CN213961524U - Conveyor system and frying device - Google Patents

Abstract

The utility model discloses aim at providing a conveying system and deep-fry equipment, need not the article on the artifical lift platform that shifts. The conveying system is provided with a lifting platform for supporting the object; the lifting platform descends until the bearing surface of the lifting platform crosses the bearing surface of the transverse moving platform, so that the object is not supported by the lifting platform and is supported by the transverse moving platform. The lifting platform descends until the bearing surface of the lifting platform crosses the bearing surface of the transverse moving platform, so that the object is not supported by the lifting platform any more and is supported by the transverse moving platform instead, and the object does not need to be manually transferred to the transverse moving platform from the lifting platform.

Description

Conveyor system and frying device

Technical Field

The utility model relates to a conveying system and fried equipment.

Background

In the prior art, after an object at a high position is brought to the ground by a lifting platform, the object needs to be manually placed on a trolley, and then the trolley is pushed to a target position for unloading. The defects of the prior art are as follows: the object of the lifting platform needs to be manually transferred to the trolley.

SUMMERY OF THE UTILITY MODEL

The utility model discloses aim at providing a conveying system and deep-fry equipment, need not the article on the artifical lift platform that shifts.

The conveying system is provided with a lifting platform for supporting the object; the lifting platform descends until the bearing surface of the lifting platform crosses the bearing surface of the transverse moving platform, so that the object is not supported by the lifting platform and is supported by the transverse moving platform.

Furthermore, the object is a left transverse track and a right transverse track, and a carrying vehicle moving along the tracks is arranged; the transverse moving platform system moves forwards and backwards.

Furthermore, the track is provided with a first positioning structure facing downwards, the lifting platform is provided with a second positioning structure, the second positioning structure is vertically butted to the first positioning structure, so that the track cannot transversely move forwards and backwards, the lifting platform descends until the bearing surface of the lifting platform crosses the bearing surface of the transversely moving platform, and the second positioning structure exits from the first positioning structure, so that the track is allowed to transversely move forwards and backwards.

Furthermore, the transverse moving platform upwards extends out two limiting blocks which are arranged in tandem, and the track is limited between the two limiting blocks when being supported by the transverse moving platform.

Furthermore, one of the first positioning structure and the second positioning structure is a pin hole, and the other one is a bolt.

Frying equipment, including the food cabinet, including the conveying system as above, the food cabinet is located the place ahead or the rear of lift platform, and the food cabinet is equipped with discharge mechanism in order to send food backward or forward to the year thing car on.

Further, the box carrying vehicle discharges towards the left or the right.

Further, including establishing the first ejection of compact department of lifting platform lift orbit side, establishing the second ejection of compact department of sideslip platform sideslip orbit side, conveying system can order about the track motion to aim at first ejection of compact department and move to aim at second ejection of compact department, carries the ejection of compact of box car through ejection of compact department.

Has the advantages that: the lifting platform descends until the bearing surface of the lifting platform crosses the bearing surface of the transverse moving platform, so that the object is not supported by the lifting platform any more and is supported by the transverse moving platform instead, and the object does not need to be manually transferred to the transverse moving platform from the lifting platform.

Drawings

FIG. 1 is a structural view from a front perspective of a frying apparatus;

FIG. 2 is a front perspective structural view of the fryer apparatus (with the insulating shell and two insulating panels hidden);

FIG. 3 is an exploded schematic view of the powder wrapper;

FIG. 4 is a schematic diagram showing the separation of the shell and the inner container of the powder wrapping tank;

FIG. 5 is a schematic view of a powder receiving state of a powder wrapping tank;

fig. 6 is a schematic view of the first feed screw nut module moving down to align with the first discharge rail after the freezer takes a food box by the box opener;

FIG. 7 is a schematic view of the food opener opening the food box and feeding food to the powder wrapping tank (with the cross rail set and the lifting platform hidden);

FIG. 8 is a schematic view showing the state of the powder wrapping tank for screening out the excessive powder from the powder receiving hopper (with the water pipe group hidden);

FIG. 9 is a schematic view of the food being transferred from the breading tank to the fryer inlet port after the breading hopper has been removed to expose the fryer inlet port (with the water tube array hidden);

fig. 10 is a schematic view of the internal structure of the fryer (with the fryer housing hidden);

fig. 11 is a schematic drawing of the discharge state of the fryer (with the fryer housing hidden);

FIG. 12 is a schematic view showing the moment when the first left and right transverse linear modules are supported by the nuts of the transverse rail set while moving down with the lifting platform;

FIG. 13 is a schematic view of the lift platform moved down to the bottom most position;

FIG. 14 is a schematic view of the first left and right transverse linear modules aligned with the second run out rail as the nut traverses;

FIG. 15 is a rear perspective view of the food box when not entering the opener;

FIG. 16 is a front bottom perspective view of the opener ready to clamp a food cartridge;

FIG. 17 is a schematic top view of the opener gripping a food cartridge;

FIG. 18 is a schematic top view of the food container opener with its knife piercing the food container sealing film;

FIG. 19 is a schematic view of the chuck plate when the bowl is picked up;

FIG. 20 is a perspective view of the fryer;

FIG. 21 is a schematic view of another angle of FIG. 11;

in the figure: 1. a thermally insulating shell; 2. a first heat insulation plate; 3. a second heat insulation plate; 4. a first discharge rail; 5. a second discharge rail; 6. A powder bin; 7. a powder outlet; 8. wrapping a powder machine; 80. adjusting the position of the driving and rotating piece; 81. a power shaft; 82. a card slot; 83. a can shell; 84. An opening; 85. a powder leakage hole; 86. an inner container; 87. an opening; 88. a water pipe group; 89. emptying the tank; 9. a powder receiving hopper; 90. a top cover; 91. a fastener; 92. driving and rotating the circular ring; 93. a mounting seat; 10. a first fryer; 101. a housing; 102. a feeding port; 103. A spoon; 104. a spoon handle; 105. a discharge guide; 106. a fryer; 107. a hinge shaft; 11. a door; 12. clamping a plate; 13. A bowl group; 14. a water tank; 15. a box recovery box; 16. a freezer; 160. a food box; 161. a first power transmission belt; 162. sealing the film; 17. a vertical rail group; 170. a first left and right transverse straight line module; 171. a pin cylinder seat; 172. a bracket; 173. a beam; 174. A bolt; 175. a box opener; 176. erecting a screw rod; 177. front and rear transverse screw rods; 178. a nut; 18. front and rear transverse rail sets; 19. a second left and right transverse straight line module; 20. a second fryer; 21. a range hood; 210. a fume tube; 276. pushing the right end of the piece; 277. a first electromagnet; 278. a first spring set; 279. pushing the left end of the piece; 280. an iron frame; 281. a cutter; 282. A second spring set; 283. a second power transmission belt; 284. a frame body; 300. a lifting module; 301. a spoon discharging driving and rotating device; 303. A limiting block; 304. a through hole; 305. a powder wrapping tank; 306. a second electromagnet; 307. pouring a spout; 308. placing a box opening; 309. A discharge end; 310. side dams.

Detailed Description

Part of the internal structure of the frying device is shown in fig. 2, the freezer 16 has a plurality of compartments, each compartment is provided with a food box 160, the inner bottom wall of each compartment is provided with a first power transmission belt 161 which is transverse front and back, the food box 160 is horizontally arranged on the first power transmission belt 161 in a mode that the top of the food box is towards the left, and the front side wall of the freezer 16 is provided with a box outlet so as to take out the food box 160. A vertical rail group 17 is arranged in front of the front surface of the freezer 16, a front transverse rail group 18 and a rear transverse rail group 18 are arranged below the bottom surface of the freezer, and the vertical rail group 17 and the transverse rail group 18 are jointly used as a conveying mechanism. The first fryer 10 is provided with a first discharge rail 4 as a discharge point, and the first discharge rail 4 is arranged at the left side of the vertical rail group 17; the second fryer (located behind the first fryer 10, hidden by the first fryer 10 in fig. 1, 2, visible in fig. 8) is equipped with a second take-off rail 5 as take-off, which second take-off rail 5 is mounted to the left of the front and rear transverse rail sets 18. The frying apparatus is provided with a controller, and the following working process is controlled by the controller. The food boxes 160 have two types, one type contains food which can be fried only by wrapping powder, the other type contains food which can be fried without wrapping powder, the food in the former type is sent to the flour wrapping machine 8 for wrapping powder through the first material outlet rail 4 serving as a conveying rail and then sent to the first frying machine 10 for frying, and the food in the latter type is sent to the second frying machine for frying through the second material outlet rail 5 serving as a conveying rail.

The complete internal structure of the frying device is shown in figure 1, and when being seen together with figure 2, the heat insulation shell 1 is arranged to wrap the refrigerator 16, the vertical rail group 17 and the front and rear transverse rail groups 18, so that cold air is prevented from overflowing. The first discharging rail 4 and the second discharging rail 5 extend out of the heat insulation shell 1; the heat shield case 1 is provided with a first heat shield 2 for a first discharge rail 4 and a second heat shield 3 for a second discharge rail 5 to prevent cold air from escaping from the heat shield case 1. As shown in fig. 6, the vertical rail set 17 includes a vertical screw rod 176, a bracket 172 capable of lifting along the vertical screw rod 176 is disposed on the vertical screw rod 176, a beam 173 as a lifting platform extends backward from the bracket 172, a first left and right horizontal linear module 170 is disposed on the beam 173, a box opener 175 driven by the first left and right horizontal linear module 170 to move transversely is disposed on the first left and right horizontal linear module 170, and the first left and right horizontal linear module 170 serves as a track of the box opener 175. Vertical pin cylinder seats 171 are arranged on the front side and the rear side of the first left and right transverse linear modules 170, a bolt 174 serving as a second positioning structure extends upwards from the far end of the beam 173, and the bolt 174 is vertically inserted into the pin cylinder seat 171 serving as the first positioning structure, so that the first left and right transverse linear modules 170 cannot transversely move back and forth. The front and rear transverse rail groups 18 comprise front and rear transverse screw rods 177, screw nuts 178 which move back and forth along the front and rear transverse screw rods 177 are arranged on the front and rear transverse screw rods 177, the screw nuts 178 serve as transverse moving platforms, and the screw nuts extend upwards to form a front limiting block 303 and a rear limiting block 303.

The process of frying the food to be breaded is as follows: the first left and right transverse linear modules 170 are moved by a beam 173 acting as a lifting platform up to the box opener 175 to align with the food box 160. The side wall of the box opener 175 is provided with a box opening 308 (see fig. 15 and 17 together), and the food box 160 is driven to move forward by the first power transmission belt 161 as a box withdrawing driving device, so that the food box 160 is put into the box opener 175 through the box opening 308. Then the first left and right transverse linear module 170 is driven by the beam 173 to move down to the state shown in fig. 6 and stop, and the left end of the first left and right transverse linear module 170 is aligned with the first discharging rail 4. The first left and right transverse linear modules 170 are provided with pushers driven by the same to move along the same, and the pushers serve as cart driving devices. The opener 175 acts as a carriage, the rear of the vehicle is hinged to the push block, and the head of the vehicle is provided with a pouring opening 307 (visible in fig. 15). Next, the first left-right transverse linear module 170 drives the box opener 175 to move left into the first discharging rail 4, the left end of the first discharging rail 4 slightly bends downward (for the first discharging rail 4 itself, the front end bends downward), so the left head of the box loading vehicle and the mouth of the food box 160 will also tilt toward the left when reaching the discharging position of the first discharging rail 4, the food in the food box 160 slides into the powder wrapping machine 8 at the left of the first discharging rail 4 through the pouring port 307 of the head under the action of self gravity, and the powder wrapping machine 8 wraps the food. If food which does not need to be wrapped with flour is fried, the beam 173 moves downwards to the state shown in fig. 6 and 7 without stopping, but directly moves downwards to the state shown in fig. 12, which means that the beam 173 descends until the bearing surface of the beam 173 passes over the bearing surface of the screw nut 178, so that the object 170 is not supported by the beam 173 but is supported by the screw nut 178, and the first left and right transverse linear modules 170 are supported by the screw nut 178 and are limited between the two limit blocks 303. Then, the beam 173 is further moved downward from the state of fig. 12 to the state of fig. 13, and since the first left and right transverse linear modules 170 are supported by the nuts 178 and do not move downward with the beam 173, the pins 174 of the beam 173 gradually come out of the pin cylinder housings 171 of the first left and right transverse linear modules 170, and finally come out of the pin cylinder housings 171 completely in the state of fig. 13, thereby allowing the first left and right transverse linear modules 170 to traverse forward and backward. Subsequently, the front and rear transverse screws 177 drive the nuts 178 to move backwards, so as to drive the first left and right transverse linear modules 170 to move backwards from the state shown in fig. 13 to the state shown in fig. 14, at this time, the left ends of the first left and right transverse linear modules 170 are aligned with the second discharging rail 5, and then the first left and right transverse linear modules 170 drive the box opener 175 to move leftwards to enter the second discharging rail 5. The left end of the second discharging rail 5 is slightly bent downward, so that the food in the food box 160 slides down to the first discharging rail 4 under the action of its own gravity and bends downward toward the left, so that the box opener 175 and the food box 160 will tilt downward toward the left when reaching the discharging position of the second discharging rail 5, and the food in the food box 160 slides down to the second fryer 20 at the left of the second discharging rail 5 under the action of its own gravity and is fried. The second fryer 20 is equipped with and connected to a hood 21. Hood 21 is also connected to first fryer 10 through a fume tube 210, and removes fumes generated by first fryer 10 and second fryer 20.

The box opener 175 and the food box 160 loaded with the same in the rear view are shown in fig. 15, in which the right end of the box opener 175 faces the first discharging rail 4, the inner bottom wall is provided with a second power transmission belt 283 which is transverse in the front-rear direction, and the top of the food box 160 (in the figure, the food box 160 is in a horizontal state, and the box opening faces the right) is provided with a sealing film 162. As shown in fig. 16 and 18, the box opener 175 has a pushing member passing through a right wall (i.e., a tail wall) of the box opener 175, a first spring set 278 is disposed between a right end 276 of the pushing member and a right outer wall of the box opener 175, and a first electromagnet 277 is disposed on the right outer wall of the box opener 175. A frame 284 is fixedly arranged at the left end of the box opener 175 (the frame 284 is shielded in fig. 16, and can be seen in fig. 17), the frame 284 serves as a vehicle head, a hollow part in the frame 284 serves as a pouring opening 307, the right side of the frame 284 shields the edge of the top of the food box 160, and the left side (namely the front side of the vehicle head) is provided with a second electromagnet 306 (shielded in the figure and visible in fig. 15); the iron frame 280 is provided to the left of the frame 284, and the back surface of the iron frame 280 is attached to the frame 284 by the second spring group 282. The back of the iron frame 280 is provided with a cutter 281 which is aligned with the sealing film 162 of the food box 160 and is used as a film opening mechanism for opening the opening of the food box 160. The operation of the opener 175 to receive the food box 160 from the cooler 16 is as follows: after the food box 160 is fed from the freezer 16 into the box opener 175 through the back of the box opener 175 by the first power transmission belt 161, the controller activates the first electromagnet 277, as shown in fig. 17, the right end 276 of the pushing member is made of a material that receives magnetic force, and attracts the right end 276 of the pushing member to move the pushing member to the left, so that the bottom of the food box 160 is pushed by the left end 279 of the pushing member to move to the left until the food box 160 is clamped by the back of the frame 284 and the left end 279 of the pushing member together. The operation of the opener 175 to open the sealing film 162 is as follows: after the box opener 175 enters the discharging position of the corresponding discharging rail, the controller enables the second electromagnet 306 to be started, starting from the state shown in fig. 17, the second electromagnet 306 attracts the iron frame 280 to move right so as to drive the cutter 281 to move right, and the cutter 281 penetrates through the pouring opening 307 of the vehicle head to puncture the sealing film 162 of the opening of the food box 160 in the process of moving right, as shown in fig. 18; since the box opener 175 located at the discharging position is inclined downward toward the left, the food box 160 discharges the food toward the lower left into the corresponding fryer. After the food is discharged, the controller turns off the second electromagnet 306, and the iron frame 280 is reset by the elastic force of the second spring assembly 282. Referring to fig. 2, the first left and right transverse linear modules 170 drives the box opener 175 to move to the right above the box recycling box 15, the controller closes the first electromagnet 277 to reset the pushing member under the elastic force of the first spring set 278, so that the empty food box 160 is no longer clamped by the frame 284 and the right end 276 of the pushing member, and then the second power transmission belt 283 in the box opener 175 is started to drive the empty food box 160 to move backwards, so that the empty food box 160 slides from the box opener 175 into the box recycling box 15 through the box opening 308.

The breading tank 305 receives food from the box opener in preparation for breading. As shown in fig. 5, the powder bin 6 is arranged right above the powder wrapping tank 305, and the powder outlet 7 of the powder bin 6 is positioned at the bottom and faces downwards to discharge powder. As shown in fig. 3 to 4, the powder coating machine 8 includes a positioning driving member 80, a powder coating tank 305 as a powder coating portion, an empty tank 89 as a cleaning portion, and a water pipe group 88, wherein the powder coating tank 305 is communicated with the empty tank 89. Referring to fig. 2, the water pipe assembly 88 includes a water supply pipe as a water supply mechanism and a water pumping pipe as a water pumping mechanism, which are arranged side by side, wherein the end of the water supply pipe is fixedly connected to the empty tank 89, and the beginning end of the water supply pipe is connected to the position-adjustable rotation member 80 and finally connected to the water tank 14, and the beginning end of the water pumping pipe is fixedly connected to the empty tank 89, and the end of the water pumping pipe is connected to the position-adjustable rotation member 80 and finally connected to the water tank 14. The powder wrapping tank 305 comprises a tank shell 83 and an inner container 86, the inner container 86 is arranged in the tank shell 83, a mounting seat 93 extends out of the back of the inner container 86, a through hole 304 is formed in the back of the tank shell, and the mounting seat 93 penetrates out of the through hole 304. The circumferential side wall of the inner container 86 is provided with an opening 87; the circumferential side wall of the tank shell 83 is provided with an opening 84 and a powder leakage hole 85, and the back surface of the tank shell extends out of a clamping piece 91. The front of the position-adjusting driving piece 80 is provided with a driving circular ring 92 as a shell driving piece and a power shaft 81 as a liner driving piece, and the power shaft 81 penetrates out through the center vacancy of the driving circular ring. The front surface of the rotation driving ring 92 is provided with a clamping groove 82, and the clamping groove 82 is clamped by a clamping piece 91 of the tank shell 83, so that the rotation driving ring 92 can drive the tank shell 83 to rotate around the power shaft 81 (according to the direction of fig. 2); the power shaft 81 of the motor is clamped in the mounting seat 93 of the inner container 86, so that the motor can drive the inner container 86 to rotate around the power shaft 81. The circumferential rotation of the position-adjusting driving element 80 will drive the powder-wrapping tank 305 and the empty tank 89 to perform the circumferential rotation together.

The powder wrapping process comprises the following steps:

firstly, receiving food. As shown in fig. 7 (the left end of the opener 175 is not tilted but actually tilted, the opener 175 seems to be separated from the first left and right horizontal linear modules 170 but not actually separated, the tail of the box opener 175 is still hinged to the pusher), the tank 83 is driven by the driving ring 92 to rotate to the upper right of the opening 84, the inner container 86 is driven by the power shaft 81 to rotate to the right of the opening 87, and the food sliding from the food box 160 on the first discharging rail 4 falls into the inner container 86 through the openings 84 and 87, that is, the openings 84 and 87 are used as the feeding ports together.

And secondly, carrying out primary powder wrapping. The tank shell 83 and the inner container 86 are driven by the driving ring 92 and the power shaft 81 respectively to rotate until the openings 84 and 87 face upwards, and as shown in fig. 5, the powder outlet 7 of the powder bin 6 faces downwards to be aligned with the powder wrapping tank 305 so as to feed powder into the inner container 86 through the openings 84 and 87. The can 83 is driven by the driving ring 92 to rotate until the opening 84 and the powder leakage hole 85 of the can 83 are staggered with respect to the opening 87 of the liner 86, which means that the can 83 is used as a partition to close the opening 87 of the liner 86, and the can 83 and the liner 86 are driven by the driving ring 92 and the power shaft 81 to synchronously rotate to wrap the food in the liner 86 with powder.

And thirdly, performing primary powder screening. The positioning rotation member 80 rotates 180 degrees around itself, as shown in fig. 8, that is, the powder wrapping tank 305 is down and the empty tank 89 is up, the tank shell 83 rotates to a state that the powder leakage hole 85 faces downward and the opening 87 of the inner container 86 also faces downward. The powder receiving hopper 9 is arranged below the powder wrapping machine 8, redundant powder in the inner container 86 successively falls into the powder receiving hopper 9 through the opening 87 and the powder leakage hole 85 to be received, and food in the inner container 86 does not fall from the powder leakage hole 85 because the food is larger than the powder leakage hole 85.

Fourthly, cleaning food. The positioning rotating member 80 rotates 180 degrees around the front-back transverse axis (in the direction of fig. 2) from the state of fig. 8 so that the powder wrapping tank 305 is on and the empty tank 89 is under, and the tank shell 83 as a partition rotates under the driving of the rotating ring 92 to open the opening 87 of the inner container 86 so that the food in the inner container 86 falls into the empty tank 89. Together with fig. 5 and 2, the water supply pipe and the water extraction pipe are respectively provided with a pump (not shown), which draws water from the water tank 14 and supplies it to the empty tank 89 for immersion washing of the food. After the food is cleaned, the water pumping pipe pumps the waste water soaked and cleaned in the empty tank 89 away.

And fifthly, carrying out secondary powder wrapping. The positioning driving element 80 rotates 180 degrees around the circumference to enable the empty tank 89 to be on and the powder wrapping tank 305 to be under, and the food in the empty tank 89 falls back into the powder wrapping tank 305 again. The tank shell 83 is driven by the driving ring 92 to rotate to close the opening 87 of the inner container 86, and then the positioning driving member 80 rotates 180 degrees around the tank shell to enable the powder wrapping tank 305 to be on and the empty tank 89 to be on. The can 83 and the inner container 86 are driven by the driving ring 92 and the power shaft 81 respectively to rotate until the openings 84 and 87 face upwards, and … … the can 83 and the inner container 86 are driven by the driving ring 92 and the power shaft 81 respectively to synchronously rotate so as to wrap the food in the inner container 86 for the second time.

And sixthly, performing secondary powder sieving. The process is the same as the first powder sieving process, and is not described in detail.

Seventhly, the food is discharged to the first fryer 10. As shown in fig. 8, the inlet 102 of the first fryer 10 is facing upward and is covered by the top cover 90. The discharge guide 105 is provided on the top cover 90, and the discharge guide 105 is provided with and driven by the second left and right transverse linear modules 19 to perform transverse movement. After the second sifting, the breading machine 8 is about to discharge food into the first fryer 10, and the second right and left lateral linear module 19 is used to drive the discharge guide 105 to move laterally to move the lid 90 laterally away from the feed port 10 of the first fryer 10, from the condition of fig. 8 to the condition of fig. 9. After the second sifting, the opening 87 of the inner container 86 is turned downward and is not moved, the tank 83 is turned to the position where the opening 84 is turned downward, and the food in the inner container 86 falls into the first fryer 10 through the inlet 102, i.e., the openings 84, 87 together serve as the outlet.

First deep fryer 10 with housing 101 hidden as shown in fig. 10, when viewed in conjunction with fig. 9, first deep fryer 10 is provided with discharge door 11 on the left side wall, the bottom of discharge door 11 is mounted on housing 101 by means of hinge shaft 107, the upper end of discharge door 11 is a free end, and the inward side of discharge door 11 is provided with discharge end 309. The casing 101 of the first fryer 10 serves as a partition for blocking external pollutants, the top of the casing is provided with a feeding port 102, the feeding port 102 faces upwards to a powder wrapping tank 305, a strainer 103 is arranged below the feeding port 102, a spoon head of the strainer 103 catches food entering the first fryer 10 from the feeding port 102, and a fryer 106 is arranged below the strainer 103. The inwardly facing side of the discharge door 11 is provided with a tubular discharge guide 105 which narrows towards a discharge end 309 of the discharge door 11. Referring to fig. 20, a lifting module 300 is disposed inside the fryer 106 as a pan-out driving device, the lifting module 300 is disposed with a spoon-out motor 301 as a spoon-out driving device and can drive the spoon-out motor 301 to lift, and the colander 103 is mounted on the spoon-out motor 301, so that it has a lever structure. The first fryer 10 operates as follows: after the head of the perforated ladle 103 receives food from the feeding port 102, the lifting module 300 drives the ladle discharging motor 301 to move downwards so as to drive the perforated ladle 103 to move downwards into the cavity of the fryer 106, and the fryer 106 fries the food in the perforated ladle 103. After the food is fried, the lifting module 300 drives the spoon discharging motor 301 to move upwards so as to drive the colander 103 to move upwards to leave the fryer 106, the spoon discharging motor 301 serving as a lever fulcrum is higher than the hinge shaft 107, and then the spoon discharging motor 301 drives the colander 103 to tilt backwards (rotate anticlockwise) by about 120 degrees, so that the state shown in fig. 11 is changed. In-process that strainer 103 is rotatory, spoon handle 104 pushes open discharge door 11 and aims at the entry of ejection of compact guide 105, and the spoon tail is less than the spoon head this moment and the spoon tail is taken on discharge door 11 inwards and discharge end 309 of discharge door 11 is less than the spoon tail to for the food formation in the spoon head in proper order through spoon handle, spoon tail, discharge door 11 towards the ejection of compact guide 105 of internal face, the discharge end of discharge door pours out the passageway of pouring out of fryer 106, spoon handle 304 side stretches out towards the front has side shield 310. Because the right end of the colander 103 in this state is high and the left end is low, food in the colander 103 falls onto the pouring channel and slides out into the bowl along the pouring channel. As shown in FIG. 19, the bowl is carried by the movable catch plate 12 to the outlet of the alignment outfeed guide 105. The clamping plate 12 moves to the lower part of the bowl group 13, then ascends to clamp the bottom of the bowl at the lowest part of the bowl group 13, then moves the bowl to the left of the discharging door 11 to receive the food discharged by the discharging guide piece 105, and then sends the bowl filled with the food out of the frying equipment after receiving the food, so that the customer can take the meal. The first fryer 10 is identical in construction to the second fryer 20.

Claims (8)

1. A conveyor system, characterized by: a lifting platform for supporting the object is arranged; the lifting platform descends until the bearing surface of the lifting platform crosses the bearing surface of the transverse moving platform, so that the object is not supported by the lifting platform and is supported by the transverse moving platform.

2. The conveyor system of claim 1, wherein: the object is a left transverse track and a right transverse track, and is provided with a carrying vehicle moving along the tracks; the transverse moving platform system moves forwards and backwards.

3. The conveyor system of claim 2, wherein: the track is provided with a first positioning structure facing downwards, the lifting platform is provided with a second positioning structure, the second positioning structure is vertically butted to the first positioning structure, so that the track cannot transversely move forwards and backwards, the lifting platform descends until the bearing surface of the lifting platform crosses the bearing surface of the transversely moving platform, and the second positioning structure exits from the first positioning structure, so that the track is allowed to transversely move forwards and backwards.

4. The conveyor system of claim 2, wherein: the transverse moving platform upwards extends out two limiting blocks which are arranged in tandem, and the track is limited between the two limiting blocks when being supported by the transverse moving platform.

5. The conveyor system of claim 3, wherein: the first positioning structure and the second positioning structure, one of which is a pin hole and the other is a bolt.

6. Frying equipment, including the food cabinet, its characterized in that: a conveyor system according to any one of claims 2 to 5, comprising a food cabinet located in front of or behind the lifting platform, the food cabinet being provided with a discharge mechanism for delivering food either backwards or forwards onto the carrier vehicle.

7. Frying apparatus according to claim 6, characterized in that: the box carrying vehicle discharges towards the left or the right.

8. Frying apparatus according to claim 7, characterized in that: including establishing the first ejection of compact department in lifting platform lift orbit side, establishing the second ejection of compact department in sideslip platform sideslip orbit side, conveying system can order about the track motion and aim at first ejection of compact department and move to aim at second ejection of compact department, carries the ejection of compact of box car through ejection of compact department.

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