CN216018924U

CN216018924U - High-efficient gel candy casting machine

Info

Publication number: CN216018924U
Application number: CN202121348243.6U
Authority: CN
Inventors: 丁国富
Original assignee: Huishen Jiusi Beijing Technology Co ltd
Current assignee: Huishen Jiusi Beijing Technology Co ltd
Priority date: 2021-06-17
Filing date: 2021-06-17
Publication date: 2022-03-15
Anticipated expiration: 2031-06-17

Abstract

The utility model discloses a high-efficiency gel candy casting machine, which comprises: the first conveying belt is arranged on the rack; a plurality of molds disposed on the first conveyor belt; the top surface of any mould is provided with at least one mould cavity for forming gel candy; a cooling cavity vertical to the conveying direction of the first conveying belt is horizontally arranged on any one die; any cooling cavity is not interfered with any die cavity; the liquid separating rod is horizontally and rotatably arranged on the rack and is vertical to the conveying direction of the first conveying belt; the liquid separating rod is provided with a liquid inlet flow channel which communicates one end of all the cooling cavities with the liquid outlet of the condensing mechanism and a liquid outlet flow channel which communicates the other end of all the cooling cavities with the liquid inlet of the condensing mechanism. The utility model has the advantages of high cooling efficiency, short molding and demolding time, improved production efficiency and greatly reduced investment of plants and molds.

Description

High-efficient gel candy casting machine

Technical Field

The utility model relates to the technical field of food processing. More particularly, the present invention relates to an efficient gel candy casting machine.

Background

The gel candy is a soft candy prepared by taking granulated sugar and starch syrup as main raw materials and one or more hydrophilic gels as coagulants through a plurality of processes such as decoction, molding and the like, and the water content is usually 10-20%. In the prior art, a gel candy pouring machine usually adopts room temperature or cold air cooling for forming and then demoulding after pouring, the cooling efficiency is low, the forming and demoulding time is long, the production efficiency is low, and the defective rate is high; in addition, in order to ensure the continuity and automation of the production of the gel candy, the gel candy pouring machine occupies a large area, and the usage amount of the mold is large, so that the plant investment and the mold investment are high.

SUMMERY OF THE UTILITY MODEL

An object of the present invention is to solve at least the above problems and to provide at least the advantages described later.

The utility model also aims to provide the high-efficiency gel candy pouring machine which has the advantages of high cooling efficiency, short forming and demolding time, production efficiency improvement and great reduction of investment of plants and molds.

To achieve these objects and other advantages in accordance with the purpose of the utility model, there is provided an efficient gel candy casting machine comprising:

the first conveying belt is arranged on the rack;

a plurality of molds disposed on the first conveyor belt; the top surface of any mould is provided with at least one mould cavity for forming gel candy; a cooling cavity vertical to the conveying direction of the first conveying belt is horizontally arranged on any one die; any cooling cavity is not interfered with any die cavity;

the liquid separating rod is horizontally and rotatably arranged on the rack and is vertical to the conveying direction of the first conveying belt; and the liquid separating rod is provided with a liquid inlet flow channel for communicating one ends of all the cooling cavities with the liquid outlet of the condensing mechanism and a liquid outlet flow channel for communicating the other ends of all the cooling cavities with the liquid inlet of the condensing mechanism.

Preferably, one end of the liquid inlet flow channel is located in the liquid separating rod and is communicated with one end of any cooling cavity through a first liquid inlet pipe, and the other end of the liquid inlet flow channel extends along the axial direction of the liquid separating rod and penetrates through the end face of one end of the liquid separating rod;

the side wall of the liquid distribution rod close to one end of the liquid distribution rod protrudes outwards along the radial direction to form an annular bump, an annular groove is formed in the end face of one end of the bump close to the liquid distribution rod to form the liquid outlet flow channel, and the bottom of the liquid outlet flow channel is communicated with the other end of any cooling cavity through a first liquid outlet pipe;

one end of the liquid distribution rod is provided with a liquid distribution block which is fixedly arranged on the rack and does not limit the rotation of the liquid distribution rod; a first groove is formed in one end face, close to the protruding block, of the liquid separation block, and a second groove is formed in the bottom of the first groove; one end of the liquid distribution rod penetrates through the first groove and is inserted into the second groove, the side wall of the liquid distribution rod is in sealing contact with the side wall of the second groove, and the side wall of the bump is in sealing contact with the side wall of the first groove; the first groove is communicated with a liquid outlet of the condensing mechanism through a second liquid inlet pipe; the second groove is communicated with a liquid inlet of the condensing mechanism through a second liquid outlet pipe.

Preferably, a first sealing ring is arranged between the side wall of the liquid separating rod and the side wall of the second groove, and a second sealing ring is arranged between the side wall of the projection and the first groove.

Preferably, one mold cavity is correspondingly provided with one ejector rod, the bottom surface of any mold cavity is provided with a through hole, one end of any ejector rod is positioned on the inner side of the first conveying belt, the other end of any ejector rod extends towards the direction close to the corresponding mold cavity and vertical to the bottom surface of the mold cavity, and the ejector rod can pass through the through hole; any of the carrier rods is movable in the axial direction thereof.

Preferably, a plurality of spring cavities are arranged on the bottom surface of any one of the dies, one spring cavity is correspondingly arranged in one die cavity, and the other end of any one of the ejector rods penetrates through the corresponding spring cavity and extends towards the corresponding die cavity in a direction perpendicular to the bottom surface of the die cavity; a limiting block is fixedly sleeved on the ejector rod, any limiting block is positioned in the spring cavity corresponding to the ejector rod, and the movement of the limiting block is not limited by any spring cavity; one spring is correspondingly arranged in one spring cavity, any spring is sleeved on the thimble corresponding to the spring cavity, one end of any spring is connected with the end surface of one end, close to the mold cavity, of the spring cavity corresponding to the spring cavity, and the other end of the spring is connected with the limiting block corresponding to the spring cavity; one limiting block is correspondingly provided with a stop block, any stop block is fixedly arranged on the bottom surface of the corresponding die, one end of any ejector rod penetrates through the corresponding stop block and extends to the inner side of the first conveying belt, and the any stop block does not limit the axial movement of the corresponding ejector rod; any limiting block is abutted with the corresponding stop block.

Preferably, a pressing plate is horizontally arranged at the lower part of the inner side of the first conveying belt, and the pressing plate can move along the vertical direction.

Preferably, at least one die cavity on any die comprises a plurality of die cavity groups annularly arranged on the first conveying belt, and any die cavity group comprises at least one die cavity; the high-efficiency gel candy casting machine further comprises:

the pouring hopper is positioned right above the first conveying belt, and syrup is filled in the pouring hopper;

the material injection nozzle is arranged at the lower end of the pouring hopper, a plunger pump is arranged in the material injection nozzle, and one material injection nozzle is correspondingly arranged in one die cavity of any die cavity group; the top of plunger pump is equipped with the connecting rod that can follow vertical direction and remove, and the one end and the plunger rigid coupling of plunger pump of connecting rod, the vertical upwards extension of the other end extend to the top of pouring hopper and be connected with the piston rod of pneumatic cylinder.

Preferably, the pouring hopper is a temperature-controlled hopper.

Preferably, the device further comprises a second conveying belt which is arranged right below the first conveying belt; for any cavity group, when the cavity group rotates to the bottom of the first conveying belt, the downward projection of any cavity of the cavity group is contained on the second conveying belt.

The utility model at least comprises the following beneficial effects:

the liquid separation device comprises a first conveying belt, a plurality of molds and a liquid separation rod, wherein the first conveying belt is arranged on a rack, the plurality of molds are arranged on the first conveying belt, any one mold is provided with a cooling cavity, the liquid separation rod is horizontally and rotatably arranged on the rack, and the liquid separation rod is provided with a liquid inlet flow channel for communicating one end of all the cooling cavities with liquid outlets of a condensation mechanism and a liquid outlet flow channel for communicating the other end of all the cooling cavities with liquid inlets of the condensation mechanism; the rotation of the liquid separating rod is synchronous with the transmission of the first conveying belt, and any cooling cavity is always communicated with the condensing mechanism through a liquid inlet channel and a liquid outlet channel of the liquid separating rod to form a circulating passage; the cooling refrigerants (including water, ethylene glycol and the like) of the condensation mechanism continuously enter the liquid inlet flow channel and then flow into all the cooling cavities, flow from one end of each cooling cavity to the other end of each cooling cavity, enter the condensation mechanism from the other end of each cooling cavity through the liquid outlet flow channel, and are cooled in the condensation mechanism to form a refrigerant circulation passage; the cooled refrigerant continuously flows from one end of the cooling cavity to the other end of the cooling cavity, and the heat of the die is continuously taken away in the process, so that the die is forcibly cooled; the cooling cavity in the mold is always communicated with the condensing mechanism through the liquid separating rod by adopting an annular rotation mode to form effective closed-loop rotation, the mold is continuously and forcibly cooled, the cooling efficiency is high, the gel candy molded by casting can be rapidly cooled and demolded, the molding and demolding time is short, and the production efficiency is effectively improved; meanwhile, the using amount of the die is reduced, the equipment is smaller, the occupied area is reduced, and the investment of plants and the die is greatly reduced;

the liquid separation block is provided with a first groove and a second groove; for any mould, the condensing mechanism, the second liquid inlet pipe, the first groove, the liquid inlet flow channel, the first liquid inlet pipe, the cooling cavity, the first liquid outlet pipe, the liquid outlet flow channel, the second groove and the second liquid outlet pipe are communicated with one another to form a refrigerant circulating passage, and the cooled refrigerant continuously and forcibly cools the mould, so that the cooling efficiency is high; divide the rotation of liquid pole and the conveying of first conveyer belt in step, first feed liquor pipe and first drain pipe all rotate along with dividing the liquid pole, and all the time with the feed liquor runner, go out the liquid runner, rather than the cooling chamber intercommunication that corresponds, divide the liquid piece to set firmly in the frame, through first recess and second feed liquor pipe with feed liquor runner and condensation mechanism intercommunication, will go out liquid runner and condensation mechanism intercommunication through second recess and second drain pipe, second feed liquor pipe and second drain pipe are all nonrotation, refrigerant circulation route communicates all the time, can effectively avoid the damage of pipeline and divide liquid pole pivoted influence, and then be favorable to further improving cooling efficiency and production efficiency.

Additional advantages, objects, and features of the utility model will be set forth in part in the description which follows and in part will become apparent to those having ordinary skill in the art upon examination of the following or may be learned from practice of the utility model.

Drawings

FIG. 1 is a schematic structural diagram of the high-efficiency gel candy casting machine according to one embodiment of the utility model;

FIG. 2 is a schematic structural diagram of the high-efficiency gel candy casting machine according to one embodiment of the utility model;

FIG. 3 is a schematic structural view of the connection between the dispensing rod and the mold according to one embodiment of the present invention;

FIG. 4 is a schematic structural diagram of the mold according to one embodiment of the present invention;

fig. 5 is a schematic structural view of the pouring hopper according to one embodiment of the present invention;

description of reference numerals: a first conveyor belt 1; a frame 2; a mold 3; a mold cavity 4; a cooling chamber 5; a liquid separating rod 6; a condensing mechanism 7; a liquid inlet flow passage 8; a liquid outlet flow passage 9; a first liquid inlet pipe 10; a bump 11; a first outlet pipe 12; a liquid separation block 13; a first groove 14; a second groove 15; a second liquid inlet pipe 16; a second outlet pipe 17; a first seal ring 18; a second seal ring 19; a top bar 20; a through hole 21; a spring chamber 22; a stopper 23; a spring 24; a stopper 25; a platen 26; a pouring hopper 27; an injection nozzle 28; a plunger pump 29; a plunger 30; a connecting rod 31; a hydraulic cylinder 32; a second conveyor belt 33; a syrup 34; a gel candy 35; a motor 36.

Detailed Description

The present invention is further described in detail below with reference to the attached drawings so that those skilled in the art can implement the utility model by referring to the description text.

It should be noted that in the description of the present invention, the indicated orientation or positional relationship is based on the orientation or positional relationship shown in the drawings, and is only for convenience of describing the present invention and simplifying the description, and does not indicate or imply that the indicated device or element must have a specific orientation, be constructed and operated in a specific orientation, and thus, should not be construed as limiting the present invention.

As shown in fig. 1 to 5, the present invention provides a high efficiency gel candy casting machine, comprising:

the first conveying belt 1 is arranged on the rack 2;

a plurality of molds 3 provided on the first conveyor belt 1; the top surface of any mould 3 is provided with at least one mould cavity 4 for forming the gel candy 35; a cooling cavity 5 vertical to the conveying direction of the first conveying belt 1 is horizontally arranged on any one die 3; any cooling cavity 5 and any die cavity 4 are not interfered with each other, and the die 3 is made of heat conducting materials, including copper or aluminum and the like;

the liquid separating rod 6 is horizontally and rotatably arranged on the rack 2 and is vertical to the conveying direction of the first conveying belt 1; the liquid separating rod 6 is provided with a liquid inlet flow channel 8 for communicating one end of each cooling cavity 5 with a liquid outlet of the condensing mechanism 7 and a liquid outlet flow channel 9 for communicating the other end of each cooling cavity 5 with a liquid inlet of the condensing mechanism 7, and the refrigerants comprise water, glycol and the like.

In the technical scheme, the rotation of the liquid separating rod 6 is synchronous with the transmission of the first conveying belt 1, and any cooling cavity 5 is always communicated with the condensing mechanism 7 through the liquid inlet channel and the liquid outlet channel of the liquid separating rod 6 to form a circulating passage; the cooling refrigerants (including water, ethylene glycol and the like) of the condensation mechanism 7 continuously enter the liquid inlet flow channel 8, then flow into all the cooling cavities 5 in a sub-flow mode, flow from one end of each cooling cavity 5 to the other end of each cooling cavity, then enter the condensation mechanism 7 from the other end of each cooling cavity 5 through the liquid outlet flow channel 9, and are cooled in the condensation mechanism 7 to form a refrigerant circulation channel; the cooled refrigerant continuously flows from one end of the cooling cavity 5 to the other end, and continuously takes away the heat of the mold 3 in the process to forcibly cool the mold 3; the cooling cavity 5 in the mold 3 is always communicated with the condensing mechanism 7 through the liquid separating rod 6 by adopting an annular rotation mode to form effective closed-loop rotation, the mold 3 is continuously and forcibly cooled, the cooling efficiency is high, the gel candy 35 molded by casting can be rapidly cooled and demolded, the molding and demolding time is short, and the production efficiency is effectively improved; meanwhile, the using amount of the die 3 is reduced, the equipment is smaller, the occupied area is reduced, and the investment of a workshop and the die 3 is greatly reduced.

In another technical scheme, one end of the liquid inlet flow channel 8 is positioned in the liquid separating rod 6 and is communicated with one end of any cooling cavity 5 through a first liquid inlet pipe 10, the other end of the liquid inlet flow channel extends along the axial direction of the liquid separating rod 6 and penetrates through the end face of one end of the liquid separating rod 6, the other end of the liquid separating rod 6 is fixedly connected with the output end of a motor, and the motor drives the liquid separating rod 6 to rotate;

the side wall of the liquid distribution rod 6 close to one end of the liquid distribution rod protrudes outwards along the radial direction of the liquid distribution rod to form an annular bump 11, an annular groove is formed in the end face of one end, close to the liquid distribution rod 6, of the bump 11 to form the liquid outlet channel 9, and the bottom of the liquid outlet channel 9 is communicated with the other end of any cooling cavity 5 through a first liquid outlet pipe 12;

one end of the liquid distribution rod 6 is provided with a liquid distribution block 13, and the liquid distribution block 13 is fixedly arranged on the rack 2 and does not limit the rotation of the liquid distribution rod 6; a first groove 14 is formed in one end face, close to the bump 11, of the liquid separation block 13, and a second groove 15 is formed in the bottom of the first groove 14; one end of the liquid separation rod 6 penetrates through the first groove 14 and is inserted into the second groove 15, the side wall of the liquid separation rod 6 is in sealing contact with the side wall of the second groove 15, and the side wall of the projection 11 is in sealing contact with the side wall of the first groove 14; the first groove 14 is communicated with a liquid outlet of the condensing mechanism 7 through a second liquid inlet pipe 16; the second groove 15 is communicated with a liquid inlet of the condensing mechanism 7 through a second liquid outlet pipe 17;

the cooling refrigerant of the condensing mechanism 7 continuously enters the first groove 14 through the second liquid inlet pipe 16, then enters the liquid inlet flow channel 8 from the other end of the liquid inlet flow channel 8, is then divided from one end of the liquid inlet flow channel 8, enters the cooling cavity 5 through the first liquid inlet pipe 10, one cooling cavity 5 is correspondingly provided with one first liquid inlet pipe 10, in any cooling cavity 5, the cooling refrigerant flows from one end to the other end of the cooling cavity 5, then is converged into the liquid outlet flow channel 9 through the first liquid outlet pipe 12 from the other end of the cooling cavity 5, then enters the second groove 15, and finally enters the condensing mechanism 7 through the second liquid outlet pipe 17 for cooling, so that a refrigerant circulating passage is formed; for any mould 3, the condensing mechanism 7, the second liquid inlet pipe 16, the first groove 14, the liquid inlet flow channel 8, the first liquid inlet pipe 10, the cooling cavity 5, the first liquid outlet pipe 12, the liquid outlet flow channel 9, the second groove 15 and the second liquid outlet pipe 17 are communicated with one another to form a refrigerant circulating passage, and the cooled refrigerant continuously and forcibly cools the mould 3, so that the cooling efficiency is high;

the liquid separating rod 6 is driven by a motor, the rotation of the liquid separating rod is synchronous with the transmission of the first conveying belt 1, and the first liquid inlet pipe 10 and the first liquid outlet pipe 12 rotate along with the liquid separating rod 6 and are communicated with the liquid inlet flow channel 8, the liquid outlet flow channel 9 and the cooling cavity 5 corresponding to the liquid inlet flow channel and the liquid outlet flow channel all the time; divide liquid piece 13 to set firmly in frame 2, through first recess 14 and second feed liquor pipe 16 with feed liquor runner 8 and condensation mechanism 7 intercommunication, through second recess 15 and second drain pipe 17 with feed liquor runner 9 and condensation mechanism 7 intercommunication, second feed liquor pipe 16 and second drain pipe 17 all nonrotation, refrigerant circulation route communicates all the time, can effectively avoid the damage of pipeline and divide liquid pole 6 pivoted influence, and then be favorable to further improving cooling efficiency and production efficiency.

In another technical scheme, a first sealing ring 18 is arranged between the side wall of the liquid separating rod 6 and the side wall of the second groove 15, and a second sealing ring 19 is arranged between the side wall of the projection 11 and the first groove 14; the sealing performance between the liquid separating rod 6 and the liquid separating block 13 is further improved, the circulation of a refrigerant is effectively guaranteed, and the cooling efficiency and the production efficiency are further improved.

In another technical scheme, a top bar 20 is correspondingly arranged on one mold cavity 4, a through hole 21 is arranged on the bottom surface of any mold cavity 4, one end of any top bar 20 is positioned at the inner side of the first conveyor belt 1, the other end of any top bar extends towards the direction close to the corresponding mold cavity 4 and perpendicular to the bottom surface of the mold cavity 4, and the top bar 20 can pass through the through hole 21; any ram 20 can move axially along it; through promoting ejector pin 20, make ejector pin 20's the other end pass through-hole 21, realize the quick drawing of patterns of fashioned gel candy 35 in die cavity 4, avoid gel candy 35 can not normally be demolded, further ensured drawing of patterns efficiency and effect, and then be favorable to improving production efficiency.

In another technical scheme, a plurality of spring cavities 22 are arranged on the bottom surface of any one of the dies 3, one spring cavity 22 is correspondingly arranged in one die cavity 4, and the other end of any one of the ejector rods 20 passes through the corresponding spring cavity 22 and extends towards the corresponding die cavity 4 in a direction perpendicular to the bottom surface of the die cavity 4; a limiting block 23 is fixedly sleeved on one ejector rod 20, any limiting block 23 is positioned in the spring cavity 22 corresponding to the limiting block 23, and any spring cavity 22 does not limit the movement of the limiting block 23; one spring cavity 22 is internally and correspondingly provided with one spring 24, any spring 24 is sleeved on the thimble corresponding to the spring cavity, one end of any spring 24 is connected with the end surface of the spring cavity 22 corresponding to the spring 24, which is close to one end of the die cavity 4, and the other end of the spring 24 is connected with the limiting block 23 corresponding to the spring cavity; a stop block 25 is correspondingly arranged on one stop block 23, any stop block 25 is fixedly arranged on the bottom surface of the corresponding die 3, one end of any ejector rod 20 passes through the corresponding stop block 25 and extends to the inner side of the first conveying belt 1, and any stop block 25 does not limit the movement of the corresponding ejector rod 20 along the axial direction; any limiting block 23 is abutted with the corresponding stop block 25; when the demolding is not needed, under the action of the spring 24, the limiting block 23 is abutted against the stop block 25, and the other end of the ejector rod 20 does not protrude out of the bottom surface of the mold cavity 4; when demoulding is needed, the ejector rod 20 is pushed, the other end of the ejector rod 20 penetrates through the through hole 21, rapid demoulding of the gel candy 35 formed in the die cavity 4 is achieved, at the moment, the spring 24 is compressed, the limiting block 23 is separated from the stop block 25, and after the pushing force disappears, the limiting block 23 is abutted against the stop block 25 again under the action of the spring 24; through stopper 23, baffle 40, spring 24's cooperation, ejector pin 20 can follow its axial displacement, and does not break away from with mould 3 all the time, and stable in structure and removal are smooth and easy, have further ensured drawing of patterns efficiency and effect, and then are favorable to improving production efficiency.

In another technical solution, a pressing plate 26 is horizontally arranged at the lower part of the inner side of the first conveyor belt 1, the pressing plate 26 can move along the vertical direction, and the pressing plate 26 can be driven by an air cylinder to make the pressing plate 26 move up and down repeatedly along the vertical direction; when the pressure plate 26 moves upwards to the limit, the pressure plate 26 is not in contact with any ejector rod 20; when the pressing plate 26 moves downwards to the limit, the pressing plate 26 pushes the ejector rods 20 positioned right below the pressing plate 26, so that the other ends of the ejector rods 20 penetrate through the through holes 21, and the gel candies 35 molded in the mold cavity 4 are quickly demoulded; the movement of the pressing plate 26 is stable and quick, so that the demolding efficiency and the demolding effect are further guaranteed, and the improvement of the production efficiency is further facilitated.

In another technical scheme, at least one mold cavity 4 on any mold 3 comprises a plurality of mold cavity groups annularly arranged on the first conveying belt 1, and any mold cavity group comprises at least one mold cavity 4; the high-efficiency gel candy casting machine further comprises:

a pouring hopper 27 positioned directly above the first conveyor belt 1, the pouring hopper 27 containing syrup 34;

at least one material injection nozzle 28 arranged at the lower end of the pouring hopper 27, a plunger pump 29 is arranged in the material injection nozzle 28, and one material injection nozzle 28 is correspondingly arranged in one die cavity 4 of any die cavity group; a connecting rod 31 capable of moving along the vertical direction is arranged above the plunger pump 29, one end of the connecting rod 31 is fixedly connected with a plunger 30 of the plunger pump 29, and the other end of the connecting rod 31 vertically extends upwards to the upper part of the pouring hopper 27 and is connected with a piston rod of a hydraulic cylinder 32;

drive hydraulic cylinder 32, drive plunger 30 through connecting rod 31 and move from top to bottom, realize opening and closing of plunger pump 29 to the accurate nature of the pouring dosage of syrup 34 has been ensured to the dosage of the syrup 34 of control slip casting mouth injection corresponding die cavity 4, is favorable to guaranteeing the quality of gel candy 35, improves production efficiency.

In another technical scheme, the pouring hopper 27 is a temperature control hopper, so that the solidification of the syrup 34 can be effectively avoided, the accuracy of the pouring dosage can be further guaranteed, and the quality of the gel candy 35 can be further guaranteed.

In another technical solution, the device further comprises a second conveyor belt 33, which is arranged right below the first conveyor belt 1; for any cavity group, when the cavity group rotates to the bottom of the first conveying belt 1, the downward projection of any cavity 4 of the cavity group is contained on the second conveying belt 33; the second conveyer belt 33 is used for conveying the gel candies 35 after demoulding, which is beneficial to improving the production efficiency.

While embodiments of the utility model have been described above, it is not limited to the applications set forth in the description and the embodiments, which are fully applicable in various fields of endeavor to which the utility model pertains, and further modifications may readily be made by those skilled in the art, it being understood that the utility model is not limited to the details shown and described herein without departing from the general concept defined by the appended claims and their equivalents.

Claims

1. High-efficient gel candy casting machine which characterized in that includes:

the first conveying belt is arranged on the rack;

2. The high efficiency gel candy casting machine as claimed in claim 1,

one end of the liquid inlet flow channel is positioned in the liquid separating rod and is communicated with one end of any cooling cavity through a first liquid inlet pipe, and the other end of the liquid inlet flow channel extends along the axial direction of the liquid separating rod and penetrates through the end face of one end of the liquid separating rod;

3. The high efficiency jelly confectionery pouring machine of claim 2 wherein a first sealing ring is disposed between the side wall of the dispensing lever and the side wall of the second groove and a second sealing ring is disposed between the side wall of the projection and the first groove.

4. The high-efficiency gel candy pouring machine as claimed in claim 1, wherein a top bar is correspondingly arranged in one mold cavity, a through hole is arranged on the bottom surface of any mold cavity, one end of any top bar is positioned at the inner side of the first conveying belt, the other end of any top bar extends towards the direction close to the mold cavity corresponding to the top bar and perpendicular to the bottom surface of the mold cavity, and the top bar can pass through the through hole; any of the carrier rods is movable in the axial direction thereof.

5. The high efficiency jelly confectionery pouring machine of claim 4 wherein a plurality of spring cavities are provided on the bottom surface of any one of the molds, one spring cavity is provided for each mold cavity, and the other end of any one of the lift pins extends through the corresponding spring cavity toward the corresponding mold cavity in a direction perpendicular to the bottom surface of the mold cavity; a limiting block is fixedly sleeved on the ejector rod, any limiting block is positioned in the spring cavity corresponding to the ejector rod, and the movement of the limiting block is not limited by any spring cavity; one spring is correspondingly arranged in one spring cavity, any spring is sleeved on the thimble corresponding to the spring cavity, one end of any spring is connected with the end surface of one end, close to the mold cavity, of the spring cavity corresponding to the spring cavity, and the other end of the spring is connected with the limiting block corresponding to the spring cavity; one limiting block is correspondingly provided with a stop block, any stop block is fixedly arranged on the bottom surface of the corresponding die, one end of any ejector rod penetrates through the corresponding stop block and extends to the inner side of the first conveying belt, and the any stop block does not limit the axial movement of the corresponding ejector rod; any limiting block is abutted with the corresponding stop block.

6. The high efficiency gel candy casting machine as claimed in claim 5 wherein the lower portion of the inside of said first conveyor belt is horizontally provided with a platen, said platen being movable in a vertical direction.

7. A high efficiency gel candy casting machine as claimed in claim 1 wherein the at least one cavity in any one of the molds comprises a plurality of cavity groups looped around the first conveyor, each cavity group comprising at least one cavity; the high-efficiency gel candy casting machine further comprises:

8. The high efficiency jelly confectionery casting machine of claim 7 wherein the casting hopper is a temperature controlled hopper.

9. The high efficiency gel candy casting machine of claim 7 further comprising a second conveyor belt positioned directly below said first conveyor belt; for any cavity group, when the cavity group rotates to the bottom of the first conveying belt, the downward projection of any cavity of the cavity group is contained on the second conveying belt.