CN111746185A

CN111746185A - Automatic fashioned ice carving manufacture equipment

Info

Publication number: CN111746185A
Application number: CN202010659122.7A
Authority: CN
Inventors: 吴兵来
Original assignee: Individual
Current assignee: Individual
Priority date: 2020-07-09
Filing date: 2020-07-09
Publication date: 2020-10-09
Anticipated expiration: 2040-07-09
Also published as: CN111746185B

Abstract

The invention discloses an automatic-forming ice sculpture manufacturing device which comprises a shell, wherein a water injection cavity is arranged in the shell, and a first connecting groove penetrates through the left wall of the water injection cavity; the invention has simple structure and convenient use, adopts a mode of mold water injection cooling to replace the cutting and polishing of the traditional cutter, reduces the manufacturing cost of equipment, is also provided with the storage box, can put the formed ice sculpture into the storage box for storage, can remind a user through the prompting lamp after a large number of ice sculptures are stored in the storage box, can completely take out the ice sculpture in the storage box by the user, improves the defect that one ice sculpture needs to be taken out when one ice sculpture is manufactured in the existing equipment, can move the storage box to the outer side of the equipment when the ice sculpture is taken out, does not need the user to deeply take the ice sculpture in the equipment by hand, and avoids the phenomenon of frostbite.

Description

Automatic fashioned ice carving manufacture equipment

Technical Field

The invention relates to the technical field of ice sculpture manufacturing, in particular to automatic forming ice sculpture manufacturing equipment.

Background

The ice sculpture is an artistic form which uses ice as a main material to carve. Modern ice sculpture is widely used, including festival celebration decorate with ice sculpture, notes wine ice sculpture, wedding ice-breaking ice sculpture, ice sculpture experience marketing etc. various use forms, and along with more and more occasions begin to use the ice sculpture, also have different requirements to the manufacture process of ice sculpture.

At first, the ice sculpture is manually carved, but the time required for carving one ice sculpture in the mode is too long, the required cost is relatively high, the existing automatic ice sculpture manufacturing equipment still needs a specially-assigned person to take care of, the formed ice sculpture is taken out after the ice sculpture is manufactured, and then the ice sculpture is put in for manufacturing the next ice sculpture.

Disclosure of Invention

The invention aims to provide an automatic forming ice sculpture manufacturing device which is used for overcoming the defects in the prior art.

According to the invention, the automatic forming ice sculpture manufacturing equipment comprises a shell, a water injection cavity is arranged in the shell, a first connecting groove penetrates through the left wall of the water injection cavity, a moving device for controlling the movement of a mold is arranged on the left side surface of the shell, a water injection device for injecting water into the mold is arranged on the top wall of the water injection cavity, a first moving cavity is arranged on the right side of the water injection cavity, a speed reducer for reducing the falling speed of the mold is arranged in the first moving cavity, the water injection cavity is communicated with the first moving cavity through a second connecting groove, a cooling cavity is arranged below the first moving cavity, the cooling cavity is communicated with the first moving cavity through a third connecting groove, a first rack plate is slidably connected with the third connecting groove, a second moving cavity is arranged below the cooling cavity, and the cooling cavity is communicated with the second moving cavity through a fourth connecting groove, the fourth connecting groove is connected with a second rack plate in a sliding manner, the right side of the cooling cavity is provided with a refrigerating pump through a gas pipe in a communicating manner, the left side of the cooling cavity is provided with a first rotating cavity, the first rotating cavity is internally provided with a linkage device for controlling the first rack plate and the second rack plate to move, the second moving cavity is internally provided with a first conveying device, the first conveying device extends rightwards to a storage cavity penetrating and arranged in the right side surface of the shell, the bottom wall of the storage cavity is internally provided with a first sliding groove, the first sliding groove is connected with a base in a sliding manner, the top surface of the base is fixedly provided with a storage box, the left side and the right side of the storage box are provided with a second sliding groove in a penetrating manner, the bottom wall of the second sliding groove is fixedly provided with a button, the front wall and the rear wall of the second sliding groove are symmetrically provided with four, two around the movable plate has set firmly between the first link block, be equipped with in the movable plate and control the movable plate is in the detent that removes in the second spout, the bin right side run through in the storage chamber roof and be equipped with the closure the third rack board in storage chamber, third rack board top is equipped with the handle, third rack board bottom with store the contact of chamber bottom wall.

Optionally, the stopping device includes a first rotating groove disposed in the front and rear side surfaces of the moving plate and opposite to the rack, a first rotating shaft is rotatably connected between the left and right walls of the first rotating groove, a first gear is fixedly disposed on the first rotating shaft, the left side surface of the first gear is fixedly connected to the left side of the first rotating groove through a first coil spring sleeved on the first rotating shaft, and the first coil spring can prevent the moving plate from automatically falling into the bottom of the second sliding groove due to the influence of gravity.

Optionally, the mobile device including set firmly in the rotation case of shell left surface, it rotates the chamber to rotate the incasement, the second rotates the intracavity and is equipped with the second conveyor that extends to right in the water injection intracavity and with second connecting groove bottom surface smooth connection.

Optionally, the water injection device comprises a water tank fixedly arranged on the top surface of the housing, a water outlet pipe extending into the water injection cavity is arranged on the bottom surface of the water tank, and a control pump is arranged on the water outlet pipe.

Optionally, the reduction gear includes a rotating belt, the front and rear positions of the rotating belt are symmetrically arranged on the left and right walls of the first moving cavity, a rotating block is fixedly arranged on the rotating belt, a second rotating groove penetrates through the rotating block, a baffle is rotationally connected in the second rotating groove, the baffle is fixedly connected with the second rotating groove through a second coil spring, a first linkage cavity is arranged on the right side of the first moving cavity, a second rotating shaft is rotationally connected between the front and rear walls of the first linkage cavity, first bevel gears are symmetrically arranged on the front and rear positions of the second rotating shaft, a third rotating shaft in the rotating belt extends into the first linkage cavity, and a second bevel gear meshed with the first bevel gear is fixedly arranged at the tail end of the right side of the third rotating shaft.

Optionally, the aggregate unit including set firmly in the first motor that rotates the chamber top surface, the fourth axis of rotation is installed to the motor bottom surface, the second gear has set firmly in the fourth axis of rotation, first rack plate extends to first rotation chamber and in flank of tooth meshing before the second gear, the fourth axis of rotation with set firmly in first fixed block on the first rotation chamber right wall rotates and is connected, fourth axis of rotation bottom and first ratchet meshing, first ratchet bottom surface with first rotation chamber diapire between through fifth axis of rotation fixed connection, the fifth axis of rotation with set firmly in second fixed block on the first rotation chamber right wall rotates and is connected, the fifth axis of rotation has set firmly the third gear, the second rack plate extend to first rotation intracavity and with flank of tooth meshing before the third gear, the third gear bottom surface with between the first rotation chamber diapire through the cover the fixed coil spring of the last third of fifth axis of rotation And (4) connecting.

Optionally, a third rotating cavity is arranged behind the storage cavity, a sixth rotating shaft is rotatably connected between the left wall and the right wall of the third rotating cavity, a fourth gear meshed with the third rack plate is fixedly arranged on the sixth rotating shaft, a third bevel gear is fixedly arranged on the left side of the fourth gear, a seventh rotating shaft is rotatably connected to the bottom wall of the third rotating cavity, the seventh rotating shaft is rotatably connected to a fourth fixed block fixedly arranged on the front wall of the third rotating cavity, a fourth bevel gear meshed with the third bevel gear is fixedly arranged at the top end of the seventh rotating shaft, a fifth gear is fixedly arranged on the seventh rotating shaft, a rack extending into the third rotating cavity is arranged on the rear side surface of the base, and the rack is meshed with the front tooth surface of the fifth gear.

Optionally, a prompting lamp is fixedly arranged on the upper surface of the shell and controlled by the button, a sensor is fixedly arranged on the right wall of the first linkage cavity and can control the motor and the cooling pump to start, and the sensor can also control the second conveying device to pause.

The invention has the beneficial effects that: the invention has simple structure and convenient use, adopts a mode of water injection and cooling of the die to replace the cutting and polishing of the traditional cutter, and reduces the manufacturing cost of the equipment. Meanwhile, the ice sculpture forming device is also provided with a storage box, the formed ice sculpture can be placed in the storage box for storage, when a large number of ice sculptures are stored in the storage box, a user can be reminded through the prompting lamp, and at the moment, the user can take out all the ice sculptures in the storage box, so that the defect that one ice sculpture needs to be taken out when being made in the conventional equipment is overcome.

The rack plate is moved to control the storage box to move in gear transmission, when a user wants to take out the ice sculpture, the storage box can move to the outer side only by pulling up the rack plate, the user can take out the ice sculpture conveniently, the user does not need to take the ice sculpture deeply into equipment by hands, and the phenomenon of frostbite is avoided.

Drawings

The technical solution in the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention; it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all embodiments, and all other embodiments obtained by those skilled in the art without any inventive work are within the scope of the present invention.

FIG. 1 is a schematic structural diagram of an automatic forming ice sculpture manufacturing device of the present invention;

FIG. 2 is a schematic view of the structure at A-A in FIG. 1;

FIG. 3 is a schematic view of the structure at B-B in FIG. 1;

FIG. 4 is an enlarged schematic view of the conveyor belt of FIG. 2;

FIG. 5 is an enlarged view of the cooling chamber of FIG. 1;

FIG. 6 is a schematic diagram of the structure at E-E in FIG. 1;

fig. 7 is an enlarged view of the structure at F-F in fig. 1.

Detailed Description

In the description of the present invention, it should be noted that the terms "upper", "lower", "inner", "outer", "top/bottom", and the like indicate orientations or positional relationships based on those shown in the drawings, and are only for convenience of description and simplification of description, but do not indicate or imply that the referred device or element must have a specific orientation, be constructed in a specific orientation, and be operated, and thus should not be construed as limiting the present invention. Furthermore, the terms "first" and "second" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

Referring to fig. 1 to 7, an automatic forming ice sculpture manufacturing apparatus according to an embodiment of the present invention includes a housing 1, a water injection cavity 26 is provided in the housing 1, a first connecting groove 2 is provided in a left wall of the water injection cavity 26, a moving device 101 for controlling movement of a mold is provided on a left side surface of the housing 1, a water injection device 102 for injecting water into the mold is provided on a top wall of the water injection cavity 26, a first moving cavity 22 is provided on a right side of the water injection cavity 26, a speed reduction device 103 for reducing a falling speed of the mold is provided in the first moving cavity 22, the water injection cavity 26 is communicated with the first moving cavity 22 through a second connecting groove 30, a cooling cavity 7 is provided below the first moving cavity 22, the cooling cavity 7 is communicated with the first moving cavity 22 through a third connecting groove 53, the third connecting groove 53 is slidably connected with a first rack plate 52, a second moving cavity 9 is provided below the cooling cavity 7, the cooling chamber 7 is communicated with the second moving chamber 9 through a fourth connecting groove 51, a second rack plate 50 is slidably connected with the fourth connecting groove 51, the right side of the cooling chamber 7 is provided with a refrigerating pump 49 through a gas pipe 17, the left side of the cooling chamber 7 is provided with a first rotating chamber 37, the first rotating chamber 37 is internally provided with a linkage device 104 for controlling the first rack plate 52 and the second rack plate 50 to move, the second moving chamber 9 is internally provided with a first conveying device 10, the first conveying device 10 extends rightwards to a storage chamber 11 arranged in the right side surface of the shell 1 in a penetrating way, the bottom wall of the storage chamber 11 is internally provided with a first chute 16, the first chute 16 is slidably connected with a base 12, the top surface of the base 12 is fixedly provided with a storage box 55, the storage box 55 is provided with a second chute 56 in a penetrating way, and a button 14 is fixedly arranged on the bottom wall of the second chute 56, position symmetry has set firmly four racks 13 on the wall behind 56 second spout, controls two be equipped with third spout 15 between the rack 13, sliding connection has first connecting block 57 in the third spout 15, two in the front and back movable plate 19 has set firmly between the first connecting block 57, be equipped with in the movable plate 19 and control movable plate 19 is in detent 105 of removal in the second spout 56, bin 55 right side run through in the 11 roof in storage chamber and be equipped with the closure the third rack board 18 of storage chamber 11, third rack board 18 top is equipped with handle 20, third rack board 18 bottom with store 11 diapire contacts in the chamber.

Preferably, the stopper 105 includes a first rotation groove 46 disposed in the front and rear sides of the moving plate 19 and opposite to the rack 13, a first rotation shaft 8 is rotatably connected between the left and right walls of the first rotation groove 46, a first gear 44 is fixedly disposed on the first rotation shaft 8, the left side of the first gear 44 is fixedly connected to the left side of the first rotation groove 46 through a first coil spring 45 sleeved on the first rotation shaft 8, and the first coil spring 45 can prevent the moving plate 19 from automatically falling to the bottom of the second sliding groove 56 due to the influence of gravity.

Preferably, the moving device 101 includes a rotating box 4 fixedly disposed on the left side surface of the housing 1, a second rotating cavity 5 is disposed in the rotating box 4, a second conveying device 3 extending rightward into the water injection cavity 26 and being smoothly connected to the bottom surface of the second connecting groove 30 is disposed in the second rotating cavity 5, when ice carving is required, a mold is placed on the second conveying device 3, the mold is conveyed into the water injection cavity 26 by the second conveying device 3 to be injected into the mold, a user only needs to place the mold on the second conveying device 3 from the second rotating cavity 5, and the mold is automatically conveyed into the device by the second conveying device 3 to be ice carved.

Preferably, the water injection device 102 comprises a water tank 24 fixedly arranged on the top surface of the housing 1, a water outlet pipe 23 extending into the water injection cavity 26 is arranged on the bottom surface of the water tank 24, a control pump 25 is arranged on the water outlet pipe 23, after the mold enters the water injection cavity 26, the control pump 25 is started to control quantitative water to be injected into the mold from the water tank 24 through the water outlet pipe 23, the amount of water injected into the mold can be changed through the control pump 25, and the requirement of different water amounts required by molds of different shapes can be met.

Preferably, the speed reducer 103 includes a rotating belt 27 disposed on the left and right walls of the first moving cavity 22 at a front-rear position, the rotating belt 27 is fixedly provided with a rotating block 32, a second rotating groove 29 penetrates through the rotating block 32, a baffle 31 is rotatably connected in the second rotating groove 29, the baffle 31 and the second rotating groove 29 are fixedly connected through a second coil spring 36, the right side of the first moving cavity 22 is provided with a first linkage cavity 32, a second rotating shaft 33 is rotatably connected between the front and rear walls of the first linkage cavity 22, a first bevel gear 34 is symmetrically disposed on the second rotating shaft 33 at a front-rear position, a third rotating shaft 28 in the rotating belt 27 extends into the first linkage cavity 32, a second bevel gear 35 engaged with the first bevel gear 34 is fixedly disposed at the right end of the third rotating shaft 28, and when the mold is transported into the first linkage cavity 22 by the second transporting device 3, the mold falls into the baffle 31, because the bottom surface of the baffle 31 is contacted with the bottom surface of the second rotating groove 29 and can not rotate, the rotating block 32 can drive the rotating belt 27 to rotate under the gravity action of the mold, when the baffle 31 on the inner side of the rotating belt 27 moves to the lowest position, the rotating belt 27 can continue to rotate for a certain distance due to inertia, when the baffle 31 is blocked by the bottom wall of the first linkage cavity 22 and rotates towards the second rotating groove 29, so as to prevent the rotating belt 27 from being blocked and jammed due to the blocking of the bottom wall of the first linkage cavity 22 by the baffle 31, after the rotating belt 27 stops rotating, another baffle 31 originally positioned on the outer side of the rotating belt 27 moves to the inner side of the conveying belt 27, the next mold can be lifted, and when the baffle 31 on the front side moves downwards, the baffle 31 on the front side drives the rotating belt 27 on the front side to rotate through the rotating block 32 on the front side, then the front third rotating shaft 28 is driven to rotate by the front rotating belt 27, the front third rotating shaft 28 is driven to rotate by the front second bevel gear 35, the front first bevel gear 34 is driven to rotate by the front second bevel gear 33, the rear first bevel gear 34 is driven to rotate by the rear second bevel gear 35, the rear third rotating shaft 28 is driven to rotate by the rear third bevel gear 27, the rear rotating belt 27 is driven to rotate by the rear second bevel gear 35, the rear rotating belt 31 is driven to move downward by the rear rotating block 32, the front baffle 31 and the rear baffle 31 move downward synchronously, and it is ensured that the molds on the baffles 31 do not tilt.

1. Preferably, the linkage device 104 includes a motor 39 fixedly disposed on the top surface of the first rotating cavity 37, a fourth rotating shaft 48 is mounted on the bottom surface of the motor 39, a second gear 38 is fixedly disposed on the fourth rotating shaft 48, the first rack plate 52 extends to the first rotating cavity 37 and engages with the front tooth surface of the second gear 38, the fourth rotating shaft 48 is rotatably connected with a first fixing block 40 fixedly disposed on the right wall of the first rotating cavity 37, the bottom end of the fourth rotating shaft 48 is engaged with a first ratchet wheel 41, the bottom surface of the first ratchet wheel 41 is fixedly connected with the bottom wall of the first rotating cavity 37 through a fifth rotating shaft 42, the fifth rotating shaft 42 is rotatably connected with a second fixing block 43 fixedly disposed on the right wall of the first rotating cavity 37, a third gear 47 is fixedly disposed on the fifth rotating shaft 42, the second rack plate 50 extends into the first rotating cavity 37 and engages with the front tooth surface of the third gear 47, the bottom surface of the third gear 47 is fixedly connected with the bottom wall of the first rotating cavity 37 through a third coil spring 67 sleeved on the fifth rotating shaft 42, when the motor 39 is started, the motor 39 drives the second gear 38 to rotate through the fourth rotating shaft 48, the second gear 38 drives the first rack plate 52 to move left and right, when the first rack plate 52 moves right, the fourth rotating shaft 48 cannot drive the fifth rotating shaft 42 to rotate through the first ratchet wheel 41, so the second rack plate 50 does not move, when the first rack plate 52 moves left, the fourth rotating shaft 48 can drive the fifth rotating shaft 42 to rotate through the first ratchet wheel 41, the fifth rotating shaft 42 drives the third gear 47 to rotate, the third gear 47 drives the second rack plate 50 to move left, and when the motor 39 stops, the third gear 47 can rotate under the action of the third coil spring 67, so that the second rack plate 50 is driven to move rightwards, the cooling cavity 7 can be sealed after the first rack plate 52 moves rightwards, the cooling effect of the refrigeration pump 49 on a mold in the cooling cavity 7 is improved, and the forming speed of ice sculpture is increased.

Preferably, a third rotating cavity 61 is arranged behind the storage cavity 11, a sixth rotating shaft 64 is rotatably connected between the left wall and the right wall of the third rotating cavity 61, a fourth gear 66 engaged with the third rack plate 18 is fixedly arranged on the sixth rotating shaft 64, a third bevel gear 65 is fixedly arranged on the left side of the fourth gear 66, a seventh rotating shaft 60 is rotatably connected to the bottom wall of the third rotating cavity 61, the seventh rotating shaft 60 is rotatably connected with a fourth fixed block 62 fixedly arranged on the front wall of the third rotating cavity 61, a fourth bevel gear 63 engaged with the third bevel gear 65 is fixedly arranged at the top end of the seventh rotating shaft 60, a fifth gear 59 is fixedly arranged on the seventh rotating shaft 60, a rack 58 extending into the third rotating cavity 61 is arranged on the rear side surface of the base 12, the rack 58 is engaged with the front tooth surface of the fifth gear 59, when the third rack plate 18 is manually pulled upwards, the third rack plate 18 drives the sixth rotating shaft 64 to rotate through the fourth gear 66, the sixth rotating shaft 64 drives the fourth bevel gear 63 to rotate through the third bevel gear 65, the fourth bevel gear 63 drives the fifth gear 59 to rotate through the seventh rotating shaft 60, the fifth gear 59 drives the base 12 to move through the rack 58, ice sculptures stored in the storage box 55 can be moved out of the equipment, selection among a plurality of ice sculptures is facilitated for a user, the distance between the base 12 and the third rack plate 18 is shortened compared with the actual distance, and the base 12 does not collide with the third rack plate 18 in the actual moving process.

Preferably, a warning light 21 is fixedly arranged on the upper surface of the housing 1, the warning light 21 is controlled by the button 14, a sensor 54 is fixedly arranged on the right wall of the first linkage cavity 22, the sensor 54 can control the motor 39 and the cooling pump 49 to be started, the sensor 54 can also control the second conveying device 3 to pause and operate, when the button 14 is pressed, the warning light 21 is turned on, and when the sensor 54 detects that the mold falls down, the motor 39 is controlled to be started.

In the initial state, the first coil spring 45 is in an unstressed state, the second coil spring 36 is in an unstressed state, the third coil spring 67 is in an unstressed state, the first rack plate 52 is completely withdrawn from the third connecting groove 53, the second rack plate 50 is completely positioned in the fourth connecting groove 51, and the base 12 is positioned at the leftmost end of the first sliding groove 16.

When ice carving work is required, a user places a mold on the second conveying device 3, the second conveying device 3 conveys the mold into the water injection cavity 26, then the control pump 25 is started, a controlled amount of water is injected into the mold from the water tank 24 through the water outlet pipe 23, then the mold is conveyed into the first linkage cavity 22 by the second conveying device 3 and falls on the baffle 31, then the mold moves downwards along with the baffle 31, enters the cooling cavity 7 through the third connecting groove 53 and falls on the second rack plate 50, at this time, after the sensor 54 detects that the mold falls, the motor 39 is controlled to be started, the first rack plate 52 is driven to move rightwards to completely enter the third connecting groove 53, the cooling cavity 7 is closed, and meanwhile, the sensor 54 controls the refrigerating pump 49 to be started, and cooling the mold to complete the making work of the ice sculpture in the mold, and at the same time, the second conveying device 3 is temporarily stopped to run, and when the making work of the ice sculpture in the cooling cavity 7 is completed, the second conveying device 3 is restarted.

When the ice sculpture needs to be accessed, after the ice sculpture in the mold is formed, the refrigerating pump 49 stops working and the motor 39 rotates reversely, and at the same time, the first rack plate 52 and the second rack plate 50 are controlled to move leftwards, the mold falls on the first conveying device 10 and is conveyed to the storage cavity 11 by the first conveying device 10 and is stored in the storage box 55, the mold falls on the moving plate 19 after leaving the first conveying device 10, but because the first gear 44 in the moving plate 19 is acted by the first coil spring 45, the mold falls on the moving plate 19 and carries the moving plate 19 to move downwards for a certain distance and then stops, after the next mold falls on the moving plate 19, the moving plate 19 continues to move downwards for a certain distance, and after the moving plate 19 moves downwards and presses the button 14, the button 14 controls the indicator light 21 to light up to inform a user that the movable plate 19 is full of molds and can be taken out;

the handle 20 is manually held and the third rack plate 18 is pulled up, the base 12 can be driven by the rack 58 to move, so as to drive the storage box 55 to move, and then the ice sculpture stored in the storage box 55 can move out of the equipment along with the storage box 55, so that the ice sculpture can be taken out.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the invention, and any modifications, equivalents, improvements and the like that fall within the spirit and principle of the present invention are intended to be included therein.

Claims

1. The utility model provides an automatic fashioned ice carving manufacture equipment, includes the shell, be equipped with water injection chamber in the shell, its characterized in that: a first connecting groove penetrates through the left wall of the water injection cavity, a moving device for controlling the movement of the mold is arranged on the left side face of the shell, a water injection device for adding water into the mold is arranged on the top wall of the water injection cavity, a first moving cavity is arranged on the right side of the water injection cavity, a speed reducer for reducing the falling speed of the mold is arranged in the first moving cavity, the water injection cavity is communicated with the first moving cavity through a second connecting groove, a cooling cavity is arranged below the first moving cavity, the cooling cavity is communicated with the first moving cavity through a third connecting groove, the third connecting groove is slidably connected with a first rack plate, a second moving cavity is arranged below the cooling cavity, the cooling cavity is communicated with the second moving cavity through a fourth connecting groove, a second rack plate is slidably connected in the fourth connecting groove, and a refrigeration pump is arranged on the right side of the cooling cavity through a gas pipe, the left side of the cooling cavity is provided with a first rotating cavity, the first rotating cavity is internally provided with a linkage device for controlling the first rack plate and the second rack plate to move, the second moving cavity is internally provided with a first conveying device, the first conveying device extends rightwards to a storage cavity arranged in the right side face of the shell in a penetrating manner, the bottom wall of the storage cavity is internally provided with a first chute, the first chute is internally provided with a base in a sliding manner, the top surface of the base is fixedly provided with a storage box, the left side and the right side of the storage box are provided with second chutes in a penetrating manner, the bottom wall of the second chute is fixedly provided with a button, the front wall and the rear wall of the second chute are symmetrically provided with four racks, a third chute is arranged between the left rack and the right rack, the third chute is internally provided with a first connecting block in a sliding manner, a moving plate is fixedly arranged between the front connecting block and the rear connecting block, the bin right side it seals to run through being equipped with in the storage chamber roof the third rack board of storage chamber, third rack board top is equipped with the handle, third rack board bottom with store the contact of chamber bottom wall.

2. The automatic molding ice sculpture manufacturing equipment as recited in claim 1, wherein: stop device including set up in side around the movable plate in and with the relative first rotating groove in rack position, it is connected with first axis of rotation to rotate between the wall about first rotating groove, first gear has set firmly on the first axis of rotation, first gear left surface with through the cover between the first rotating groove left side first epaxial first coil spring fixed connection, first coil spring can prevent the movable plate falls into because gravity influences is automatic second spout bottom

The automatic molding ice sculpture manufacturing equipment as recited in claim 1, wherein: the mobile device including set firmly in the rotation case of shell left surface, it rotates the chamber to rotate the incasement, the second rotates the intracavity and is equipped with right extension to the water injection intracavity and with second connecting groove bottom surface smooth connection's second conveyor.

3. The automatic molding ice sculpture manufacturing equipment as recited in claim 1, wherein: the water injection device comprises a water tank fixedly arranged on the top surface of the shell, a water outlet pipe extending into the water injection cavity is arranged on the bottom surface of the water tank, and a control pump is arranged on the water outlet pipe.

4. The automatic molding ice sculpture manufacturing equipment of claim 4, wherein: the speed reducer comprises a rotating belt, the front position and the rear position of the rotating belt are symmetrically arranged on the left wall and the right wall of the first movable cavity, a rotating block is fixedly arranged on the rotating belt, a second rotating groove penetrates through the rotating block, a baffle is rotationally connected in the second rotating groove, the baffle is fixedly connected with the second rotating groove through a second coil spring, a first linkage cavity is arranged on the right side of the first movable cavity, a second rotating shaft is rotationally connected between the front wall and the rear wall of the first linkage cavity, first bevel gears are symmetrically arranged on the front wall and the rear wall of the second rotating shaft, a third rotating shaft in the rotating belt extends into the first linkage cavity, and a second bevel gear meshed with the first bevel gears is fixedly arranged at the tail end of the right side of the third rotating shaft.

5. The automatic molding ice sculpture manufacturing equipment as recited in claim 1, wherein: the linkage device comprises a motor fixedly arranged on the top surface of the first rotating cavity, a fourth rotating shaft is arranged on the bottom surface of the motor, a second gear is fixedly arranged on the fourth rotating shaft, the first rack plate extends to the first rotating cavity and is meshed with the front tooth surface of the second gear, the fourth rotating shaft is rotatably connected with a first fixed block fixedly arranged on the right wall of the first rotating cavity, the bottom end of the fourth rotating shaft is engaged with the first ratchet wheel, the bottom surface of the first ratchet wheel is fixedly connected with the bottom wall of the first rotating cavity through a fifth rotating shaft, the fifth rotating shaft is rotatably connected with a second fixed block fixedly arranged on the right wall of the first rotating cavity, a third gear is fixedly arranged on the fifth rotating shaft, the second rack plate extends into the first rotating cavity and is meshed with the front tooth surface of the third gear, and the bottom surface of the third gear is fixedly connected with the bottom wall of the first rotating cavity through a third coil spring sleeved on the fifth rotating shaft.

6. The automatic molding ice sculpture manufacturing equipment as recited in claim 1, wherein: a third rotating cavity is arranged behind the storage cavity, a sixth rotating shaft is rotatably connected between the left wall and the right wall of the third rotating cavity, a fourth gear meshed with the third rack plate is fixedly arranged on the sixth rotating shaft, a third bevel gear is fixedly arranged on the left side of the fourth gear, a seventh rotating shaft is rotatably connected to the bottom wall of the third rotating cavity, the seventh rotating shaft is rotatably connected with a fourth fixed block fixedly arranged on the front wall of the third rotating cavity, a fourth bevel gear meshed with the third bevel gear is fixedly arranged at the top end of the seventh rotating shaft, a fifth gear is fixedly arranged on the seventh rotating shaft, a rack extending into the third rotating cavity is arranged on the rear side face of the base, and the rack is meshed with the front tooth face of the fifth gear.

7. The automatic molding ice sculpture manufacturing equipment of claim 6, wherein: the shell upper surface has set firmly the warning light, the warning light receives button control, set firmly the sensor on the first linkage chamber right wall, the sensor can control the motor with the cooling pump starts, the sensor also can control second conveyor operation of suspending.