CN112868698A - Continuous core pouring device for slicing and closing sandwich bread - Google Patents

Abstract

The invention relates to the field of bread processing, in particular to a core-filling device without separating sandwich bread slices, gathering and closing. The technical problems of the invention are as follows: provides a core-filling device which is continuously separated from the sandwich bread slices and is close to the core. The technical scheme is as follows: a continuous separation sandwich bread slicing, gathering and core-filling device comprises a bottom frame, a conveyor belt, a continuous separation height limiting system, a slicing and opening supporting system, a filling system and a control screen; the bottom frame is connected with the conveying belt; the underframe is connected with the disconnection height limiting system; the bottom frame is fixedly connected with the control screen. The invention can adjust according to the connection length between toast slices, simultaneously slice toast, and continuously open the core, and can also compress slices by matching inertia after core injection; the whole toast is neat and beautiful after being sliced, the packaging is convenient, and the processing efficiency is higher; the phenomenon of overflow adhesion is not easy to occur after the packaging tape is packaged.

Description

Continuous core pouring device for slicing and closing sandwich bread

Technical Field

The invention relates to the field of bread processing, in particular to a core-filling device without separating sandwich bread slices, gathering and closing.

Background

In general, we refer to bread, most of which think of European and American bread or Japanese stuffed bread, sweet bread, etc. In fact, there are many specific types of bread in the world. The raw materials for making bread widely used in the world include buckwheat flour, brown rice flour, corn flour, etc. in addition to rye flour and wheat flour. Some bread is fermented by yeast and becomes more fluffy and soft in the baking process; there are also many breads, on the contrary, that do not require fermentation. Although the raw materials and the manufacturing process are different, they are all called bread;

bread is also called artificial fruit, and has various varieties and flavors;

the toast with the sandwich is characterized in that when the sandwich toast is processed and produced, the sandwich is filled between two toasts in order to increase the taste of the toast, but the toast is a whole piece and is sliced into a plurality of small pieces for independent core injection, equipment is required to continuously and independently turn over the cores and cover the cores, a plurality of sandwich toasts are inconvenient to place when being integrally packaged, and meanwhile, the sandwich overflows and is mutually adhered due to the fact that the sandwich between the toast and the toast moves in a staggered mode during transportation and transfer, so that the packaging bag is adhered, and the toast is often torn and cannot be completely taken out when being eaten and taken out; affecting the eating experience.

In view of the above, there is a need for a device that will overcome the above problems without breaking the sandwich of the bread slices and without breaking the slices to the core.

Disclosure of Invention

In order to overcome the defects that when the sandwich toast is processed and produced, in order to increase the taste of the toast, a sandwich is injected between two toasts, but the toast is a whole piece and is sliced into a plurality of small pieces for independent core injection, the equipment needs to continuously and independently turn over the core injection and cover the surface, and the plurality of sandwich toasts are inconvenient to place when being integrally packaged, and meanwhile, the sandwich overflows and is adhered to each other due to the fact that the sandwich toasts can move in a staggered mode during transportation and transportation, so that the packaging bag is adhered, and the toast is often torn and cannot be completely taken out when being eaten and taken out; the invention has the defects of influencing the eating experience, and the technical problems of the invention are as follows: provides a core-filling device which is continuously separated from the sandwich bread slices and is close to the core.

The technical scheme is as follows: a continuous separation sandwich bread slicing, gathering and core-filling device comprises a bottom frame, a conveyor belt, a continuous separation height limiting system, a slicing and opening supporting system, a filling system and a control screen; the bottom frame is connected with the conveying belt; the underframe is connected with the disconnection height limiting system; the underframe is fixedly connected with the control screen; the conveyor belt is connected with the disconnection height limiting system; the disconnection height limiting system is connected with the slice opening supporting system; the slice opening supporting system is connected with the filling system; the slice opening supporting system and the filling system are both positioned above the conveying belt.

The disconnection height limiting system comprises a motor, a linear guide rail, a first gear, a first bevel gear, a second gear, a first supporting rod, a first driving wheel, a second bevel gear, a first driving rod, a third bevel gear, a fourth bevel gear, a first supporting frame, a first bidirectional screw rod, a first sliding sleeve, a first sliding block, a first connecting rod, a first limiting block, a first height limiting plate, a second sliding sleeve, a second sliding block, a second connecting rod, a second limiting block, a fifth bevel gear, a sixth bevel gear, a second bidirectional screw rod, a third sliding sleeve, a third sliding block, a third connecting rod, a third limiting block, a second height limiting plate, a fourth sliding sleeve, a fourth sliding block, a fourth connecting rod and a fourth limiting block; the motor is fixedly connected with the linear guide rail; the linear guide rail is fixedly connected with the underframe; the output shaft of the motor is fixedly connected with the first gear and the first bevel gear at the same time; a second gear is arranged on the side surface of the first gear; the first supporting rod is simultaneously in rotating connection with the second gear and the first driving wheel through a rotating shaft; the first supporting rod is fixedly connected with the underframe; a second bevel gear is arranged on the side surface of the first bevel gear; when the first gear is meshed with the second gear, the second gear rotates, and the first bevel gear idles; when the first bevel gear is meshed with the second bevel gear, the second bevel gear rotates, and the first bevel gear idles; when the first gear and the first bevel gear are not meshed with the second gear and the second bevel gear respectively, the second gear and the second bevel gear do not rotate; the outer surface of the first transmission rod is rotationally connected with the first support frame; the outer surface of the first transmission rod is fixedly connected with a second bevel gear, a third bevel gear and a sixth bevel gear in sequence; the third bevel gear is meshed with the fourth bevel gear; the axis of the fourth bevel gear is fixedly connected with the first bidirectional screw rod; the outer surface of the first bidirectional screw rod is rotationally connected with the first support frame; one side of the outer surface of the first support frame is in screwed connection with the first sliding sleeve; the other side of the outer surface of the first support frame is in screwed connection with the second sliding sleeve; the first sliding sleeve is rotatably connected with the first sliding block through a rotating shaft; the interior of the first sliding block is in sliding connection with the first connecting rod; the first connecting rod is rotatably connected with the first limiting block through a rotating shaft; the first limiting block is in sliding connection with one side of the first height limiting plate; the first height limiting plate is connected with the first support frame in a sliding mode; the second sliding sleeve is rotatably connected with the second sliding block through a rotating shaft; the inner part of the second sliding block is in sliding connection with the second connecting rod; the second connecting rod is rotatably connected with the second limiting block through a rotating shaft; the second limiting block is connected with the other side of the first height limiting plate in a sliding mode; the first connecting rod and the second connecting rod are far away from one side of the first height limiting plate and are simultaneously in rotating connection with the first support frame through a rotating shaft; the fifth bevel gear is meshed with the sixth bevel gear; the axis of the sixth bevel gear is fixedly connected with a second bidirectional screw rod; the outer surface of the second bidirectional screw rod is rotationally connected with the first support frame; one side of the outer surface of the second bidirectional screw rod is in screwed connection with the third sliding sleeve; the other side of the outer surface of the second bidirectional screw rod is in screwed connection with the fourth sliding sleeve; the third sliding sleeve is rotatably connected with the third sliding block through a rotating shaft; the inside of the third sliding block is in sliding connection with a third connecting rod; the third connecting rod is rotatably connected with the third limiting block through a rotating shaft; the third limiting block is in sliding connection with one side of the second height limiting plate; the second height limiting plate is connected with the first support frame in a sliding manner; the fourth sliding sleeve is rotatably connected with the fourth sliding block through a rotating shaft; the inner part of the fourth sliding block is in sliding connection with the fourth connecting rod; the fourth connecting rod is rotatably connected with the fourth limiting block through a rotating shaft; the fourth limiting block is in sliding connection with the other side of the second height limiting plate; the first support frame is fixedly connected with the underframe; the first support frame is positioned in the conveying belt; the first supporting frame is connected with the slicing opening supporting system.

The slicing opening supporting system comprises a second supporting frame, a second driving wheel, a third gear, a third driving wheel, a fourth gear, a fourth driving wheel, a fifth gear, a fifth driving wheel, a sixth gear, a seventh gear, a third bidirectional screw rod, a first slide rail frame, a fifth slide sleeve, a fifth slide block, a fifth connecting rod, a first T-shaped slide sleeve, a sixth slide block, a sixth connecting rod, a first cutter, a second slide rail frame, an eighth gear, a fourth bidirectional screw rod, a seventh slide sleeve, a seventh slide block, a seventh connecting rod, a second T-shaped slide sleeve, an eighth slide block and an eighth connecting rod; the second support frame is simultaneously in rotating connection with the second driving wheel and the third gear through a rotating shaft; the second support frame is simultaneously in rotating connection with the third driving wheel and the fourth gear through a rotating shaft; the second support frame is simultaneously in rotating connection with the fourth transmission wheel and the fifth gear through a rotating shaft; the second support frame is simultaneously in rotating connection with the fifth driving wheel and the sixth gear through a rotating shaft; the outer ring surface of the second driving wheel is in transmission connection with a third driving wheel through a belt; the outer ring surface of the second driving wheel is in transmission connection with a fourth driving wheel through a belt; the outer ring surface of the fourth driving wheel is in transmission connection with the fifth driving wheel through a belt; the second support frame is fixedly connected with the first support frame; the outer ring surface of the second driving wheel is in transmission connection with the first driving wheel through a belt; the second support frame is connected with the filling system; a first slide rail frame is arranged on one side in the second support frame; a second slide rail frame is arranged on the other side in the second support frame; the first slide rail frame is connected with the filling system; the second slide rail frame is connected with the filling system; the first slide rail frame is rotationally connected with the third bidirectional screw rod; the third bidirectional screw rod is fixedly connected with the seventh gear; one side of the outer surface of the third bidirectional screw rod is in screwed connection with the fifth sliding sleeve; the other side of the outer surface of the third bidirectional screw rod is in screwed connection with a sixth sliding sleeve; the fifth sliding sleeve is rotatably connected with the fifth sliding block through a rotating shaft; the interior of the fifth sliding block is in sliding connection with a fifth connecting rod; the fifth connecting rod is rotatably connected with one side of the first T-shaped sliding sleeve; the sixth sliding sleeve is rotatably connected with the sixth sliding block through a rotating shaft; the inner part of the sixth sliding block is in sliding connection with the sixth connecting rod; the sixth connecting rod is rotatably connected with the other side of the first T-shaped sliding sleeve; the first T-shaped sliding sleeve is in sliding connection with the first sliding rail frame; the sixth connecting rod is rotatably connected with one side of the first cutter; the fifth connecting rod is rotatably connected with one side of the second cutter; the first slide rail frame is in sliding connection with one side of the first cutter; the first slide rail frame is in sliding connection with one side of the second cutter; the other side of the first cutter is in sliding connection with the second sliding rail frame; the other side of the second cutter is in sliding connection with a second sliding rail frame; the other side of the first cutter is rotationally connected with a seventh connecting rod; the other side of the second cutter is rotationally connected with an eighth connecting rod; the second slide rail frame is rotationally connected with the fourth bidirectional screw rod; the fourth bidirectional screw rod is fixedly connected with the eighth gear; one side of the outer surface of the fourth bidirectional screw rod is in screwed connection with the seventh sliding sleeve; the other side of the outer surface of the fourth bidirectional screw rod is in screwed connection with the eighth sliding sleeve; the seventh sliding sleeve is rotatably connected with the seventh sliding block through a rotating shaft; the inside of the seventh sliding block is in sliding connection with the seventh connecting rod; the seventh connecting rod is rotatably connected with one side of the second T-shaped sliding sleeve; the eighth sliding sleeve is rotatably connected with the eighth sliding block through a rotating shaft; the inner part of the eighth sliding block is in sliding connection with the eighth connecting rod; the eighth connecting rod is rotatably connected with the other side of the second T-shaped sliding sleeve; the second T-shaped sliding sleeve is in sliding connection with the second sliding rail frame; when the seventh gear and the eighth gear are simultaneously meshed with the third gear and the fifth gear respectively, the seventh gear and the eighth gear rotate simultaneously, and the fourth gear and the sixth gear idle at the moment; when the seventh gear and the eighth gear are simultaneously meshed with the fourth gear and the sixth gear respectively, the seventh gear and the eighth gear rotate simultaneously, and the third gear and the fifth gear idle at the moment; when the seventh gear and the eighth gear are not meshed with the third gear, the fifth gear, the fourth gear and the sixth gear, the seventh gear and the eighth gear are not rotated.

The filling system comprises a connecting frame, a toothed bar, a ninth gear, a sixth driving wheel, a seventh driving wheel, a supporting sliding frame, a first cylinder, a second cylinder, a one-way screw rod, a sliding plate, a J-shaped rod, an injection hopper, a connecting pipe, a first spring rod, a first inclined rod, a transverse plate, a second inclined rod and a second spring rod; the connecting frame is fixedly connected with the toothed bar; the connecting frame is fixedly connected with the second supporting frame; the toothed bar is meshed with the ninth gear; the toothed bar is fixedly connected with the second support frame; the axis of the ninth gear is fixedly connected with the sixth driving wheel through a rotating shaft; the axis of the sixth driving wheel is rotationally connected with the supporting sliding frame through a rotating shaft; the outer ring surface of the sixth driving wheel is in transmission connection with the seventh driving wheel through a belt; the axle center of the seventh driving wheel is fixedly connected with the one-way screw rod; the one-way screw rod is rotatably connected with the supporting sliding frame; one side above the supporting sliding frame is fixedly connected with the first cylinder; the other side above the supporting sliding frame is fixedly connected with a second cylinder; the first cylinder is fixedly connected with the second support frame; the second cylinder is fixedly connected with the second support frame; the support sliding frame is connected with the sliding plate in a sliding way; one side of the support sliding frame is fixedly connected with the first sliding rail frame; the other side of the support sliding frame is fixedly connected with a second sliding rail frame; the sliding plate is connected with the one-way screw rod in a rotating mode; one side inside the supporting sliding frame is connected with the first spring rod in a sliding mode; the other side in the supporting sliding frame is connected with a second spring rod in a sliding manner; the first spring rod is fixedly connected with the first inclined rod; the outer surface of the first inclined rod is in sliding connection with the sliding plate; the second spring rod is fixedly connected with the second inclined rod; the outer surface of the second inclined rod is in sliding connection with the sliding plate; the first spring rod and the first inclined rod are fixedly connected with one side of the transverse plate; the second spring rod and the second inclined rod are fixedly connected with the other side of the transverse plate; the sliding plate is fixedly connected with the three J-shaped rods at equal intervals; the three J-shaped rods are rotatably connected with the injection hopper; the side of the injection hopper is inserted with four connecting pipes at equal intervals.

The upper parts of the first cutter and the second cutter incline towards the opposite direction, and two sides of the first cutter and the second cutter are respectively connected with two round pins.

The three J-shaped rods are all in a bent L shape.

The first diagonal rod and the second diagonal rod are inclined relative to the transverse plate.

An inverted J-shaped sliding groove and a straight sliding groove are symmetrically arranged in the first sliding rail frame and the second sliding rail frame.

The invention has the following advantages: (1) the method comprises the following steps of filling a filling between two toasts for increasing the taste of the toast during the processing and production of the sandwich toast, wherein the toast is a whole piece and is sliced into a plurality of small pieces for independent core injection, the equipment is required to continuously and independently turn over the filling and cover the filling, the plurality of sandwich toasts are inconvenient to place during integral packaging, and meanwhile, the filling between the toasts overflows and is adhered to each other due to the fact that the sandwich toasts can move in a staggered mode during transportation and transportation, so that the packaging bag is adhered to the filling, and the toasts are often torn and cannot be completely taken out when the toasts are eaten and taken out; the problem of influencing the eating experience.

(2) When in use, the whole toast to be cut is placed on the conveyer belt in line; the conveyor belt keeps a certain angle of forward inclination, then the conveyor belt drives the toast to move below the continuous-off height limiting system, the continuous-off height limiting system is adjusted according to the connection length between toast slices to be reserved, then the toast is sliced by the filling system in a linkage mode with the slice opening supporting system, the toast is opened by the continuous-off height limiting system in a linkage mode with the slice opening supporting system after slicing, meanwhile, the filling system is matched for core injection, the slice opening supporting system is used for supporting the toast during core injection, the core injection is slowly matched with the rising after cutting, and after the core injection is finished, the conveyor belt keeps a certain angle of forward inclination, so that the toast to be cut by the conveyor belt can tightly press the core due to inertia, slices of the toast cannot be misplaced, and can be kept attached.

(3) The invention can adjust according to the connection length between toast slices, simultaneously slice toast, and continuously open the core, and can also compress slices by matching inertia after core injection; the whole toast is neat and beautiful after being sliced, the packaging is convenient, and the processing efficiency is higher; the phenomenon of overflow adhesion is not easy to occur after the packaging tape is packaged.

Drawings

FIG. 1 is a schematic perspective view of a first embodiment of the present invention;

FIG. 2 is a schematic perspective view of a second embodiment of the present invention;

FIG. 3 is a third perspective view of the present invention;

FIG. 4 is a schematic perspective view of a first embodiment of the disconnection height limiting system of the present invention;

FIG. 5 is a schematic perspective view of a second embodiment of the disconnection height limiting system of the present invention;

FIG. 6 is a schematic diagram of a third perspective view of the disconnect height limiting system of the present invention;

FIG. 7 is an enlarged view of the area S of the present invention;

FIG. 8 is a schematic view of a first three-dimensional structure of the slice opening support system of the present invention;

FIG. 9 is a schematic diagram of a second embodiment of the slice opening system of the present invention;

FIG. 10 is a schematic view of a third embodiment of the slice stenting system of the present invention;

FIG. 11 is a schematic perspective view of a first embodiment of the filling system of the present invention;

FIG. 12 is a schematic diagram of a second embodiment of the filling system of the present invention;

FIG. 13 is a schematic view of a third embodiment of the filling system of the present invention;

fig. 14 is a perspective view of the first spring rod, the first inclined rod, the cross plate, the second inclined rod and the second spring rod according to the present invention.

The meaning of the reference symbols in the figures: 1: chassis, 2: conveyor belt, 3: disconnection height limiting system, 4: slice opening system, 5: filling system, 6: control screen, 301: motor, 302: linear guide, 303: first gear, 304: first bevel gear, 305: second gear, 306: first support bar, 307: first drive wheel, 308: second bevel gear, 309: first drive lever, 3010: third bevel gear, 3011: fourth bevel gear, 3012: first support bracket, 3013: first bidirectional screw, 3014: first runner, 3015: first slider, 3016: first link, 3017: first stopper, 3018: first height limiting plate, 3019: second runner, 3020: second slider, 3021: second link, 3022: second stopper, 3023: fifth bevel gear, 3024: sixth bevel gear, 3025: second bidirectional screw rod, 3026: third runner, 3027: third slider, 3028: third link, 3029: third stopper, 3030: second height limiting plate, 3031: fourth runner, 3032: fourth slider, 3033: fourth link, 3034: a fourth stopper, 401: second support bracket, 402: second drive wheel, 403: third gear, 404: third transmission wheel, 405: fourth gear, 406: fourth transmission wheel, 407: fifth gear, 408: fifth transmission wheel, 409: sixth gear, 4010: seventh gear, 4011: third bidirectional screw, 4012: first rail mount, 4013: fifth slip sleeve, 4014: fifth slider, 4015: fifth link, 4016: first T-shaped sliding sleeve, 4017: sixth sliding sleeve, 4018: sixth slider, 4019: sixth link, 4020: first cutter, 4021: second cutter, 4022: second slide rail bracket, 4023: eighth gear, 4024: fourth bidirectional screw, 4025: seventh sliding sleeve, 4026: seventh slider, 4027: seventh link, 4028: second T-shaped sliding sleeve, 4029: eighth runner, 4030: eighth slider, 4031: eighth link, 501: connecting frame, 502: rack bar, 503: ninth gear, 504: sixth transmission wheel, 505: seventh transmission wheel, 506: support carriage, 507: first cylinder, 508: second cylinder, 509: one-way lead screw, 5010: slide plate, 5011: j-bar, 5012: injection hopper, 5013: connecting pipe, 5014: first spring bar, 5015: first diagonal, 5016: transverse plate, 5017: second diagonal, 5018: a second spring bar.

Detailed Description

Reference herein to an embodiment means that a particular feature, structure, or characteristic described in connection with the embodiment can be included in at least one embodiment of the invention. The appearances of the phrase in various places in the specification are not necessarily all referring to the same embodiment, nor are separate or alternative embodiments mutually exclusive of other embodiments. It is explicitly and implicitly understood by one skilled in the art that the embodiments described herein can be combined with other embodiments.

Example 1

A continuous separating sandwich bread slicing and closing core-filling device is shown in figures 1-14 and comprises a bottom frame 1, a conveyor belt 2, a continuous cutting height limiting system 3, a slicing opening supporting system 4, a filling system 5 and a control screen 6; the chassis 1 is connected with the conveyor belt 2; the underframe 1 is connected with the disconnection height limiting system 3; the underframe 1 is fixedly connected with the control screen 6; the conveyor belt 2 is connected with the disconnection height limiting system 3; the disconnection height limiting system 3 is connected with the slice opening supporting system 4; the slice opening system 4 is connected with the filling system 5; the slice opening system 4 and the filling system 5 are both located above the conveyor belt 2.

When the device is used, the device is moved to a processing table of a processing plant, then the bottom frame 1 is horizontally and fixedly installed, then an external power supply is connected, the control screen 6 starts the device to operate, and the whole toasts to be cut are arranged on the conveyor belt 2; the conveyor belt 2 keeps a certain angle of forward inclination, then the conveyor belt drives the toast to move below the continuous cut-off height limiting system 3, the continuous cut-off height limiting system 3 is adjusted according to the connection length between toast slices to be reserved, then the toast is sliced by the linkage of the filling system 5 and the slice opening supporting system 4, the toast is spread by the linkage of the continuous cut-off height limiting system 3 and the slice opening supporting system 4 after slicing, the filling system 5 is matched for core injection, the slice opening supporting system 4 is used for supporting the toast during core injection, the cut ascending slow core injection is matched, and after the core injection is finished, the conveyor belt 2 keeps a certain angle of forward inclination, so that the toast to be cut in the latter can be compressed by inertia, the slices of the toast cannot be dislocated, and the toast can be kept attached; the invention can adjust according to the connection length between toast slices, simultaneously slice toast, and continuously open the core, and can also compress slices by matching inertia after core injection; the whole toast is neat and beautiful after being sliced, the packaging is convenient, and the processing efficiency is higher; the phenomenon of overflow adhesion is not easy to occur after the packaging tape is packaged.

The disconnection height limiting system 3 comprises a motor 301, a linear guide rail 302, a first gear 303, a first bevel gear 304, a second gear 305, a first support rod 306, a first transmission wheel 307, a second bevel gear 308, a first transmission rod 309, a third bevel gear 3010, a fourth bevel gear 3011, a first support frame 3012, a first bidirectional screw rod 3013, a first sliding sleeve 3014, a first slider 3015, a first connecting rod 3016, a first limit block 3017, a first height limiting plate 3018, a second sliding sleeve 3019, a second slider 3020, a second connecting rod 3021, a second limit block 3022, a fifth bevel gear 3023, a sixth bevel gear 3024, a second bidirectional screw rod 3025, a third sliding sleeve 3026, a third slider 3027, a third connecting rod 3028, a third limit block 3029, a second height limiting plate 3030, a fourth sliding sleeve 3031, a fourth slider 3032, a fourth connecting rod 3033, and a fourth limit block 3034; the motor 301 is fixedly connected with the linear guide rail 302; the linear guide rail 302 is fixedly connected with the underframe 1; an output shaft of the motor 301 is fixedly connected with the first gear 303 and the first bevel gear 304; the first gear 303 is provided with a second gear 305 at the side; the first supporting rod 306 is simultaneously in rotation connection with the second gear 305 and the first driving wheel 307 through a rotating shaft; the first supporting rod 306 is fixedly connected with the underframe 1; a second bevel gear 308 is arranged on the side surface of the first bevel gear 304; when the first gear 303 is engaged with the second gear 305, the second gear 305 rotates, and the first bevel gear 304 idles; when the first bevel gear 304 is engaged with the second bevel gear 308, the second bevel gear 308 rotates, and the first gear 303 idles; when the first gear 303 and the first bevel gear 304 are not meshed with the second gear 305 and the second bevel gear 308, respectively, neither the second gear 305 nor the second bevel gear 308 rotates; the outer surface of the first transmission rod 309 is rotatably connected with the first support 3012; the outer surface of the first transmission rod 309 is fixedly connected with the second bevel gear 308, the third bevel gear 3010 and the sixth bevel gear 3024 in sequence; third bevel gear 3010 meshes with fourth bevel gear 3011; the axis of the fourth bevel gear 3011 is fixedly connected to the first bidirectional screw 3013; the outer surface of the first bidirectional screw rod 3013 is rotatably connected with the first support 3012; one side of the outer surface of the first support 3012 is screwed with the first sliding sleeve 3014; the other side of the outer surface of the first support 3012 is screwed with the second sliding sleeve 3019; the first sliding sleeve 3014 is rotatably connected to the first sliding block 3015 through a rotating shaft; the inside of the first slider 3015 is connected to the first link 3016 in a sliding manner; the first link 3016 is rotatably connected to the first stopper 3017 through a rotating shaft; the first limiting block 3017 is connected with one side of the first height limiting plate 3018 in a sliding manner; the first height limiting plate 3018 is connected with the first support 3012 in a sliding manner; the second sliding sleeve 3019 is rotatably connected with the second sliding block 3020 through a rotating shaft; the inside of the second slider 3020 is slidably connected to the second link 3021; the second connecting rod 3021 is rotatably connected with the second limiting block 3022 through a rotating shaft; the second limiting block 3022 is slidably connected to the other side of the first height limiting plate 3018; the first connecting rod 3016 and the second connecting rod 3021 are far away from the first height limiting plate 3018 and are connected with the first support 3012 through a rotating shaft; the fifth bevel gear 3023 meshes with the sixth bevel gear 3024; the axis of the sixth bevel gear 3024 is fixedly connected with the second bidirectional screw rod 3025; the outer surface of the second bidirectional screw rod 3025 is rotatably connected with the first support 3012; one side of the outer surface of the second bidirectional screw rod 3025 is screwed with the third sliding sleeve 3026; the other side of the outer surface of the second bidirectional screw rod 3025 is screwed with the fourth sliding sleeve 3031; the third sliding sleeve 3026 is rotatably connected with the third sliding block 3027 through a rotating shaft; the inside of the third slider 3027 is slidably connected to a third link 3028; the third connecting rod 3028 is rotatably connected with the third limiting block 3029 through a rotating shaft; the third limiting block 3029 is slidably connected with one side of the second limiting plate 3030; the second height limiting plate 3030 is in sliding connection with the first support frame 3012; the fourth sliding sleeve 3031 is rotatably connected with the fourth sliding block 3032 through a rotating shaft; the inside of the fourth slider 3032 is connected with a fourth connecting rod 3033 in a sliding way; the fourth connecting rod 3033 is rotatably connected with the fourth limiting block 3034 through a rotating shaft; the fourth limiting block 3034 is in sliding connection with the other side of the second height limiting plate 3030; the first support 3012 is fixedly connected with the underframe 1; the first support 3012 is located within the conveyor 2; the first support 3012 is connected to a slice port system 4.

According to the connection length between toast slices to be reserved, the motor 301 is controlled to drive the first gear 303 and the first bevel gear 304 to rotate simultaneously, then the motor 301 is driven to drive the first gear 303 and the first bevel gear 304 to slide simultaneously under the drive of the linear guide rail 302, the first bevel gear 304 is meshed with the second bevel gear 308, the second bevel gear 308 drives the first transmission rod 309 to drive the third bevel gear 3010 and the fifth bevel gear 3023 to rotate simultaneously, the third bevel gear 3010 is meshed with the fourth bevel gear 3011 to drive the first bidirectional screw 3013 on the first support 3012 to rotate, the first bidirectional screw 3013 is driven to move by the first sliding bush 3014 and the second sliding bush 3019, the first sliding bush 3014 moves to drive the first connecting rod 3016 in the first sliding block 3015 to swing on the first support 3012 at a fixed point, the first limiting block 3017 connected to the other side driven by the fixed point during swinging slides on the first limiting plate 3018, and at the same time the second sliding bush 3019 moves to drive the second connecting rod 3021 in the second sliding block 3020 to swing on the first supporting frame 3012 at a first supporting point When the toast rack swings, the second limiting block 3022 connected to the other side of the fixed point is driven to slide on the first height limiting plate 3018, when the first limiting block 3017 and the second limiting block 3022 slide in the opposite direction, the first height limiting plate 3018 is lifted up in the first support 3012, and the lifting height is adjusted according to the connection length between toast pieces to be reserved; at the moment, the fifth bevel gear 3023 engages with the sixth bevel gear 3024 to drive the second two-way screw rod 3025 on the first support 3012 to rotate, the second two-way screw rod 3025 is driven by the third sliding sleeve 3026 and the fourth sliding sleeve 3031 to move, the third sliding sleeve 3026 moves to drive the third connecting rod 3028 in the third sliding block 3027 to swing at a fixed point on the first support 3012, and during the swing, the third limiting block 3029 connected to the other side of the fixed point is driven to slide on the second height limiting plate 3030, meanwhile, the fourth sliding sleeve 3031 moves to drive a fourth connecting rod 3033 in a fourth sliding block 3032 to swing at a fixed point on the first support frame 3012, a fourth limiting block 3034 connected to the other side of the fixed point is driven to slide on the second height limiting plate 3030 during swinging, the second height limiting plate 3030 is lifted in the first support frame 3012 when the third limiting block 3029 and the fourth limiting block 3034 slide oppositely, and the lifting height is adjusted according to the connection length between toast sheets to be reserved; the first height limiting plate 3018 and the second height limiting plate 3030 keep the same height, so that the breaking length of toast after slicing is kept consistent; when the slice supporting port system 4 needs to be linked, the motor 301 drives the first gear 303 and the first bevel gear 304 to slide simultaneously under the driving of the linear guide rail 302, so that the first gear 303 is meshed with the second gear 305 to drive the first driving wheel 307 on the first supporting rod 306 to drive the second driving wheel 402; the system realizes the adjustment, matching and limiting of the connection length between toast slices reserved for toast, and can be linked with the operation of the slice opening supporting system 4.

The slicing and opening system 4 comprises a second support frame 401, a second transmission wheel 402, a third gear 403, a third transmission wheel 404, a fourth gear 405, a fourth transmission wheel 406, a fifth gear 407, a fifth transmission wheel 408, a sixth gear 409, a seventh gear 4010, a third bidirectional screw 4011, a first slide rail bracket 4012, a fifth slide sleeve 4013, a fifth slide block 4014, a fifth connecting rod 4015, a first T-shaped sliding sleeve 4016, a sixth sliding sleeve 4017, a sixth sliding block 4018, a sixth connecting rod 4019, a first cutter 4020, a second cutter 4021, a second slide rail bracket 4022, an eighth gear 4023, a fourth bidirectional screw 4024, a seventh sliding sleeve 4025, a seventh sliding block 4026, a seventh connecting rod 4027, a second T-shaped sliding sleeve 4028, an eighth sliding sleeve 4029, an eighth sliding block 4030 and an eighth connecting rod 4031; the second support frame 401 is simultaneously in rotating connection with a second driving wheel 402 and a third gear 403 through a rotating shaft; the second support frame 401 is simultaneously in rotating connection with a third driving wheel 404 and a fourth gear 405 through a rotating shaft; the second support frame 401 is simultaneously in rotating connection with a fourth driving wheel 406 and a fifth gear 407 through a rotating shaft; the second support frame 401 is simultaneously in rotating connection with a fifth driving wheel 408 and a sixth gear 409 through a rotating shaft; the outer annular surface of the second driving wheel 402 is in transmission connection with a third driving wheel 404 through a belt; the outer annular surface of the second transmission wheel 402 is in transmission connection with a fourth transmission wheel 406 through a belt; the outer annular surface of the fourth driving wheel 406 is in transmission connection with a fifth driving wheel 408 through a belt; the second support frame 401 is fixedly connected with the first support frame 3012; the outer annular surface of the second transmission wheel 402 is in transmission connection with the first transmission wheel 307 through a belt; the second support 401 is connected with the filling system 5; a first slide rail frame 4012 is arranged on one side inside the second support frame 401; a second slide rail bracket 4022 is arranged on the other side in the second support frame 401; the first slide rail frame 4012 is connected with a filling system 5; the second slide rail bracket 4022 is connected with the filling system 5; the first slide rail frame 4012 is rotatably connected with a third bidirectional screw 4011; the third bidirectional screw 4011 is fixedly connected with a seventh gear 4010; one side of the outer surface of the third bidirectional screw 4011 is rotatably connected with a fifth sliding sleeve 4013; the other side of the outer surface of the third bidirectional screw 4011 is in screwed connection with a sixth sliding sleeve 4017; the fifth sliding sleeve 4013 is rotatably connected with the fifth sliding block 4014 through a rotating shaft; the interior of the fifth slide block 4014 is in sliding connection with a fifth connecting rod 4015; the fifth connecting rod 4015 is rotatably connected with one side of the first T-shaped sliding sleeve 4016; the sixth sliding sleeve 4017 is rotatably connected with the sixth sliding block 4018 through a rotating shaft; the inside of the sixth slide block 4018 is connected with a sixth connecting rod 4019 in a sliding manner; the sixth connecting rod 4019 is rotatably connected with the other side of the first T-shaped sliding sleeve 4016; the first T-shaped sliding sleeve 4016 is in sliding connection with the first sliding rail frame 4012; the sixth connecting rod 4019 is rotatably connected with one side of the first cutter 4020; the fifth connecting rod 4015 is rotatably connected with one side of the second cutter 4021; the first slide rail frame 4012 is in sliding connection with one side of the first cutter 4020; the first slide rail frame 4012 is in sliding connection with one side of the second cutter 4021; the other side of the first cutter 4020 is in sliding connection with a second sliding rail frame 4022; the other side of the second cutter 4021 is in sliding connection with a second sliding rail frame 4022; the other side of the first cutter 4020 is rotationally connected with a seventh connecting rod 4027; the other side of the second cutter 4021 is rotatably connected with an eighth connecting rod 4031; the second slide rail bracket 4022 is rotationally connected with the fourth bidirectional screw 4024; the fourth bidirectional screw 4024 is fixedly connected with the eighth gear 4023; one side of the outer surface of the fourth bidirectional screw 4024 is in screwed connection with a seventh sliding sleeve 4025; the other side of the outer surface of the fourth bidirectional screw 4024 is in screwed connection with an eighth sliding sleeve 4029; the seventh sliding sleeve 4025 is rotatably connected with the seventh sliding block 4026 through a rotating shaft; the inside of the seventh slider 4026 is connected with a seventh connecting rod 4027 in a sliding manner; the seventh connecting rod 4027 is rotatably connected with one side of the second T-shaped sliding sleeve 4028; the eighth sliding sleeve 4029 is rotatably connected with the eighth sliding block 4030 through a rotating shaft; the inner part of the eighth sliding block 4030 is connected with an eighth connecting rod 4031 in a sliding manner; the eighth connecting rod 4031 is rotatably connected with the other side of the second T-shaped sliding sleeve 4028; the second T-shaped sliding sleeve 4028 is in sliding connection with the second sliding rail bracket 4022; when the seventh gear 4010 and the eighth gear 4023 are simultaneously engaged with the third gear 403 and the fifth gear 407, respectively, the seventh gear 4010 and the eighth gear 4023 are simultaneously rotated while the fourth gear 405 and the sixth gear 409 are idly rotated; when the seventh gear 4010 and the eighth gear 4023 are simultaneously engaged with the fourth gear 405 and the sixth gear 409, respectively, the seventh gear 4010 and the eighth gear 4023 are simultaneously rotated while the third gear 403 and the fifth gear 407 are idly rotated; when neither the seventh gear 4010 nor the eighth gear 4023 is engaged with the third gear 403, the fifth gear 407, the fourth gear 405, and the sixth gear 409, neither the seventh gear 4010 nor the eighth gear 4023 rotates.

During slicing, the filling system 5 connected with the second support frame 401 drives the components connected with the first slide rail frame 4012 and the second slide rail frame 4022 to descend; in the descending process, the first cutter 4020 and the second cutter 4021 descend in a closed and attached state to slice toast, the third gear 403 is meshed with the seventh gear 4010 in the continuous descending process, the fifth gear 407 is meshed with the eighth gear 4023, in the process, the first driving wheel 307 drives the second driving wheel 402, the seventh gear 4010 is driven to rotate, the third driving wheel 404 is driven to drive the fourth gear 405 to rotate, the fourth driving wheel 406 is driven to drive the fifth gear 407 to rotate, and the fourth driving wheel 406 drives the fifth driving wheel 408 to drive the sixth gear 409 to rotate; when the seventh gear 4010 rotates, the third bidirectional screw 4011 is driven to rotate, and the fifth sliding sleeve 4013 and the sixth sliding sleeve 4017 are driven to move relatively, when the fifth sliding sleeve 4013 moves, the fifth connecting rod 4015 in the fifth sliding block 4014 is driven to slide, and when the fifth sliding sleeve moves, one side of the second cutter 4021 is driven to slide in the two sliding grooves of the first sliding rail frame 4012; the sixth sliding sleeve 4017 drives a sixth connecting rod 4019 in the sixth sliding block 4018 to slide, and drives one side of a first cutter 4020 to slide in two sliding grooves of a first sliding rail frame 4012 when the belt moves; the fifth connecting rod 4015 and the sixth connecting rod 4019 slide simultaneously to make the first T-shaped sliding sleeve 4016 slide downwards in the first sliding rail frame 4012; meanwhile, the eighth gear 4023 drives the fourth bidirectional screw 4024 to rotate and simultaneously drive the seventh sliding sleeve 4025 and the eighth sliding sleeve 4029 to move relatively, the seventh sliding sleeve 4025 drives the seventh connecting rod 4027 in the seventh sliding block 4026 to slide when moving, and simultaneously drives the other side of the first cutting knife 4020 to slide in the two sliding grooves of the second sliding rail bracket 4022 when moving, the eighth sliding sleeve 4029 drives the eighth connecting rod 4031 in the eighth sliding block 4030 to slide, and simultaneously drives the other side of the second cutting knife 4021 to slide in the two sliding grooves of the second sliding rail bracket 4022 when moving, and the seventh connecting rod 4027 and the eighth connecting rod 4031 slide simultaneously to enable the second T-shaped sliding sleeve 4028 to slide downwards in the second sliding rail bracket 4022; when the first cutter 4020 and the second cutter 4021 slide to the bent arc part of the inverted J-shaped sliding chute in a translation manner, the first cutter 4020 and the second cutter 4021 can be turned over relatively, even if the first cutter 4020 and the second cutter 4021 are inverted splayed, sliced toasts can be spread, the filling system 5 is matched with the toasting core for core injection, the filling system 5 slowly ascends along with the ascending of the toasting core, and when the seventh gear 4010 is meshed with the fourth gear 405 and the eighth gear 4023 is meshed with the sixth gear 409, the first cutter 4020 and the second cutter 4021 are driven to gradually return to a cutter state; the system realizes slicing of toast, and meanwhile, the toast is matched with the slowly-rising and slowly-rising center of gravity which is kept in a spread shape from the inner bottom of the slice.

The filling system 5 comprises a connecting frame 501, a toothed bar 502, a ninth gear 503, a sixth transmission wheel 504, a seventh transmission wheel 505, a supporting sliding frame 506, a first air cylinder 507, a second air cylinder 508, a one-way screw 509, a sliding plate 5010, a J-shaped rod 5011, an injection bucket 5012, a connecting pipe 5013, a first spring rod 5014, a first inclined rod 5015, a transverse plate 5016, a second inclined rod 5017 and a second spring rod 5018; the connecting frame 501 is fixedly connected with the toothed bar 502; the connecting frame 501 is fixedly connected with the second support frame 401; the rack 502 meshes with a ninth gear 503; the rack 502 is fixedly connected with the second support frame 401; the axis of the ninth gear 503 is fixedly connected with the sixth driving wheel 504 through a rotating shaft; the axle center of the sixth driving wheel 504 is rotationally connected with the supporting sliding frame 506 through a rotating shaft; the outer annular surface of the sixth driving wheel 504 is in driving connection with a seventh driving wheel 505 through a belt; the axle center of the seventh driving wheel 505 is fixedly connected with the one-way screw 509; the one-way screw 509 is rotatably connected with the support carriage 506; one side above the supporting sliding frame 506 is fixedly connected with a first air cylinder 507; the other side above the supporting sliding frame 506 is fixedly connected with a second air cylinder 508; the first cylinder 507 is fixedly connected with the second support frame 401; the second cylinder 508 is fixedly connected with the second support frame 401; support carriage 506 is slidably connected to slide plate 5010; one side of the support sliding frame 506 is fixedly connected with a first sliding rail frame 4012; the other side of the support sliding frame 506 is fixedly connected with a second sliding rail frame 4022; the sliding plate 5010 is screwed with the one-way screw 509; one side of the interior of the support carriage 506 is slidably connected to the first spring post 5014; the other side of the interior of the support carriage 506 is slidably connected to a second spring post 5018; the first spring rod 5014 is fixedly connected with the first inclined rod 5015; the outer surface of the first inclined rod 5015 is in sliding connection with the sliding plate 5010; the second spring rod 5018 is fixedly connected with the second inclined rod 5017; the outer surface of the second inclined rod 5017 is in sliding connection with the sliding plate 5010; the first spring rod 5014 and the first inclined rod 5015 are fixedly connected with one side of the transverse plate 5016 at the same time; the second spring rod 5018 and the second inclined rod 5017 are fixedly connected with the other side of the transverse plate 5016 at the same time; the sliding plates 5010 are fixedly connected with the three J-shaped rods 5011 at equal intervals; the three J-shaped rods 5011 are all in rotational connection with the injection bucket 5012; the injection buckets 5012 are inserted into four connecting pipes 5013 at equal intervals from the side.

When the first slide rail frame 4012 and the second slide rail frame 4022 descend, the first air cylinder 507 and the second air cylinder 508 descend simultaneously to drive the support sliding frame 506 to drive the first slide rail frame 4012 and the second slide rail frame 4022 to descend simultaneously to cooperate to slice and expand toast; when the injection is performed, the supporting sliding frame 506 descends to drive the ninth gear 503 to be meshed with the toothed bar 502 on the connecting frame 501, the ninth gear 503 descends to cooperatively drive the sixth driving wheel 504 to drive the seventh driving wheel 505, the seventh driving wheel 505 drives the one-way lead screw 509 to rotate to drive the sliding plate 5010 to slide under the limit of the supporting sliding frame 506, the sliding plate 5010 can slide upwards in an inclined manner relative to the supporting sliding frame 506 during the sliding process due to the simultaneous limit of the first inclined rod 5015 connected with the first spring rod 5014 and the second inclined rod 5017 connected with the second spring rod 5018, the sliding plate 5010 can drive the plurality of J-shaped rods 5011 to be in contact with the transverse plate 5016, the plurality of J-shaped rods 5011 are overturned and downwards inclined to drive the injection bucket 5012 to downwards move to be matched with the injection under the limit of the transverse plate 5016, the injection is matched with the injection under the support of the first cutter 4020 and the second cutter 4021, and the connecting pipe 5013 is matched with the injection bucket 5012; this system has realized linkage section and has propped a mouthful system 4, and the cooperation is simultaneously annotated the heart.

The upper parts of the first cutter 4020 and the second cutter 4021 incline towards opposite directions, and two sides of the first cutter 4020 and the second cutter 4021 are respectively connected with two round pins.

The inclined surface can facilitate the flow guiding of the filling, and prevent the filling from overflowing to the surface of toast; meanwhile, round pins on two sides can be respectively contacted with the first slide rail frame 4012 and the second slide rail frame 4022, and when the round pins are matched to slide in the first slide rail frame 4012 and the second slide rail frame 4022, the round pins can drive the first cutter 4020 and the second cutter 4021 to be converted into an inclined shape by translation.

The three J-shaped rods 5011 are all in a bent L shape.

Can cooperate with the transverse plate 5016 to lower the transverse plate 5016 to drive the three J-bars 5011 to lower the associated injection bucket 5012.

The first inclined rod 5015 and the second inclined rod 5017 are both inclined relative to the transverse plate 5016.

The slide plate 5010 is slidably connected to the first and second sloped bars 5015 and 5017 at the same time when being driven to slide, and then ascends by the first and second sloped bars 5015 and 5017, and the slide plate 5010 drives the three J-shaped bars 5011 to be pressed against the connected injection bucket 5012 by the horizontal plate 5016 while ascending.

The first slide rail frame 4012 and the second slide rail frame 4022 are symmetrically provided with an inverted J-shaped sliding groove and a straight sliding groove.

The first cutter 4020 and the second cutter 4021 can be connected with round pins on two sides of the first cutter 4020 and the second cutter 4021 respectively, and the first cutter 4020 and the second cutter 4021 can be turned over relatively by an angle when the first cutter 4020 and the second cutter 4021 slide to the bent arc part of the inverted J-shaped sliding chute in a translation mode.

The embodiments described above are provided to enable persons skilled in the art to make or use the invention and that modifications or variations can be made to the embodiments described above by persons skilled in the art without departing from the inventive concept of the present invention, so that the scope of protection of the present invention is not limited by the embodiments described above but should be accorded the widest scope consistent with the innovative features set forth in the claims.

Claims (8)

1. A continuous separating sandwich bread slicing and closing core-filling device comprises a bottom frame (1) and a control screen (6), and is characterized by also comprising a conveying belt (2), a continuous cutting height limiting system (3), a slicing opening supporting system (4) and a filling system (5); the bottom frame (1) is connected with the conveyor belt (2); the underframe (1) is connected with the disconnection height limiting system (3); the underframe (1) is fixedly connected with the control screen (6); the conveyor belt (2) is connected with the disconnection height limiting system (3); the disconnection height limiting system (3) is connected with the slice opening supporting system (4); the slice opening supporting system (4) is connected with the filling system (5); the slice opening supporting system (4) and the filling system (5) are both positioned above the conveyor belt (2).

2. The device for slicing, gathering and core-injecting sandwich bread without breaking from a sandwich bread as claimed in claim 1, wherein the breaking-connection height limiting system (3) comprises a motor (301), a linear guide rail (302), a first gear (303), a first bevel gear (304), a second gear (305), a first support rod (306), a first transmission wheel (307), a second bevel gear (308), a first transmission rod (309), a third bevel gear (3010), a fourth bevel gear (3011), a first support frame (3012), a first bidirectional screw rod (3013), a first sliding sleeve (3014), a first sliding block (3015), a first connecting rod (3016), a first limiting block (3017), a first height limiting plate (3018), a second sliding sleeve (3019), a second sliding block (3020), a second connecting rod (3021), a second limiting block (3022), a fifth bevel gear (3023), a sixth bevel gear (3024), a second bidirectional screw rod (3025), The height limiting device comprises a third sliding sleeve (3026), a third sliding block (3027), a third connecting rod (3028), a third limiting block (3029), a second height limiting plate (3030), a fourth sliding sleeve (3031), a fourth sliding block (3032), a fourth connecting rod (3033), and a fourth limiting block (3034); the motor (301) is fixedly connected with the linear guide rail (302); the linear guide rail (302) is fixedly connected with the chassis (1); an output shaft of the motor (301) is fixedly connected with the first gear (303) and the first bevel gear (304) at the same time; a second gear (305) is arranged on the side surface of the first gear (303); the first supporting rod (306) is simultaneously in rotating connection with the second gear (305) and the first driving wheel (307) through a rotating shaft; the first supporting rod (306) is fixedly connected with the underframe (1); a second bevel gear (308) is arranged on the side surface of the first bevel gear (304); when the first gear (303) is meshed with the second gear (305), the second gear (305) rotates, and the first bevel gear (304) idles; when the first bevel gear (304) is meshed with the second bevel gear (308), the second bevel gear (308) rotates, and the first gear (303) idles; when the first gear (303) and the first bevel gear (304) are not meshed with the second gear (305) and the second bevel gear (308), respectively, the second gear (305) and the second bevel gear (308) are not rotated; the outer surface of the first transmission rod (309) is rotationally connected with the first support frame (3012); the outer surface of the first transmission rod (309) is fixedly connected with the second bevel gear (308), the third bevel gear (3010) and the sixth bevel gear (3024) in sequence; the third bevel gear (3010) is engaged with the fourth bevel gear (3011); the axis of the fourth bevel gear (3011) is fixedly connected with a first bidirectional screw rod (3013); the outer surface of the first bidirectional screw rod (3013) is rotatably connected with the first support frame (3012); one side of the outer surface of the first support frame (3012) is connected with the first sliding sleeve (3014) in a screwing way; the other side of the outer surface of the first support frame (3012) is connected with a second sliding sleeve (3019) in a screwing way; the first sliding sleeve (3014) is rotatably connected with the first sliding block (3015) through a rotating shaft; the inside of the first sliding block (3015) is connected with a first connecting rod (3016) in a sliding way; the first connecting rod (3016) is rotatably connected with the first limiting block (3017) through a rotating shaft; the first limiting block (3017) is in sliding connection with one side of the first height limiting plate (3018); the first height limiting plate (3018) is connected with the first support frame (3012) in a sliding manner; the second sliding sleeve (3019) is connected with the second sliding block (3020) in a rotating way through a rotating shaft; the inside of the second sliding block (3020) is connected with the second connecting rod (3021) in a sliding way; the second connecting rod (3021) is rotatably connected with the second limiting block (3022) through a rotating shaft; the second limiting block (3022) is in sliding connection with the other side of the first height limiting plate (3018); the first connecting rod (3016) and the second connecting rod (3021) are far away from one side of the first height limiting plate (3018) and are connected with the first support frame (3012) in a rotating mode through a rotating shaft; the fifth bevel gear (3023) is meshed with the sixth bevel gear (3024); the axis of the sixth bevel gear (3024) is fixedly connected with a second bidirectional screw rod (3025); the outer surface of the second bidirectional screw rod (3025) is rotatably connected with the first support frame (3012); one side of the outer surface of the second bidirectional screw rod (3025) is in screwed connection with the third sliding sleeve (3026); the other side of the outer surface of the second bidirectional screw rod (3025) is in screwed connection with the fourth sliding sleeve (3031); the third sliding sleeve (3026) is rotatably connected with the third sliding block (3027) through a rotating shaft; the inside of the third slider (3027) is connected with a third connecting rod (3028) in a sliding way; the third connecting rod (3028) is rotatably connected with the third limiting block (3029) through a rotating shaft; the third limiting block (3029) is in sliding connection with one side of the second height limiting plate (3030); the second height limiting plate (3030) is connected with the first support frame (3012) in a sliding way; the fourth sliding sleeve (3031) is rotatably connected with the fourth sliding block (3032) through a rotating shaft; the inside of the fourth sliding block (3032) is connected with a fourth connecting rod (3033) in a sliding way; the fourth connecting rod (3033) is rotatably connected with the fourth limiting block (3034) through a rotating shaft; the fourth limiting block (3034) is in sliding connection with the other side of the second height limiting plate (3030); the first support frame (3012) is fixedly connected with the underframe (1); the first support frame (3012) is positioned in the conveyor belt (2); the first supporting frame (3012) is connected with the slice supporting port system (4).

3. The slicing, gathering and core-injecting device without separating sandwich bread as claimed in claim 2, wherein the slicing and opening system (4) comprises a second supporting frame (401), a second driving wheel (402), a third gear (403), a third driving wheel (404), a fourth gear (405), a fourth driving wheel (406), a fifth gear (407), a fifth driving wheel (408), a sixth gear (409), a seventh gear (4010), a third bidirectional screw (4011), a first slide rail frame (4012), a fifth sliding sleeve (4013), a fifth sliding block (4014), a fifth connecting rod (4015), a first T-shaped sliding sleeve (4016), a sixth sliding sleeve (4017), a sixth sliding block (4018), a sixth connecting rod (4019), a first cutter (4020), a second cutter (4021), a second slide rail frame (4022), an eighth gear (4023), a fourth bidirectional screw (4024), a seventh sliding sleeve (4025), A seventh sliding block (4026), a seventh connecting rod (4027), a second T-shaped sliding sleeve (4028), an eighth sliding sleeve (4029), an eighth sliding block (4030) and an eighth connecting rod (4031); the second support frame (401) is simultaneously in rotating connection with the second driving wheel (402) and the third gear (403) through a rotating shaft; the second support frame (401) is simultaneously in rotating connection with a third driving wheel (404) and a fourth gear (405) through a rotating shaft; the second support frame (401) is simultaneously in rotating connection with a fourth driving wheel (406) and a fifth gear (407) through a rotating shaft; the second support frame (401) is simultaneously in rotating connection with a fifth driving wheel (408) and a sixth gear (409) through a rotating shaft; the outer annular surface of the second driving wheel (402) is in transmission connection with a third driving wheel (404) through a belt; the outer annular surface of the second driving wheel (402) is in transmission connection with a fourth driving wheel (406) through a belt; the outer ring surface of the fourth driving wheel (406) is in transmission connection with a fifth driving wheel (408) through a belt; the second support frame (401) is fixedly connected with the first support frame (3012); the outer ring surface of the second driving wheel (402) is in transmission connection with the first driving wheel (307) through a belt; the second support frame (401) is connected with the filling system (5); a first slide rail frame (4012) is arranged on one side in the second support frame (401); a second slide rail frame (4022) is arranged on the other side in the second support frame (401); the first slide rail frame (4012) is connected with the filling system (5); the second slide rail frame (4022) is connected with the filling system (5); the first slide rail frame (4012) is rotatably connected with the third bidirectional screw rod (4011); the third bidirectional screw rod (4011) is fixedly connected with a seventh gear (4010); one side of the outer surface of the third bidirectional screw rod (4011) is in screwed connection with a fifth sliding sleeve (4013); the other side of the outer surface of the third bidirectional screw rod (4011) is in screwed connection with a sixth sliding sleeve (4017); the fifth sliding sleeve (4013) is rotatably connected with the fifth sliding block (4014) through a rotating shaft; the interior of the fifth sliding block (4014) is in sliding connection with a fifth connecting rod (4015); the fifth connecting rod (4015) is rotatably connected with one side of the first T-shaped sliding sleeve (4016); the sixth sliding sleeve (4017) is rotatably connected with the sixth sliding block (4018) through a rotating shaft; the inside of the sixth sliding block (4018) is in sliding connection with a sixth connecting rod (4019); the sixth connecting rod (4019) is rotatably connected with the other side of the first T-shaped sliding sleeve (4016); the first T-shaped sliding sleeve (4016) is in sliding connection with the first sliding rail frame (4012); the sixth connecting rod (4019) is rotatably connected with one side of the first cutter (4020); the fifth connecting rod (4015) is rotatably connected with one side of the second cutter (4021); the first slide rail frame (4012) is in sliding connection with one side of the first cutter (4020); the first slide rail frame (4012) is in sliding connection with one side of the second cutter (4021); the other side of the first cutter (4020) is in sliding connection with the second sliding rail frame (4022); the other side of the second cutter (4021) is in sliding connection with a second sliding rail frame (4022); the other side of the first cutter (4020) is rotationally connected with a seventh connecting rod (4027); the other side of the second cutter (4021) is rotatably connected with an eighth connecting rod (4031); the second slide rail frame (4022) is in rotary connection with the fourth bidirectional screw rod (4024); the fourth bidirectional screw rod (4024) is fixedly connected with the eighth gear (4023); one side of the outer surface of the fourth bidirectional screw rod (4024) is in screwed connection with the seventh sliding sleeve (4025); the other side of the outer surface of the fourth bidirectional screw rod (4024) is in screwed connection with an eighth sliding sleeve (4029); the seventh sliding sleeve (4025) is rotatably connected with the seventh sliding block (4026) through a rotating shaft; the inside of the seventh sliding block (4026) is in sliding connection with a seventh connecting rod (4027); the seventh connecting rod (4027) is rotatably connected with one side of the second T-shaped sliding sleeve (4028); the eighth sliding sleeve (4029) is rotatably connected with the eighth sliding block (4030) through a rotating shaft; the inner part of the eighth sliding block (4030) is connected with an eighth connecting rod (4031) in a sliding way; the eighth connecting rod (4031) is rotatably connected with the other side of the second T-shaped sliding sleeve (4028); the second T-shaped sliding sleeve (4028) is in sliding connection with the second sliding rail frame (4022); when the seventh gear (4010) and the eighth gear (4023) are simultaneously engaged with the third gear (403) and the fifth gear (407), respectively, the seventh gear (4010) and the eighth gear (4023) are simultaneously rotated while the fourth gear (405) and the sixth gear (409) are idly rotated; when the seventh gear (4010) and the eighth gear (4023) are simultaneously engaged with the fourth gear (405) and the sixth gear (409), respectively, the seventh gear (4010) and the eighth gear (4023) are simultaneously rotated while the third gear (403) and the fifth gear (407) are idly rotated; when the seventh gear (4010) and the eighth gear (4023) are not engaged with the third gear (403), the fifth gear (407), the fourth gear (405), and the sixth gear (409), the seventh gear (4010) and the eighth gear (4023) are not rotated.

4. A device for slicing, gathering and filling a sandwich bread without separating from the sandwich bread according to claim 3, characterized in that the filling system (5) comprises a connecting frame (501), a rack bar (502), a ninth gear (503), a sixth transmission wheel (504), a seventh transmission wheel (505), a supporting sliding frame (506), a first cylinder (507), a second cylinder (508), a one-way screw rod (509), a sliding plate (5010), a J-shaped rod (5011), an injection hopper (5012), a connecting pipe (5013), a first spring rod (5014), a first inclined rod (5015), a transverse plate (5016), a second inclined rod (5017) and a second spring rod (5018); the connecting frame (501) is fixedly connected with the toothed bar (502); the connecting frame (501) is fixedly connected with the second support frame (401); the rack bar (502) is meshed with a ninth gear (503); the toothed bar (502) is fixedly connected with the second support frame (401); the axis of the ninth gear (503) is fixedly connected with a sixth driving wheel (504) through a rotating shaft; the axle center of the sixth driving wheel (504) is rotationally connected with the supporting sliding frame (506) through a rotating shaft; the outer ring surface of the sixth driving wheel (504) is in transmission connection with a seventh driving wheel (505) through a belt; the axle center of the seventh driving wheel (505) is fixedly connected with the one-way screw rod (509); the one-way screw rod (509) is rotationally connected with the support sliding frame (506); one side above the supporting sliding frame (506) is fixedly connected with a first air cylinder (507); the other side above the supporting sliding frame (506) is fixedly connected with a second air cylinder (508); the first cylinder (507) is fixedly connected with the second support frame (401); the second cylinder (508) is fixedly connected with the second support frame (401); the supporting sliding frame (506) is in sliding connection with the sliding plate (5010); one side of the support sliding frame (506) is fixedly connected with a first sliding rail frame (4012); the other side of the supporting sliding frame (506) is fixedly connected with a second sliding rail frame (4022); the sliding plate (5010) is screwed with the one-way screw rod (509); one side of the inner part of the supporting sliding frame (506) is in sliding connection with a first spring rod (5014); the other side in the supporting sliding frame (506) is in sliding connection with a second spring rod (5018); the first spring rod (5014) is fixedly connected with the first inclined rod (5015); the outer surface of the first inclined rod (5015) is in sliding connection with the sliding plate (5010); the second spring rod (5018) is fixedly connected with the second inclined rod (5017); the outer surface of the second inclined rod (5017) is in sliding connection with the sliding plate (5010); the first spring rod (5014) and the first inclined rod (5015) are fixedly connected with one side of the transverse plate (5016) at the same time; the second spring rod (5018) and the second inclined rod (5017) are fixedly connected with the other side of the transverse plate (5016) at the same time; the sliding plates (5010) are fixedly connected with the three J-shaped rods (5011) at equal intervals; the three J-shaped rods (5011) are rotatably connected with the injection hopper (5012); the side surfaces of the injection buckets (5012) are equidistantly inserted with four connecting pipes (5013).

5. A device for continuously slicing bread from a filling to close a filling as claimed in claim 4, wherein the first cutter (4020) and the second cutter (4021) are inclined upward in opposite directions and have two round pins attached to both sides thereof.

6. A device for slicing bread without breaking its center and closing it, as claimed in claim 5, wherein the three J-shaped bars (5011) are each in the shape of a curved L.

7. A device for slicing and closing a sandwich without breaking the sandwich as claimed in claim 6, characterized in that the first inclined bar (5015) and the second inclined bar (5017) are both inclined with respect to the transverse plate (5016).

8. The device for slicing bread from sandwich to be close to the center of gravity as claimed in claim 7, wherein the first slide rail frame (4012) and the second slide rail frame (4022) are symmetrically provided with an inverted J-shaped sliding groove and a straight-line-shaped sliding groove.

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