mounting rod 170, so that the position of the lifting member 140 relative to the turnover surface 122 and the position of the auxiliary climbing member 130 relative to the guide surface 121 can be adjusted, and the applicability of the lifting member 140 and the auxiliary climbing member 130 is improved.

Specifically, as shown in fig. 6 and 7, a first transverse through hole 1611c and a first longitudinal through hole 1611d are further disposed on the first connecting block 1611, wherein the first transverse through hole 1611c is sleeved on the first mounting rod 160, the first longitudinal through hole 1611d is sleeved on the first connecting rod 1613, the first threaded hole 1611a is communicated with the first transverse through hole 1611c, and the third threaded hole 1611b is communicated with the first longitudinal through hole 1611 d; a second transverse through hole 1711c and a second longitudinal through hole 1711d are further formed in the second connecting block 1711, the second transverse through hole 1711c is sleeved on the second mounting rod 170, the second longitudinal through hole 1711d is sleeved on the second connecting rod 1713, the second threaded hole 1711a is communicated with the second transverse through hole 1711c, the fourth threaded hole 1711b is communicated with the second longitudinal through hole 1711d, and the structure is simple and easy to achieve.

In actual production, the dough belt 200 is usually folded on both sides simultaneously, at this time, the first mounting rod 160 may be mounted with two folding devices 120 and two lifting members 140, the guiding surfaces 121 and the folding surfaces 122 on the two folding devices 120 are disposed oppositely, and the two lifting members 140 are located between the two folding devices 120, one lifting member 140 of the two lifting members 140 is disposed opposite to and spaced from the folding surface 122 of one folding device 120 of the two folding devices 120, and the other lifting member 140 is disposed opposite to and spaced from the folding surface 122 of the other folding device 120; the second mounting rod 170 is correspondingly provided with two auxiliary climbing members 130, the two auxiliary climbing members 130 are located between the two folding devices 120, and the two auxiliary climbing members 130 are respectively opposite to the guide surfaces 121 of the two folding devices 120 and are arranged at intervals. Therefore, the flour strip 200 to be folded is placed between the two turners 120, then the conveyor belt 110 drives the flour strip 200 to transmit, and in the transmission process of the flour strip 200, two edges of the flour strip 200 can be folded at the same time, so that the folding speed of the flour strip 200 is improved.

Example two

The embodiment of the present application further provides a dough strip folding apparatus, as shown in fig. 1, including the dough strip folding structure 100 according to the first embodiment.

The structure of the first flap structure 100 may be the same as the structure of the first flap structure 100 in the first embodiment, and may have the same or similar beneficial effects, which specifically refers to the description in the first embodiment, and is not repeated herein.

In the embodiment of the application, the dough strip folding structure 100 included in the dough strip folding device not only can enable the dough strip 200 with a narrow width to be automatically folded, but also can enable the dough strip 200 with a wide width, the dough strip 200 with a thick width and the dough strip 200 needing to be folded for multiple times to be automatically folded, and the situation of folding, pressing and the like is not easy to occur, so that the dough strip 200 has high folding quality and a good folding effect. Therefore, when the noodle strip folding device comprises the noodle strip folding structure 100, the noodle strip 200 folding device can automatically fold noodle strips 200 which are narrow in width, wide in width, thick in thickness of the noodle strips 200 and need to be folded for multiple times, and the folding quality of the noodle strips 200 is high.

The above describes in detail a dough belt folding structure and a dough belt folding device disclosed in the embodiments of the present invention, and a specific example is applied in the description to explain the principle and the embodiments of the present invention, and the description of the above embodiments is only used to help understand the dough belt folding structure, the dough belt folding device and the core concept thereof of the present invention; meanwhile, for a person skilled in the art, according to the idea of the present invention, there may be variations in the specific embodiments and the application scope, and in summary, the content of the present specification should not be construed as a limitation to the present invention.

Claims (12)

1. A kind of surface area turns over the structure, characterized by comprising:

the conveying belt is used for conveying a dough belt, and the dough belt comprises a dough belt turning part and a dough belt tiling part which are arranged in parallel along the width direction of the conveying belt;

the conveying belt can move relative to the turner, a guide surface and a turning surface are sequentially arranged on one side of the turner along the conveying direction of the dough belt, the front end of the guide surface is abutted to the surface of the conveying belt on which the dough belt is placed, the guide surface is used for guiding the dough belt turning part to move to the turning surface, and the turning surface is used for guiding the dough belt turning part to be turned and folded on the dough belt laying part;

supplementary climbing piece, supplementary climbing piece with the guiding surface is relative and the interval sets up, face area turns over a part and can follow supplementary climbing piece with pass between the guiding surface, supplementary climbing piece be used for with face area turns over a part and is to being close to the direction extrusion of guiding surface.

2. The noodle strip folding structure according to claim 1, wherein the auxiliary climbing member is a roller, an axial direction of the roller is perpendicular to a conveying direction of the noodle strip, and a surface of the roller for pressing the folded portion of the noodle strip is parallel to the guide surface.

3. The noodle folding structure of claim 2, wherein the roller is a drum roller, and the diameter of the drum roller is gradually reduced from the middle to both ends.

4. The webbing folding structure according to any one of claims 1 to 3, further comprising a lifting member disposed opposite to and spaced apart from the folding surface, wherein the webbing folding portion can pass through between the lifting member and the folding surface, and the lifting member is configured to support the webbing folding portion in a direction close to the folding surface so as to prevent the webbing folding portion from slipping off.

5. The webbing fold over structure of claim 4, wherein the surface of the lifting member for supporting the webbing fold over portion is a first curved surface, the first curved surface is convex in a direction of the fold over surface, and the fold over surface is a concave curved surface.

6. The noodle turn-over structure of claim 5, wherein a distance between the first curved face and the noodle flat portion in a conveying direction of the noodle is gradually reduced.

7. The noodle turnover structure of claim 6, further comprising a support frame, wherein the conveyor belt is positioned on the support frame and the conveyor belt is movable relative to the support frame;

follow on the support frame the direction of transmission in face area has set gradually first installation pole and second installation pole, first installation pole with second installation pole all span in the top of conveyer belt, just first installation pole is close to the folded surface sets up, second installation pole is close to the spigot surface sets up, lift the piece with first installation pole is connected, supplementary climbing spare with the second installation pole is connected.

8. The noodle folding structure according to claim 7, wherein the lifting member is slidably connected to the first mounting bar in a width direction of the conveyor belt, and the auxiliary climbing member is slidably connected to the second mounting bar in the width direction of the conveyor belt.

9. The noodle folding structure according to claim 8, wherein a first connecting assembly is slidably sleeved on the first mounting rod, a connecting end of the first connecting assembly is fixedly connected with the lifting piece, and an adjusting end of the first connecting assembly is slidably sleeved on the first mounting rod;

the sliding sleeve is equipped with second coupling assembling on the second installation pole, second coupling assembling's link with supplementary climbing piece fixed connection, second coupling assembling's regulation end sliding sleeve is located on the second installation pole.

10. The noodle folding structure according to claim 9, wherein the first mounting rod is further provided with a first fastening member, the adjusting end of the first connecting assembly is provided with a first threaded hole, the first fastening member is in threaded connection with the first threaded hole, and the first fastening member passes through the first threaded hole and can abut against the outer peripheral wall of the first mounting rod;

still be provided with the second fastener on the second installation pole, second screw hole has been seted up to the regulation end of second coupling assembling, the second fastener with second screw hole threaded connection, the second fastener passes the second screw hole can with the periphery wall butt of second installation pole.

11. The structure of claim 10, wherein the first connecting assembly includes a first connecting rod, a first connecting block, and a third fastening member, one end of the first connecting rod is fixedly connected to the lifting member, the other end of the first connecting rod is slidably disposed on the first connecting block along a vertical direction, a third threaded hole is disposed on the first connecting block, the third fastening member is threadedly connected to the third threaded hole, the third fastening member passes through the third threaded hole and can abut against an outer peripheral wall of the first connecting rod, the first threaded hole is disposed on the first connecting block, and the first connecting block is further slidably sleeved on the first mounting rod;

the second connecting assembly comprises a second connecting rod, a second connecting block and a fourth fastener, one end of the second connecting rod is fixedly connected with the auxiliary climbing piece, the other end of the second connecting rod is along the transmission direction of the surface belt in a sliding and penetrating mode, a fourth threaded hole is formed in the second connecting block, the fourth fastener is in threaded connection with the fourth threaded hole, the fourth fastener penetrates through the fourth threaded hole and can be abutted to the outer peripheral wall of the second connecting rod, the second threaded hole is located in the second connecting block, and the second connecting block is further sleeved with the second mounting rod in a sliding mode.

12. A noodle folding apparatus comprising the noodle folding structure according to any one of claims 1 to 11.

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